PIPE DRAFTING ANDDESIGN
ToKathy I am my beloved's, and my beloved is mine. Roy
ToMary Thank you for your help and support. Robert
PIPE DRAFTING ANDDESIGN THIRD EDITION RoY
A. PARISHERAND
RoBERT
A.
A.MSTERDAM • BOSTON • HEIDELBERG • LONOON NEW YORK • OXFORD • PARIS • SAN DIEGO SAN FRANCISCO • SINGAPORE • SYDNEY • lOKYO Gulf Professional Publishing is an imprinl oí Elsevier
RHEA
Gulf Professional Publishing is an imprint of Elsevier 225 Wyman Street, Waltham, MA 02451, USA Toe Boulevard, Langford Lane, Kidlington, Oxford, OX5 lGB, UK First edition 1995 Second edition 2001 Third edition 2012 Copyright© 2012 Elsevier Inc. Ali rights reserved
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Contents
Preface vii Acknowledgments ix About the Authors xi
Chapter 4 Flange Basics Raring Flanges 56 Flange Facings 56 Flange Types 58 Boles 65 Gaskets 67 Chapter 4 Review Quiz 71 Exercise Information 71 Chapter 4 Drawing Exercises
Chapter 1 Overview of Pipe Drafting and Design Types of Projects 1 Employers of Pipe Drafters and Designers 1 Engineering and Construction Companies 1 Operating Companies 2 Architectural Enginecring Companies 2 Construction Companies 2 Fabrication Companies 2 Prepararion for Piping Drafring 2 Technical Skills 2 Personal Skills 3 Creation of Pipe Drawings 3
Chapter 5 Valves What is a Valve? 79 Common Valve Types 79 Valve Operators 91 Chapter 5 Review Quiz 96 Exercise Informarion 96 Chaprer 5 Drawing Exercises
Types of Equipment 112 Mechanical Equipment Descriptions Equipment in Use 124 Equípment Terminology 125 Vendor Data Drawings 128 Drawing Equipment 128 Chapter 6 Review Quiz 133 Chapter 6 Drawing Exercises 133
4
Píping Marerials 4 Manufacturing Methods 4 Sizing of Pipe 5 Wall Thickness 5 Mechods of Joining Pipe 6 Cast Iron Pipe 9 Plasric Pipe 1 O Drawing Pipe 11 Chapter 2 Review Quia 11
123
Chapter7 Flow Diagrams and lnstrumentation Uses of Flow Diagrams 134 Type of Flow Diagrams 134 Flow Diagram Instruments 135 Flow Diagram Drawing Symbols 138 Flow Plan Arrangemenr 139 Chapter 7 Review Quiz 146 Exercise Information 146 Chapter 7 Drawing Exercises 148
Chapter 3 Pipe Fittings 90º Elbows 14 45° Elbows 20 Weld Tee 22 The Srub-in 30 Coupling 32 Reducers 32 WeldCap 36 Use of Firtings 36 Screwed and Socket-Weld Fittings 38 Pipe Nipples 43 Flanged Fittings 44 Cast Iron Firtíngs 45 Plastic Fittings 45 Fitting Exercise Instructions and Information Chapter 3 Review Quu 47 Chapter 3 Drawing Exercises 48
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Chapter 6 Mechanical Equipment
Chapter 2 Steel Pipe Hísrorv of Pipe
73
Chapter 8 Codes and Specifications Codes 154 Specíficatíons 154 General Piping Specífications Specíficatíon Classes 158 Abbreviations 159 Piping Abbreviations 166 Chapter 8 Review Quiz 169
45
V
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vi Chapter 9 Equipment Layout Plant CoordinareSystem 170 Plant Elevations l 70 Site Plans 176 Unit Plor Plan 176 EquipmentLocarion Drawing 176 Foundation Location Drawing 176 Piping Drawinglndex 176 Chapter 9 Review Quíz 182 Chapter 9 DrawingExercises 183
Chapter 1 O Piping Arrangement Drawings, Sections, and Elevations Arrangement Drawings 186 Responsibilítiesof che Pipíng Designer 186 lnformationSources for Piping Arrangement Drawings 186 Layout Procedures 187 Píping ArrangementDrawingLayout 187 Dimensioning 233 Piping Sections and Elevations: What Are They? 233 Detail Drawings 237 Pipe Line List 23 7 Chapter 10 ReviewQuía 241 Exercises: Plans, Elevatíons, and Sections 241
Chapter 11 Standard Piping Details Pipe Rack Spacing 242 Drawing Pipe in The Rack 242 Pipe Flexíbiliry 243 Planning for Heat Expansion 244 Pipe Anchors 246 Pipe lnsulation Shoes 247 Pipe Guides 247 Pipe Spans 247 Pipe Supports 248 Field Supports 248 DummySupports 250 Hanger Rods 25 l Spring Hangers 25 l Píck-up Pipe Supports 25 l Chapter 11 Review Quiz 258
Chapter 12 Piping Systems Plant Utilities 259 Control Valve Manifolds 260
Uríliry Starions 262
Meter Runs 263 Sewerand Underground Piping Svsrems 266 Chapcer 12 Review Quiz 267 Chapter 12 Exercises 267
Chapter 13 Piping lsometrics What is an lsometric? 269 lsometric Orientation 272 Drawing Piping Isometrics 275 lsometric Dimensions,Notes, and Callouts 278 IsometricOffsets 278 Chapter 13 Review Quíz 288 Chapter 13 DrawingExercises 289
Chapter 14 Building 3D Piping Models Advantagesof 3D Modeling 307 Checking for lnterferences 307 Generating DrawingsAutomaticallyfrom a Model 311 Generating Isometric Drawings Automatically 312 Computer-AidedEngineeringof Models 312 Choosing a ModelingSoftwarePackage 314 Building a 3D Model Using PDMS 314
Chapter 15 Project Coordination Processand lnstrument Diagrams 342 Piping Arrangement Drawingswith Elevations 345 Foundation and Equipment Location Drawings 352 Mechanical Equipment: Vender Drawings 358 Mechanical Equipment: Footings, Foundations, and Pedestals 378 Main Pipe Rack and Miscellaneous Pipe Supports: Plans, Elevations, and Derails 390 Electrical Drawings: Lightingand PowerSupply and Grounding Plan 395 3D Model Views: Units 01-04 403
Appendix A: Dimensional Data 408 Appendix B: Alphabet of Lines 448 Appendix C: Review of Math 449 Appendix D: Use of the Calculator 450 Appendix E: Architect's Scale 453 Glossary 454 lndex 461
Preface
Pipe Drafting and Design, Third Edition provides step-by-step instructions to walk pipe designers, drafters and students through the creation of flow diagrams, piping arrangement and isometric drawings. It includes instructions for the proper drawing of symbols for fittings, flanges, valves and mechanical equipment found on various types of piping drawings. More than 350 illustrations and photographs provide examples and visual instructions. A unique feature is the systematic creation and arrangement of drawings that begins with the development of a flow diagram then progresses to the layout of the structural and equipment foundations of a piping facility. Once mechanical equipment has been positioned and oriented the piping components are added. The text continues through to the development of a 3D model. Advanced chapters díscuss the use of 3D software tools from which elevation, section and isometric drawings, and bilis of materials are extracted.
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New to this edition • A large-scalefour-Unit imaginary project that includes Flow diagrams, Foundation Location, Equipment Location, and Piping Arrangement drawings, as well as structural steel drawings and details, civil/foundation details, equipment vendar drawings, and electrical Power, Lighting, and Grounding Plans for each Unit. • Updated discussion and use of modem CAD and 3D software tools • Additional exercisers, drawings and dimensioning charts to provide practice and assessment. Ancillaries: For instructors, an educational support package is available that contains a set of electronic images of figures in the book, and solutions to the end of chapter problem sets. The files are available to instructors by registering at: http://textbooks.elsevier.com/web/ Manuals.aspx?isbn=9780123847003.
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Acknowledgments
Nicole Blythe: AutoCAD 3D model Michael F. Fox: San Jacinto College Central R. B. Herrscher: Nisseki Chemical Texas, Inc. Alan Human: Flexitallic, Inc. Kenneth Kluge: PDMS 3D model lrv Levine: AVEVA,Inc. Heather Marquis: PDMS 3D model and www.learnpdms.com tutorials Roger Parisher: Hodell-Natco, Inc.
included for their instructional value. They have been proofed for accuracy but are not guaranteed for any particular purpose. Toe publisher and authors do not offer any representations or warranties, nor do they accept any liabilities with respect to the material, applications, procedures, dímensíoning charts, and/ or routines. Trademarks AutoCAD® is registered in the U.S. Patent and Trademark office by Autodesk, Inc. PDMS® is a registered trademark of AVEA, Inc. an AVEVA Group ple company.
Toe material, applications, procedures, dimensioning charts, and routines presented in this book have been
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About the Authors
Roy A. Parisher is a professor in the engineeríng design graphics department at San Jacinto College Central in Pasadena, Texas, where he has taught for over 30 years.
Robert A. Rhea is a former associate professor of engineering technology at the University of Houston Downtown, Houston, Texas.
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CHAPTER
1 Overview of Pipe Drafting and Design
In the design of an industrial facility, engineers develop process flow sheets, set up project specifications, and design or select equipment. Toe design drafters use the information supplied by engineers and equipment vendors and apply the knowledge and experience gained in the office and field to design and lay out the facility. In the design and layout of an industrial complex, thousands of piping drawings are needed to provide detailed information to the craftsmen who will construct the facility. Facility design and layout must meet the customer's expectations as well as comply with safety codes, government standards, client specifications, budget, and start-up date. Toe piping group has the main responsibility for the design and layout of the facility. Drafters and desígners must coordinate their efforts with the civil, structural, electrical, and instrumentation groups throughout the design process. Toe piping group must provide all other design groups with the information they need to complete their part of the project. This timely 'sharing' of information will guarantee the complete set of construction drawíngs will be finished on schedule. Duríng this time, it may be necessary for designers to visit the plant construction site to establish tie-ins or verify information necessary to complete the design.
• • • • • • •
Many projects will be designed for construction in other countries, offering the designer opportunities for travel. Each project presents drafters and designers with opportunities to expand their skills and knowledge of the field of piping design.
EMPLOYERSOF PIPE DRAFTERS ANO DESIGNERS Employers seek to hire pipe drafters and designers range for various companies. Among them are • • • • •
TYPES OF PROJECTS
engineering and construction companies; operating companies; architectural firms; construction companies; fabrication companies.
ENGINEERING ANO CONSTRUCTION COMPANIES
Toe pipe drafting and design discipline includes the widest range of opportunities in the field of design drafting. Toe types of design projects one could expect to work on may include • • • • •
pharmaceutical plants; food and beverage processíng plants; synthetic fuel plants; offshore platforms; pipe line installations; water treatment facilities; environmental waste disposal.
Engineering and construction companies provide the design and layout of a facility. Many clients award the engineering and design phase of a project to one firm and the construction phase to another. Although many operating companies have a small engineering staff who handle the day-to-day needs of changing and updating drawings, such as adding a pump or other small equipment, they do not have the manpower to design and engineer a grassroots plant or major add-on, Total plant design and
power plants; petrochemical complex; pulp and paper plants; fertilizer plants; pipe systems for hospitals and high-ríse office buildings;
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1. OVERVIEW OF PIPE DRAFTING ANO DESIGN
construction may require hundreds of workers and may entail years in the design and construction of the plant.
OPERATING COMPANIES Operating companies are the clients who engage in the day-to-day operation of a facility and who seek out the services of engineering and construction firms when expanding existing facilities or constructing a new project. Many operating companies keep a small engineering staff in the home office or at the plant job site. Designers are exposed to the day-to-day operations of the facility and follow the construction of small projects. This situation may require that the designer have a broad range of knowledge and skills, as he or she often may be asked to desígn and lay out the complete project. The design may prepare foundation, steel, and piping drawings as needed, and may even do sorne electrical and instrumentation design when requíred.
ARCHITECTURAL ENGINEERING COMPANIES Pipe drafters and designers employed by architectural engíneering companies apply theír skills to commercial and high-rise buildings. These may include multistory office buildings, hospítals, condominiums, shopping malls, or other similar structures. In addition to the industrial piping components such as those found in a typícal boiler room, supplementary píping systems must be desígned for plumbing, HVAC (heating, ventilating, and air conditioning), and drainage systems that are also required in these structures. Pipe drafters and designers must therefore be able to develop drawíngs such as • • • • •
piping flow sheets; plot plans; equipment location drawings; piping arrangement drawings; píping isometric drawings.
purchasing; material control; material takeoff; estimating; pipe stress and pipe supports; computer-aided drafting (CAD) support; project management.
Many firms specialize only in the construction of plants. Here the piping designer may actually help oversee the construction of the facility while working under the supervisíon of a constructíon superintendent. The designer is often called upon to make small design changes resulting from mistakes discovered during the construction phase or as customers dictate changes. At the completion of the project, drawings are updated to reflect the many changes made duríng construction. These drawings are called or referred to as "as-built" drawings.
FABRICATION COMPANIES Fabrication companies fabricate and ship much of the pípíng necessary for the construction of the plant to the job site. Many fabrication drawings called piping spool drawings must be prepared. These drawings give detailed dimensions from which welders can fabricate the pipe. The drafter who prepares these drawings will not be required to have an extensive background in plant layout; however, the positíon provides the drafter with valuable experience in materials and material scíence.
PREPARATION FOR PIPING DRAFTING Students must have a good background in basic drafting before pursuing a job in the field of pipe drafting and design. Students should have good manual drafting skills related to line quality and freehand lettering. At the same time, students must acquire knowledge of the latest drafting software programs such as AutoCAD1 and MicroStation2. As students advance, they may use sophisticated three-dimensional (3D) software programs that automatícally generate plotted drawíngs and isometrics from a 3D model.
TECHNICAL SKILLS
Leaming the "language" of piping prepares employees for advancement to other departments within the engineering firms. These departments include not only the drafting and desígn departments but also • • • • • • •
CONSTRUCTION COMPANIES
A pipe drafter must become familiar with the numerous symbols used to represent fittings, flanges, valves, and mechanical equipment. This will requíre the time and effort needed to draw the symbol shapes by searchíng through catalogs and dimensioning charts in order to find the síze dimensíons needed to draw each piping component to scale. Often beginning drafters start out making corrections to existing drawings. This is where 1 Autodesk.
Inc,
2Bentley Systems, Inc,
PIPE DRAFTING ANO DESIGN
CREATION OF PIPE DRAWl1'GS
they acquire the skills and knowledge of piping that will allow them to advance to the position of piping designer. Drafters who have held field positions as pipe fitters or welders find this real-world experience valuable. Many times this experience allows them to advance ata faster pace.
PERSONAL SKILLS Students should not neglect their speaking, writing, and math skills. Every company appraises future employees during the interview process not only for technical skills but also for the personal skills needed to interact with the engineering team. This interaction is a must for the team in order to complete the job with a minimal amount of rnistakes. Honesty, reliability, dedication to improving skills, and a positive attitude contribute much to the successful career of the designer. You will be a member of a design team. You may work with people from countries all over the world. Getting along with fellow workers has much to do with successful yearly evaluations and compensation for your efforts.
CREATION OF PIPE DRAWINGS Manual Drafting Though new piping projects are no longer developed by hand, or manually, old vellum, mylar, and even cloth drawings are still in existence. As time perrnits and funds exist, companies are gradually converting their "hard copy" drawings into electronic files. But when older facilities that were originally drawn manually need to be revamped, desígners and drafters may still find the need to use traditional drafting techniques. Manual drafters use a variety of triangles, plastic templates (circle and ellipse), and scales to lay out pípíng drawings. Although electric erasers are not necessary, they make the job of erasing much easier and faster. Pencils and leads come in a wide range of sizes and shapes. Drafters usually use a 4H lead to draw projection lines and guidelines, and use an H or F lead for other line work and lettering needs. Line thickness also
3
has an important role in piping drawings. A 0.7mm or wider lead holder is commonly used on major elements of the drawing such as pipe and lettering. Background components such as equipment, foundations, support structures, and dimension lines are typically drawn with a 0.Smm lead. One cannot stress enough the importance of quality line work and lettering. Manual drawings are constantly slid in and out of the file drawers and run through blueprint machines. This requires that lettering and line work be neat and of good quality to maintain clarity of dimensions and callouts.
CAD Software Tools There are many different CAD software tools on the market today. Many engineering companies require their designers to know and use several different CAD software tools. Engineering companies must be prepared to accommodate the client's preference of CAD programs. To be competitive in the job market, the pipe drafter must leam how to use AutoCAD and/ or MicroStation. These two CAD programs are widely used by engineering firms in the United States and throughout the world. As with CAD programs, there are several 30 pipe modeling software programs on the market today. Engineering firms must be responsive to the needs and preferences of their clients. Software developers steadily develop, revise, and refine programs to meet the demands of engineering and design firms. As with any business trying to attract new customers, software developers try to incorporate special features, functions and amenities into their software programs that will attract potential users. Often clients will dictate that all bid packages subrnitted for a project shall be completed using a particular piping software program. Most piping software packages provide the end user with the ability to develop 30 computer models of the completed facility. Software packages such as PDMS3, PDS4, SmartPlant3D4, CADWorx4, PLANT-4D5, and MPDS46, among others have the intelligence to generate not only 30 renderings with walk-through animations but also dimensioned and annotated 20 drawings as well as dimensioned isometrics with a complete Bill of Materials.
3AVEVAGroup
ple. Corporation Part of Hexagon Group. 5CEA Systems, Inc. 6CAD Schroer GmbH. 4Intergraph
PIPE DRAFTING AND DESIGN
CHAPTER
2 Steel Pipe
HISTORY OF PIPE
MANUFACTURING METHODS
Long ago someone discovered that carrying water from the nearby stream back to his or her dwelling was time-consuming and laborious. Ingenuity gave birth to invention and the pipe was bom. Using the natural resources available, early humans probably fashioned the first pipe from bamboo. Needing to move larger amounts of water, they later hollowed out logs. Egyptian and Aztec civilizations made pipes from clay. Toe first metallic pipes were made from lead and bronze by the Greeks and Romans. Toe use of iron as a material to manufacture pipe carne about with the invention of gun powder. Gun powder, of course, is not used to make the iron, but gun powder necessitated the invention of stronger gun barrels. lron pipes soon followed. Eventually, exotic metals were developed, and the pipe became the highly specialized product it is toda y.
Carbon steel pipe can be manufactured using severa! different techniques, each of which produces a pipe with certain characteristics. These characteristics include strength, wall thickness, corrosion resistance, and temperature and pressure limitations. For example, pipes having the same wall thickness but manufactured by different methods may vary in strength and pressure limits. Toe pipe manufacturing methods to be discussed include: seamless, butt-welded, and spiral-welded, Seamless pipe is formed by piercíng a solid, nearmolten, steel rod, called a billet, with a mandrel to produce a pipe that has no seams or joints. Figure 2.1 depicts the manufacturing process of seamless pipe. Butt-welded pipe is formed by feeding a hot steel plate through shapers that will roll it into a hollow circular shape. Forcibly squeezing the two ends of the plate together will produce a fused joint or seam. Figure 2.2 shows the steel plate as it begins the process of forming butt-welded pipe. Least common of the three methods is spiral-welded pipe. Spiral-welded pipe is formed by twisting strips of metal into a spiral shape, similar to a barber's pole, then welding where the edges join one another to form a seam. This type of pipe is restricted to piping systems using low pressures due to its thin walls. Figure 2.3 shows spiral-welded pipe as it appears before welding. Figure 2.4 shows the three pipes previously described in their final forros. Each of the three methods for producing pipe has its advantages and disadvantages. Butt-welded pipe, for example, is formed from rolled plate that has a more uniform wall thickness and can be inspected for defects prior to forming and welding. This manufacturing method is particularly useful when thin walls and long lengths are needed. Because of the welded seam, however, there is always the possibility of defects that
PIPING MATERIALS Applied in a general sense, pipe is a term used to designate a hollow, tubular body used to transport any commodity possessing flow characteristics such as those found in liquids, gases, vapors, liquefied solids, and fine powders. A comprehensive list of the materials used to manufacture pipes would be quite lengthy. Sorne of the materials include concrete, glass, lead, brass, copper, plastíc, aluminum, cast iron, carbon steel, and steel alloys. With such a broad range of materials available, selectíng one to fit a particular need can be confusing. A thorough understanding of the pipe's intended use is essential. Each material has limitations that may make it inappropriate for a gíven application. Throughout this text, we will base our discussion on carbon steel pipe, the most common material used in the piping industry. 4
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WALL TIIICKKESS
SIZING OF PIPE
Mondrel
FIGURE 2.1 Sizing seamless pipe.
Just as manufacturing methods differ, there are also different ways to categorize the size of a pipe. Pipe is identified by three different size categories: nominal pipe size, outside diameter, and inside diameter (see Figure 2.5). Nominal pipe size (NPS) is used to describe a pipe by name only. It is essentially a "reference" size and does not translate to an exact diameter measurement of pipes 12'' and smaller. In process piping, the term nominal simply refers to the name of the pipe, much like a 2" X 4" piece of lumber. A 2" X 4'' board does not actually measure 2 X 4", nor does a 6 pipe actually measure 6" in diameter. lt is just a convenient and easy way to identify pipe andlumber. Outside diameter (OD) and inside diameier (ID), as their names imply, categorize pipes by their true outside and inside measurements. One of the complexities of pipe design is that different sizes of ,Pipes are manufactured differently. Pipe sizes (NPS) Vs through 12" have an outside diameter greater than its nominal pipe size, whereas pipe sizes 14" and above have an outside diameter equal to its nominal pipe size. In process piping, the aforementioned method of sizing the pipe maintains a uniform outside diameter while varying the inside diameter. This method achieves the desired strength necessary for the pipe to perform its intended function while operating under various temperatures and pressures. 11
Pipe FIGURE 2.2 Shaping butt-welded pipe.
11
1
FIGURE 2.3 Forming spiral-welded pipe.
WALL THICKNESS StAMLESS
ROLLE O
SPIRAL-WELD
FIGURE 2.4 Manufactured carbon steel pipe.
escape the numerous quality control checks performed during the manufacturing process. As a result, the American National Standards Institute (ANSI) developed strict guidelines for the manufacture of pipe. Pressure Pípíng Code 831 was written to govem the manufacture of pipe. In particular, code 831.1.0 assigns a strength factor of 85% for rolled pipe, 60% for spiral-welded pipe, and 100% efficiency for seamless pipe. Generally, wider wall thicknesses are produced by the seamless method. However, for the many low-pressure uses of pipe, the continuous welded method is the most economical. Seamless pipe is produced in single and double random lengths. Single random lengths vary from 16'-0" to 20'-0". Pipes 2 and below are found in double random lengths measuring from 35' -0" to 40'-0". 11
Wall thickness is the term used to describe the measurement of how thick the metal is that a pipe is made from. There are three systems in which a pipe's wall thickness can be categorized: the weight system, the schedule system, and the fractional/ decimal system. The weight system uses three categories to define the thickness of a pipe: standard, extra strong, and double extra strong. Limited in number, these three pipe thicknesses restricta pipe designer's options. Over time, pipe selection has increased in complexity. With the development of new chemical processes, the methods of manufacturing pipe have expanded to meet process requirements. Such a wide array of commodity possíbilities, with their ever changing corrosive properties and their extreme range of temperature and pressure variances, has necessitated the manufacture of pipe in additional wall thicknesses. Now called sched ules, these additional wall thicknesses allow a designer to specify a particular pipe that will meet the exact requirements needed for quality installation and safe
PIPE DRAFTING AND DESIGN
6
2. STEEL PIPE
O.O. O.O.= 1.0.=
OUTSIOE OIAMETER INSIOE OIAMETER
FIGURE 2.5 Pipe measurements.
operation. Pipe, depending on the diameter, is manufactured in the following schedules: 10, 20, 30, 40, 60, 80, 100, 120, 140, and 160. Toe third system of categorizing wall thickness is to simply measure the thickness in either a fractional or decimal value. No matter which method is used to categorize a pipe's wall thickness, it will not affect the OD of a pipe. OD is a set value that will not change. As wall thickness increases or decreases, it is the inside díameter that adjusts. An example of this variance in wall thickness is shown in Figure 2.6. As you can see in Table 2.1, nominal size is not equal to the actual OD or the ID for pipe 12" and smaller. lt is simply a convenient method to use when referring to pipe. As a piping drafter, you should be aware however that pipe 14" and larger is identified by its actual outside measurement. Toe chart in Table 2.1 shows typical pipe diameters and wall thicknesses. Toe following formula can be used to calculate a pipe's inside diameter (ID): ID
= OD -
6" NOMINAL PIPE SIZE
O.O.
a
6.625" (ACTUAL SIZE)
xxs
EXTRA STROHC
DOUBLE EXTRA STRONC
FIGURE 2.6 Pipe weight and wall thicknesses.
flow rates needed to adequately supply the commodity at its prescribed rate and pressure. Buying and installing pipe that does not meet the mínimum requirements can be dangerous and deadly. Conversely, "overdesigning" with pipe that far exceeds what is necessary to do the job can result in tremendous cost overruns.
(2 x Wali Thickness)
Before selecting pipe, careful consideration must be gíven to its material, temperature and pressure allowanees, corrosion resistance, and more. Toe process engineer will need to pay careful attention to the flow requirements of a pipe used for a particular process. Toe pressures and temperatures of a commodity in a pipe may dictate its wall thickness. But with thick-wall pipe, the inside diameter may not permit the required
METHODS OF JOINING PIPE There are several methods for joining pipe together. Toe three methods we will focus on are those most widely used in piping systems made of carbon steel, as shown in Figure 2.7. They are butt-welded (BW), screwed (Scrd), and socket-weld (SW). Later in the chapter, cast iron and plastic pipe uses will be discussed.
PIPE DRAFTING ANO DESIGN
7
METIIODS OF JOINING PIPE
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....
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A butt-weld joint is made by welding the beveled ends of pipe together. Beveled ends (BE) indicate that the ends of the pipe are not cut square but are rather cut or ground to have a tapered edge. In preparation for the welding Yirocess, a welder will separate two pieces of pipe by a 1/ space, known as a root gap. During the weldinp process, the two ends are drawn together and the gap disappears. If two pieces of pipe 3' -0" long were welded together in this manner, the result would be a total length of 6' -O''. However, sometimes a backup ring is used in critical situations. Toe back-up ring is used when there is a need to prevent the formation of weld icicles inside the pipe. The back-up ring creates a gap of Ys11 between the two pieces of pipe. In this situation, the ring does not allow the ends of the pipe to be drawn together and keeps them separated by Ys". If two lengths of pipe measuring 3' -O'' each were welded together usíng a back-up ring, the result would be a total length of 6' -O Ys". In this instance, the Ys" gap would be shown when dimensioning the pipe . Otherwise, the root gap would not be considered at ali. Figure 2.8 shows the X/ root gap and the resulting butt-weld joint.
x6l
i:,..
e"'
..
,e
u
Screwed or Threaded Connections
-; .5
g z :§ "' "' ..,.
o
00
o
"'...
;:!:
- ... '°
00
Another common means of joining pipe is the threaded end (TE) connection. Typically used on
PIPE DRAFTING AND DESIGN
8
2. STEEL PIPE
TABLE 2.2 American Standard and API Thread Engagement Dirnensions Dimensions (in inches and millimeters) Pipe size
THREAD
ENGAGtMENT
· 1
1·
~IF-9 SCREWED
Thread engagement
(in.)
(mm)
(in.)
(mm)
;.,•
13
;.,•
13
3,4•
20
rit
14
1·
25.4
•xt
18
llh"
38
•Y.t
18
2·
50.8
3,4"
20
21h"
63.5
·r.t
24
3•
76.2
1·
25.4
TABLE 2.3 Forged Steel Socket-Weld Fitting Socket Depth Dirnensions Dimensions (in inches and millimeters) Pipe size
SOCKET WELD
Thread engagement
(in.)
(mm)
(in.)
(mm)
1h"
13
;.,•
13
3,4•
20
rit
14
1·
25.4
lW
38
o/s" 3A•
20
2·
50.8
7/s"
22
2~·
63.5
l1/s"
29
3•
76.2
13/8"
35
pipe 3" and smaller, threaded connections are generally referred to as screwed pipe. With tapered grooves cut into the ends of a run of pipe, screwed pipe and screwed fittings can be easily assembled without welding or other permanent means of attachment. Screwed pipe and its mating fittings will have threads that are either male or female. Male threads are cut into the outside of a pipe or fitting, whereas female threads are cut into the inside of the fitting. As screwed pipe and fittings are assembled, a short length of pipe is drawn into the fitting. This connection length is called a thread engagement. When drawing and dirnensioning screwed pipe, a piping drafter must be aware of this lost length of pipe. As the diameter of the pipe increases, so will the length of the thread engagement. Table 2.2 provides a chart indícatíng the thread engagements for small-bore pipe.
16
Socket-Weld Connections Toe third method of joining carbon steel pipe is socket welding. When assembling pipe with socketweld fittings, the pipe is inserted into the fitting before welding, unlike a butt-weld connection that has the pipe and fitting placed end to end. lnside the socketweld fitting is a collar that prevents the pipe from being inserted too deeply into the fitting. As with screwed connections, a short amount of pipe length is lost when the socket-weld connections are made. Table 2.3 provides the socket depths for pipe sizes through 3" in diameter. Befare the weld is made, the pipe fitter will back the pipe off the collar approxímately Ys" to allow for heat expansion during the welding procedure. Pipe used for socket-weld connections will be prepared with a plain end. Plain end (PE) means
PIPE DRAFTING ANO DESIGN
9
CAST IRON PIPE
SPIGOT END
LEAD
SPIGOT END
FIGURE 2.9 Cast iron pipe compression joint.
FIGURE 2.1 O Cast iron Jead and oakum joint.
the pipe is cut square, or perpendicular to, the long axis, unlike butt-weld fittings that have beveled ends.
wall. Considering the low cost of raw manufacturing materials and the relative ease of manufacture, cast iron is the least expensive of the engineering metals. These benefits make cast iron the choice application in environments that demand good corrosion resistance.
CAST IRON PIPE Not ali piping systems require pipes designed to withstand the extreme conditions found in process piping facilities. Cast iron pipe, which has been in use for centuries, is used primarily in gravity flow applications such as storm and sanitary sewers, and waste and vent piping installations. Residential, commercial, and industrial facilities routinely are built with sorne form of gravity flow systems. Toe corrosion resistance properties of cast iron pipe make it the ideal product for permanent below-ground gravity flow installations. Toe term cast iron refers to a large group of ferrous metals. Cast irons are primarily alloys of iron that contain more than 2% carbon and 1 % or more silicon. Cast iron, like steel, does corrode. What makes cast iron different is its graphite content. As cast iron corrodes, an insoluble layer of graphite compounds is produced. Toe density and adherent strength of these compounds form a barrier around the pipe that prevents further corrosion. In steel this graphite content does not exist, and the compounds created duríng corrosion cannot bond together. Unable to adhere to the pipe, they flake off and expose an unprotected metal surface that perpetuates the corrosion cycle. In tests of severely corroded cast iron pipe, the graphite compounds have withstood pressures of severa! hundred pounds per square inch, although corrosion had actually penetrated the pipe
Joining Cast lron Pipe Cast iron pipe is grouped into two basic categories: hub and spigot, and hubless. Toe hub, or bell, and spigot joint uses pipe with two different end types. Toe hub end of the pipe has an enlarged diameter, thus resembling a bell. Toe spigot end of the adjoining pipe has a flat or plain-end shape. Toe spigot is inserted into the bell to establish a joint. Two methods of preventing leaks on bell and spigot joints are compression and lead and oakum. Toe compression joint uses a one-píece rubber gasket to create a leak-proof seal. As shown in Figure 2.9, when the spigot end of the pipe is placed into the hub containing a gasket, the joint is sealed by displacing and compressing the rubber gasket. Unlike welded pipe, this joint can absorb vibration and can be deflected up to 5° without leakage or failure. Toe lead and oakum joint is made with oakum fiber and molten lead to create a strong, yet flexible, leakproof and root-proof joint. When the molten lead is poured over the waterproof oakum fiber, which is a loose, oil-laden, hemp-like packing material, the joint becomes completely sealed. Water will not leak out and, when used underground, roots cannot grow through the joints (see Figure 2.10).
PIPE DRAFTING AND DESIGN
10
2. STEEL PIPE
STAINLESS
STEEL
TABLE 2.4 Tabor Abrasion Test Results
RETAINING
CLAMP
Abrasion ring CS-10, load lkg
HUBLESS PIPE ,---,
'-'-----
,---, ,---, ,---, ,---, ,---, ,---, ,---,
1--------l
,---,
,---, ,---, ,---, ,---, ,---, ,---, ,---,
_,_,
STAINLESS STEEL SHIELD FIGURE 2.11 Cast iron hubless pipe coupling.
Hubless cast iron pipe uses pipe and fittings manufactured without a hub. Toe method of joining these pipe and fittings uses a hubless coupling that slips over the plain ends of the pipe and fittings and is tightened to seal the ends. Hubless cast iron pipe is made in only one wall thickness and ranges in diameter from 1 'h'' to 10 Figure 2.11 depicts the hubless cast iron pipe joint. 11•
PLASTIC PIPE Toe latest entry into the materials list for manufacturing pipe is plastic. Not orígínally thought of as a product capable of performing in the environs of a píping process facility, plastic has emerged as a reliable, safe, and cost-effective altemative material. There is a broad range of plastic compounds being developed toda y. For piping systems, two categories are most effective: fluoroplastics and thermoplastics. Fluoroplastics are found in materials like PTFE, PVDF, EC1FE, CTFE, PFA, and FEP. As a group, fluoroplastics perform extremely well in aggressive chemical services at temperatures from -328 to +SOOFº. Thermoplastics are those plastics that require melting during the manufacturing process. These plastics can be welded or injection molded into shapes for machining into pipíng system components.
Nylon 6-10
Smg/1,000 cycles
UHMWPE
s
PVDF
5-10
PVC (rigid)
12-20
pp
15-20
CPVC
20
CTFE
13
PS
40-50
Steel (304 55)
so
ABS
60-80 500-1000
PTFE
For sorne piping systems, it is now inconceivable not to use plastics. Pipes made from plastic are replacing traditional, expensive materials like glass or ceramiclined pipe. Sorne plastics such as UHMW PE, PVDF, CTFE, and nylon have such excellent wear resistance that they prove in Taber Abrasion Tests to be 5-10 times better in this regard than 304 Stainless Steel. Toe Taber Abrasion Test cycles an abrasíve wheel over the face of a plate made of the material being tested. After 1,000 cycles of the wheel, the plate is measured to determine the amount of weight loss. Table 2.4 lists the results.
Joining Plastic Pipe Plastic pipe can be joined by one of the followíng methods: threading, solvent cement, or fusion. Threading plastic pipe is not a viable option because it is expensive. Heavy wall thicknesses are required, and leaks from high pressures and expansion and contraetion are difficult to control. Joints made with solvent cement have proven more reliable. Though, once hardened, cemented joints cannot be disassembled. They offer good resistance to abrasive chemical and híghpressure commodities and are available in a Iarge selection of fittings without the need of threads. Heat fusion must be performed on sorne plastic compounds that are resistant to chemical solvents. Pipe can either be butt-joined or socket-joíned, Heat fusion can be used with thinner wall thicknesses and are pressure resistant beyond the burst pressure of the pipe. Socket fittings provide large surface contact between the pipe and the fittings and are resistant to separation. For this reason, they cannot be disassembled. Though fabrication with plastic may sound simple, caution must be exercised when using plastic pipe. Toe effectiveness of a particular grade of plastic must be
PIPE DRAFTING ANO DESIGN
11
CHAPTER 2 REVIEW QUIZ
DRAWING SYMBOLS FOR PIPE
NOTE:
l_
MANUAL DRAnlNG:
~5 j
DRAW PIPE TO THE NOMINAL PIPE SIZE.
CAD SOFTWARE:
SINGLE UNE PIPE 12" ANO SMALLER
3 ~
~
ENO VIEW
SINGLE UNE PIPE WITH INSULATION
DRAW PIPE TO THE NOMINAL PIPE SIZE.
2 "/H
30 MODELING SOFTWARE: DRAWS PIPE TO THE ACTUAL PIPE SIZE (OD).
OOUBLE UNE PIPE 14" ANO LARGER
OOUBLE UNE PIPE WITH INSULATION
FIGURE 2.12 Drawing representations of pipe.
tested before it is chosen for a particular service. Four important variables must be evaluated: chemical resistance, pressure limitations, temperature limitations, and stress. The various molecular components of plastics make them susceptible to chemical reactions with certain compounds. Hazardous mixtures must be avoided. Pressure and temperature Iimitations must be established for obvious reasons. Pipe that is overheated or pressurized beyond capacíty can rupture, split, or burst. Stress, as applied to pipe, entails physical demands such as length of service, resistance to expansion and contraction, and fluctuations in pressure and temperature. Excessive stresses in the form of restricted expansion and contraction, and frequent or sudden changes in interna! pressure and temperature must be avoided.
ENO VIEW
<>
When pipe is represented on a drawing, typically the pipe's nominal size dimension is used to identify pipe size. One would find it difficult to draw a 4" pipe to its actual outside diameter of 41h'', especíally on such a small scale as 3¡,;' = l '-0". There are certain applications, however, when the pipe's true outside diameter dimension is used to represent the pipe on a drawing. Drawings created with most software packages are an example. Piping software programs draw with such accuracy that pipe is drawn using the actual outside diameter. NOTE: Pipe created by means other ihan a piping soft ware program in this text will be draum using nominal sizee. Be auiare that drawings generaied by pipe modeling software programe such as PDMS1 and PDS2 will use actual outside dimensions and will differ slightly from manual and CAD generated drawings.
DRAWING PIPE
CHAPTER 2 REVIEW QUIZ
Toe pipe can be represented on drawings as either single line or double line. Toe pipe 12" and smaller is typícally drawn single line and the pipe 14" and larger is drawn double line. Single-line drawings are used to identify the centerline of the pipe. Double lines are used to represent the pipe's nominal size diameter. Toe standard scale used on piping drawings is W' = l '--0". Typically hand-drawn, single-line pipe is drawn with a 0.9mm ora double wide 0.7mm fine-line lead holder. When drawing single-line pipe with CAD software, a line havíng a width (lineweight) of approximately o/i:' is used on full-scale drawings. Toe doubleline pipe uses standard, or "default" line widths to draw the pipe's nominal size diameter. A centerline is used on all double-line pipes to allow for the placement of dimensions. Figure 2.12 provides severa! representations of pipe as it may appear on a drawing.
1. Name three methods of manufacturing carbon steel pipe.
2. Name the three most commonly used end preparations for joining pipe.
3. What is meant by the term nominal pipe size? I
Aveva Group, ple. Systems, Inc,
2 Bentley
PIPE DRAFTING AND DESIGN
12
2. STEEL PIPE
4. Which diameter of pipe varíes as the wall thickness changes?
8. What is the name for the amount of pipe "lost" when screwed connections are used?
5. What is the most common material used in the manufacture of pipe used in petrochemical facilities?
9. What is the standard scale piping drawíngs are plotted to?
6. When drawing pipe, which pipe sizes are drawn single-line and which sizes are drawn double-line? Síngle-líne Double-line _
10. Name three methods for joining carbon steel and plastic pipe.
7. How long is the gap between two lengths of pipe when a back-up ring separates them?
PIPE DRAFTING ANO DESIGN
CHAPTER
3 Pipe Fittings
Fittings are fabricated pipe components that are used to perform specific functions throughout the routing of a pipeline. Fittings can make directional changes (elbow), create a branch from a main pipe (tee), or make a reduction in the diameter of the pipe (reducer) (see Figure 3.1). Because fittings are part of the pipíng system, they must match as closely as possible in specification and rating to the pipe to which they are being attached. Fittings, like pipe, are manufactured and classified according to their wall thickness or schedule. There are many more wall thicknesses of pipe, however, than there are thicknesses of fittings. Fittings
are commercially manufactured in standard weight, extra strong, Schedule 160, and double extra strong categories. In the petrochemical industry, most companies have guidelines known as Piping Specifications that state pipes 3" in diameter and larger used in their facility will have butt-welded connections. These specifications, or specs as they are more commonly referred, may also require pipes smaller than 3" in diameter to have screwed or socket-weld connections. For uniformity, the previously mentioned specifications will be used throughout this book as a basis for determining pipe connection requirements. However, this is not to say this is the only spec
FIGURE 3.1 Fittings.
13
C, 2012 Ehcvic-r lnc. Ali rlghts rcserved.
14
3. PIPE FlITIKGS
that can be written. There may be cases where smallbore pipe configurations are butt-welded, whereas larger-size routings may be screwed or socket-weld.
90ºELBOWS
Notice the relationship between the nominal size and the length of the fitting. Toe 90º elbow's length is equal to the nominal pipe size plus onehalf of the nominal size. A simple formula that makes calculating this dimension easy to remember is: Fitting length equals 1~ times NPS (nominal pipe size). Example: Toe length of an 8 90º long-radíus elbow is 11
Of all the fittings, the elbow is the one most often used. Simply put, the elbow, or ell, is used when a pipe changes direction. Elbows can turn up, turn down, turn left, right, or any angle in between (see Figure 3.1). Toe 90º elbows can be classified as one of the following: • • • •
long-radíus elbow; short-radius elbow; reducing elbow; mitered elbow.
811 X l~ = 12"
NOTE: Use this formula Jor buttweld fittings only.
Long-Radius Elbow
Of these four types, the long-radius elbow, shown in Figure 3.2, is the one most com.monly used. When one finds it necessary to draw a 90° elbow or calculate how much space it will occupy in a routing configuration, knowing its length becomes essential. An elbow's length is commonly referred to as the cenierio end dimension and is measured from the centerpoint of its radius to the end of either opening (see Figure 3.3).
Dimensional sizes of fittings are typically provided by the manufacturer of the fitting. Manufacturers issue dimensioning charts containing lengths for a particular fitting. Toe dimensional chart used to establish sizes of fittings discussed in this text are listed on the Welded Fittings-Flanges Chart provided in Appendix A. For brevity, portions of that chart are used throughout this chapter when fitting measurements are needed. Use the 90º elbow portion of the Welded Fittings-Flanges Chart (Figure 3.4) to find the length of the fitting. In the thumbnail sketch on the left end of the chart, the A TO END
..
t O.D.
-t
_j_
112 X
NPS
_L..._.__.._ RAOIUS of L.R. elbow= 112 x NOMINAL PIPE Sil[.
FIGURE 3.2 Long-radius elbow.
FIGURE 3.3 Center-to-end dimension of a 90° long-radíus elbow.
@
NOMINAL PIPE SIZE -(INCHES)
2"
3"
4"
6"
8"
PIPE ( ÜUTSIDE
2j
3~ 412
6~8
si
1~4 1 2.J4 14"
9
12
15
V
90ºL.R.
D1AMETER)
EII
I
A
3
4~
FIGURE 3.4 Welded Fittings-Flanges Dimensioning Chart.
PIPE DRAFTING ANO DESIGN
6
1 o" 12"
18
14"
21
90ºELOOWS
15
-ElB
63
'3
ffi
o
(ff u? (íJ @¡ ~ ~ ~ tr1
V
'3
'3
-'4B FIGURE 3.5 90° Elbow rotations.
dirnension represents the length or center-to-end dimension of the elbow. To find the fitting's length (in inches), locate the appropriate pipe size in the row labeled Nominal Pipe Size (Inches). Below the nominal pipe size, in row A, the center-to-end dimension is shown. When drawing the elbow, the center-to-end dimension is used as the radius measurement for the elbow's centerline are. This measurement must be determined before the elbow can be drawn. In time, once the centerto-end dirnension formula is memorized, referencíng the Welded Fittings-Flanges Chart should no longer be necessary.
Drawing Symbols for the 90º Long ..Radius Elbow As with all drafting disciplines, symbols are used to represent real-world items on drawings. Like door symbols on an architectural floor plan or resistor symbols on an electronic schematic, piping symbols are developed to represent components uníque to the piping discipline. What makes the piping discipline so challenging is that all pipe components, whether they be fittings, flanges, or valves, have multiple symbols for each individual component. So a single elbow can have multiple representations. Lookíng at it from the side,
the top, or the end wil1 yield different symbol shapes. For example, the 90º long-radius elbow can be rotated in numerous orientations, as shown in Figure 3.5. As one can see, these rotations represent an elbow turning to the ríght, as well as it rolling toward (right and bottom orthographic views) and rolling away (left and top orthographic views) from the viewer. Toe drawing symbols for the 90º long-radius elbow are derived from these rotations. Another drawing technique unique to the piping discipline is that each component, depending on its pipe diameter, can be represented as eíther a single-line or double-line symbol. As with pipe, fittings that are 12" and smaller are drawn with single-line symbols and those 14" and above are drawn with doubleline symbols. Figure 3.6 shows the drawing symbols for the various orthographic views of a 90° elbow. To better visualize the long-radius elbow, a short length of pipe has been attached to each end of the elbow. This depicts how the elbow might appear if it were welded to a run of pipe. Remember, only the centerline are of the elbow is drawn when representing the single-line symbols. Toe doubleline symbol requires one-half of the pipe' s OD be added and subtracted, respectively, from the centerline are to represent the total pipe diameter. Keep in mind as the front view of the elbow is rotated, so too will the adjacent orthographic views be rotated.
PIPE DRAFTING AND DESIGN
16
o
3. PIPE FlITIKGS
},:$
ti{
Single-line: 12" and smaller
Double-line: 14" and larger
FIGURE 3.6 90° Long-radius elbow drawing symbols.
Drawing the 90º Long-Radius Elbow Toree "step-by-step" methods will be presented for constructing the 90° long-radius elbow. Figure 3.7 describes the step-by-step procedures for drawing an elbow with traditional drafting techniques, Figure 3.8 shows the steps required to draw double-line symbols using AutoCAD commands, and Figure 3.9 shows the steps required to draw a síngle-líne 12" elbow symbol, NOTE: The stepbystep instructional procedures pre sented using computeraided drafting techniques pre sume each student has a comprehensive knowledge of basic AutoCAD commands. These instructional steps provide a simple method to create each fitting. They are not intended to restrict the student to any particular series of commands. Each student is encouraged to experiment with uarious com mands that may achieve the same result.
Short-Radius Elbow
Example: Toe length of an 8" 90° long-radíus elbow is 8"
X
1 = 8"
NOTE: Use this formula Jor buttweld fittings only.
Drawing Symbols for the Short-Radius Elbow Toe drawing symbols for a short-radius elbow are shown in Figure 3.12. NOTE: Anytime a shortradiue ell is used, the abbreoiated note S.R. must be placed adjacent to the drawing symbol, as shown in Figure 3.12.
Reducing Elbows
Another elbow that may be used under certain circumstances and with permission from the customer is the 90° short-radius elbow. Toe 90° short-radius ell makes a much sharper turn than does the long-radius ell (see Figure 3.10). Conversely, the short-radius ell also creates a rather large pressure drop inside the line and does not have the smooth flow characteristics the longradius ell has. For these reasons, the short-radius ell is seldom used. A simple formula can be used to cakulate the centerto-end dimension of a 90º short-radius ell: Fitting length equals 1 times NPS (nominal pipe size). Or, even simpler, fitting length equals nominal pipe size (Figure 3.11).
For a relatively short period of time, reducing elbows were experimented with in various piping projects. Toe development of the reducing elbow carne about from the thinking that in a situation where a 90° turn and line-size reduction occurred a single fitting could be implemented. It was thought that a new fitting could be manufactured that combined a 90º long-radius elbow and a pipe reducer to save money and shorten the installation measurement, one fitting as opposed to two. However, though theoretically correct, in practica! application the shortened fitting length made it more difficult to install and remove bolts when it was welded to flanges that were to be bolted to valves or nozzles.
PIPE DRAFTING ANO DESIGN
17
90ºELOOWS
~3
2.
1.
Uf+
~~
1
. j r¡ rj. 7"
=\
OD of 14" 90· elbow.
=
Rodius of 14" elbow
21 ".
4.
3.
Outer ore rodius (28")
=
21
"+ 7".
5.
6.
íl 1
~
\
Weld lines odded ond
elbow dorkened.
=
lnner ore rodius (14")
--
~,,<5>,,
\
-,
<,
.... <,
1 \
/
X
\ \
Rodius of 12" elbow SO,
-,
21 "- 7".
12"
Rodius of 12" elbow
/
/
= = =
/
1 I
1 \
x NPS
18". 18".
FIGURE 3. 7 14"-90° Elbow. Manual step-by-step drafting procedure. Step l. From the eenterline of the intersecting pipes, develop a eenterpoint measuring 21• (14" NPS x l~ = 21") toward the proposed elbow's center, Step 2. From the centerpoint, draw a 21" are, which will represen! the elbow's eenterline. Step 3. Draw the elbow's outer are (28")by adding r (one-half the pipe's OD) to the 21" centerline dimension. Step 4. Draw the elbow's inner are (14")by subtracting 7" (one-half the pipe's OD) from the 21• centerline dimension. Step S. Draw two "weld lines" across the ends of the ares. Step 6. Remember, for fittings 12" and below, only the are representing the elbow's centerline is drawn when ereating single-líne symbols.
PIPE DRAFTING AND DESIGN
18
3. PIPE FlITIKGS
1.
Dlt 1
21"
1
2.
~ =3 ~7,,1
1
_µ4q_ 7"
=\
00 of 14"
so'
{¡_ Radius of 14" elbow
elbow.
3.
21 ".
4.
OFFSET are 7" on each side.
Add weld lines and change middle orc's linetype to "Center",
FIGURE 3.8 14"-90° Elbow. AutoCAD step-by-step drafting procedure. Step l. Use the OFFSET command to create construction lines parallel to the pipe's centerline 21" (14"NPS X 1 \., = 21") away. Step 2.. From the construction line's intersection, create a 21" radius ARC using the Center, Start, End option. Step 3. Develop the elbow by OFFSETing the centerline are 7" (one-half the pipe's OD) above and below. Step 4. Draw the elbow's "weld lines" and change the middle are to the "Center" linetype.
Toe cramped space made it more costly to use in the long run, thus its use has largely been discontinued.
Mitered Elbows Toe last 90° elbow to be discussed is the rnitered elbow. A rnitered elbow is not an actual fitting that is purchased but is instead a field-fabricated bend in the routing of the pipe configuration. Generally used on 24" and larger pipe sizes, a rnitered elbow is much less expensive to fabricate at the job site than to purchase a manufactured elbow and have it shipped to the job site.
Toe rniter ell is made by making angular cuts through a straight run of pipe and then welding the pipe back together after the cut sections have been rolled at varying angles (see Figure 3.13). A 90° rnitered ell can be fabricated in two, three, or four welded sections. Toe number of welded sections used depends on the smoothness of flow required through the tum. A two-weld rniter will create more commodity turbulence within the pipe than will a four-weld rniter. Though one-weld rniters are used, they are rare and typically reserved for 30°, 45°, or 60ºtums.
PIPE DRAFTING AND DESIGN
19
90ºELOOWS
!
1.
2.
Stort
~~
Center
lf= --ffi-
End
3.
= 18". 18" Are (C,S,E).
OFFSET pipe equal to center-to-end dimension.
Construct
4.
-+ 1
Match pipe ond are lineweíghts.
Add weld dots.
FIGURE 3.9 Single-line 12"-90° elbow. AutoCAD step-by-step drafting procedure. Step l. Use the OFFSET command to create construction lines parallel to the pipe 18" away. Toe offset distance is equal to the elbow's center-toend dimension (12" x 1 ~ = 18"). Step 2. From the intersection of the construction lines crea te an 18" radius ARC using the Center, Start, End option. Step 3. Change the arc's lineweight to match the pipe's. Step 4. Add weld dots to complete the elbow symbol. Crea te the weld dots with the OONUT command. The donut will have an inside radius of O.O" andan outside radius of 1.75".
1 •
r
CENTER TO END
1O.O. _i
RAOIUS of S.R. elbow= 1 x NOMINAL PIPE SIZf. FIGURE 3 .1 O Long-radíus and short-radíus elbows.
FIGURE 3.11 Center-to-end dimensión of a 90° short-radius elbow.
PIPE DRAFTING AND DESIGN
20
3. PIPE FlITIKGS
Single-line: 12" and smaller
Double-line: 14" and larger
FIGURE 3.12 Short-radius elbow drawing symbols.
--+
--l
RADIUS
I~
2-WELD
--+
--l
RADIUS
.,
3-WELD
--+
--l
RADIUS
~
4-WELD
FIGURE 3.13 Mitered elbows.
Drawing Symbols for Mitered Elbows Figure 3.14 shows the síngle-line and double-line drawing symbols for mitered elbows. Unlike the previous ells, the weld dots and weld lines in the adjacent orthographic views of the mitered elbow are represented by ellipses. Ellipses are used because the welds are not perpendicular to your line of sight. Therefore, when projecting from the front view to any of the four
orthographic views, the welds must be drawn elliptical in shape.
45ºELBOWS Another important fitting is the 45º elbow. This elbow is also used to make changes in direction within the piping configuration. Toe obvious difference
PIPE DRAFTING ANO DESIGN
21
45ºELOOWS
Two-weld
Three-weld miter
miter
FIGURE 3 .14 Mitered elbows drawing symbols.
between the 90º and 45º elbows is the angle formed by the turn. Because the 45° elbow is one-half of a 90° elbow, as shown in Figure 3.15, it is obviously shorter. It is logical, therefore, to assume that a design using two 45º elbows to make a directional change, instead of two 90º elbows, would result in considerable savings. Savings not only related to the cost of the fittings themselves, but savings in the physícal space needed to route the pipe. Figure 3.15 shows that two 14" 90º elbows, when welded together, require 3'-6" (42") of space to alter the course of the piping run. This is considerably more than when two 45° elbows are used to make the directional change (Figure 3.16). Unlike the 90º elbow, there is not a simple formula that can be applied to establish the center-to-end dimension of all 45° elbows, simply dividing the length
FIGURE 3.15 45º Elbow.
1
1
3'-6"
3'-6"
1
1 14" NOMINAL
PIPE SIZE
FIGURE 3.16 90° Ell versus 45° elbow. PIPE DRAFTING AND DESIGN
22
3. PIPE FlITIKGS
NOMINAL PIPE SIZES
PIPE ( Ü UTSIDE ~
0 45ºL.R.
-(INCHES)
2"
3"
4"
6"
8"
1 O" 12"
14"
ÜIAMETER)
2i
3~ 4~
6i
Bi
1 oj 12j
14
EII
1 i
3Í
5
I
B
2
2~
6t
7~ 8Í
FIGURE 3.17 Welded Fittings-Flanges Chart.
Single-line: 12" and smaller
Double-line: 14" and larger
FIGURE 3.18 45° Elbow drawing symbols.
of the 90º elbow by 2 will not work. One can multiply the nominal pipe size times 0.625 (%") to determine the elbow's length, but that only works for elbows 4"-24 in size. To avoid confusion, it is recommended to use the Welded Fittings-Flanges Dimensioning Chart to get the length of a 45º elbow (see Figure 3.17). 11
Drawing Symbols for the 45º Elbow Toe drawing symbols for the 45° elbow are shown in Figure 3.18.
used without the 45º ell and the elbow is rolled at an angle not perpendicular to your line of sight, the open of the 90° ell will appear as an ellipse. In any view where the open end of the elbow appears at any angle to our line of sight other than 90°, ellipses must be used to represent the fitting. Figure 3.23 shows the orthographic views of 90º elbows rolled at a 45° angle. Figure 3.24 illustrates the use of 45º ellipses to draw the 90° elbow rolled at a 45° angle. lf the 90° elbow is rolled at a 30º or 60º angle, use the respective degree ellipse to lay out and construct the elbows.
Drawing the 45º Elbow Three "step-by-step" methods will be presented for constructing the drawing symbols for the 45º elbow. Figures 3.19 and 3.20 describe two manual drawing methods and Figure 3.21 will describe the AutoCAD procedures.
90° Elbows Rolled at 45º Many times to avoid using two 90° elbows in succession, designers will use one 90º ell and one 45º ell welded together (see Figure 3.22). When a 90º elbow is
WELDTEE Toe name of this fitting comes from its resemblance to the letter T. It is a three-outlet fitting used to make perpendicular connections to a pipe (see Figure 3.25). Toe two terms used to describe the pipe and its perpendicular connection are header and branch. Toe main run of pipe is called the header, whereas the perpendicular line that connects to the header is known as a branch. Figure 3.26 shows a pipe header with two branch connections. Notice there are two tees installed
PIPE DRAFTING ANO DESIGN
23
WELDTEE
2.
1. -~
'
+-1 Duplicote
procedure
for o 90" elbow.
Drow 45" line from ell's
centerpoint.
4.
3. \
1
\
\
\
\
+-\! 1 1 1
l
Erase one-half
+ 1
1 1 1
1
-
l
x-:i 1
-
of ell.
Drow attaching 45' pipe and centerline.
6.
5.
Draw vertical weld line from f. to outer are. Trim 45· weld line.
Change middle orc's linetype to "Center".
FIGURE 3.19 45° Elbow. Manual step-by-step drafting procedure. Step l. Using construction lines duplicates the step-by-step procederes used to draw the 90º long-radius elbow. Step 2. From the centerpoint used to construct the ares, draw a 45° angla line that will divide the elbow in half. Step 3. Erase the half of the 90" elbow that is not needed. Step 4. Draw the attaclúng 45º pipe. Step S. Draw vertical and 45° weld lines from arc's centerpoint. Trim and darken the weld lines. Step 6. Change the middle are to a "Center" linetype.
PIPE DRAFI'ING AND DESIGN
24
3. PIPE FlITIKGS
1.
2. 'B'
dim.
<$>,
~"<
-,
-,
Drow intersecting
Meosure 'B'
45" lines.
3.
4.
~"~fl . , I
I
.....
.,..
-
I N I ( \ \
\ \\
\
'
5.
,
/:
I
f
7" on eoch side of
f.
olong
,,,,,,,,.------ .......
I
Meosure
dimension
~-
'
\'
' , __ .... '
' <, ...... '
Drow concentric
\
~ I ,,1/ I
\ ',
1 ~
j
Í""
//
........
.... ,, / I __ .,,,,
circles
from o 21"
f.
6.
+ Trim
ores ond
odd
weld lines.
Dorken
weld
lines
ond
odd pipe ends.
FIGURE 3.20 45° Elbow. Altemative manual step-by-step drafting procedure. Step l. Draw intersecting 45° construction lines as shown. Step 2. Using the B dimension for a 14" 45° elbow from the Welded Fittings-Flanges Chart, measure this length along each construction line beginning at the point of intersection, Step 3. Determine one-half of the pipe's diameter (7") and mark this distance on each side of each construction líne. This will establish the OD of the pipe. Step 4. Use a circle template or compass to draw concentric circles that will represent the elbow's center, inside, and outside ares. These circles are 21•, 14", and 28", respectively. Step 5. Draw vertical and 45° weld lines from the arc's centerpoint. Trim the concentric circles and darken the weld lines. Step 6. Change the middle are to a "Center" linetype.
PIPE DRAFTING AND DESIGN
25
WELDTEE
1.
2.
INSERT
existing
go·
elbow.
3.
Drow 45· line from crc's
centerpoint.
4.
~,~ I
i
I
1
1
1
1 1
1
1 1
1
+
~ TRIM/ERASE elements
Draw 45· pipe & centerline.
not needed.
5.
6.
+ Drow 45· weld line from {¡_ to outer are. TRIM weld lines.
Change middle orc's linetype to "Center",
FIGURE 3.21 45° Elbow. AutoCAD step-by-step drafting procedure. Step l. INSERT the 90º elbow created previously. Step 2. From the elbow's centerpoint, draw a 45° construction lineas shown. Use Polar Tracking set to 45° to simplify this procedure. Step 3. TRIM and ERASE the portion of the 90° elbow not needed. Step 4. Draw the attaching 45° pipe. Step 5. TRIM the 45° weld line. Step 6. Change the middle are to a "Center" linetype.
PIPE DRAFTING AND DESIGN
26
3. PIPE FlITIKGS
in Figure 3.26. One is known as a straight tee and the other is a reducing tee. On a straight tee, all three outlets are of the same nominal pipe size. A reducing tee has a branch that has a smaller line size than the header. Since a1l pipelines 12" and smaller are drawn singleline, and therefore, the pipe diameters are difficult to distinguish, a branch that is 12" and smaller must be identified with a note that defines the header size and the branch size (see Figure 3.26). Notice the weld tee requires three welds be made to install the fitting within the header. Pay particular attention to the weld
dot used to represent the weld on the 12 and smaller branch outlet on the reducing tee. 11
Drawing Symbols for the Weld Tee Toe drawing symbols used to represent the tee are developed from the rotations of the tee into the various orthographic views. Figure 3.27 depicts the rotations of the tee into the profile and horizontal projection planes. Figure 3.28 shows the drawing symbols derived from the 90° rotations of a straight and reducíng tee. Remember, a callout is required on the reducing tee to identify the header and branch sizes. Toe header size is always shown first in the note.
Drawing the Weld Tee
90.ELL /'
1
~¡5'~~
~ROLLED 45')
l
45'ELL
FIGURE 3.22 90° and 45° elbows welded together.
Before drawing the weld tee, two dimensions must be determined. Toe first dimension is required to establish the center-to-end length of the header portion of the tee and the second dimension is used to establish the length of the branch portion of the tee. If a straight tee is to be drawn, use the Welded Fittings-Flanges Dimensioning Chart to find the C dimension of the tee. Toe C dimension is the center-to-end measurement for both the header and branch lengths. Therefore, the C dimension must be doubled to find the total length (end-to-end) of the fitting (see Figure 3.29).
+-~ 45º
'
FIGURE 3.23 Orthographic views of 90° rolled ata 45° angle.
PIPE DRAFTING ANO DESIGN
27
WELDTEE
21"
45º
-
~-
(((+ / I -:
21 "
\ -,\ <,""--) / -,
..............
------
/
\
\\'/!\_ __ \
\
90ºELBOW
/
<,
<,
USE CIRCLE
\
_....,/
<;
__..
t
1
/
/
USE 45º ELLIPSE
90ºELBOW (ROLLED
AT 45º)
FIGURE 3.24 Constructing the 90° rolled ata 45° angle.
When a reducing tee is drawn, the branch length is slightly shorter than that of a straight tee. Therefore, the new branch length must be determined. Toe M dimension, as defined on the Taylor Forge Seamless Welding Fittings Chart, establishes the length of the reducing branch. Toe Taylor Forge Seamless Welding Fittings Chart is found in Appendi.x A. Figures 3.30 and 3.31 provide the step-by-step procedures for drawing double-line and single-line tee symbols, respectively. FIGURE 3.25 Weld tee.
14" STRAIGHT TEE
PIPE BRANCHES
14"
X
10"
RED. TEE
PIPE HEADER FIGURE 3.26 Header and branch connections.
PIPE DRAFTING AND DESIGN
28
3. PIPE AlT!NGS
FIGURE 3.27 Weld tee fitting rotatíons.
+~-1::r~~ ~
~ Single-line:
12" and smaller
LL.pJ)
Double-line: 14" and larger
FIGURE 3.28 Weld tee drawing symbols.
CLP
2" 3" 4" PIPE ( ÜUTSIDE ÜIAMETER) 2i 3f 4f fil Center-to-End I C 2t 3i 4i NOMINAL PIPE SIZES
-(INCHES)
FIGURE 3.29 Welded Fittings-Flanges Dimensioning Chart.
PIPE DRAFI1NG AND DESIGN
6"
8"
6~
8~
Si
7
1 O" 12" 14" 1 o-i 1 2-i 14 11 8~ 10
29
WELDTEE
1.
2.
I l_ 1
1. Drow
o 22" horizontal
(A)
3.
.1
22"
7"
• 1
Center on 11" vertical
(A)
7" 1
centerline.
t
11"
_L
centerline.
4.
1 ·
1 1
~1-
(B)
(B)
Drow 14" lines equolly spoced from the two fs.
Orow lines connecting the ends ond bronch.
FIGURE 3.30 14" Welded straight tee drawing symbols. Step l. Using the 11" C dimension found in the 14" column of the Weld tee section of the Welded Fittings-Flanges Dimensioning Chart, draw a centerline 22" long (11" ['12 a tee] X 2 = 22") to represen! the tee's total Jength. Step 2.. From the midpoint of the tee's centerline, draw a perpendicular line 11" long in !he desired direction of the branch to represen! tee's branch length. Step 3. Draw a 7" ('12 of the pipe's nominal size) horizontal Jine on each side of the branch's centerline (A) and two 14" vertical Jines on each end of the header's centerline as shown (B) to establish the weld lines of !he tee. Step 4. Add a 22" horizontal Jine to connect the two ends of the tee, then draw two horizontal lines, parallel to the tee's centerline, that will connect the two vertical weld Jines. Add two vertical lines that will connect the horizontal weld line of the branch to the header. Trim the horizontal line as necessary.
2.
1.
3. 1
17" 1
1
Drow o 17" horizontal centerline.
1
a\·
T
Center on 8 1/2" verticol centerline.
.L Add three weld dots.
FIGURE 3.31 10" Straight tee. AutoCAD step-by-step drafting procedure. Step l. Draw a UNE 17" long, having a 0.53mm Jineweight, to represen! the tee's total header length (81-2" [center-to-end length] X 2 = 17"). Step 2.. To represen! the length of the tee's branch, draw an 8'12" perpendicular UNE, from the M!Dpoint of the tee's centerline, in !he desired direction of the tee, having a 0.53mm lineweight. Step 3. Add the tee's weld dots. Create the dots with the OONUT command. The OONUT will have an inside diameter of O" and outside diameter of l. 75".
PIPE DRAFTING ANO DESIGN
30
3. PIPE FlITIKGS
CONNECTIONS
BRANCH COPEO TO FIT ONTO HEADER PIPE
HOLE BORED INTO HEADER FOR BRANCH
14"
WELD SYMBOL VARIES ACCORDING TO COMPANY STANDARD
PIPE
HEADER
FIGURE 3.32 Stub-in connections.
Single-line: 12" and smaller
Double-line: 14" and larger
FIGURE 3.33 Stub-in drawing symbols.
THESTUB,IN Another method. of branching a pipe from a header
is called a stubin. Toe stub-in is most commonly used
as an alternative to the reducing tee. Toe stub-in is not an actual fitting that can be purchased, but rather a description of how the branch connection is fabricated. Quite simply, a hole, either the size of the OD or ID of the desired branch, is bored into the header pipe, and the branch is then stubbed onto it. To create a better fit, the connectíng end of the branch pipe is cut, or coped, in such a way as to fit around the hole that has been bored into the header pipe. The two pipes are fitted together and then welded. Although the branch connection can be of the same pipe size as the header or smaller, it cannot be larger. Figure 3.32 depicts the attachment of a stub-in.
Figure 3.33 depicts the single-line and double-line drawing symbols for a stub-in connection. Notice only one weld dot is shown on the single-line symbol and it is placed at the intersection of the header and branch pipe lines. Also notice that the weld dot is not a complete circular shape. lt is semi-circular and drawn only on the branching side of the connection. Toe proximity to which stub-ins can be placed adjacent to one another is another important consideration.Toe generally accepted welding practice is to allow a mínimum of '?/' between welds or one header pipe diameter, whichever is larger, between welds. This means 18" (in Figure 3.34) is the mínimum spacing between the two branches (16" and 14") when attached to a common header. This also applies to the placement of branch when welded near a fitting. Figure 3.34 provides the mínimum measurements allowed between 16" and 14" branches and fittings on an 18" header.
PIPE DRAFTING ANO DESIGN
31
TIIESTUB-IN
MAINTAIN ONE PIPE DIA. (NPS) MIN. CLEARANCE BETWEEN WELDS OF ELBOW ANO EDGE OF 16" BRANCH.
.>:
~
J
1
14' 1
18"
+r--------.
.--"""T""--1
18" -90' elbow = 27" MIN. CLEAR.(one pipe dio.-NPS) = 18" + 1/2 O.D. of 16" pipe - 9" TOTAL 4'-6"
4'-6"
MAINTAIN ONE PIPE DIA. (NPS) MIN. CLEARANCE BETWEEN WELDS OF BRANCH CONNECTIONS. 18"
1/2 0.D. of 16" pipe = 8" MIN. CLEAR.(one pipe dio.-NPS)=18" + 1/2 O.D. of 14" pipe = 7"
2'-9"
=
TOTAL = 2' -9"
FIGURE 3.34 Spacing minimums fer welding stub-ins.
Stub-in Reinforcements
Single-line symbol
Even though the use of the stub-in is limited by the pressure, temperature, and commodity within a pipe, its use is becoming increasingly popular. Its chief advantage over the tee is cost. Not only is a cost saving realized in the purchase of a fitting, but also in the installation. The stub-in requires only one weld, whereas the tee requires three. Although the cost of boring the hole and coping the branch must the factored in, the overall expense of fabricating a stub-in is much less than the purchase and installation of a reducing tee. When interna! conditions such as pressure or temperature of the commodity or externa! forces such as vibrations or pulsations are placed on a stub-in, special reinforcement may be necessary to prevent the branch from separating from the header. Three reinforcing altematives are listed below: • Reinforcing pad. The primary intent of the reinforcing pad is to provide strength to the pipe header in the area where the branch hole has been cut. Resembling a round, metal washer that has been bent to conform to the curvature of the pipe, the reinforcing pad is a ring cut from steel plate that has a hole in the center equal to the outside diameter of the branch connection. It is slipped onto the branch pipe befare the branch pipe is welded to the header. Once the branch has been welded to the header, the reinforcing pad is slid down the branch to cover the weld connection. Toe reinforcing pad is then welded to both the branch and the header. • Welding saddle. A precision manufactured reínforcíng pad, the welding saddle has a short nec~ ?n the branch outlet that is designed to gíve additíonal support to the branch connection. Figure 3.35 shows single-line and double-line drawing
Double-line symbol
REINFORCING
PAD
WELDING
SADDLE
FIGURE 3.35 Reinforcing pads and saddles.
representations of reinforcing pads and welding saddles. • 0-lets. Purchased fittings, o-lets have one end shaped to the contour of the outside diameter of the pipe header and the other end manufactured to accept the type of end connections being used on the branch. 0-lets are manufactured for buttwelded, socket-welded, and threaded connections. Weld-o-lets are manufactured for butt-weld fittings. Sock-o-lets are made for socket-weld fittings. And thread-o-lets are available for screwed fittings. Toe photograph in Figure 3.36 shows how a thread-o-let sits atop a header pipe before welding. Figure 3.37 provides drawing symbols for weld-o-lets, sock-olets, and thread-o-lets. By design weld-o-lets, sock-o-lets, and thread-olets all form 90° branch connections to the header.
PIPE DRAFTING AND DESIGN
32
3. PIPE FlITIKGS
Single-line symbol
Double-line symbol
LATR-0-LET
FIGURE 3.36 Thread-o-let.
Single-line symbol
ELB-0-LET
Double-line symbol
FIGURE 3.38 Latr-o-let and Elb-o-let drawing symbols.
where instrument connections are required. There are two common methods used to make branch connections with couplings:
WELD-0-LET
1. Toe coupling rests on the external surface of the
pipe header and is welded from the outside (see Figure 3.39). 2. Ahole is bored into the pipe header large enough to accept the OD of the coupling. Toe coupling is inserted into the hole and is then welded (see Figure 3.40). Figure 3.41 shows the drawing symbols for a coupling. Because of it being a branch connection, the nominal pipe size and the position of a coupling must be provided on a drawing, typically the isometric fabrication drawing .
SOCK-0-LET
THREAD-0-LET
REDUCERS
FIGURE 3.37 0-let drawing symbols.
For situations where a 45º angular connection may be required, other o-lets are available for installation. Speófically, they are the latr-o-let and elb-o-let. Figure 3.38 shows drawing symbols for a latr-o-let and an elb-o-let.
COUPLING Another type of fitting used to make branch connections is the coupling. Used primarily for connecting small-bore screwed or socket-weld pipe to large-bore pipe headers, the couplíng is also used extensively
When the piping designer wants to reduce the diameter of a straight run of pipe, a reduóng fitting must be used. Appropriately named, the reducer is available in two styles as shown in Figure 3.42:
concentrichaving a common centerline; eccentric-having offset centerlines. Toe differing characteristics of these two reducers are quite noticeable. The concentric reducer maintains the same centerline through both the large and small ends of the fitting. Conversely, the eccentric reducer has offset centerlines that will create a flat surface on either the top or the bottom of the fitting, depending on how the fitting is rolled prior to welding. There are specific situations where the eccentric reducer must be installed
PIPE DRAFTING ANO DESIGN
33
REDUCERS
FIGURE 3.39 Welding a coupling onto a pipe header.
COUPLING WELD
FIGURE 3.40 Inserting a coupling into a pipe header.
COUPLING
Single-line symbol
Double-line symbol 1
FIGURE 3 .41 Couplings as branches.
with its flat side on the top, or the flat side on the bottom of the fitting. For example, when a pipe is routed through a pipe rack, it naturally will rest on the steel beams and will be supported throughout its length. But if that pipe changes its pipe size while in the pipe rack, it will not rest on all the steel supports. Toe small end will not have a diameter large enough to touch the steel supports. Therefore, an eccentric reducer is used in pipe
FIGURE 3.42 Eccentric and concentric reducer.
racks to maintain a constant Bottom of Pipe (BOP) (see Figure 3.43). When representing the reducer on a drawing it is necessary to include a note that identifies the reducer's size and type, as well as its orientation. In the example in Figure 3.43, the reducer is to be installed
PIPE DRAFTING AND DESIGN
34
3. PIPE FlITIKGS
18"x14" ECC. RED.(FOB) -.... __
18"x14" CONC. RED.
OFFSET CENTERLl~NE=-l..-==----lr-
COMMON CENTERLINE
PIPE
---
UNSUPPORTED
_/
FIGURE 3.43 Reducers in a pipe rack.
A quícker, though less accurate method, is to take one-half the difference between the two outside diarneters. Figure 3.45 shows the method of dimensioning the offset distance between the centerlines of the eccentric reducer in its FOT and FOB orientations.
FIGURE 3.44 Eccentric reducer on pump suction nozzle.
with its flat side on the bottom. Therefore, the abbreviation FOB in the note instructs the fabricator how to install the reducer. Eccentric reducers are also used on pump suction nozzles to keep entrained air from entering the pump. By keeping a Flat on Top (FOT) surface, vapor pockets can be eliminated. Figure 3.44 depicts the installation of an 18" X 14" eccentric reducer installed on a pump suction nozzle with the flat surface installed on the top. It is important for a designer not to forget to include the dimensional difference between the two centerlines of an eccentric reducer when calculating the elevations of pipe in a pipe rack. The formula for calculating this difference is
Drawing Symbols for the Concentric and Eccentric Reducer The orthographic views for the concentric and eccentric reducers are shown in Figure 3.46. No matter what the size of the reducer is, it is always drawn as a double-line symbol. Notice the callouts that must be included with the eccentric reducer. The large end is always listed first, no matter what the direction of flow is, and the flat side must be indicated.
Drawing the Reducers Before drawing the reducer, the length of the fitting must be found on the Welded Fittings-Flanges Dimensioning Chart (see Figure 3.47). The H dimension will provide the end-to-end length for either the concentric or eccentric reducer. NOTE: Always use the H dimension of the large end when determining the fitting length of any reducing fitting. Figure 3.48 represents the step-by-step procedures used to draw a 16" X 14 concentric reducer. Figure 3.49 shows the step-by-step procedures that a 10" x 8 eccentric reducer, flat on bottom, is drawn with. 11
Offset = large ID - small ID 2
11
PIPE DRAFTING ANO DESIGN
35
REDUCERS
12"X8"
14"X10"
ECC. RED. (F.O.T.)
ECCENTRIC REDUCER
ECC. REO. (F.O.T.)
- FLAT ON TOP
Of'F'SET 00.IENSION
12"X8"
14"X10"
ECC. REO. (F.O.B.) ECCENTRIC REDUCER
ECC. REO. (F.O.B.) - FLAT ON BOTTOM
FIGURE 3.45 Offset dimensioning of eccentric reducers,
~
t Hc. 1
BJ---n
~ Bc.x,,
CONCENTRIC REOUCER
t ~8t
~
~
~
ECC. RED. (F.O.B.)
~ 1~
ECC. REO. (F.O.B.)
ECCENTRIC REOUCER FIGURE 3.46 Drawing symbols for concentricand eccentric reducers.
PIPE DRAFilNG AND DESIGN
36
3. PIPE FlITIKGS
-D 1-H-1
NOMINAL PIPE SIZE-(INCHES)
2"
3"
4"
6"
8"
1 O" 12" 14"
PIPE ( ÜUTSIDE ÜIAMETER)
2i
3~ 4~
6i
s¡
1 oj 12j
-D- lenolh of Reducerl H
3
5~
6
3~
4
7
8
14" 13
FIGURE 3.4 7 Welded Fittings-Flanges Dimensioning Chart.
2.
1.
--l.
Draw a 14"
3.
14"
.1
horizontal
centerline.
Drow lorge ond smoll ends to match pipe's NPS.
4.
B Add the diagonal
:t~--H:: 16"
) lines.
-
X
14"
(
Dorken weld lines ond odd connecting pipe.
FIGURE 3.48 16" X 14" Concentric reducer. Manual step-by-step drafting procedures. Step l. Using the H dimension found on the Welded Fittings-Flanges Dimensioning Chart, draw a centerline 14" long. Step 2. Measure 8" (one-half the 16" large end size) on each side of the centerline on one end of the centerline and 7" (one-half the 14• small end síze) on each side of the opposite end of the centerline. Step 3. Connect the opposing ends of the fitting by drawing lines from endpoint to endpoint. Step 4. Darken the sides and weld lines of the reducer then add the connecting pipe.
WELDCAP
USE OF FITIINGS
Though there are others, the last weld fitting we will discuss is the weld cap. Toe weld cap is used to seal or cap the open end of a run of pipe. To dirnension the positional location of a weld cap on a drawing, sirnply dirnension the length of the run of pipe. Toe cap is not included in the length dirnension of the pipe. A pipe fitter will know to weld the cap on the end of the pipe. Toe weld cap, like the reducer, is another fitting that is drawn as a double-line symbol, no matter what the pipe's nominal size is. When representing the capona drawing, use an ellipse to construct the round end of the fitting. Figure 3.50 shows the single-line and double-line drawing symbols for a weld cap. Notice the weld dot on the single-line symbol is drawn as a half-circle only. Toe length of the fitting is found on the Taylor Forge Seamless Welding Fitting Chart in Appendix A.
Thus far we have discussed each fitting individually. We will now look at how they relate to other fittings when used in the design of various pípíng systems. Depending on the given situation, fittings will be either welded to each other or separated by lengths of pipe. Welding one fitting directly to another is called fitting makeup. Single-line and double-line representations of fitting make-up are shown in Figure 3.51. In most situations, the erection of the piping system will require the designer to use pipes of various lengths between the fittings. In these cases, the pipe is cut to the required length and then beveled in preparation for welding to a fitting. When a pipe configuration is not assembled as fitting make-up, and the fittings are separated by a short section of the pipe, most companies stipulate that the pipe must be at least one
PIPE DRAFTING AND DESIGN
37
USE OF FIITINGS
1.
2.
-,-
L - -
10"
_L_
Lz:_J
Drow a 1 O" vertical
line.
3.
Drow a
4.
LJ]
horizontal
line.
~"~]-~"n t 10"
1
Draw an 8" vertical
7"
X
8"
ECC. REO. {F.0.B.) line.
Drow the top connecting
line.
FIGURE 3.49 10" x 8" Eccentric reducer (FOB)-AutoCAD step-by-step drafting procedure. Step 1. Torepresent the large diameter end of the reducer,draw a vertical LINE 10" long (NPS), having a 0.53mm linewcight. Step 2. Draw a horizontal LINE perpendicular and to the right measuring 7" (H dimension from Welded Fittings-Flangeschart), which will represent the length of the reducer. Step 3. Create the small diameter end of the reducer by drawing an 8" (NPS) vertical LINE up from the right end of the reducer. Step 4. Complete the eccentric reducer by drawing a sloping LINE back to the top of the 10" line, connecting the two vertical ends. Add the reducer's weld dots with the DONUT command. Toe DONUT will have an inside diameter of O" and outside diameter of 1.75". TRIM the weld dots so that only one-half of the dot is visible.
DRAW THE CAP WITH A 30º ELLIPSE
Single-line: 12" and smaller
Double-line: 14" and larger
FIGURE 3.50 Weld cap drawing symbols.
pipe-diameter long or 3" mínimum length, whichever is longest. A cut length of one pipe diameter means that any section of pipe that is to be placed between two fittings must be at least as long as the nominal pipe size of the fitting used. For example, if 8" fittings are being used, the mínimum cut length of pipe between any two fittings is 8". For pipe configurations of a 3" nominal size or smaller, the mínimum pipe cut length is 3". These short sections of pipe are sometimes referred to as spool or pup pieces.
It is important to maintain this rrurumum spacing because once assembled each weld in every piping configuration in the facility must be x-rayed and heat treated. X-rays are performed to guarantee the quality of the weld. Once a weld has been completed, if another weld procedure is performed too close to it, the heat from the new weld may have an adverse effect on the first weld. Therefore, the one pipe-diameter mínimum spacing allows the pipe to dissipate the heat before it can spoil the first weld. By maintaining a minimum spacing between
PIPE DRAFTING AND DESIGN
38
3. PIPE FlITIKGS
welds, a pipe can be conveniently cut, beveled, and welded without adverse effects on adjacent welds. Figure 3.52 depicts the one pipe-diameter mínimum spacing. NOTE: The one pipediameter mínimum spacing is a standard used throughout the piping industry and will be applied to the drawing exercises and projects used in this text. Welds may seem insignificant to the beginning drafter, but it goes without saying that a piping facility could not be built without them. So remember, ali welds must be shown on drawings in their exact and proper locations. And, use weld dots on single-line pipe symbols and weld lines on double-line pipe symbols.
Applying Fitting Make-up Dimensions Toe next step in the drawing of pipe is the calculation and placement of dimensions on drawings. At the present time, the only concem is how to position and align dimensions on butt-weld fitting configurations. As a general rule of thumb, there are three methods in which dimensions are placed on butt-weld piping configurations. They are as follows: • Center-to-center. Place dimensions from center of fitting to center of fitting. • Center-to-face. Place dimensions from center of fitting to face of flange. • Face-to-face, Place dimensions from face of flange to face of flange. Figure 3.53 provides sorne examples for placing dimensions on drawings. Notice though, when a weld cap is installed, the dimension needed is a center-to-end of pipe measurement.
Single-line: 12" and smaller
SCREWED AND SOCKET,WELDFITTINGS Screwed and socket-weld fittings perform the same basic functions as butt-weld fittings. Like butt-weld fittings, elbows, tees, and reducers are manufactured for screwed and socket-weld applications. There are, however, a few differences that must be examined. Screwed and socket-weld fittings are normally reserved for installations where the nominal pipe size is 3" and smaller. Screwed and socket-weld fittings are also available in cast iron, malleable iron, or forged steel. Typically, forged steel fittings are used on high pressure and temperature lines. However, low pressure and temperature lines, such as air, water, or condensate, are fabricated using either cast or malleable iron fittings. Pipe lines containing high pressure and temperature commodities, which are subject to substantial amounts of movement and vibration, mandate fittings made of forged steel. For these reasons, forged steel screwed and socket-weld fittings are manufactured in two pressure classes~3000# and 6000#. Toe sizing charts, shown in Appendix A, provide the dimensional measurements for 3000# and 6000# screwed and socket-weld fittings. Figures 3.54 and 3.55 display a portion of the screwed and socket-weld fitting dimensioning charts found in AppendixA. Most screwed fittings are manufactured with ínternal, or fema/e, threads as defined by the American Standard and API thread guídelines. As shown in Figure 3.56, of particular concem to the pipe designer is the amount of pipe length lost during the assembly of screwed fitting configurations. When screwed fittings and threaded pipe are assembled, a certain amount of
Double-line: 14" and larger
FIGURE 3.51 Fitting make-up.
PIPE DRAFTING ANO DESIGN
39
SCREWED AND SOCKET-WRD FITTINGS
---
ONE
PIPE-DIAMETER
(Nominal
Pipe Size)
BETWEEN WELDS
-
---i
or 3" MIN.
Single-line: 12" and smaller
Double-line: 14" and larger
FIGURE 3.52 Mínimum pipe cut lengths.
2·
-st 2· -9f'
FIGURE 3.53 Placement of dimensions on butt-weld configurations.
8' - 7"
01-2-C30-16"
O)
1
'iD
-+---
+
-----,f-
pipe length is lost as a result of the interna! and external, or male, thread connecting process. Each time a threaded connection, or engagement, is made, the configuration gets shorter. Toe length of this engagement varies depending upon the nominal pipe size and pound rating of the fitting. Toe procedure to determine the actual center-to-center length of a threaded configuration is to subtract the total length of all the thread
engagements from the total unassembled length of pipe and fittings. Toe unassembled length can be thought of as all the pieces, both fittings and pipe, being laid out end to end. From this unassembled length, the total of all the thread engagements is then subtracted to determine the total assembled lengih. Toe formula below applies the values shown in Figure 3.56 to calculate the assembled length,
PIPE DRAFTING AND DESIGN
40
3. PIPE FlITIKGS
SCREWED
NOMINAL PIPE
SIZE
-(INCHES)
3000 #
90ºELL
~
tffit]
41\--4 ce-¡
EJ
~]
FITTINGS
6000 # 3000 # HALF TEE 6000 # 3000 # 45ºELL
6000 # 3000 #
A A A A B B
COUPLING
6000 # 3000 #
UNION
e e D D
6000 # NORMAL THREAD 3000 # ENGAGEMENT 6000 #
1 .. 141 .. 121 .. 2" 221 .. 3" 1.J 31 3.J 2 218 2.1 4 2 8 4
1 .. 3" 2 4 5 115 1.l2
1.l 1.J4 2 5 115 1.l2 11 2 1
2
21
1.J
2
8
4
3 21 31 3.J 415 2 8 4 2i 2~ 3i 3.J 4
3 2 218 212 318 3.J4 415 7 1 5 1..l 115 115 111 16 2 215 212 8 11
4
5 111 111 123 1 21 31 1..l 116 8 32 16 32 215 2 8 1.Z. 2 21 2-º- 3.l 31 3-º- 4..l 4 8 8 8 8 8 8 1.Z.
2i 3i 3i 3i 4..l 4 7 7 1 3 215 218 215 214 16 315 315 415 4..l 2 2
2i
8 3i
3i
8
21 1
9
2
16
1
9
2
3i
11 16 11
16
16
11
16 11 16
3 415 42. 8 11 16 11
16
.J 4
.J 4
15 16 15
16
1 1
FIGURE 3.54 Screwed fittings dimensioning chart.
Sorne fittings, such as plugs and swages, however, are manufactured with externa! threads and their assembled lengths are treated differently, as will be explained later. Toe socket-weld fitting has become the fitting of choice for many fabricators because it offers greater strength at each point of connection. Even though screwed fittings can be seal-welded if necessary, strength of the fitting is decreased when the threads are cut during the manufacturing process. Socket-weld fittings can be easily fitted and welded without the need of special clamps or tack-welds, which are often required to hold a fitting in place before the final weld is made. Like screwed fitting configurations, during the assembly of socket-weld configurations, there is pipe length loss. This lost length is equal to the depth of the socket, or socket depth, and must be accounted for when
calculating overall lengths of pipe runs. However, there is a slight difference from screwed pipe assemblies. On socket-weld connections, a .){6• gap is factored into each socket-weld connection. Figure 3.57 provides a sectional view of two socket-weld elbows and the connectíng pipe. Notice two socket depths must be subtracted from the total unassembled length of the two elbows and the piece of pipe, then Ys" is added back to account for the two Yi/ gaps, before an assembled configuration length can be determined. If a formula were applied to calculate the ossembled length using the values shown in Figure 3.57, it would look like AL
= CE1
+ CE2 + PL - (501 + 502) + ¡"
Fittings Like butt-weld fittings, screwed and socket-weld fittings are used to make similar routings in the piping
PIPE DRAFTING ANO DESIGN
41
SCREWED AND SOCKET-WRD FITTINGS
SOCKET-WELD
NOMINAL PIPE D~
o-'
+
A
~
o,~ r-li...+--11~
FITTINGS
1 .. SIZE -(INCHES) 21 .. 43" 1 ,, 1-4 121 " 2" 221 .. 3" 5 11 1.J 11 115 3.d 2 2l 3000 # 8 2 4 8 3 8
1
B
o::-:RJº oJ~I , ~
SOCKET DEPTH
90ºELL 6000 # 3000 #
HALF TEE 6000 # 3000 #
A A A A
B B
45ºELL 6000 # 3000 # COUPLING 6000 # 3000 # E UNION 6000 # E 3000 # D 6000 # D
e e
5 115 112 1.J 4 5 11 115 11 8 2 5 115 112
1.J
4
2 1.J
4
2l8 212 314 3.d4 2
2l8
3
3.d
8
21 3.l 3.J 2 2l 8 2 4 4 7 11J 1 21 5 115 115 16 215 2
8
7
1
1
11
1 _l_ 8
2
5 1D 123 1 21 115 1D 32 16 32 215 2 2j 2i 3i 3j 3-º-8 4...1.. 4
1 i.
2
2l8 2-º-8 318 3.d8 3-º-8 4...1.. 4
8
8
1.l 8
115 2...1.. 2.l 16 4 2 5 215 212 1
2 11 16
9 16 3
4
1 7 213 16 315 315
4
5 415
213 2l 2l 31J 315 4-º16 4 8 16 16 8 .2
8 7
8
11 16 15 16
l.
7
4
8
, .1 8
1
1 l.
8 1.1 2
, .1 8 1-º8
FIGURE 3.55 Socket-weld fittings dimensioning chart.
system, but only in srnaller pipe sizes. Screwed and socket-weld fittings differ in size and shape, but they achieve the same purpose as butt-weld fíttings. However, there are sorne differences. Ninety degree elbows are not available as long-radius or short-radius, and their center-to-end dimension must be found on a dimensioning chart, as no formula is available for calculating their radius length. Figure 3.58 provides examples of sorne screwed and socket-weld fittings. Screwed and socket-weld fittings are represented differently on drawings than their butt-weld counterparts. For example, screwed and socket-weld elbows are drawn with square corners, usíng short hash marks to represent the connection points of the fitting and its mating pipe. Sorne engineering companies even draw short ears on the hash marks to indicate a difference between screwed and socket-weld symbols (see Figure 3.59).
There are, however, sorne fittings that are unique to the screwed and socket-weld family of fittings. These fittings do not lend themselves to butt-weld applications and are manufactured solely for use in screwed and socket-weld configurations. A brief discussion of those is as follows.
Unions Toe uníon, shown in Figure 3.60, is a fitting placed within a pípíng configuration that will allow the assernbly to be disassernbled for inspection, repair, or replacernent. Manufactured for screwed and socket-weld applícatíons, the union is represented on drawings as shown in Figure 3.61. Unions should be positioned in locations that will facilitate the easy rernoval of critica! pieces of equípment, Figure 3.62 shows how unions are placed in a configuration to allow easy rernoval of a valve.
PIPE DRAFTING AND DESIGN
42
3. PIPE AlT!NGS
CENTER- TO-CENTER DIMENSION CENTERTO-END DIMENSION OF FITIING
(CE1)
Assernbled Length
= AL
PIPE LENGTH (TE 1)
(TE z)
(PL)
THREAD ENGAGEMENT
CENTERTO-END DIMENSION OF FITIING
(TE)
FIGURE 3.56 Interna! and externa! thread engagements.
CENTERTO-END DIMENSION OF FITIING
CENTER- TO-CENTER Assernbled Length
DIMENSION = AL
(CE1)
CENTERTO-BOTIOM OF SOCKET
(CEz)
PIPE LENGTH (PL)
FIGURE 3.57 Socket-weld fitting connections.
PIPE DRAFI1NG AND DESIGN
CENTERTO-END DIMENSION OF FITIING CENTERTO-BOTIOM OF SOCKET
43
PIPE NIPPLES
FIGURE 3.60 Union. FIGURE 3.58 Screwed and socket-weld fittings.
HH
TEE
SCREWED ELL
UNION
PIPE NIPPLE
HH
SCREWED FITTINGS
SOCKET-WELD
UNION
FIGURE 3.61 Unión drawing symbols.
Coupling
PIPE NIPPLE SOCKET -WELD
Although this fitting is used in butt-welding applications as a branch connection, its primary use is to connect lengths of screwed and socket-weld pipe together. Sorne clients may stipulate, however, that all socket-weld pipe must be connected with a butt-weld rather than a coupling.
FITTINGS
PIPE NIPPLES
FIGURE 3.59 Screwed and socket-weld drawing symbols.
Plug Toe plug, like a cap, is designed to seal the end of a run of pipe. Plugs are manufactured for screwed fittings with male threads and are screwed into the end of a pipe to create a seal. Figure 3.63 shows the drawing symbols for the plug.
By design, screwed and socket-weld fittings cannot be assembled by placing one fitting directly in contact with another fitting. There must be pipe in between. As mentioned previously, screwed fittings are manufactured with threads on the inside of the fitting and socket-weld fittings have an internal socket that prevents fitting make-up assembly like butt-weld fittings. To facilitate the assembly of screwed and socket-weld fittings, short lengths of pipe called pipe nipples are placed between the fittings. Pipe nipples can vary in
PIPE DRAFTING AND DESIGN
44
3. PIPE FlITIKGS
UNION
ELL
FIGURE 3.62 Positioning of unions.
PLUG IN COUPLING (Vent)
PLUG
a drawing (see Figure 3.64). Figure 3.64 shows varyíng lengths and sizes of screwed pipe and swage nipples. Swages are unique in that they can be used in screwed, socket-weld, or butt-weld configurations. When used in these configurations, swages will have a variety of different end preparations. These end preparation combinations allow the swage to be used in a number of different attachment applications-in other words, screwed to socket-weld, butt-weld to screwed, or butt-weld to socket-weld. Screwed swages will have threaded ends (TE), socket-weld swages will have plain ends (PE), and butt-weld swages will have beveled ends (BE). Because socket-weld swages are inserted into mating fittings, many companies allow the substitution of beveled end swages. Since the end is inserted into the fitting and the weld is made on the outside of the fitting, it makes little difference how the end cut is made. Swages are also manufactured with different preparations on their opposing ends. When specifying a swage, use the following abbreviations: BBE-bevel both ends; TBE-thread both ends; PBE-plain both ends; BLE/TSE-bevel large end/thread small end; PLE/TSE-plain large end/thread small end.
IN
VALVE (Droin) FIGURE 3.63 Plug drawing symbols.
length depending upon the distance required to fabricate the pipe configuration. A clase nipple is one that allows for the mínimum assembly length between two pipe fittings. Remember, screwed and socket-weld configurations have a certain amount of pipe length loss due to thread engagement and socket depth. Because thread engagement and socket depth varíes depending on the pipe's nominal size, each pipe size has a different minimum length for the dimension of a close nipple. Many companies will use 3", as the standard mínimum length of pipe nipples. This length will accornmodate the amount of pipe length lost on both ends of the fitting as well as provide sufficient wrench clearance during assembly for the larger screwed pipe sizes.
Figure 3.65 depicts three different concentric swage nipples. Notice the end preparation combinations on the examples. Figure 3.66 shows the drawing symbols for various swages. Toe swage section of the Screwed Fittings dimensioníng chart, shown in Figure 3.67, provides the length or, S dimension, of swage fittings. Like reducers, one must always use the large end pipe size to find the length of the swage on the dimensioning chart. Notice the Out/et section of the chart. This section simply indicates the range in which the small end pipe size can reduce to. It does not affect the length of the fitting. Remember, all fittings that are attached after the swage are obviously of a smaller pipe size and, therefore, will not only be shorter in length, but will also have a shorter thread engagement. These important factors should not be overlooked when calculating the center-to-center dimensions of screwed or socket-weld configurations.
Swage One exception to the standard 3" mínimum rule is the swage nipple. Swages are functionally similar to reducers, in that they are used to make line-size reductions in a straight run of pipe, but they are specifically designed for screwed and socket-weld pipe. Screwed swages have extemal (male) threads and are connected directly to other screwed fittings without the need of a pipe nipple. Llke reducers, they are available in either a concentric or eccentric shape and are always drawn double-line on
FLANGED FITTINGS Flanged fittings perform functions similar to other fittings of the same type. Toe mejor difference is their method of connection. Toe connection joint for flanged fittings is made by bolting two specially designed metal surfaces together. Sandwiched between the two surfaces is a gasket that prevents leaks. Flange types will be discussed at great length in a following chapter.
PIPE DRAFTING ANO DESIGN
45
FllTING EXERCISE INSTRUCTIOI\S ANO 11\FORMATION
SWAGE CALLOUTS 4"x3"SWAGE BLE-TSE
í
FIGURE 3.64 Pipe and swage nipples.
í
3"x2"SWAGE
PLE-TSE
3"x2"SWAGE
TBE
FIGURE 3.65 Concentric swage nipples.
CAST !RON FITTINGS
FIGURE 3.66 Swage drawing symbols.
Cast iron fittings are typically designed for use in gravity-flow installations using low-pressure water services. Toe physical appearance of pipe configurations made of cast iron fittings is quite different from pipe routed with forged steel fittings. Toe large assortment of available fittings and the method in which these configurations are assembled make their appearance quite distinguishable. Above-ground cast iron confígurations often require multiple changes in direction and elevation to avoid obstructions with preexisting installations. Because molten cast iron can be easily manufactured into many unique shapes that cannot be attained with steel, pipe routings that have many varying turns, bends, and branches are quite common.
PLASTIC FITTINGS Plastic fittings are also manufactured in many diverse and unique shapes. Therefore, they have become the material of choice for many low-pressure and low-temperature applications, replacing cast iron.
Ali the standard fitting shapes are available: elbows, tees, reducers, couplings, unions, etc. Plastic fittings are manufactured for either screwed, socket, or butted assembly. Plastic screwed and socket fittings are available in sizes through 4" in diameter. Butt fittings are manufactured for sizes 6-10".
FITTING EXERCISE INSTRUCTIONS AND INFORMATION Toe fittings depicted in Figure 3.68 will be used to complete exercíses in Chapters 3, 4, 5, and 10. To complete those exercises, draw the symbols below usíng the following instructions: • Draw ali fitting symbols full size using dimensions found on the Welded Fittings and Flanges Dimensioning Charts. • Double-line symbols are drawn with a "default" lineweight. Single-líne symbols are drawn with a 0.53mm lineweight.
PIPE DRAFTING AND DESIGN
46
3. PIPE FlITIKGS
• Draw all weld dots with the DONUT comrnand. Toe DONUT will have an inside diameter of O" and outside diameter of 1.75". • Create a BLOCK of each symbol, Use a block name that appropriately describes the fitting and its size. (DO NOT include text with the blocked symbol.)
s,
NOMINAL PIPE SIZE 1 1
l
111
• BLOCK the symbol with the base point placed at an appropriate location using an ENDpoint, MIDpoint, or CENter OSNAP. • SAVEthe file as Fitting Symbols. NOTE: When drawing the symbol that represents the back of the elbow, break the are so that it creates an opening approximately 45° to the pipe.
s w A G
E
~
-
2
4
3"
1 ,,
1-4
1- 12"
1/4
1/4
1/4
1/4
1/4 1/4
1"
-(INCHES) 1--
L....L.....J __J
1--
:::::>
e=:,
s
to
to
to
1"
to
to
2" 2-21 "
to
1/4
to
3" 1/4
to
1 1114 1112 2114 2112 23/4 3 3112 4 4112 6112 7 8 3/s
1/2 3/4
FIGURE 3,67 Swage dimensioning chart.
-E8
14-90 BACK
(i? 14-90
SIDE
e-
e
14-90
SIDE
8-90
12-90 OPEN
14 TEE BACK
OPEN
12 TEE SIDE
83
~ 14 TEE END
/
@
_L
'f
6-90
12 TEE BACK • OPEN
6-90 SIDE
4-90
BACK
4-90
SIDE
OPEN
»<. <:»
B
~ OPEN 14x12
FIGURE 3.68 Fitting drawing syrnbols with file names.
PIPE DRAFTING ANO DESIGN
@
.L
10 TEE BACK • ~
4-90
12 TEE END •
10 TEE OPEN~
10 TEESIDE
r
Cf
ffi-
BACK
e-
10-90
14 TEE SIDE
12 TEE OPEN~
r
10-90 BACK
10-90
.: 'r
8-90 SIDE
6-90
e-
r
8-90 BACK
e-~
12-90 SIDE
14 TEE OPEN~
OPEN
12-90 BACK
í
e-
CONC RED
•
10 TEE END
B 12x1 O CONC RED
47
CHAPTER 3 REVIEW QUIZ
CHAPTER 3 REVIEW QUIZ
9. Which fitting is used to make a reduction in the line
size of a run of pipe?----------1. Typically, pipe smaller than 311 in diameter is
manufactured as having ---------
or end connections.
10. Name the two types of reducers.
2. What is the most common fitting used?
11. Define fitting make-up.
3. What are the four classifications of elbows?
12. What are the two pressure classifications for
_ _
screwed and socket-weld fittings?
4. What is the formula for calculating the center-to-end
dimension for LR and
SR elbows?
13. What type of fittings must be bolted together? __
LR = ---------------SR=--------------5. Describe a mitered elbow.
_
6. When confíguríng tee connections, what is the main run of pipe called? _
14. What is the typical installation service for cast iron
pipe?
15. Name the three types of plastic fitting end types
manufactured.
7. Name the two types of tees. --------8. What are sorne altemate methods to a tee fitting
when fabricating branch connections?
_
_
PIPE DRAFTING AND DESIGN
_
G)
DRAW ALL VIEWS AS SHOWN 12" ELBOW
DRAW ALL VIEWS AS SHOWN 14" ELBOW
~
DRAW ALL VIEWS AS SHOWN 1 2" 45' ELBOW
1
DRAW ALL VIEWS AS SHOWN 14" 45' ELBOW
EXERCISE
3-1
G)
DRAW ALL VIEWS AS SHQWN 1 'L TEE
~
~~
~
@
DRAW ALL VIEWS AS SHOWN 14" TEE
_, $
rh
ca""
~-y
111
o
s'
21
~ ~ o
IB C)
o
:i:
>
~;a ....
/
lil ~
@
DRAW ALL VIEWS AS SHOWN 14" x ,O" CONCENTRIC REDUCER
z
i
ttr.rl
~ .!
©
zo m
DRAW ALL VIEWS AS SHOWN 14" x 1 O" ECCENTRIC REDUCER
i
X
93 o ¡¡; ¡¡¡
ttr.rl
~x1 ECC. RED.
F.0.8.
EXERCISE
3-2
50
3. PIPE AlT!NGS
FITIING MAKE-UP DRAW THE FRONT VIEW /!S SHOWN.
G)
12" 1
-+ 1 1
1 4" ELBOWS
®
ELBOWS
1
1
+-
1
1
¡
1
1
+-+---
--+--+-1
-+-
-+-+~+-+-+l -+-+-
PROJECT TOP, LEFT ANO RIGHT SIOE VIEWS.
1
1
- -+ -
1
1
1
1
'
1
1
-+--+-+-
1 4"
---+--
-+1 4" X 1 2"
EXERCISE 3-3
PIPE DRAFI1NG AND DESIGN
51
CHAPTER J DRAWING EXERCISES
CD
1 4.. 45· ELBOWS
CENTER OF 45· ELLIPSE
NOTE: USE 4H LEAD FOR PROJECTION UNES MAKE PROJECTION UNES LIGHT
42"
_ _.____ ~-=-==__ _ ._ t-
CENTER OF 45· .ELLIPSE
14" DRAW THE FRONT VIEW AS SHOWN. PROJECT TOP, LEFT ANO RIGHT SIDE VIEWS. DRAW ALL VIEWS AS SHOWN 1 Z' 45· ELBOWS
142"
1 2,, EXERCISE 3-4
PIPE DRAFilNG AND DESIGN
52
3. PIPE AlT!NGS
FITIING MAKE-UP SOLVE FOR THE MISSING DIMENSIONS
G)
8"
--
18"
ff'
1 6" X 1 2"
EXERCISE 3-5
PIPE DRAFI1NG AND DESIGN
53
CHAPTER J DRAWING EXERCISES
FITTING MAKE-UP
SOLVE f"OR THE MISSING OIMENSIONS
1 O"
10"
8"
®
8"
®
10" X 8"
EXERCISE 3-6
PIPE DRAFilNG AND DESIGN
54
3. PIPE AlT!NGS
FITIING MAKE-UP SOLVE FOR THE MISSING DIMENSIONS
SCREWED CD 3000#FS 3" LONG NIPPLES
M\ 6000#FS SCREWED \6J 3" LONG N!PPLES
1rn
3000# FS SW \:::!.) 3" LONG NIPPLES
3/4.x1/t
6000# FS SW \:::!) 3" LONG NIPPLES (A"'\
SWG
3/4.x1/'l SWG
JBE
1.
JBE
1EXERCISE
PIPE DRAFI1NG AND DESIGN
J 3- 7
55
CHAPTER J DRAWING EXERCISES
FITTING CALCULATIONS 3"-3000#
FITTING
SCRD. FITTINGS
2"-
3" LONG PIPE NIPPLES
3000#
CALCULATIONS S.W.
FITTINGS
3" LONG PIPE NIPPLES
"TOTAL ASSEMBLED LENGTH" "TOTAL ASSEMBLED LENGTH" TOTAL UNASSEMBLED LENGTH:
_
TOTAL UNASSEMBLED LENGTH:
THREAD ENGAGEMENT LENGTH:
_
SOCKET DEPTH LENGTH:
TOTAL ASSEMBLED LENGTH:
_
TOTAL ASSEMBLED LENGTH:
_
EXERCtSE 3-8
EXERCISE 3- 1 O
FITTING CALCULATIONS 2"- 3000# S.W. FITIINGS
FITTING CALCULATIONS 2"-6000# SCRO. FITIINGS
3" LONG PIPE NIPPLES
3" LONG PIPE NIPPLES
2"x%"
"TOTAL ASSEMBLED LENGTH"
SWG.
"TOTAL ASSEMBLED LENGTH"
TOTAL UNASSEMBLED LENGTH:
TOTAL UNASSEMBLED LENGTH:
SOCKET DEPTH
THREAD ENGAGEMENT LENGTH: ----
LENGTH:
TOTAL ASSEMBLED LENGTH:
TOTAL ASSEMBLED LENGTH: ---EXERCISE 3-9
PIPE DRAFilNG AND DESIGN
_ EXERCISE 3-1 1
CHAPTER
4 Flange Basics
Toe flange is a ring-shaped device that is used as an altemative to welding or threading various pipíng system components together. Flanged connections, which require bolting, are the preferred altemative to welding because they can be easily assembled, disassembled, then reassembled when needed for shipping, inspection, maintenance, or replacement. Flanged connections are favored over threaded connections because threading large-bore pipe is not an econornical or reliable operation, as leakage on large-bore threaded pipe is difficult to prevent. For these reasons, the flange is an important component of any piping system. Flanges are primarily used where a connecting or dismantling joint is needed. These joints may include attaching pipe to fittings, valves, mechanical equipment, or any other integral component within a piping configuratíon. In the typical pipe facility, every piece of mechanical equipment is manufactured with at least one inlet and outlet connection point. Toe point where the piping configuration is connected to the equipment is called a nozzle. From this nozzle-to-flange connection point, the piping routing is begun. Figure 4.1 depicts multiple
examples of how piping configurations are connected to a vertical vessel vía a nozzle.
RATING FLANGES Rating, as applied to flanges, may best be defined as the maximum pressure allowed by the Pressure Piping Code for the specific temperature at which the flange will be operating. Flanges and nozzles are sized according to pressure ratings established by the American Society of Mechanical Engineers (ASME). These pressure ratings, often called pound ratings, are divided into seven categories for forged steel flanges. They are 150#, 300#, 400#, 600#, 900#, 1500#, and 2500#. Cast iron flanges have pound ratings of 25#, 125#, 250#, and 800#. Pound ratings, when combined with the temperature of the commodity within the pipe, are used to select the appropriate size, rating, and type of flange. This pressure/temperature relationship will allow any given flange to be used in a number of different applications. For example, a 150# forged steel flange is rated to perform at 150# PSIG at 500 ºF. If the temperature were decreased to lOOºF, this same flange could be used for 275# PSIG. However, if the temperature were increased to 750ºF, the flange could only be used for 100# PSIG. As you can see, the pressure/temperature relationship is important. When temperature decreases, the allowable pressure increases, and vice versa. Pound ratings are also used to establish the outside diameter and thickness of a flange. Typically as pound ratings increase, so will the flange's diameter and thickness.
FLANGE FACINGS
FIGURE 4,1 Vessel nozzles.
Toe mating surface of a flange, nozzle, or valve is called the face. Toe face is usually machined to create a smooth surface. This smooth surface will help assure
56
C, 2012 Ehcvic-r lnc. Ali rlghts rcserved.
57
FI.ANGE FACINGS
a leak-proof seal when two flanges are bolted together with a gasket sandwiched between. Although numerous types of flange faces are produced, we will focus only on the following three: • flat face; • raised face; • ring-type joint,
Flat Face As the name implies, flanges with flat faces are those that have a flat, level connecting surface (see Figure 4.2). Forged steel flanges with a flat face flange are commonly found in 150# and 300# ratings. Their principal use is to make connections with 125# and 250# cast iron flanges, respectively. Attaching steel pipe to the cast iron flanges found on sorne valves and mechanical equipment always presents a problem because of the brittle nature of cast iron. Usíng a flat face flange will assure full surface contact, thereby reducing the possibility of cracking the softer cast iron. Figure 4.3 shows a sectional view of a flange with a flat face.
ones provided in this text, include the Vil' raised face thickness in the length dimensions for 150# and 300# flanges. However, the 1,4'' raised face thickness is not always included in the length dimensions for 400# and higher pound ratings. To assure accurate dimensioníng, always determine if the dimensíoning chart being used includes the W' raised face thickness for the larger pound rating flanges. The 1,4" raised face thickness must be added to the dimensioning chart measurement to obtain the overall flange length if the dimensióning chart indicates it has not been added. Figure 4.5 includes a sectional view of a weld neck flange having a raised face.
Ríng-Type Joint Also known simply as ring joint, the ring-type joint does not use a gasket to form a seal between connecting
Raised Face Toe most common face type in use, the raised face, is available in all seven of the aforementioned pound ratings. Appropriately named, this flange face has a prominent raised surface. With shallow grooves etched into the raised surface, this flange face assures a posítive grip with the gasket. Flanges rated 150# and 300# have a Yil' raised face, whereas flanges 400# and above have a W' raised face (see Figure 4.4). lt is important to note that most dimensíoníng charts, including the GASKET FACING FLAT FACE (FF) FIGURE 4.3 Flat face welding neck flange.
FIGURE 4,2 Flat face flange.
FIGURE 4,4 Raised face flange. PIPE DRAFTING AND DESIGN
58
-t
4. FLANGE BASICS
1/16" FOR 150# ANO 300# 1/4" FOR 400# ANO HEAVIER
GASKET FACING RING JOINT FACE (RTJ) GASKET FACING RAISED FACE (RF)
FIGURE 4. 7 Ring-type joint welding neck flange.
FIGURE 4.5 Raised face welding neck flange.
dismantling ring joint connections, the flanges must be forcibly separated to release the ríng from the groove. In crowded instaliations, this could cause major problems. Because of this, the ring joint flange is relegated to applications where space for maintenance and replacementare adequate. Although available for ali pound ratings, flanges with ring-type joint faces are normally used in piping systems rated 400# and higher. See Figure 4.7 for the sectional view of a flange with a ring-type joint face.
FLANGE TYPES Flanges have been designed and developed to be used in a myriad of applications. Each one has its own special characteristics and should be carefully selected to meet specific function requirements. Toe following flanges will be discussed in this chapter:
FIGURE 4.6 Ring-type joint flange.
flanges. Instead a round metallic ring is used that rests in a deep groove cut into the flange face (see Figure 4.6). Toe donut-shaped ring can be oval or octagonal in design. As the bolts are tightened, the metal ríng is compressed, creating a tight seal. Although it is the most expensive, the ring-type joint is considered to be the most efficient flange used in process piping systems. Toe ring and groove design actualiy uses intemal pressures to enhance the sealing capacity of the connecting flanges. Toe superiority of this seal can have its disadvantages, however. When
• • • • • • • •
weldneck; threaded; socket-weld; slip-on; lap-joint; reducing; blind; orífice.
NOTE: A photograph and short description accompanies each flange, as well as symbols to depict the flange as it would appear on a drawing. Because ali flange symbols are somewhat typical, only the step-by-step drawíng techniques used to create the
PIPE DRAFTING ANO DESIGN
59
FLANGE TYPES
orthographic drawing symbols for a weld neck flange will be shown. Toe drawing symbols for the remaining flanges can be created in a similar fashion with only a few minor alterations.
Weld Neck Flange Toe weld neck Jlange shown in Figure 4.8 is occasionally referred to as the "high-hub" flange. It is designed
FIGURE 4.8 Weld neck flange.
to reduce high-stress concentrations at the base of the flange by transferring stress to the adjoining pipe. Although expensive, the weld neck flange is the bestdesigned butt-weld flange available because of its inherent structural value and ease of assembly. Known for its strength and resistance to dishing, the weld neck flange is manufactured with a long tapered hub. Toe tapered hub is created by the gradual increase in metal thickness from the weld joint to the flange facing, Toe symmetrical taper transition is extremely beneficia! under conditions of repeated bending caused by line expansion, contraction, or other externa! forces. See Figure 4.9 for weld neck flange drawing symbols. Weld neck flanges are normally used in severe service applications involving high pressures, high temperatures, or subzero conditions. Toe hole in a weld neck flange is bored to match the ID of the adjoining pipe. In other words, the thinner the wall thickness of the pipe, the larger the bore (hole) through the flange. Conversely, the thicker the wall thickness of the pipe, the smaller the bore through the flange. Because the pipe and the flange have matching inside diameters, there is little restriction to the flow. Turbulence and erosion are therefore eliminated.
Single-line: 12" and smaller
Double-line: 14" and larger
FIGURE 4.9 Weld neck flange drawing symbols.
NOMINAL PIPE SIZES
PIPE R
F L
FA
w~ NE
s
( Ü UTSIDE
-{INCHES)
DIAMETER)
WTL' lºI~
o L T
2" 2 ;,-2" 3" 4" 6" 8" 1 O" 1 2" 1 4" 1 6" 1 8" 2j
2i
3~ 4~
6i 8i 1 oí 12Í
14
16
18
6~ 7~ 8¡ 10 12~ 15 17~ 20~ 23 25~ 28 2Í 3 3! 3~ 3¡ 43..8 4~8 si 5¡ 5Í 6¡ l 1 1; 1 ¡ 1,76 1¡ 1.Z.8 2 2i 2¡ 2~ 8 1 / 16" RAISED FACE INCLUDED ON 'L' & 'T' DIMENSIONS
FIGURE 4.10 Welded Fittings-Flanges Dimensioning Chart.
PIPE DRAFTING AND DESIGN
60
4. FLANGE BASICS
2.
1.
2
1g"
• 11 •
t
23"
J_
-~-5%"
Drow o 23" vertical
3.
line.
OFFSET the flonge foce ond drow the
4.
~-+.-t.
t
~~-
7"
Represent
the
f
14" NPS.
Drow
the 30· flonge
hub
lines.
FIGURE 4.11 Drawing procedures for a 14"-300#RFWN flange. Step l. Using architectural units, draw a vertical line 23" tall. This line will represen! the flange's face diameter. Step 2. OFFSET a line 21/s" to the right to represen! the flange face thickness. Draw a horizontal line across the ends of the two vertical lines to cap the flange face. From the MIDpoint of the flange's face (left Iine), draw a centerline SS/8" to the right to represent the flange length (length thru hub). Step 3. From the right end of the centerline, draw a vertical line 7" upward and downward to represent the pipe's 14" NPS. Step 4. From the vertical ends, draw 30° lines to the flange faceto represent the hub. (45° lines are used when constructing single-líne symbols.)
Drawing the Weld Neck Flange Before constructing the orthographic drawing symbols, three important dimensions must be determined. These dimensions can be found on the Welded Fittings-Flanges Dimensioning Chart, shown partially in Figure 4.10. Toe thumbnail image in this chart represents the raised face weld neck (RFWN) flange and the position of its three dimensions in the chart. Toe three dimensions needed to draw the flange are O, T, and L. Toe O dimension represents the flange's outside diameter. The T defines the flange's face thickness and the L provides the flange' s length or lengih thruhub dimension (sorne charts may show this as the Y dimension). These three dimensions vary for each pipe size and pound rating and must be determined before constructing the drawing symbols of each flange. To find the numerical values for these dimensions of a particular flange, select the appropriate pound ratíng chart, which is, 150#, 300#, 400#, etc. Next, find the
proper size pipe in the Nominal Pipe Size row. Follow the pipe size column down, through the chart, to determine the O, T, and L dimensions. For demonstration purposes, the procedures to draw double-line drawing symbols for a 14"300# Raised Face, Weld Neck (RFWN) flange (Figure 4.11), and a síngle-líne 12"-150#-RFWN flange (Figure 4.12) will be presented. You should find the O, T, and L measurements for these flanges to be 23" (O), 2Ys" (T), SYs" (L) and 19" (O), l W' (T), and 41h'' (L), respective}y. Use Figure 4.11 and the step-by-step procedures that follow to construct the drawing symbols for a 14"-300# raised face, weld neck flange.
Slip-on Flange
Toe slipon flange shown in Figure 4.13 has a low hub that allows the pipe to be inserted into the flange prior to welding. Available with a flat (FFSO) or raised face (RFSO) and shorter in length than a weld neck flange, the slip-on flange is used in areas where short tie-ins
PIPE DRAFTING ANO DESIGN
61
FLANGE TYPES
2.
1.
t
19"
J_ Draw a 19" vertical line. Set lineweight to .70mm.
3.
4.
r
Draw DONUT to represent
Draw horizontal
weld dot.
Set lineweight
. n.
41;;i'
line to represent hub length.
r of hub
line
to .53mm.
FIGURE 4.12 Drawing procedures for a 12"·150#RFWNflange. Step l. Using architectural units, draw a vertical UNE 19". (O dimension from Welded Fitting-Flanges dimensioníng chart) tall. Give the linea 0.70mm lineweight. This line will represent the flange's face diameter, Step 2. From the MIDpoint of the flange's face, draw a horizontal line 4W (T dimensión) to the right to represent the flange's Jength (length thru hub). Step 3. On the right end of the horizontal line, draw a DONUT having a O.O" inside diameter anda 1.75" outside diameter to represent the weld dot. Step 4. Change the LINEWEIGHT of the horizontal line (hub) to 0.53mm. This will match the lineweight of the pipe when the symbol is attached to it.
are necessary or space limitations necessitate its use and in replacement operations when connecting preexisting equipment. Toe slip-on flange does have two significant disadvantages, however: the requirement of two fillet welds, one interna! and one external, to provide sufficient strength and prevent leakage, and a life span about one-third that of the weld neck flange. They are preferred over welding neck flanges by many users because of their lower initial cost. However, the total cost after installation is not much less than the welding neck because of the additional welding involved. See the Taylor Forge Seamless Fittings Dimensioning Chart in Appendix A for dimensions of the slip-on flange. Toe drawing symbols for the slip-on flange are shown in Figure 4.14.
Lap-Joint Flange Toe lapjoint jlange in Figure 4.15 is primarily used in carbon or low alloy steel piping systems. Attachment
FIGURE 4,13 Slip-on flange.
of the lap-joint flange to the piping system requires a lap-joint stub end. The lap-joint flange and stub end assembly are used mainly in piping systems that necessitate frequent dismantling for inspection or
PIPE DRAFTING AND DESIGN
62
4. FLANGE BASICS
Single-line: 12" and smaller
Double-line: 14" and larger
FIGURE 4, 14 Slip-on flange drawing symbols.
A seal weld is sometimes applied around the threaded joint to reduce the possibility of leakage. This technique, however, cannot be considered as entirely satisfactory nor is it always possible. Figure 4.18 represents the síngle-líne threaded flange drawíng symbol.
Socket-Weld Flange Toe socketweld
flange
shown
in Figure
4.19
is also similar to the slip-on flange. lt was originally
FIGURE 4.15 Lap-joint flange.
routine maintenance. It is also used in the erection of large-diameter or hard-to-adjust pípíng configurations because of its quick bolt hole alignment. Figure 4.16 depícts the drawing symbols for the lap-joínt flange.
Threaded Flange Toe threaded jlange depicted in Figure 4.17 is similar to the slip-on flange, but the bore is threaded. Its principal value is that it can be assembled without welding. This feature makes the threaded flange well suited to extreme pressure services that operate at normal atmospheric temperatures and in highly explosive areas where welding may create a hazard. Threaded flanges are not suited, however, for conditions involving temperatures or bending stresses of any significance, particularly when cyclic conditions exist, which may cause leakage through the threads. After just relatively few cycles of expansion and contraction or movement caused by stress, the threaded flange no longer performs adequately.
developed for use in small-diameter (~') híghpressure piping systems. Like socket-weld fittings, pipe is inserted into the socket then welded. An interna! weld is often employed for added strength. By grinding the interna! weld smooth, turbulence and flow restriction are kept to a minimum. Toe single-line drawing symbol for the socket-weld flange is shown in Figure 4.20.
Reducing Flange Like the reducer fitting, the reducing jlange in Figure 4.21 is used to make a reduction in the diameter of the pipe. A reducing flange is most frequently used in installations with limited space. Crowded situations may necessitate the use of the reducing flange because it has a shorter overall length when compared to a weld neck flange and reducer-fitting configuration. Be advised however, the flow should travel from the smaller size to the larger. If the flow were reversed, severe turbulence could develop. Callouts are placed on drawings to describe the reducing flange in the same manner as those used on the reducer fitting: large end first, small end second. One additional note is needed, however. The pound ratíng and flange type are included in the callout. Toe reducing flange maintains all the dimensional characteristics of the larger end size. One exception, however, is the interna! bore. Toe interna! bore is
PIPE DRAFTING ANO DESIGN
63
FLANGE TYPES
Single-line: 12" and smaller
Double-line:
14" and larger
FIGURE 4.16 Lap-joint flange drawing symbols.
g
OR g
FIGURE 4.17 Threaded flange.
FIGURE 4.20 Socket-weld flange drawing symbols.
,,
FIGURE 4.18 Single-line threaded flange drawing symbol.
-
..• Á
FIGURE 4.21 Reducing flange.
FIGURE 4.19 Socket-weld flange.
manufactured to match that of the smaller pipe size. Figure 4.22 shows a 12" X 6"-300# Raised Face Slip-On flange. Notice the use of abbreviations to keep the size of the callout to a mínimum. Reducing flanges are manufactured as weld neck, slip-on, or threaded flange types. PIPE DRAFTING AND DESIGN
64
4. FLANGE BASICS
Blind Flange Toe blind flange depicted in Figure 4.23 serves a function similar to that of a plug or cap. It is used to termínate the end of a piping system. Toe blind flange is basically a flange that does not have a hub ora bored center. Blind flanges have the face thickness of a flange, a matching face type, and similar belting pattem. Blind flanges can also be used to seal a nozzle opening on a pressure vessel. Because it is bolted, the blind flange provides easy access to the interior of a vessel or pipe, unlike a cap that is welded. Figure 4.24 represents the drawing symbol for the blind flange.
Orifi.ce Flange Of the flanges discussed, the orífice jlange (Figure 4.25) is the only one that actually performs a function. Toe function of the orífice flange is to measure the rate of
the flow of the commodity through the piping system. Orífice flanges are easy to recognize because they have a hole drilled through the face of the flange perpendicular to the pipe. They also have an additional set of bolts
called jack screws. These screws are used to help separate the flanges so inspection and/ or replacement of the orífice plate can be performed. Toe orífice flange is a single component of the orífice jlange union assembly. Toe orífice flange union is composed of two orífice flanges, an orífice plate, bolts, nuts, [ack screws, and two gaskets. Toe orífice flange union is used to measure, or meter, the amount of pressure drop through the orífice plate. Toe length of pipe within the piping system where orífice flanges are installed and where these measurements are recorded is known as a meter run. Figure 4.26 shows the orífice flange union assembly installed in a meter run. Toe broken-out section shown in Figure 4.27 shows the interna! view of a meter run. Toe orífice plate, which is not typically furnished with the orífice union assembly package, looks similar to a large ring washer with a handle attached. When fully assembled, the orífice plate is sandwiched between the orífice flanges. Valve taps are inserted into pressure holes that allow for the attachment of field monitoring equipment so accurate measurements can be recorded.
BLIND
FIGURE 4.24 Blind flange drawing symbols. {Vessel nozzle is o
12"-300#
RFSO)
FIGURE 4.22 Reducing flange drawing symbol with callout.
FIGURE 4.23 Blind flange.
FIGURE 4.25 Orifice flange.
PIPE DRAFTING ANO DESIGN
FLANGE
65
llOLTS
Orifice flanges can be either weld neck, slíp-on, or threaded. Toe weld neck and threaded orifice flanges are manufactured in 300# and larger pound ratings. However, the slip-on orifice flange is only available as a 300# raised face flange. Toe single-line and doubleline drawing symbols for the orifice flange are shown in Figure 4.28.
BOLTS
FIGURE 4,26 Orífice flange unión assembly. Courtesy of Nisseki Chemical Texas lnc., Bayport, Texas.
To complete any flanged assembly, two additional items are required: bolts and gaskets. Bolts obviously hold mating flanges, nozzles, or valves together. Toe pressure rating of a flange will determine the size, spacing, and number of bolts required. As the nominal pipe
ORIFICE FLANGES
ORIFICE PLATE
FLANGE TAPS FIGURE 4.27 Broken-out section of meter run.
%"(TYP)
G)
Single-line: 12" and smaller
FIGURE 4.28 Orífice flange drawing symbols.
V2 "(TYP)
---fi~3/8"
Double-line: 14" and larger
PIPE DRAFTING AND DESIGN
66
4. FLANGE BASICS
size and pressure ratíngs change, so will the diameter, spacing, and number of bolts. Flanges are designed to match the bolt circle and bolt hole dimensions of other flanges that are of the same diameter and pressure ratíng. Bolt hole arrangements may seem inconsequential, but when one considers the fact that components of a piping system may be fabricated in one country, then shipped to another country for assembly, bolt alignments become increasingly important. lt is critical that drawings convey the exact orientation of flanges to the fabricator. Otherwise, bolt holes may not align properly. ANSI standards require all flanges straddle the horizontal, vertical, or northsouth centerlines of pipe and equipment, as shown in Figure 4.29, unless otherwise noted on a drawíng.
To assure that bolt holes on flanges, nozzles, or valves align properly, holes are equally spaced around the flange. One column on the Taylor Forge Forged Steel Flanges Dimensioning Chart found in Appendix A indicates the number and diameter of the bolt holes on flanges. Notice bolts are found in quantities of 4, that is, 4, 8, 12, 16, etc. The following formula makes bolt hole location and alignment quick and simple. Formula: 360º/# of holes = angular location Example: 360º/8 (holes) = 45º Using this formula shows holes on an eight-hole flange to be spaced 45º apart. By straddling the centerline, holes will be positioned 221/zº on each side of the centerline (see Figure 4.30).
HORIZONTAL BOLT HOLES STRADDLE HORIZONTAL ANO VERTICAL (t_.
ELEVATION I 1-
::::)
o (/)
<,
~I O:::
o z
BOLT HOLES STRADDLE NORTH/SOUTH ANO EAST/WEST (t_.
PLAN FIGURE 4.29 Bolt hole orientation.
PIPE DRAFTING ANO DESIGN
67
GASKETS
45·
4-BOLT HOLES
8-BOL T HOLES
12-BOLT HOLES
16-BOLT HOLES
FIGURE 4.30 Bolt hole spacing.
Bolts are available in two types: machine or stud. Machine bolts have a ''head" on one end and threads on the other. Stud bolts have threads throughout their entire length and require the use of two nuts (see Figure 4.31). Stud bolts are the most commonly used type and are available in two grades: A-193-87 and A-193-816. B7 grade bolts are used for temperatures up to 1,000ºF. 816 bolts are used when temperatures exceed l,OOOºF. Figure 4.32 depicts a sectional view of two flanges being mated around a gasket and secured with stud and machine bolts.
GASKETS Toe primary purpose of any flanged assembly is to connect piping systems in such a manner as to produce a leak-free envirorunent. Hazardous and combustible materials and extreme pressures and temperatures require the utmost in safety precaution. Creating a leak-proof seal between two connecting metal surfaces in an industrial setting is almost impossible. Therefore, gaskets perform a vital function in plant safety.
PIPE DRAFilNG AND DESIGN
68
4. FLANGE BASICS
Using a gasket material softer than two adjoining flanges is an excellent way to eliminate the possibility of a fluid escape. Gaskets can be made of materials such as asbestos, rubber, neoprene, Teflon, lead, or copper. When bolts are tightened and flange faces are drawn
FIGURE 4.31 Stud and machine bolts.
together, the gasket material will conform to any ímperfections in the flange faces to create a uniform seal. Figure 4.33 demonstrates the three types of gaskets that can be found in piping systems. They are full face, flat ring, and metal ring, Full face gaskets (Figure 4.34) are used on flat face flanges. Flat ring gaskets (Figure 4.35) are used on raised face flanges. Metal rings (Figure 4.36) are used on ring-type joint flanges. A gasket's thickness must be accounted for when dimensioning the piping system. Toe typical gasket has a thickness of Ys" (3.175mm). At every occurrence of a flange bolting to a nozzle, two flanges joining one another, two valves joining one another, or a flange connecting to a valve, a gasket thickness must be added to the length of the pipe components. Figures 4.37 and 4.38 show that a flat-ring gasket does occupy space. Though it is only Ys" thick, a gasket cannot be ignored. Figure 4.39 depicts the gap between ring-type joint flanges. Toe ring-type joint section of the Welded Fittings-Flanges Dimensioning Chart gíves the gap measurement as the G dimension. This dimension will
STUD BOLT
MACHI NE BOLT FIGURE 4.32 Drawing representation of stud and machine bolts.
PIPE DRAFTING ANO DESIGN
GASKETS
69
FIGURE 4.33 Gaskets. Courtesy of Flexitallic, lnc.
FIGURE 4.36 Metal ríngs for ring-type joint flanges. Courtesy of
Fle:xitallie, !ne.
FIGURE 4.34 Full face gaskets.
FIGURE 4.3 7 Flat ring gasket and flange. Courtesy of Flexitallic, lnc.
FIGURE 4.35 Flat ring gaskets. Courtesy of Flexítallic, lnc. FIGURE 4.38 Flat ring gasket between flanges. Courtesy of Fle:xitallie, lnc.
vary depending on the size and pound rating of the flange. This is an important consideration to keep in mind when dimensioning piping runs that have ringtype joint connections.
For each instance of a gasket or ríng, gap spacing must be reflected in the dimensions shown on a piping drawing. Tick marks are used to indicate each location where a gasket or ring gap has been included in
PIPE DRAFilNG AND DESIGN
70
4. FLANGE BASICS
the dimensioning of the p1pmg configuration. Tick rnarks are drawn approximately W' long and are placed on piping drawings near the location where a gasket or ring is to be installed. Figure 4.40 depicts two tick marks, one on each end of a valve, that have been included in the total dimension between the faces of the two flanges. Toe dimension would be the sum total of one valve and two gaskets.
~·--.=_.!,.....,. ;;;---~·
.-,r,J,lii.
-
, .. ,
1
~ :~
~-·~Á'
FIGURE 4.39 Ring-type joint gap spacing.
EACH BOLTED CONNECTION MUST HAVE A GASKET! ~~ TIC MARK USED TO ----REPRESENT THE GASKET 6"-150#,
FACE TO FACE LENGTH OF VALVE
+ THICKNESS OF TWO GASKETS = VALVE/FLANGE ASSEMBLY OIMENSION
( 1
o
Y2~)
Y4 1 o}¡
+
___..¡ 1
GATE
~[><]~ I' ,o}¡ 'I
FIGURE 4.40 Include gaskets with dímensions.
PIPE DRAFTING ANO DESIGN
71
EXERCISE INf-ORMATION
CHAPTER 4 REVIEW QUIZ
8. Name the two types of bolts used to assemble
flanges.
1. Name the seven forged steel flange pound ratings. 9. Accordíng to ANSI standards, which centerlines
should flanges straddle on pipe and equipment?
2. Name the four pressure classes for cast iron flanges.
3. What are the three flange face types discussed in this chapter?
10. Llst four materials used to manufacture gaskets.
4. What is the thickness of the raised face on a 600#
raised face flange?
EXERCISE INFORMATION S. Briefly describe five types of flanges depicted in this
chapter.
SIZE/RATING 4"-150# R.F.W.N.
o
T
L
_
6"-300# R.F.W.N. ---10"-400# R.F.W.N. 16"-600# R.F.W.N. 8"-óOO# R.F.W.N.
_
6. Give O, T, and L dimensions of the following flanges. 7. What is the purpose of an orifice flange union assembly?
Toe flanges depicted in Figure 4.41 wil1 be used to complete the exercises in Chapters 4, 5, and 10. To complete the exercises, draw the symbols shown usíng the following guídelines: • Draw ali flange symbols ful1 size using dimensions found on the Welded Fittings-Flanges Dimensioning Charts, • Items in Figure 4.41 that are represented with a "Phantom" linetype are for reference only and are not to be drawn. They will not be part of the finished symbol. • Double-line symbols are drawn with a "default" Iineweíght, Síngle-line symbols are drawn with a 0.53mm lineweight. • Draw ali weld dots with the DONUT command having a O'' inside diameter anda 1.75" outside diameter. • Create a BLOCK of each symbol. Use a block name that appropriately describes the flange and its size and pound rating. (DO NOT include text with the blocked symbol.) • BLOCK the symbol with the base point placed at an appropriate location usíng an ENDpoint, MIDpoint, or CENter osnap. SAVE the file as Flange Symbols.dwg.
PIPE DRAFTING ANO DESIGN
72
4. FLA1'GE BASJCS
300# RFWN
~
1 4"
~-1
00
@-10"-300
8"
00
@12"-300
1 O"
c--1 ~--
_ _J
14"-300
1 2"
150#RFWN
00
@>
__ _J
~
14"-300
14"-150
LT
~
12"-300
t
1 o"-300
LT
12"-150
00
00
~--
LT
10"-150
OD
@---
~
~
14"-150
LT
~
12"-150
LT
~
10"-150
LT
~
8"-300
OD
8"-300
LT
8"-150
OD
8"-150
LT
6"-300
00
6"-300
LT
6"-150
OD
6"-150
LT
4"-300
LT
4"-150
00
4"-150
LT
6"
4" 4"-300 00 FIGURE 4.41 Flange drawing symbols.
PIPE DRAFI1NG AND DESIGN
e, Sil "'*
!. :::,
o
::!1 Sil
~ ~
(JQ
G)
DRAW ALL VIEWS AS SHOWN 1 '.t' -300# RFWN
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EXERCISE 4-1
zo m X
93 o ¡¡; ¡¡¡
74
4. FLA1'GE BASJCS
FITIING MAKE-UP DRAW ALL VIEWS AS SHOWN 14" -300# RFWN
DRAW ALL VIEWS AS SHOWN 1 ~ -300# RFWN
1
r-! 1
EXERCISE 4-2
PIPE DRAFI1NG AND DESIGN
75
CHAPTER 4 DRAWING EXERCISES
FITIING MAKE-UP SOLVE FOR THE MISSING DIMENSIONS
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@
150# RFWN
1 2"
1 O"
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150# RFWN
300# RFWN
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300# RFWN
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8" 1 O"
1
1 O"x8"
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®
300# RFWN
150# RFWN
8"
1
1 o"
1 O" xB"
1 2" x 1 O" NOTE: ALL
GASKETS 1 /e:'
PIPE DRAFilNG AND DESIGN
EXERCISE
4-3
DRAW ALL VIEWS AS SHOWN 1 4" -300# RFWN DO NOT DIMENSION
14"
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EXERCISE 4-6
CHAPTER
5 Val ves WHAT IS A VALVE?*
As long as industries continue to devise new reasons to control gases, liquids, and even solids, valve design will continue to meet the demand.
A valve is a product rarely noticed by the average person, yet it plays an important role in the quality of our lives. Each time you turn on a water faucet, use your dishwasher, turn on a gas range, or step on the accelerator in your car, you operate a valve. Without modern valve systems, there would be no fresh, pure water in your home, no modern appliances, and no gasoline waiting at the comer service station. One of the most widely observed, but least recognized, type of valve is the fire hydrant. Fire hydrants are connected to municipal water supply systems. They are specialized in that they are underground valves that can be opened and closed from an aboveground location when needed in emergency situations. By definition, a valve is a device that controls the flow of a fluid. But today's valves can control not only the flow but also the rate, the volume, the pressure, and the direction of a fluid within a pipe. Valves are not Iimited to fluids. They can control liquids, gases, vapors, slurries, or dry materials. Valves can turn on or off, regulate, modulate, or isolate. They can range in size from a fraction of an inch to as large as 30 ft in diameter and can vary in complexity from a simple brass valve, available at the local hardware store, to a precision-desígned, highly sophisticated coolant system control valve made of exotic metal alloy used in a nuclear reactor. Valves can also control the flow of all types of commodities. From the thinnest gas to highly corrosive chernicals, from superheated steam to toxic gases, from abrasive slurries to radioactive materials, valves can be desígned to service them all. They can handle temperatures from the cryogenic region to molten metal exceeding 1,500ºF, and valves can contain pressures ranging from severe vacuum to 20,000 pounds per square inch. The valve is one of the most basic and indispensable components of our modem technological society.
COMMON VALVE TYPES Valves are manufactured in numerous sizes, body styles, and pound ratings to meet a wide variety of application needs. Valves are also manufactured with varying types of end preparations that allow them to be readily mated to flanges or pipes of the same size and rating. Valve end preparations can be screwed, socketweld, beveled, or flanged. Flanged valves are manufactured to have either raised, flat, or ring-type joint faces.
Gate Valves The gate valve is the most frequently used valve in pípíng systems. It is a general service valve that is used primarily for on-off, nonthrottling applications. When fully opened, the gate valve creates rninirnal obstruction to the flow. Gate valves control the commodíty flowing through the pipe with a flat, vertical wedge, or gate, that slides up or down as the valve's handwheel is turned. As the handwheel is rotated, the wedge will slide through the valve body to block or release the flow. Designed to be either fully opened or closed, the gate valve should not be operated in a partially opened/ closed position. A partially opened gate valve will hasten erosion caused by the commodity within the pipe and will ruin the valve seat in a short period of time. Turbulence from the commodity will also cause the wedge to vibrate, creating a "chattering" noise when the valve is partially opened. Figure 5.1 depicts the externa! and intemal views of a typical gate val ve.
• "What is a Valve?" Courtesy of VMA (Valve Manufacturers Association).
79
C, 2012 Ehcvic-r lnc.
Ali rlghtsrcserved.
80
5. VALVES
FIGURE 5.1 Gate valve.Courtesyof [enkins Bros.
As with pipe, fittings, and flanges, valves are represented by symbols on piping drawings. These symbols are developed in such a manner as to describe the valve's body style, end type, and handwheel orientation. Syrnbol sizes are established from dimensions provided in manufacturers' catalogs or data sheets. Three dimensions are crucial when drawing a valve symbol: face-to-faoe (length), handwheel height, and handwheel diameter (see Figure 5.2). The length of a valve is represented on most dimensioning charts as the facetoface dimension. The faceto-face dimension is a length that is standard among valve manufacturers and defines the length of a valve from one end to the other. Also important are the height and diameter of a valve's handwheel. These measurements are necessary to establish operational clearances
and worker accessibility around the valve. Of particular importance is the valve's open handwheel height. This dimension defines the maximum height of the valve when it is in the full-open position. The open handwheel height is measured from the centerline of the valve body to the tip of the valve stem. The valve stem is a threaded rod that connects the valve's wedge or gate to the handwheel. Valve stems fall into one of two categories: rising or nonrising. A risíng stem is one in which the stem rises and lowers as the handwheel is rotated. The handwheel remains in a stationary position as the stem passes through it. On valves having a nonrising stem, the handwheel is attached to the end of the stem and moves up and down with the stem as the valve is opened or closed. The length of a rising stem must be determined before the handwheel is represented on a drawing. When the valve is fully opened, the stem is at its híghest point. The maximum distance the stem will extend above the handwheel is approximately equal to the nominal size of the pipe. Knowing the length of the stem allows a piping designer to draw the valve symbol with the handwheel located at the proper distance from the end of the stem which ultimately aids in determining when interference problems may occur, Another important dimension is the diameter of the flanged faces on flanged valves. When representing flanged valves, the diameter of the valve's flanges must be drawn to match the size and pound rating of the flange or nozzle to which the valve is being bolted. Because most valve dimensioning charts do not provide this information, a drafter must refer to the flange dimensioning chart to find the proper flange OD measurements. Valve symbols vary from company to company and client to client. It is therefore imperative that a drafter be familiar with the syrnbols being used on a project before work begíns on that new project. The symbols shown in this text are typícal of those found on many piping drawings. They should not be considered standard for all applications, however. The symbols shown in Figure 5.3 represent screwed, socket-weld, and flanged gate valves. Notice also the two methods of representing handwheels. The valve rotations represented in Figure 5.4 depict the possible rotations in which valves may appear on drawings. Bolt-hole orientations of nozzles on vessels, pumps, or other equipment may not always straddle the preferred north-south or east-west centerlines. Also, accessibility may not always allow for vertical or horizontal positioning of handwheels. Therefore, angular rotation of valves becomes imperative and the rotations shown in Figure 5.4 indicate how those valve rotations would appear on piping drawings.
PIPE DRAFTING ANO DESIGN
81
COMMOJ\ VALVE TYPES
VALVES
150#
NOMINAL PIPE SIZES -{INCHES) PIPE ( ÜUTSIDE 01AMETER) G A T E
G L
V o A EB
L
V
e
E o
s
N
T R
o L
-~
L --~
1
i l~ o L H
[~9 ¡-L
H
E
e
K
o
L H
r~
e
L H
H--
-J
__ ÍH
-r
o L H
2
3 4
2i
312 412 6g 8g 1014 12..24 14
7
8
6
8 10 1 2 14 1 6 18
9 10~ 11~
15i 2oj 25i 35f 8 9 10 14 8 9~ 1 1 "1 16 13j 1 6"1 19..24 24"1
13
14
7
6
9
18
1 6 17
44 52 "1 60"1 70"1 79~ 89 16 18 18 22 24 27 19
"1
26
* * * * * * * * * * * * 26"1 * * * 46-¡¡* * * 21i * * *
8 9 10 12 16 10 111 4 13 i 171 4 21j 27i 28t5 29t5 38 39f 13i 13i 13i 16 16 8 9~ 1 112 14 1912 24~ 5
15
16
27"1
1ot 12i 13Í
* * * * * * * *
35 39 18 20~
150# RF
NOTE: ALL DIMENSIONS ARE IN INCHES * REFER TO VENDOR'S CATALOG FIGURE 5.2 Flanged valve dimensioning chart.
SCREWED
FLANGED
PLAN PLAN ELEVATION
PLAN
END
SOCKET-WELD ~
PLAN
ELEVATION
END
ELEVATION
END
SINGLE-UNE FIGURE 5.3 Gate valve drawing symbols.
PIPE DRAFilNG AND DESIGN
ELEVATION
END
DOUBLE-LINE
82
5. VALVES
so'
60.
45•
30·
o·
o· -so'
-45.
-60·
-so'
FIGURE 5.4 Gate valve rotation drawing symbols.
Drawing the Gate Valve Figures 5.5 and 5.6 are pictorial representations of the step-by-step procedures used to draw a 10''-300# RFWN gate valve using manual and AutoCAD methods of construction. Symbols depicting other valve types are developed using similar step-by-step procedures but with minor changes or alterations that would reflect the representation of that particular valve.
Globe Valves Globe valves are used primarily in situations where throttling of the commodity is required. By simply rotating the handwheel, the rate at which the commodity flows through the valve can be adjusted to any desired level. Havíng the valve seat parallel to the line of flow is an important feature of the globe valve. This feature makes the globe valve efficient when throttling commodities as well as yielding minimal disk and seat erosion. This configuration, however, creates a large amount of resistance within the valve. Toe design of the globe valve body forces the flow of the commodity to change direction within the valve itself. This change in direction creates substantial pressure drop and turbulence. Toe globe valve is therefore not recommended when flow resistance and pressure drop are to be avoided. Figure 5.7 depicts the interna! view of a globe valve.
Drawing symbols of the globe valve are similar to those of the gate valve. Measurements used to draw the valve are found on manufacturers' dimensioning charts. One noticeable difference is the use of a darkened circle positioned at the intersection of the diagonal lines in the valve's body. One other difference, though not quite as noticeable, is the use of a nonrising stem on globe valves. Drawing symbols for globe valves are shown in Figure 5.8.
Angle Valves Toe angle valve, like the globe valve, is used for throttling. As shown in Figure 5.9, the flow entering the valve and the flow leaving the valve form a 90º angle. In the event a pipe is making a 90° turn, the angle valve is used to eliminate the need for a 90º elbow and additional fittings. Angle valves as well as globe valves are typically installed so a commodity will flow in an upward direction through the valve body. This upward flow direction will keep pressure under the disk seat. Pressure from below the seat promotes easier operation and reduces the erosive action on the seat and disk. For high-temperature commodities, however, such as superheated steam, the flow direction is reversed. When the valve is closed, temperature on the lower side
PIPE DRAFTING ANO DESIGN
83
COMMON VALVE TYPES
1.
2.
{D
1~·
-ii--=-
1.
Llci Gother volve's
dimensions
from chort.
3.
18"
..
1
Orow volve' s body length and flange diameter.
4. B.
~
B.
Draw the handwheel 's centerline.
Draw diagonal body lines and erase construction.
5.
1 O" 1 O"
LfJ
6.
u, o. 3
r-, l{)
Drow hondwheel's diameter and stern's height.
Add diagonal
handwheel
lines.
FIGURE 5.5 Gate valve. Manual step-by-step drawing procedures. Step l. Use the appropriate vendor's catalog to determine the overall dimensions of a 10"-300#RFWN gate valve. Find the valve's length, L (face-to-face) (18"); handwheel height, H (57"); handwheel diameter (handwheel O) (20"); and flange diameter (flange O) (171h"); and flange face thickness (flange T) (!%"). Step 2. Lightly draw a rectangle having the width of the face-to-face (18") dimension and the height of the flange diameter (171h"). Draw two lines parallel to the vertical ends 17-'" away from and toward the center of the rectangle. Step3. A. Draw intersecting, diagonal lines (A) from the ends of the inner vertical lines to create the valve body. B. Erase the horizontal construction lines (B) between the inner vertical lines that form the val ve' s flange faces. Step 4. From the intersection of the diagonal lines (center of valve body), draw a vertical centerline the length of the handwheel's "open" height (57"). Step S. Measure 10" (distance equal to NPS) down from the top of the centerline. Draw a construction line perpendicular to the centerline. Measure one-half (10") of the handwheel's diameter (20") on either side of the handwheel centerline. Draw a line below and parallel to the handwheel to represent the thickness of the handwheel. Draw lines parallel to the top of the valve centerline, above the handwheel to represen! the valve stem. Though not the actual measurement, 1" can be used for both the handwheel and valve stem thickness. Step 6. To complete the handwheel representation, draw a line from each end of the handwheel down to the center of the valve body. Lines drawn in the opposite direction can also be used as an alternative.
PIPE DRAFTING AND DESIGN
84
5. VALVES
1.
2.
tf
c.
1.
~ Gather
volve's
dimensions
from chart.
11'
18" ..
c.
1
B.
Draw valve body length, height and foce thickness.
4.
3. A.
A.
~
A.
A. Draw the hondwheel' s centerline.
Drow diagonal body and flange cap lines.
5.
1~"
20"
LfJ
6. V)
o..
3
r-, l{)
Draw hondwheel's
diameter and stern's height.
Add diagonal
handwheel
lines.
FIGURE 5.6 Gate valve. AutoCAD step-by-step drawing procedures. Step l. Use the appropriate vendor's catalog to determine the overall dimensions of a 10"-300# RFWN gate valve. Find the valve's length, L (face-to-face) (18"); handwheel height, H (57"); handwheel diameter (handwheel O) (20"); flange diameter (flange O) (17W); and flange thickness (flange T) (17,4(). Step 2. A. Draw a vertical line 17'h" long to represen! the flange diameter of the valve's face. B. OFFSETthe vertical Iine 18" (face-to-face dimension) to the right to establish to valve's length. C. From each end of the valve OFFSET,toward the center, the valve's flange face thickness (17,{¡"). Step3. A. Draw horizontal Iines (A) to "cap" the ends of the valve's flange face. B. Draw intersecting, diagonal lines (B) from the ends of the vertical lines to create the valve body. Step 4. Draw a vertical centerline from the center of the valve's body 57" long to represen! the handwheel's "open" dimension. Step S. Draw a 20" (handwheel's diameter) horizontal Iine, equally centered on the valve's centerline, 10" (distance equal to NPS) from the top end of the valve's centerline. Give the valve's handwheel and stem a 0.3mm lineweight. Step 6. To complete the handwheel representation, draw a line from each end of the handwheel down to the center of the valve body. Lines drawn in the opposite direction can also be used as an altemative.
PIPE DRAFTING ANO DESIGN
85
COMMON VALVE TYPES
~ TOP
FRONT
END
TOP
FRONT
END
FIGURE 5.8 Globe valve drawing symbols. FIGURE 5. 7 Globe valve. Courtesy
of VELAN.
of the disk is signífícantly higher than that on the upper side. Because the valve's stem is on the upper side of the disk, it will be cooler. This temperature differential causes the valve stem to contract, lifting the disk off the seat. This lifting action will result in the seat and disk faces being scored. To avoid this problem, valve manufacturers recommend installing globe and angle valves so high-temperature commodities flow into the valve from the upper side. This flow direction will keep pressure above the disk, forcing it into the seat and creating a tighter seal. Figure 5.10 depicts the drawing symbols for the angle valve.
Check Valves Check valves differ signifícantly from gate and globe valves. Check valves are designed to prevent backflow. Backflow simply means the flow that has reversed itself within a pipe and begins to flow backward. There are many designs of check valves, but the two most common types are the swing check and the lift check. Check valves do not use handwheels to control the flow of a commodity but instead use gravity and the pressure of the commodity to operate the valve (see Figure 5.11). Toe swing check valve is installed as a companion valve to the gate valve. As the name implies, thís valve has a swinging gate that is hinged at the top and opens as a commodity flows through the valve. When the valve disk is in the open position, a clear flow path is
FIGURE 5.9 Angle valve. Courtesy of [enkins Bros.
created through the valve. This clear path creates minimal turbulence and pressure drop within the valve. Pressure must always be under the disk for the valve to function properly. When flow reverses, the pressure and weight of the commodity against the disk will force the disk against the seat, stopping all backflow. Check valves are often regarded as safety or precautionary equipment.
PIPE DRAFTING AND DESIGN
86
5. VALVES
TOP
TOP
FRONT
FRONT
END
Single-fine symbols
END
Double-line symbols
FIGURE 5.10 Angle valve drawing symbols.
FIGURE 5.11 Swing and lift check valves. Courtesy of Crane Co.
Toe lift check valve is often bolted directly to a globe valve. Figure 5.11 shows the lift check valve has a body style similar to the globe valve. As the flow enters the valve, the disk is lifted up off the seat to allow the flow to pass. As with the globe valve, there is significant turbulence and pressure drop. There are two types of lift check valves: horizon tal and vertical. Both of these valves use either a disk or ball and the force of gravity to close the valve in the event of reverse flow. Toe horizontal lift check valve has a seat that líes parallel to the flow. Toe result is an S-shaped body style that mandates the valve be installed in the horizontal position only and has a flow that enters from below the seat. Toe flow entering the valve raises the disk or ball off the seat, permitting the commodity to pass through the valve body. Toe vertical lift check valve is designed to work automatically on flow that is traveling in an upward
direction only. Similar to the horizontal lift check, vertical lift check valves use a disk or ball that raises off the seat when a commodity flows upward through the valve. When the flow stops, gravity will reseat the disk or ball preventing backflow. This check valve requires the outlet end of the valve to always be installed in the up position. Sorne manufacturers refer to lift check valves that employ the use of a ball as a hall check valve. Figure 5.12 depicts drawing symbols used to represent the check valve. Notice the top and front views are identical and both symbols indicate the direction of flow.
Ball Valve Toe ball valve is an inexpensive altemative to other valves. Ball va/ves use a metal ball with a hole bored through the center, sandwiched between two seats to control flow. Used in many hydrocarbon process
PIPE DRAFTING ANO DESIGN
87
COMMON VALVE TYPES
TOP
TOP
END
FRONT
FRONT
Single-line symbols
END
Double-line symbols
FIGURE 5.12 Checkvalve drawing symbols.
Plug Valves
FIGURE 5 .13 Ball valve. Courtesy of Jenkins Bros.
applications, hall valves are capable of throttling gases and vapors and are especially useful for low-flow situations. These valves are quick opening and provide a very tight closure on hard-to-hold fluids (see Figure 5.13). Ball valves do not use a handwheel but instead use a wrench to control the flow. A 90° turn of the wrench opens or doses the valve. This simple design yields a nonsticking operation that produces minimal pressure drop when the valve is in its full-open position. Drawing symbols for the hall valve are shown in Figure 5.14.
Plug Valve Unlike other valves, the plug valve uses either a handwheel or a wrench to operate the valve. Plug valves provide a tíght seal against hard-to-hold commodities and require a mínimum amount of space for
installation. Unlike the hall valve, the plug valve uses a tapered wedge rather than a hall to create a seal. This wedge, or plug, has an elongated opening, which when placed in the open position, allows the commodity to pass through the valve. The plug is the only movable part of the valve and its tapered shape assures positive seating (see Figure 5.15). Plug valves are designed with etched grooves along the tapered plug to permit a lubricant to seal and lubricate the interna} surfaces as well as to provide a hydraulic jacking force to lift the plug within the body, thus permitting easy operation. The clear and open passageway through the valve body provides little opportunity for scale or sediment to collect. In fact, the plug seats so well that as the plug is rotated, foreign debris is wiped from the plug's externa! surfaces. These valves, however, do require constant lubrication to maintain a tight seal between the plug and the body. Figure 5.16 depicts drawing symbols used to represent the plug valve.
Butterfly Valve The butterfly valve has a unique body style unlike the other valves we have discussed. The butterfly uses a circular plate or wafer operated by a wrench to control the flow. A 90º tum of the wrench moves the wafer from a fully open position to a fully closed position. The wafer remains in the stream of flow and rotates around a shaft connected to the wrench. As the valve is being closed, the wafer rotates to become perpendicular to the direction of flow and acts as a dam to reduce or stop the flow. When the wrench is rotated back to the original position, the wafer aligns itself with the direction of flow and allows the commodity to pass through the valve (see Figure 5.17).
PIPE DRAFTING AND DESIGN
88
5. VALVES
TOP
TOP
FRONT
FRDNT
END
Single-line symbols
END
Double-line symbols
FIGURE 5.14 Ball valve drawing symbols.
WEDGEPLUG O·SEAL VALVE
FIGURE 5.15 Plug valve. Ccurtesy of Siockham Valves.
Butterfly valves have minimal turbulence and pressure drop. They are good for on - off and throttling service and perform well when controlling large flow amounts of liquids and gases. However, these valves do not normally create a tight seal and must be used in low-pressure situations or where sorne leakage is permissible. Drawing symbols for the butterfly valve are shown in Figure 5.18. A dimensioning chart for the butterfly valve is included in the appendix.
Relief Valves Relief valves have a purpose quite different from the previous valves. They are designed to release excessive pressure that builds up in equipment and piping
systerns. To prevent major damage to equipment, and more importantly, injury to workers, relief valves can release elevated pressures before they become extreme. Relief valves use a steel spring as a means to automatically open when pressures reach unsafe levels. These valves can be adjusted and regulated to pop off when interna! pressures exceed predetermined settings. Once interna! pressures return to operational levels, the relief valve doses. Figure 5.19 shows the interna! mechanism of a relief valve. Another valve that performs the same basic function as the relief valve is the pressure safety valve. Although similar in design and appearance, the two valves operate differently. Relief valves are used in píping systems that service líquíd commodities and are designed to open proportionally, that is, as pressure from the commodity increases so does the opening of the valve. Toe hígher the pressure, the larger the opening. Toe pressure safety valve, however, is used with hígherpressure commodities such as steam and gas. Pressure safety valves are designed to open completely when interna! pressures exceed the setting for which the interna! spring has been set. As with the relief valve, once interna! pressures return to operational levels, the valve will close itself. Figure 5.20 provides drawing symbols used to represent the relief valve and pressure safety valve. Control Valve Toe flow, level, pressure, and temperature of all commodities being processed must be monitored, adjusted, and regulated to maintain a safe, efficient, and profitable facility. Pressures and temperatures that are allowed to elevate unchecked to extreme levels
PIPE DRAFTING ANO DESIGN
89
COMMON VALVE TYPES
1
~
TOP
FRONT
TOP
FRONT
END
Single-line symbols
END
Double-line symbols
FIGURE 5 .16 Plug val ve drawing symbols.
Wafer
Waferlug
Two-flange
FIGURE 5 .1 7 Butterfly valve. Courtesy of Crane Ce.
HNH TOP
TOP
HNH FRONT Single-line symbols
END
FRONT
Double-line symbols
END
FIGURE 5.18 Butterfly valve drawing symbols.
can become deadly. Commoctity flow rates and product storage levels that are insufficient may lead to less production. Therefore, the control valve, which is a remotely operated valve that can make precise adjustments to regulate and monitor any commodity flowíng through a piping system, is widely used. Toe most
common valve body style used as a control valve is the globe valve. Ball, butterfly, and plug valves can also be used as control valve body types. Control valves receive a signa! from instruments positioned throughout the pipíng system to automatically make adjustments that regulate the commoctity within the piping system.
PIPE DRAFTING AND DESIGN
90
5. VALVES
SPRING
A()j_
SCREW
CAP GASKET SPRING BUTTON BONNET BUTTON
BELLOWS BODY STUO HEX. NUT LOCK SCREW (P.HJ LOCK SCREW STUO LOCK SCREW GASKET LOCK SCREW (.B.O.R.) HE.X.. NUTl,B.QR.L SJ
DRAIN FIGURE 5 .19 Relief valve. Courtesy
of Farris SafetyRelief
Va/ves.
~-
TOP
FRONT
TOP
FRONT
END
Single-line symbols
Double-line symbols
FIGURE 5.20 Relief and pressure safety valve drawing symbols.
Control valves can perform many routine and repetitive operations or they can be designed for one specific task. Figure 5.21 shows the drawing symbols for a control valve.
Control valves are positioned throughout a piping facility, often in remote locations where access by plant personnel is problematic. However, when operational procedures require that there be continuous
PIPE DRAFTING ANO DESIGN
91
VALVE OPERATORS
TOP
TOP
FRONT
END
Single-line symbols
FRONT
END
Double-tine symbols
FIGURE 5.21 Control valve.
PLAN 8"x6"
SECTION
"A-1'!.'
(1YP. 2)
FIGURE 5.22 Control valve manifold.
functionality, a back-up to the control valve must be incorporated. To achieve this, control valve manifolds are configured. Control valve manifolds, also known as manifold control stations, use a combination of gate, globe, and control valves, uniquely arranged, to make continuous operational control of the commodity feasible. Control valve manifolds are discussed in greater detail in Chapter 12. Figure 5.22 depicts the Plan and Elevation views of a typical control valve manifold. Depending upon the space available for the installation of a manifold control station, different configurations can be employed. Figure 5.23 shows two possible installations of a control valve manifold.
VALVE OPERATORS A valve operator is a mechanism that causes a valve to perform its function. Operators can be manual or automatic. Manual operators employ levers, gears, or wheels to facilitate movement within a valve. A designer / drafter has freedom and responsibility to determine the positional location and orientation of valves. However, consideration must be gíven not only to make valve operation convenient and practícal, but also to make the operation safe for facility personnel. When locatíng a valve, the diameter and length of its handwheel, and if possible "clash" or interference with other components, must be addressed. Therefore, the
PIPE DRAFTING AND DESIGN
92
5. VALVES
6"
4"
FRC
6"x4"
301
RED. TEE
FIGURE 5.23 Control valve manifold configurations.
placement and orientation of handwheels must follow sorne specific guídelínes, Figure 5.24 provides the location preferences for operating, emergency, and isolating valves when their stems are installed horizontally. Notice, specific ''hazard" zones are shown for the head and lower leg area that must be avoided. Figure 5.25 shows similar guidelines for orienting valves when they are installed vertically. Notice that once a valve handwheel reaches its maximum installed height of 4 '-6", the ~al~e is then rotated and bolted at such an angle so that ít will eventually become horizontal in orientation. In situations where the standard handwheel is insufficient to operate the valve, gears are commonly used to enhance a handwheel's effectiveness. Bevel, spur, and worm gears supply the handwheel with a greater mechanical advantage to open, close, or throttle the commodity within the pipe. If a valve is installed ata height that is out of a worker's reach, a chain operator is often used. Toe chain operator is a sprocket-like attachment bolted to a valve's handwheel. A looped chain is passed through the sprocket and is hung down to a height that is accessible by a worker. This allows a worker to operate the valve without the aid of a ladder or moveable scaffold. Figure 5.26 shows a typical chain operator.
~
-: ~
Actuators Automatic operators known as aciuaiors use an externa! power supply to provide the necessary force required to operate valves. Automatic actuators use hydraulic, pneumatic, or electrical power as their source for operating valves. Hydraulíc and pneumatic actuators use fluid or air pressure, respectively, to operate valves needing linear or quarter-tum movements. Electric actuators have motor drives that operate valves requiring multiple tum movements. Automatic actuators are often provided on control valves that require frequent throttling or those found in ~mote and inaccessible locations within a piping facil1ty. Another common application for automatic actuators is on control valves of large-diameter pipe. These valves are often so large that a worker simply cannot provide the torque required to operate the valve. Also, in an effort to protect workers, control valves located in extremely toxic or hostile environments are outfitted wi~ automatic actuators. Additionally, in emergency situatíons, valves that must be immediately shut down are operated automatically. Figure 5.27 shows a diaphragmstyle valve actuator. Notice it is attached to a doubleport, globe valve body, which makes throttling possible.
PIPE DRAFTING ANO DESIGN
93
YALVE OPERATORS
VALVE SERVICE
VALVE LOCATION PREFERENCES (HORIZONTAL STEM) HEIGHTS SHOWN REFER TO CENTERLINE or HANOWHEEL -
USE CHAIN OPERATOR WHEN PERMITTED BY PLANT MANAG[MENT. CHAIN MUST NOT HANC IN WALKWAY.
~ ~-
PERMISSIBLE lf ACCESSIBLE BY PORTABLE LADDER UP TO ,o·-o·
8'-0" 6" 7'-0"
6'-0"
HEAD HAZARD ZONE
6" 5'-0"
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SMALL VALVES--ACCEPTABLE LARGE VALVES UN O ESIRAB LE ---
~~~~~
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NOTES: 1. WHENEVER DESIGN CONDITIONS ALLOW, VALVES ARE BEST INSTALLED WITH THE STEM ALIGNED VERTICALLY (POINTING STRAIGHT UP). THIS POSITION FACILITATES BETIER IN-FIELD MAINTENANCE (INSPECTION, REPACKING, LUBRICATION, ETC.) 2. VALVES MAY BE ROTATED TO THE HORIZONTAL POSITION WITHOUT SACRIFICING MAINTENANCE CONVENIENCE, BUT THEY MUST NOT BE INSTALLED WITH THE STEM POINTING DOWNWARD, SINCE THIS CAUSES THE BONNET TO ACT AS A TRAP FOR ABRASIVE SEDIMENT. 3. SAFETY REQUIRES THAT VALVES BE POSITIONED ~ RATHER THAN ADJACENT TO THEM.
PLATFORMS 1 O' -0" OR HIGHER,
FIGURE 5.24 Valve location preferences with horizontal stem.
PIPE DRAFilNG AND DESIGN
94
5. VALVES
VALVE
LOCATION
PREFERENCES
(VERTICAL STEM)
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1. WHENEVER DESIGN CONDITIONS ALLOW, VALVES ARE BEST INSTALLED WITH THE STEM ALIGNED VERTICALLY (POINTING STRAIGHT UP). THIS POSITION FACILITATES BETTER IN-FIELD MAINTENANCE (INSPECTION, REPACKING, LUBRICATION, ETC.) 2. VALVES MAY BE ROTATED TO THE HORIZONTAL POSITION WITHOUT SACRIFICING MAINTENANCE CONVENIENCE, BUT THEY MUST NOT BE INSTALLED WITH THE STEM POINTING DOWNWARD, SINCE THIS CAUSES THE BONNET TO ACT AS A TRAP FOR ABRASIVE SEDIMENT. 3. SAFETY REQUIRES THAT VALVES BE POSITIONED ABOVE PLATFORMS 1 O' -0" OR HIGHER, RATHER THAN ADJACENT TO THEM. FIGURE 5.25 Valve location preferences with vertical stem.
PIPE DRAFTING ANO DESIGN
95
YALVE OPERATORS
FIGURE 5.26 Valve chain operator.
----'-'AlVf'1,.IIQ
FIGURE 5.2 7 Valve actuator. Courtesy of Fisher Controls.
PIPE DRAFilNG AND DESIGN
96
5. VALVES
CHAPTER 5 REVIEW QUIZ
10. What type of device is used to opera te valves
installed in remote locations of a piping facility?
1. What is a valve?
EXERCISE INFORMATION 2. Name four end preparations for manufactured valves.
3. What is the pri.mary application for gate valves? 4. What phrase describes a valve's length
measurement?
5. What can be used to approximate the distance a stem will rise above a handwheel? 6. Globe valves are used for what service situation? 7. When using angle valves, in which direction must the flow be traveling when it enters the valve? 8. What is the purpose of a check valve? 9. Which valve prevents excessive pressure on gas and vapor service line?
Toe valves depicted in Figure 5.28 will be used to complete the exercises in this chapter and Chapter 10. Draw the valve symbols using the following guidelines: • Draw ali valve symbols full size usíng dimensions from the Welded Fittings-Flanges and Valves Dimensioning Chart. • Draw the valve's body, centerline, and handwheel bonnet with "default" lineweights. • Create a BLOCK of each symbol. Use a block name that appropriately describes the valve and its size and pound rating. (DO NOT include text with the blocked symbol.) • Place a base point on either end of the "bouitieshape" symbols and in the center of "endoieu/'symbols usíng either MIDpoint, or CENter OSNAP options. • SAVE the file as "VALVE SYMBOLS.dwg." After the symbols have been created and the drawing saved, begin a NEW drawing and use AutoCAD Design Center or the INSERT command to place the required valve symbols in their appropriate locations to reproduce Exercises 5.1 and 5.4. Solve for the missing dimensions using the required dimensioning charts Exercises 5.2 and 5.3. Exercises 5.5 and 5.6. Use dimensions found on the appropriate valve dimensions charts to draw the specified valves. Exercises 5.7 through 5.13. Sketch the missing views of the pipe configurations shown.
PIPE DRAFTING ANO DESIGN
97
EXERCISE INf-ORMATION
GATE VALVES:150
14" CATE TOP
12" CATE TOP
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1 O" Fígure 5.28 Valve drawing symbols.
PIPE DRAFTING AND DESIGN
98
5. VALVES
GATE VALVES:150
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GATE VALVES:300
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4"
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DRAW ALL VIEWS AS SHOWN 1 4" -300# RF GATE VALVE
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14" 300# GATE VALVE RF 1 /8" GASKETS
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Solve for the missing dimensions. 14" 14"
150# GATE VALVE RF 150# CHECK VALVE RF 1 /8" GASKETS
Solve for the missing dimensions. 8" 300# GLOBE VALVE RF 1/8" GASKETS
GASKETS
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EXERCISE
5-2
Solve for the missing
dimensions.
Solve for the missing dimensions. 1 O" 150# GATE VALVE RF 8" 150# GLOSE VALVE RF 8" 300# CONTROL VALVE RF 1/8" GASKETS
8" 150# GATE VALVE RF 6" 150# GLOSE VALVE RF
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EXERCISE 5-4
103
CHAPTER 5 DRAWING EXERCISES
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EXERCISE 5-5 PIPE DRAFTING AND DESIGN
104
5. VALVES
8"-1 SO#RFWN, GLOBE
T 16"-600#RFWN,
GATE
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EXERCISE
PIPE DRAFI1NG AND DESIGN
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CHAPTER
6 Mechanical Equipment
TYPES OF EQUIPMENT Although piping components such as fittings, flanges, and valves are important and impossible to do without in a process facility, they play a minor role in the actual manufacturing of a salable product. Other components of a pipíng facility actually perform the tasks for which the facility is being built. Collectively, they are known as mechanical equipment. Mechanical equipment can be used to start, stop, heat, cool, liquefy, purify, distill, refine, vaporize, transfer, store, mix, or separate the commodity flowing through the piping system. Toe discussion in this chapter will concentrate on the pieces of equipment that are used in a majority of ali chemical and refining facilities. Vessels Horizontal Vessels/Accumulat.ors Toe horizontal vessel, similar to the one shown in Figure 6.1, is a cylindrical-shaped storage tank that is installed in a facility with its long axis parallel to the
FIGURE 6.1 Horizontalvessel. Courtesy of Nisseki Chemical Texas, lnc., Bayport, Texas.
horizon. Also known as an accumulator, it is used primarily as a receiving and collectíng container for líquids and/or gaseous vapors and, therefore, has no intemal moving parts. Accumulators can be located at grade level or placed high in an equipment structure. Support saddles, which are U-shaped supports, are welded on the underside to secure and stabilize the vessel as it rests on two concrete foundations, which are located near each end of the vessel. A nozzle on the top of the vessel allows liquids to enter and fill the vessel. Another nozzle, coming off the bottom, allows the liquids to be drawn out. Smaller nozzles are positioned that are used for venting, drainíng, and instrumentation attachment. As will be discussed in Chapter 7, specíalized monitoring instruments are needed to measure the leve! and pressure of the commodity within the vessel. Lastly, a large-diameter nozzle, typically 18" ID, called a manway ar manhole, provides an entrance into the vessel for a worker who must perform intemal inspection and/ or maintenance. Figure 6.2 shows the Plan and Elevation views of a typical horizontal vessel. Vertical Vessels!Fractionation Columns!Reactors Toe vertical vessel is a cylindrical vessel whose long axis is perpendicular to the horizon (see Figure 6.3). It is one of the most visible pieces of equipment, and sorne vertical vessels can exceed 200 ft in height. Configured as a Fraaionation column, these vertical vessels have intemal plates called trays that aid in the refining and collection of the various molecular compounds of a feedstock. Toe process of refining, or breaking a feedstock down into its various molecular compounds, is called fraciional distillation. Distillation elicits only a physical change in a commodity, not a chemical one. After further refinement and processing, these compounds will become salable commodities such as fuels, plastics, and many other essential products. A detailed explanation of the fractional distillation process will be presented later in this chapter.
112
C, 2012 Ehcvic-r lnc.
Ali rlghtsrcserved.
113
TYPES OF EQUIPM8' T
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EAST ELEVATION
FIGURE 6.2 Plan and Elevation views of a horizontal vessel.
framework structures. Being the primary piece of equipment in a more volatile process, reactors are more closely monitored than fractionation columns because of the higher temperatures and pressures they operate under. See Figure 6.4 for the Plan and Elevation views of a vertical vessel.
Ladders, Cages, and Platforms Many vessels and other pieces of equipment are built to such heights that they are accessible only by ladders. Ladders allow workers to access the hígher elevations of equipment for routine inspection and maintenance. Ladders are made of steel bar and plate, and are welded or bolted to the exterior of a vessel. Cages are designed to endose a ladder and prevent a worker from falling. Made of steel plate, cages provide the worker with a sense of security when scaling tall structures. Plaiforms are like elevated walkways installed around the outside of a vessel or between pieces of equipment. Having a minirnum width of 3' -0", they have a floor made of steel grating or diamond" plate. With 42" tall handrails, workers can safely operate, inspect, and maintain a vessel. Platforms are spaced so ladders will not have a vertical run of more than 30' -0", but are not spaced closer than 8' -O" to provide adequate headroom clearance. Larger platforms can actually become large multilevel structures that provide flooring for equipment needed at higher elevations, as seen in Figure 6.3. A typical vertical ladder and cage are shown in Figure 6.5. Platform walkways are also depicted spanning between storage tanks in Figure 6.5. II
FIGURE 6.3 Vertical vessel. Courtesy of Nisseki Chemical Texas, lnc., Bayporl, Texas.
Reactors, through the introduction of a reagent or catalyst, change the chemical composition of a commodity. Typically much larger in size than a fractionation column, reactors can be housed in large, steel
PIPE DRAFTING AND DESIGN
114
6. MECHA,'llCAL EQUIPMENT
270·
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-N.::::=-
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PLAN
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270· 135·
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PLATFORM NO.
ELEVATION FIGURE 6,4
1
Plan and Elevation views of a vertical vessel with platform orientations.
Pumps Pumps, similar to the one shown in Figure 6.6, are mechanical devices used to move fluids under pressure from one location to another. Pumps accelerate the speed at which a comrnodity travels within a pipe, thereby increasing its rate of flow. Pumps used in pipíng facilities typically will be one of the following classifications: centrífugal, reciprocating, or rotary. Centrifu.gal Pumps Toe centrifuga! force created by the high-speed impellers of a centrifuga! pump creates a smooth
nonpulsating rate of flow. With a fast spinning impeller creating a low-pressure center point, any comrnodity entering the pump will naturally seek the center of the impeller only to be spun out at a hígh rate of speed. Toe efficient operation of the centrifugal pump makes it the standard of most piping facilities. Reciprocating pumps Toe reciprocating pump creates pressure with a piston or plunger that alternately move back and forth. With each stroke of the piston, pressure is increased forcing the comrnodity out of the pump.
PIPE DRAFTING ANO DESIGN
115
TYPES OF EQUIPM8'T
TABLE 6.1 Pump Nozzle Arrangements
FIGURE 6.5 Ladder, cage, and platforms. Courtesy of Nisseki Chemical Texas, lnc., Baypcrt, Texas.
FIGURE 6.6 Pump. Courtesy of Nisseki Chemical Texas, lnc., Baypcrt, Texas.
Toe recíprocatíng pump is installed in piping systems where extremely high pressures are required. RotaryPump Toe rotary pump is similar to the reciprocating pump in that it is a positive displacement type. Rotary
Suction
Discharge
1
SIDE
SIDE
2
TOP
TOP
3
SIDE
TOP
4
END
TOP
5
END
END (IN-UNE)
Position
pumps use mechanical devices such as pistons, gears, or screws to discharge a commodity at a smooth, continuous rate of flow. lt performs without creating the extreme pressure surges often associated with the reciprocating pump. Nozzle Arrangements To effectively locate a pump withín a píping facility, one must be especially concemed with the suctíon and discharge nozzles. Toe suction nozzle is where the commodity is drawn into the pump. Toe discharge nozzle is where the commodity is propelled from the pump. Toe positioning of the nozzles on the pump is called pump nozzle arrangemeni. Dependíng on the type, pumps typically are available in five different nozzle arrangements. Toe chart in Table 6.1 shows the arrangements of pump nozzles. Of primary concern to pumps, especially centrifuga! ones, is NPSH. Net Positive Suciion Head is, in simplified terms, the mínimum amount of pressure (head) needed by the commodity flowing into the pump that will keep the pump primed, or pumping. NPSH, mathematically, is the sum of the resident pressure on the commodity in the pipe, at the pump's suction nozzle, plus the pressure caused by gravity's effect on the commodity minus the amount of friction on the commodity flowing through the pipe. More simply stated, NPSH is head pressure plus gravity pressure minus friction. To achieve maximum efficiency, most pumps are installed with its suction line enteríng the pump from a vertical orientation to maximize head pressure. Figure 6.7 depicts the Plan and Elevation views of a typical pump. Notice only two nozzles are represented
PIPE DRAFTING ANO DESIGN
116
6. MECHA,'llCAL EQUIPMENT
-N-=SUCTION
PLAN
il ~~ 1
suc_r_1o_N_~~-
FIGURE 6.8 Bayport, Texas.
Electric motor. Courtesy of Nisseki Chemical Texas, lnc.,
FIGURE 6.9 Bayport, Texas.
Diesel engine. Courtesy of Nisseki Chemical Texas, lnc.,
J 11
1'
PAVING
EAST ELEVATION FIGURE 6. 7 Pump Plan and Elevation views.
in detall. A pipe drafter's primary concern is the location, size, and rating of these nozzles. Toe type of pump driver is secondary, unless it is a steam turbine, in which case the turbine's steam supply and retum nozzles must be represented on the piping arrangement drawing. Pump Drivers Ali pumps require a starting device to function. These devices are known as drivers. Toe driver is connected to the pump vía a rotating shaft and coupling. Toe shaft tums the impellers, gears, and screws or moves the pistons to initiate the "pumping" action. An electric motor is the most commonly used driver. As an alternative to electricity and as a back-up to the electric motor, a steam turbine is often employed. Toe steam turbine can operate duríng power outages or when a motor is being repaired or replaced. Steam turbines are also chosen over electric motors for use in areas where explosive gases may be present. Toe electric current, which is required to power the motor, is a possible ignítion source to flammable gases that may have leaked and collected near the motor. The turbine, driven by steam, obviously reduces the possibility of an expíosion. Figure 6.8 shows an electric motor driver. A diesel engine is used duríng times of emergency. When piping systems have been damaged and shut
down because of an explosion or a fue, diesel engines provide power to the pumps that provide water to fue monitors, hoses, and other firewater systems in a facility. Turbines can also provide electrical power to other essential plant services. Limited to outdoor service only, diesel engines can be used when conditions render electric motors and steam turbines useless. Figure 6.9 shows a typical diesel engíne driver. Compressors Toe compressor is similar to the pump, but it is designed to move air, gases, or vapors rather than
PIPE DRAFTING AND DESIGN
117
TYPES OF EQUIPM8'T
SHELL OUTLET WARM PROCESS
TUBE OUTLET WARM LIQUID FIGURE 6.1 O Interna! view of a shell and tube exchanger.
liquids. The compressor is used to increase the rate at which a gaseous commodity flows from one location to another. Gases, unlike liquids, are elastic and must be compressed to increase flow rate. Liquids obvíously cannot be compressed, unless you are building a hydraulic application. Like pumps, compressors are manufactured in centrífugal, reciprocating, and rotary configurations. Exchangers Another common piece of mechanical equipment is the exchanger. The exchanger's primary function in a piping facility is to transfer heat from one commodity to another. Whether the objective is to heat a liquid to a desired temperature or cool a product for final storage, the exchanger can accomplish both. The most important feature of the exchanger is that commodities are mot mixed with another agent to heat it up or cool it down. A substantial amount of time and money has been invested to purify the commodity, so mixing anything with it, just to heat it up or cool it down, would
be counterproductive. Exchangers simply transfer heat through contact with a metal surface of a different temperature. An exchanger most people are familiar with is the common household water heater whereby cold water flows around a heated element to warm the water. A number of exchanger types are available; they include the shell and tube, double pipe, reboiler, and air fan. Shell and Tube Exchanger The shell and tube exchanger performs its task by circulating a hot líquíd around tubes that contain a cooler liquid. The hot liquid circulates in an enclosed area called the shell. Tubes containing the cooler líquid are looped through the shell. Hot liquid in the shell warms the cooler liquid in the tubes, whereas the cooler líquíd in the tubes cools the warm liquid in the shell. Figure 6.10 provides a look into the shell and tube exchanger. Contact between the cool and hot liquids will naturally exchange heat from the hotter to the colder. Figure 6.11 shows the Plan and Elevation views of a shell and tube exchanger.
PIPE DRAFTING AND DESIGN
118
6. MECHA,'llCAL EQUIPMENT
-N-c:::==r , 1
1 1
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PLAN
SOUTH FIGURE 6.11
ELEVATION
EAST ELEVATION
Shell and tube exchanger Plan and Elevation views.
To prevent the two pipes of the exchanger from coming in contact with one another, thin metal plates called fins are welded to the outside of the smaller pipe. Figure 6.13 shows an end view of the double-pipe exchanger. These fins also aid in the transfer of heat from one commodity to the other. Figure 6.14 provides the Plan and Elevation views of the double-pipe exchanger. Rebofler Toe reboiler, as the name implies, is a device used to replenish the heat lost by a process commodity. It is natural that during the refining process commodities will lose heat. In many cases lower temperature means less efficiency and productivity. Therefore, it becomes necessary to reheat certain commodities after a period of time. Two types of reboilers are available for use: the FIGURE 6.12 Double-pipe exchanger. Courtesy of Nisseki Chemical kettle-type and the thermosyphon. A kettle-type reboiler Texas, lnc., Bayport, Texas. is similar in design and appearance to the shell and tube exchanger. Toe commodity to be heated is routed, via pipe, to and from the heater and fractionation column. Toe thermosyphon reboiler, however, is attached directly Double-Pipe Exchanger to a fractionating column via its nozzles. Toe inlet and Also known as the GFin or Hairpin. exchanger, double- outlet nozzles of a reboiler are bolted directly to the two pipe exchangers are manufactured with a single, small- nozzles on the fractionating column. Figure 6.15 reprediameter pipe inserted into a larger-diameter pipe. Toe sents an exploded view of a kettle-type reboiler, two pipes contain commodities of different temperaReboilers are used to keep fluids, which are circulattures similar to the shell and tube exchanger. Figure ing through a tower, at their peak operating tempera6.12 includes two double-pipe exchangers stacked atop ture. Toe process commodity enters the reboiler from one another. Toe upper is shown without protective the tower in a liquid state, is heated by either superinsulation and the lower one with insulation. heated steam or another hot liquid, and is returned PIPE DRAFTING ANO DESIGN
119
TYPES OF EQUIPM8' T
in a vaporous state to an area in the tower called the flash zone. Figure 6.16 depicts the location and use of a reboiler. As we will see later, the flash zone is crucial to the distillation process. Figure 6.17 shows the Plan and Elevation views of a kettle-type reboiler. AirFan
Air fans are large fan-type coolers placed above or below a pipe rack that draw air across pipes to cool them. Air fans opérate on the same principle as an automobile' s radiator, only on a much larger scale. Air fans can be as large as 20' -0'' wide and 30' -O'' long. If linked together, air fans can span up to lOOftor more, running the entire length of a pipe rack.
Cooling Towers
FIGURE 6.13
After circulating through equipment such as exchangers and condensers, cooling water will have accumulated substantial heat gain. Without dissipating the heat gain, cooling water will lose its cooling effectiveness and become less efficient. A cooling tower is a mechanical device that will lower the temperature of cooling water. Cooling towers are uniquely designed to dissipate heat gaín by evaporating large amounts of aerated water that is circulated through an air-induced
End view of a double-pipe exchanger.
- N-.:::::=-
PLAN
EAST ELEVATION FIGURE 6.14
Double-pipe exchanger. Pipe and Elevation views.
PIPE DRAFTING AND DESIGN
120
6. MEQ !ANICAL EQUIPMENT
VAPOR OUTLET 20S"F
OIL INLET
OIL OUTLET SSO"F FIGURE 6.15
lntemal views of a kettle-type reboiler.
HEATER FRACTIONATION COLUMN FIGURE 6.16
Reboiler in use.
PIPE DRAFI1NG AND DESIGN
TYPES OF EQUIPM8' T
r, 1 1
$-$--:,-1:1
L-'
1
121
-($PLAN
EAST ELEVATION FIGURE 6.1 7 Plan and Elevation views of a kettle-type reboiler.
Heaters/Boilers
FIGURE 6.18
Cooling tower. Courtesy of Nisseki Chemical Texas,
tnc., Bayport, Texas.
tower. Large fans sit atop a honey-combed charnber and draw through cascading sheets of water. As the air passes through the falling water, it extracts heat. Although there is a significant amount of drift (the amount of water lost during the aerating and evaporation sequence), cooling towers are extremely efficient and are widely used. Older cooling towers are easily recognizable because they are constructed of wood and have horizontal slats resernbling louvers with water cascadíng down the walls. Figure 6.18 represents a typical cooling tower.
Heaters, or furnaces as they are also known, are used to raise the ternperature of a feedstock to the point where it can be used in a process facility. Sorne feeds, like crude oil, rnust be heated to approximately 700ºF before it can be piped into a fractionation column where its refining process begins, Firebrick lines the interior walls of a heater to retain heat. Open-flame burners, fueled with oil or gas, are used to generate the extreme temperatures inside the heater's firebox. Traversing back and forth in a continuous S or U pattern are the pipes carrying the comrnodity being heated. Heaters can be of the vertical or horizontal type. Vertical heaters are often circular in shape and have interna! piping traveling in a vertical direction (see Figure 6.19). Horizontal or box heaters are rectangular in shape and have pipes routed in the horizontal plane. Both the S and U pattern heaters have similar characteristics that indude brick-Iined heating chambers, flaming burners, and baffled venting stacks (see Figure 6.20). Boilers employ the same heating principle as a heater. They are used primarily to generate superheated steam or stripping steam. Constructed similar to a heater, boílers can raise the temperature of water or condensate to 1,000 ºF or more. Storage Tanks From the name, it is easy to determine what this piece of equiprnent is used for. Storage tanks are used in severa! phases of the refining process. They can be
PIPE DRAFTING AND DESIGN
122
6. MECHA,'llCAL EQUIPMENT
FIGURE 6.19 Vertical heater. Courtesy of Nisseki Chemical Texas, lnc., Bayport, Texas.
used to store crude oil before its use in the facility, as holding tanks for a partially refined product awaiting further processing, or to collect a finished product before its delivery or pickup by a customer. Usually placed within a common area of a fácility known as a tank farm, storage tanks come in various shapes and sizes. Sorne are shaped similar to horizontal vessels and sorne are spherical, like a hall. Toe majority of storage tanks, however, are huge, ground-supported vessels, as muchas 200ft in diameter and up to 60ft tall. Spherical tanks are used primarily for storing liquefied petroleum gases like butane, methane, or propane. Toe expanding nature of gaseous commodities requires that a spherical shape be used. As gases expand equally in all directions, it becomes necessary to store them in a vessel that distributes load stresses equally to its walls. Toe larger tanks, used for storing liquid product, may have either a conical, elliptical, geodesic dome, floating, or open roof. Floating roofs raise and lower to automatically adjust to the level of the commodity in the tank. Floating roof tanks use "pontoons" to create a seal agaínst the tank's wall to help reduce evaporation and prevent the buildup of dangerous gases that often occur with flammable liquids. As a preventative measure, containment díkes are erected to contain mejor leaks or spills. Should a storage
EXHAUST STACK ----
CONVECTION TUBES SUPPORT STRUCTURE FIRE BRICK HEATER BOX
RADIANT TUBES
HEATING CHAMBER FLAME BURNER
FIGURE 6.20 Box heater. PIPE DRAFTING ANO DESIGN
MECHAi'llCAL EQUIPMENT DESCRIPTIONS
123
• Deethanizerthe first in a series of three distillation
• •
• FIGURE 6.21 Storage tanks. Courtesy of Nisseki Chemical Texas, lnc., Baypqrt, Texas.
tank rupture or suffer severe damage, the dike will prevent major contanúnation to surrounding areas. Dikes can be earthen dams or concrete retaining walls built around the perimeter of the entire storage facility, or a single tank, at a height that would hold the contents of a storage tank, should a spill occur. Figure 6.21 depicts typical storage tanks and surrounding concrete retaining wall.
• •
• •
MECHANICAL EQUIPMENT DESCRIPTIONS Numerous pieces of mechanical equipment are used in process facilities. Below is a list and description of sorne of them:
• Accumulatora horizontal-axis vessel havíng no •
• • • • •
intemal parts used to collect product as it circula tes through the refining process. Air cooler (air fan, finfan)a rectangular device having small-diameter pipes or tubes winding back and forth, side-to-side, similar to that of an automobile radiator. Sometimes mounted above a pipe rack, it uses large fans to draw air across the tubes for cooling. Chillerone of the many types of exchangers used to reduce the temperature of a process commodity. Columnsee fractionation column. Compressora mechanical device used to increase the flow pressure of a gaseous or vaporous commodity. Cooling toweruses a large fan to remove the latent heat from coolíng water by drawing air across cascading water. Debutanizera distillation column that receives the bottoms residue from a depropanizer whose overhead product is a mixture of normal and iso-butane. Its bottoms residue is a C5+ mixture (pentane).
•
•
• •
• •
• •
columns whereby heavier gaseous molecule hydrocarbons, or NGL (natural gas liquids) are fractionated. Toe deethanizer distillation column's overhead product is ethane gas. Its bottoms residue is routed to a depropanizer far further processing. Deisobutanizera distillation column that fractionates butane. lso-butane is a refrigerant that is used to replace ozone layer-depleting gases. Demethanizera fractionating column in a cryogenic low-temperature distillation process whereby lighter gaseous molecule hydrocarbons (methane) are fractionated from raw natural gas. Depropanizera distillation column that receives the bottoms residue from a deethanizer whose overhead product is propane. Its bottom residue is routed to a debutanizer. Distillation columnsee fractionation column. Exchanger (shell and tube, gfin)Generic name gíven to a device used to transfer heat from one commodity to another, though available in a number of different configurations it is spedfícally designed to prevent the two commodities from mixing. Flare stacka vertical-axis tower that uses an open fiare to bum waste or contaminated product. Fractionation columnany number of vertical-axis, separating devices having intemal trays, plates, or other packing materials that are used to separate, or fractionate a feedstock into various component by-products (fractions) by refining it (distilling, fractionating) at the molecular level. Heater-horizontal- or vertical-axis device used to heat a commodity by circulating it through pipes that run through an open-flame firebox. Knockout drum-used to collect any liquids present in the waste stream prior to entering a fiare system, especially important if substantial cooling of heavy liquids is necessary. Mixer-device used to combine liquid, semi-liquid, or bulk materials needed in the refining process. Pump-mechanical device used to increase the flow pressure of a liquid commodity. Reactora vertical-axis vessel that introduces a reagent or catalyst into a feedstock to induce a chemical reaction that will yield a uniquely different product. Reboilerused to superheat or vaporize the liquid feed befare entering a distillation column. Kettletype (horizontal) and thermosyphon (vertical) reboilers use steam or hot oil to vaporize the feed befare it enters the distillation column. Scrubberused to separate contaminants from gases during the refining process. Separatorany collection-type vessel used to separate liquids from gases or other liquids duríng the refining process.
PIPE DRAFTING AND DESIGN
124
6. MEQ !ANICALEQUIPMENT
• Storage tank-containment vessel used to store gases or liquids before, duríng, or after the refining process.
EQUIPMENT IN USE Now that we have discussed the major pieces of equipment, let us look at how they are integrated and function in a typical piping facility. The description to follow will be an abbreviated sequence of steps
AVIATION GASOLINE (AV GAS)
LIGHT NAPHTHA
MOTOR GASOLINE
HEAVY NAPHTHA
necessary to transform raw crude oil into its various byprod.uct components. Crude oil and its derivatives are the most comrnon supply prod.ucts used in petrochemical facilities. Known as Jeed, crude oil is made up of molecules formed by thousands of different hydrogen and carbon atom combinations. Because the molecules are different, each crude oil molecule will boíl at a different temperature. But because they are comparatively similar in molecular structure, groups of molecules often boíl within a narrow range of each other. These groups are called
MILITARY & COMMERCIAL JET FUEL
DIESEL FUEL
LIGHT GAS OIL
FUEL Oll LUBE Oll
HEAVY GAS OIL
Jl
HEATER/FURNACE
,,,;:=== ...===:a: STRIPPING STEAM
FLASH ZONE
zoo'r
780.F
ASPHALT COKE TAR
BOTTOMS RESIOUE
CRUDE
780.F
DISTILLATION
FLOW
FIGURE 6.22 Crude feed by-products. PIPE DRAFI1NG AND DESIGN
CHART
EQUIPMENT TERMINOLOOY
fractions. The process that will separate these fractions into their various groups, so they may be collected for further processíng, is called fractionai distillation. Figure 6.22 depicts the by-products refined from crude oil feed. A closer look at the fractional distillation schematic will allow us to examine how each piece of equipment has a unique and distinct role in the refining process. From the storage facility, crude oil feed is pumped through preheat exchangers. These exchangers are the first stage of the heating process. From the preheat exchangers, the crude is sent to a heater or furnace. Once inside the heater, the feed is circulated through a series of pipes and is heated to a temperature of approximately 700 ºF. The boiling feed is then piped to the fractíonatíng column. This area of the column is known as the flash zone. The flash zone is the position in the fractionating column where the incoming feed, when infused with stripping steam, separates into vapor and liquid states. Siripping steam is superheated, dry steam that enhances the molecular breakdown of the crude feed. Inside the column, the heated crude oil molecules will begín to group together accordíng to their weights. The natural tendency of lighter-weight molecules to rise causes the light fractions, those with a low-temperature boiling point, to vaporize and rise to the top of the column. Heavy fractions, the heavier molecules with a high-temperature boiling point, remain in a liquid state and settle to the bottom of the column. Horizontal trays, spaced 18-24" apart inside the column, act as a filter that will separate and collect the rising vapors and falling liquids into various fractions. As vapors rise through the column, they begín to cool. At one specific and unique height in the column, when the vapors cool to a precise temperature, the fractions condense. Toe condensing fractions, now liquid, collect on a tray that has been placed in the column at that exact height based on temperatures cakulated by a process engineer, Trapping the liquid is a short, vertical plate, known as a weir, which acts as a dam to contain the líquid on the tray. The weir is of such a height that liquid by-product will collect and be drawn off by pipe attached to a nozzle. Toe liquid fraction, now a by-product of the feed, is routed to other areas of the facility for additional refinement and processing. If an excess amount of liquid collects on the tray, it will overflow the weir and fall down through an area known as a downcomer to a lower section of the column. There it is once again heated to the point of vaporization. The vapors will begín to rise and start the process over agaín, Depending on precise fractionation requirements, trays can have a number of configurations. Figure 6.23 shows a "single-pass" and "double-pass" tray configuration. Figure 6.24 shows an expanded schematic flowchart of a fractionating column and the by-products extracted
125
for its crude oil feed. As you look at this example, keep in mind that the extraction and refinement of these by-products would require multiple stages of further processing, taking place in numerous additional fractionation columns. In the typical fractional distillation process, heavy by-producís such as asphalt and tar come off the bottom of the column as residue. As the vapors rise and temperatures begin to decrease, the molecules of heavy oil products, which include fuel and lubricatíng oils, condense, collect on a tray, and are extracted. At hígher elevations in the column, light oil products such as diese! fuel and kerosene are removed. Above the kerosene, heavy naphtha, used in makíng motor gasoline, and light naphtha, used to make aviation gasoline, are collected for further processíng. Toe light naphtha is a prime example of how further processing can yield additional products. When the light naphtha vapors are removed from the top of the column, they are sent through exchangers to be condensed. As the liquid naphtha is condensed, it is piped to an accumulator for collection. In the accumulator, the liquid naphtha settles to the bottom and is pumped away for additional processing to later become aviation gasoline (av gas). The naphtha vapors left in the accumulator rise to the top and are removed by a compressor to be further processed into liquefied petroleum gases (LPG) such as butane, methane, and propane of burned in a fiare stack as waste gases.
EQUIPMENT TERMINOLOGY Toe following list identifies items generally associated with mechanical equipment and vessels: • Base plateA flat, metal ring welded to the bottom of a vessel's supporting skirt that rests on a concrete foundation. Holes around the perimeter of the metal ring make it possible to position it over anchor bolts and secure it to the foundation. • Downcomers-Verticalopenings adjacent to a tray that allow liquids flowing over a weir plate to fall to the tray below and begin the fractionation process agaín,
• HeadThe end enclosures of a vessel. They can be either semi-elliptical, spherical, or dished. • Insulaiion rings-Continuous circular rings welded to the exterior of a vertical vessel that support a vessel's insulation. They are typically spaced on 12'-0" centers. • Lifting lugs-Donut-shaped rings welded to the vessel's shell or head that allow the vessel to be raised and positioned during installation. • ManholesSimilar to large nozzles that allow workers entry points into a vessel. They generally are
PIPE DRAFTING AND DESIGN
126
6. MECHA,'llCAL EQUIPMENT
SINGLE PASS
DOUBLE PASS
P~N
P~N
WEIR PLATE DOWNCOMERS
\
'\ 1
~,..\ t1
1, ;, a,
/
I \
'
~t I:
i A ,'11
,a,
f
I
l) ', ' r ''
, 1
I
,a ,
ELEVATION FIGURE 6.23
• •
• • •
•
ELEVATION
Single-pass and double-pass tray configurations.
18" ID and are accessible by ladders and platforms. When not in use, the manhole is sealed with a blind flange. MilnholehingeA hinge that creates a pivot point allowing the blind flange attached to the manhole to be easily removed for worker entrance. NozzleA flange-faced tie-in connection that allows a piping configuration to be bolted to a vessel, pump, exchanger, or other piece of mechanical equipment. Nozzles are provided in locations where a commodity is either introduced or removed from a vessel or piece of equipment. Nozzle orientationThe angular arrangement of nozzles around the perimeter of a vessel' s shell. Nozzle projectionUsed to establish the distance from the vessel's centerline to the nozzle's face of flange. Reinforcing padA plate contoured to the shape of a vessel shell. It is positioned around nozzles and provides additional strength in the areas where metal was removed from the shell. SaddlesUshaped supports welded on horizontal vessels and exchangers. Saddles are bolted to
• • •
• •
• •
concrete foundations and create a cradle-like support in which the vessel can rest. Sea/ panA tray installed below the bottom tray in a vessel to prevent liquids from bypassing the trays. ShellThe cylindrical walls of a vessel. SkirtA cylinder-shaped support for a vertical vessel. One end is welded to the base plate allowing it to rest on the foundation and the other end is welded to the bottom head of a vertical vessel. Skirt access openingAn 18" ID hole 2'-6" above the foundation that allows workers' entrance for inspection and maintenance. SkirtfireproofingGenerally brick or gunite, fireproofing is applied around the interior and exterior walls of a vessel skirt. It is necessary to prevent damage to vessel skirt in case a fue occurs. Skirt vents-Equally spaced holes approximately 3-4" in diameter bored near the top of the vessel skirt that allow toxic and explosive gases to escape. TraysFlat metal plates spaced approximately 18-24" apart inside a vertical vessel. They can be bolted or welded to the vessel shell. Trays are
PIPE DRAFTING ANO DESIGN
127
EQUIPMENT TERMINOLOOY
CRUDE OIL FROM STORAGE
~
PRE-HEAT EXCHANGERS
255'F
STEAM
J1
HEATER/FURNACE 700'F
BOTTOMS
CRUDE FIGURE 6.24
RESIDUE
DISTILLATION
FLOW
Flowchart of fractional distillation process.
PIPE DRAFTING AND DESIGN
CHART
128
6. MECHA,'llCAL EQUIPMENT
perforated to allow rising vapors and.falling liqu~ds to pass through with the aid of a valvíng mecharusm called a cap. • WeirA dam-like plate welded on a tray that allows a fractionated by-product to collect and be extracted by a nozzle.
VENDOR DATA DRAWINGS With a myriad of piping facilities in operation, one should not expect specialized piping equipment to be an item found on a store shelf, waiting to be purchased, like repair parts for an automobile. Each piece of e~uipment has certain criteria that must be met before ít can become part of a process unit, boiler room, or production facility. Although duplicate pieces of equipment are found within the same facility, every piping facility has equipment installations unique unto itself. Thei:efore, equipment must be specifically designed and fabncated for each situation. Once specilic performance requirements for equipment have been established by engíneeríng, process, and other design groups, purchase orders are placed with companies called vendors who specialize in m~ufacturing the specialized equipment. Although equipment such as pumps and compressors are considered to be somewhat "standard" and are readily available, other pieces of equipment such as vessels, he~~ers, an? exchangers must be custom-made for a specific ap~bcation. Vendors provide engineering and construction companies data drawings that show exact measurements, locations, pound ratings, and overall sizes of the newly manufactured item. Engineering companies ~en use the information found on these vendor data drawmgs as a reference so pipe connecting to the piece of equipment can be designed, drawn, fabricated, and installed with precision. Vendor data drawings also provide designers the necessary information required to build
foundations, locate supports, and calculate interferences without having the actual piece of equipment available to measure.
DRAWING EQUIPMENT Vendor data drawings are valuable sources of information when the need to represent equipment on a piping drawing arises. Although piping drawings do not require the duplication of all the information shown on equipment data drawings, they do require_representation of overall equipment lengths and heights, along with nozzle sizes, locations, projections, orientations, and pound ratings. The drawings shown in the Figures 6.25 and 6.26 are typical representations of vendor data drawings for a shell and tube exchanger and horizontal vessel, respectively. Piping arrangement drawings can be tedious and time-consuming to create. Toe step-by-step procedures shown in Figure 6.27 can be used as a guide to develop the various elements of a horizontal vessel. Toe measurements used to represent vessel 01-V-102 on a plan, elevation, or section view are taken from the vendor data drawing shown in Figure 6.26. This accumulator is capped on each end with a 2:1 semi-elliptical head. Drawing the vessel's shell is not difficult, but deve~opment of the 2:1 semi-elliptical head can be challengmg. Use the step-by-step procedure shown in Figure 6.28 to create a 2:1 semi-elliptical head on each end of 01-V-102.
Drawing the Horizontal Vessel See Figure 6.27.
Drawing the 2: 1 Semi-elliptical Head See Figure 6.28
PIPE DRAFTING ANO DESIGN
NOZZLE "A"&"B" 11"
lH_L
NOZZLE
7/8tn
NOZZLE "D" 15"
T~-1
Jcga"(TYP.) 1"
"e"
-!4---,
µ2:jL3·
(TYP.)
NOZZLE
1 5/8"-iÍI T~
SERVICE
A
C.W.INLET C.W.OUTLET
6" 6"
150# 150#
RF RF
1 '-8"
8
10"
o
VAPOR IN LIQUID OUT
300# 300#
RF RF
1 '-8" 1 '-8"
V
TW/VENT
e
w
NOZZLE SCHEDULE NO. SIZE RATING FACE
MK
8
8" 1 ..
6000#
1 1
l
PLAN
31/2"t 1 1/2"
2" 50.8
r~~ ~_J_
1 1
J
SEE DETAil
24'-0"
DETAil 1'-4"
-+-+-11+11----+--+--
"A"
18'-10·
-
--
1'-8"
ci
p ---
•N
1·-a·
1s·-o·
EAST ELEVATION
DEPROPANIZER FIGURE 6.25
OVERHEAD
Shell and tube exchanger vendor data drawing.
NORTH
CONDENSER
1'-8"
CPLG W/PLUG
DETAILS
-N-=-
PROJ.
ELEVATION
01-E-102
....
l.,J
NOZZLE
NOZZLE "Nl"
NOZZLE "N2"
15"
5/8"-iM~
r'H Ld
8" 3"(TYP.)
NOZZLE "N4"&"N5"
NOZZLE "N3",''N6"&"N7"
125·1;~.10"
4"_¡_¡_
M l=~-f8. ~-i 17.5"
7/8"
6.5"
,¡a·J;j}·
MK Nl N2 N3 N4 NS
SERVICE LIQUIO LIQUIO
NO.
SIZE
RATING
FACE
PROJ.
IN
8"
300/1
RF
2'-8"
OUT
10"
300#
RF
2'-8"
2"
300#
RF
2'-6"
4•
300#
RF
2'-8"
4•
300"
RF
2'-8"
ORAIN VAPOR
o
SCHEDULE
OUT
RELIEF
N6
LEVEL
GAGE
2"
300"
RF
2'-6"
N7
LEVEL
GAGE
2"
300#
RF
2'-4"
Cl
VENT
,·
6000#
M1
MANWAY
18"
300"
r ,
NOZZLE DETAILS
1 1
1 1
1
1
1
1
,!-
·+: ----+',+,,
'l'. ,
I
RF
,,
'f
SOUTH ELEVATION
FIGURE 6.26
Horizontal vessel vendor data drawing.
REFLUX
2'-10"
- f\l---,;::::=-
PLAN
DEPROPANIZER
CPLG W/PLUG
ACCUMULATOR O 1-V-102
131
DRAWING EQUIPMEJ--T
Dimensions needed to draw shell of
15'-0"
01V102:
Tangent to Tangent Dim.:= 15'-0" 01-V-102
~¡
i::
o 1
~
ID: 4' -0"
8
(lnside Oiometer)=
STEP 1
STEP 2
Dimensions needed loca te nozzle N of 2
A
STEP 3
to
01V102:
T ongent line to
t
N2 = 1 '-0"
Nozzle size (NPS)
= 1 O"
Nozzle pound roting= Nozzle projection
STEP 4
300#
= 2'-8"
1 '
•
~! STEP 5
STEP 6
FIGURE 6.2 7 Step-by-step procedures for drawing 01-V-102. • • •
• •
•
Step l. Determine the vessel's diameter and length as provided by the vendor drawing. Using the measurements from Figure 6.26, the vessel's ID (lnside Diameter) is 4' ..()" and its length from Tangent line to Tangent line is 15' -O". Step 2. Draw a horizontal centerline equal to the vessel's length. Step 3. Create two lines parallel to the centerline measuring one-half of the vessel's ID (2'-0") above (A) and below (B) the centerline. Toe total height should be equal to the vessel's ID (4' -O"). Connect the endpoints of the two new horizontal lines with phantom lines to establish the ends of the vessel' s shell (C). Step 4. Using measurements provided on the 01-V-102 vender drawing, determine the following values for nozzle N2: the distance the nozzle's centerline measures from the Tangent line (1 '..()"), nozzle size (10"), nozzle pound rating (300#), and nozzle projection length (2'-8"). Step S. From the left Tangent line, OFFSET a parallel line l'-0" to the right to establish the centerline of nozzle N2. From the centerline of the vessel, OFFSET a parallel line 2'-8" below, to establish the face of the nozzle. Using dimensions found on the 300# Welded Fittings-Flanges Dirnensioning Chart in Appendix A, draw the nozzle using the flange's OD (17'1h") and face thickness (lW'). Step 6. Use the step-by-step procedures shown in Figure 6.28 to develop the 2:1 semi-elliptical heads.
PIPE DRAFTING AND DESIGN
132
6. MECHA,'llCAL EQUIPMENT
"ICSSEL OIAMETER
•1
-1- ~_jl_
1.
TANGENT UNE
STEP
7
1
STEP 2
*----t-
POINT 1
POINT 2
1
CPt\
-¡-
STEP
CIRCLE 2
/CP2
3
STEP 4 ERASE TANGENT UNE
I
\
/
ADD WELD UNE \,,-- CIRCLE J
1
\
\
-, <,
FIGURE 6.28 • • • •
• •
-
STEP
5
- _.,,.
/
/
I
I STEP 6
Step-by-step procedures for drawing a 2:1 semi-elliptical head.
Step l. Develop the vessel's shell using the step-by-step procedures shown in Figure 6.27. Step 2. OFFSET a line above and parallel to the Tangent line that is a distance equal to the IDD (lnside Depth of Dish) dimension. Use the following formula to establish the IDD dimension. IDO = vessel diameter X 0.25 Step 3. Draw 30° lines from Points 1 and 2 that will intersect on the vessel's centerline and establish Point 3. Step 4. Construct Circle 1 by drawing a CIRCLE having its centerpoint at the intersection of the 30° line and the Tangent line (CP1 in step 3). The radius of Circle 1 is measured from CPl, then horizontally to the left end of the vessel. Circle 2 is constructed in a similar manner on the opposite side of the vessel using CP2 as its centerpoint. Step 5. Circle 3 is a TANgent, TANgent, TANgent circle type. The three tangen! selection points are identified by the three "dots" shown in the Step 5 figure. The resulting circle is shown as dashed lines. Step 6. Use OFFSET to construct a weld line that measures 2-3" below and parallel to the Tangent line. TRIM the ares as necessary. ERASE the Tangent line.
PIPE DRAFTING ANO DESIGN
133
CHAPTER 6 DRAWING EXERCISES
CHAPTER 6 REVIEW QUIZ
10. How does a cooling tower perform its function?
1. Define mechanical equipment. 11. What items are typically found on a tank farm? 2. What is an accumulator?
12. Name sorne of the common by-products derived from crude oil feedstock?
3. Explain fractional distillation. 13. What interna! device is used as a separator and collector of molecules in a fractionation column?
4. What is a byproduct ? 11
11
14. Which directions do light and heavy molecules travel within a fractionation column?
S. What does a pump do?
6. What are the five pump nozzle configurations?
7. Name three types of pump drivers.
15. Where is the dimensional data used to draw mechanical equipment found?
CHAPTER 6 DRAWING EXERCISES Exercises: Drawing Equipment
8. What does a compressor do?
Exercise 6.1. Draw the plan and elevation views of the shell and tube exchanger as shown in Figure 6.25 to full scale and place in an A size border to % = l '-0" scale. Exercise 6.2. Draw the plan and elevation views of the horizontal vessel as shown in Figure 6.26 full scale and place in an A size border to %'' = l '--0" scale. II
9. Describe the function of an exchanger.
II
PIPE DRAFTING AND DESIGN
11
11
11
CHAPTER
7 Flow Diagrams and lnstrumentation Flow diagrams describe, in a schematic drawing format, the sequential flow of liquids, gases, and vapors as they enter, flow through, and exit the process facility. By using simplified drawing symbols, to represent various pieces of mechanical equipment, valvíng, and instrumentation, and specific notes, callouts, and abbreviations, the flow diagram provides the pípíng designer with an overall view of the operation of a facility. Toe flow diagrams presented in this chapter are representative of the types used by many engineering and design companies. While actual symbols may vary slightly from company to company, the general appearance of flow diagrams is the same throughout the pipíng industry. Anyone new to flow diagrams must become familiar with the piping, equipment, and instrumentation symbols, as well as the abbreviations used on flow díagrams, in order to be able to interpret them. One of the most difficult concepts for students to comprehend is the absence of scale in the preparation of flow diagrams. Toe flow diagram should be laid out in a very simplistic and logícal order and be "read" from left to right. It guides the drafter and designer in the same manner a road map guides a traveler.
USES OF FLOW DIAGRAMS Toe flow diagram is used by the pípíng group to develop and lay out the Plot Plan. When developing the Plot Plan, the arrangement of the mechanical equipment in the facility reflects, in part, the logical sequence of flow depicted on the flow diagram. However, many other factors such as code requirements, client standards and preferences, worker safety, and cost influence the positioníng of equipment. Once the Plot Plan is finalized, the piping designer routes the pipe between the various pieces of mechanical equipment as indicated by the flow diagram usíng
project specifications, standards, and accepted design practices. Toe flow diagram is usually "yellowed out" as each line is completed and incorporated into the design.
TYPE OF FLOW DIAGRAMS Process engineers are responsible for developing flow diagrams. In many large engineering firms, an entire department is dedicated to the development of flow díagrams. Today almost all flow diagrams are laid out with CAD drafting software or a 30 plant modeling software program that has a flow diagram package included. Although there are various types of flow diagrams used during the design phase, we will concentrate on just three: the Process, Mechanical, and Utility flow diagrams.
Process Flow Diagram Toe Process flow diagram is the first flow diagram developed during the design process. Toe Process flow diagram will include the following: 1. 2. 3. 4.
Major mechanical equipment Main pípíng Direction of commodíty flow Operating pressures and temperatures of the facility components S. Major controlling instrumentation Toe Process flow diagram will denote the following: • Conditions to be used for the design of various pieces of mechanical equipment required for facility operation, that is, fractionation columns, pumps, heaters, etc. • Toe operating and design conditions (pressures and temperatures) of which a particular piece of mechanical equipment will function. Design conditions establish the lirnits that certain
134
C, 2012 Ehcvic-r lnc.
Ali rlghts rcserved.
135
FLOW DIAGRA}"1 INSTRUMENTS
components such as gaskets and valve seats used in the facility can withstand. Design pressure is calculated to be at least 10% above the maximum operating pressure or 25# greater (whichever is largest). Toe design temperature will be at least the maximum operating temperature, but should be at least 25 degrees above the normal operating temperature. • Composition of the commodities used in the refining or treatment process sequence as they enter and leave the unit. Figure 7.1 is the Process flow diagram of Unit-Ol.
Mechanical Flow Diagram From the Process flow diagram, the mechanical group develops the Mechanical flow diagram. Toe Mechanical jlow diagram provides much more detailed data than the process flow diagram. Many companies refer to the Mechanical flow diagram as the "P&ID" (Process and lnstrument Diagram). Often referred to as the "bible" of the design process, this drawing provides the pipe drafter with specific desígn criteria. Mechanical flow diagrams include the following: 1. 2. 3. 4. 5.
Pipe line numbers with direction of commodity flow Pipe specifications and line sizes All mechanical equipment All operating and isolating valves All controlling instrumentation with transmitting devices
Mechanical flow diagrams define the exact sequence in which all mechanical equipment, valves, instrumentation, connections, etc. are to be made on each process pipe routed through the facility. Figure 7.2 is the Mechanical flow diagram of Unit-01.
The Utility Flow Diagram Toe Utility jlow diagram includes all pipes, valves, and instrumentation of the facility utilities. Utilities are services that are essential to the proper function of the facility. Although the facility is not being constructed to make condensate, condensate will be present in the facility and must be dealt with. Similarly, the facilíty is not being designed to gather and sell rainwater but the collection, treatment, and disposing of rainwater must be incorporated into the facility's design. Sorne utilities found in a petrochemical facility correspond to those found in a typícal house, such as water, gas, heating oil, and sewer drains. Others are specific to industrial applícations, such as compressed aír for pneumatic tools and steam for high-pressure cleaning.
Sorne of the common plant utilities are the following: • • • •
Steam Fue! oil Instrument air Draínage systems
• Condensate tility air • Cooling water • Fiare system
• u
Once flow diagrams have been finalized, they will be stamped for "release" by a registered professional engíneer, approving them for construction by the engíneeríng group. Toe flow diagram is a dynamíc document. They may be revised and updated during the project's desígn phase to reflect the client changes or modifications imposed by governmental regulations. Continua! review of relevant flow diagrams must occur on a regular basis. Figure 7.3 is the Utilíty flow diagram of Unit-Ol.
FLOW DIAGRAM INSTRUMENTS To ensure the safe and efficíent operation of a facility controlling instrumentation is an absolute necessity. Controlling instruments function by sensing conditional changes in the commodities they monitor, either in pipes or mechanical equipment. These conditional changes comprise the four basic instrument groups; they are the following: Flow
(F)
Level
(L)
Pressure
(P)
Temperature
(T)
Within these four instrument groups are uniquely desígned instruments that carry out the sensing, controlling, and monitoring of the commodíty, These instruments can be one or a combination of the following five specific types: Controller
(C)
Indicator
(I)
Gauge
(G)
Alarm
(A)
Recorder
(R)
By learníng the combination of these nine instrument groups and types, students will be able to ínterpret most of the instrumentation symbols present on a Mechanical flow diagram. Figure 7.4 illustrates a combination of the instrument group and type to develop symbols and abbreviations
PIPE DRAFTING AND DESIGN
01-E-101 REBOILER
01-V-101
01-E-102
DEPROPANIZER
OVERHEAD CONDENSER
01-V-102 REFLUX ACCUMULATOR
125"f
36
01-V-101
COOLING WATER SEE UTIUlY FLOW DIAGRAM
01-E-102
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FlARE
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& 1018
PRODUCT ANO REFLUX PUMPS FIGURE 7.1 Process flow diagramof Unit-01.
OJ-y-101
01-E-JOJ
FRACTlONATOA REBOUR
OJ-E-J02
FRACTIOHATOA 4'-0" OO. X 52'-0" T/T
01-y-102
REFI.UX ACCUMUlATOA 4'-0" OO. X 15'-0'l/T
01-1$-A.15-6. Ol-14-A15-S• 1W 3
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s
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QJ-P-JOJA & 6 PROOUCT a< REFWX PUMPS
FIGURE 7 .2 Mechanical flow diagram of Unit-01.
COOUNG WATER SEE UTIUTY FI.OW ow.RAM
138
7. FLOW DIAGRAMS ANO l?-:STRUMENTATION
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FIGURE 7 .3 Utility flow diagram of Unit-01.
that represent an instrument's function on a flow díagram. Toe first letter in the symbol typically indicates the instrument group, while the second and/or third letters indicate(s) the instrument type. To respond to a change in, or to control the flow, level, pressure, or temperature of a commodity, an instrument must first sense a change in a particular variable. Once a change has been detected, the instrument then transmits this information, via mechanical, electronic, or pneumatic means, to a control panel where it can be observed, recorded, and responded to. At the same time, the instrument may actívate other devices that will affect and change process conditions elsewhere in the facility. Sorne instruments are read in the plant at the instrument's actual location; others are displayed on a control panel located in the operator 's control room.
lnstrument Types Gauges-instruments that measure the liquid level inside a vessel or the temperature and/or pressure in the piping system. Level, temperature, or pressure gauges can be locally mounted to enable plant operators to obtain a visual reading. Controllers-devices used to maintain a specified liquid level, temperature, pressure, or flow inside a vessel or piping system. Controllers can actívate a control valve, which regulates the level, temperature, pressure, or flow of the commodity coming into or out of a vessel. Alarms-instruments that send a sígnal via lights, horns, or sirens indicate the liquid level, temperature,
or pressure inside a vessel is too high or too low or that there is no flow or reverse flow. Indicators-devices used to indicate the liquid level, temperature, pressure, or flow rate inside a piping system. Recorders-electronic devices used to record the liquid level, temperature, pressure, and flow rate inside a vessel or piping system throughout a certain shift or period of time. Although they are often installed independently, multitype instruments are engineered to perform various functions simultaneously. If there are the need to record and control the level of a commodity in a vessel, one would install a level recording controller (LRC). Toe LRC would not only record the level of the commodity in the vessel but also send a sígnal to a control valve that opens or doses to adjust the commodity level inside the vessel.
FLOW DIAGRAM DRAWING SYMBOLS Figure 7.Sa-e provides sorne examples of the many mechanical equipment symbols that can be found on flow diagrams. Figure 7.6 shows sorne of the common valve symbols used on flow diagrams along with various pipe and instrument line symbols. Note all valves, irrespective of their pipe size or pound rating, are drawn the same size. Remember, flow diagrams are schematic drawings where drawing to the exact dimensional size is not necessary. Generally, nozzles and
PIPE DRAFTING ANO DESIGN
o
LOCALL Y MOUNTED
INSTRUMENT
FLOW INSTRUMENTS
@
® ® @
® ®
FLOW ALARM FLOW ELEMENT
8 8
@ @
0
@ @
8 @ @
®
FLOW RECOROER
@
FLOW RECOROING CONTROLLER FLOW TRANSMITIER
INSTRUMENTS
8 8 8
@
LEVEL ALARM LEVEL ALARM HIGH
MOUNTED
INSTRUMENT
INSTRUMENTS
PRESSURE ALARM PRESSURE
CONTROLLER
PRESSURE
INOICATOR
PRESSURE
RECORDER
PRESSURE INOICATING
CONTROLLER
PRESSURE RECOROING
CONTROLLER
PRESSURE
SAFETY VALVE
RELIEF VALVE
TEMPERATURE INSTRUMENTS
@
LEVEL ALARM LOW
LEVEL INOICATOR
0 ® 8
LEVEL INOICATING CONTROLLER
@
LEVEL CONTROLLER
LEVEL GAUGE/GLASS
LEVEL RECOROING
PANEL/BOARD
PRESSURE
FLOW INOICATOR
LEVEL
@
139
FLOWPl.N\ ARRANGEMENT
CONTROLLER
®
TEMPERATURE
ALARM
TEMPERATURE
INDICATOR
TEMPERATURE RECORDER TEMPERATURE RECORDING CONTROLLER TEMPERATURE/THERMO
rn
TRANSMITTER
(OR)
WELL
0
FIGURE 7.4 Flow diagram instrument symbols.
reducers are not shown on the Mechanical flow díagram. Toe flow diagram in Figure 7.2 shows reducers in order to aid in the visualization and understanding of the flow diagram and its relationship to the piping arrangement drawing. Symbols used on flow diagrams are symbolic representations of actual pieces of equipment. lypically, these symbols have a rudimentary resemblance to the actual piece of mechanical equipment installed in the field.
FLOW PLAN ARRANGEMENT Toe flow plan, or sequence of flow, should be arranged in a logical order of commodity flow. Even with a brief examination of the flow diagram, the primary flow of commodity through the facility should be obvious. Use the following checklist as an aid when developing a flow diagram.
PIPE DRAFilNG AND DESIGN
140
7. FLOW DIAGRAMS ANO l?-:STRUMENTATION (a) (.. .____I
_____.,I)
_
HORIZONTAL YESSEL (ACCUMULATOR)
HORIZONTAL VESSEL (SEPARATOR}
'
...
,. ,
FLARE STACK
VERTICAL VESSEL (FRACTIONATION COLUMN) FIGURE 7 .5a-e
• • • • •
Flow diagram mechanical equipment symbols.
Avoid crossing lines where possible. Space mechanical equipment to avoid overcrowding. Add notes to symbols where necessary for clarity. Use arrows to show commodíty flow direction. Show equipment numbers when it is necessary to identify mechanical equipment. • Show control systems on the sketch. Toe control scheme is frequently the most important part of a flow plan sketch.
• Show important valves, orifice flanges, and control valves. • Show commodity flow directions through exchangers with arrows. • Do not run lines diagonally across the drawing. • Label feed lines entering the unit from the field where the line enters the unit. Label product lines leaving the unit by name. • Do not draw lines any closer together than necessary.
PIPE DRAFTING ANO DESIGN
141
FLOWPl.N\ ARRANGEMENT (b)
x~
G-----
SHELL AND TUBE EXCHANGER
SHELL AND TUBE EXCHANGERS (IN SERIES)
G-FIN
EXCHANGER
n
G-FIN EXCHANGERS (IN SERIES)
t5 G AIR COOLER (FIN-FAN)
..
COOUNG TQWER
FIGURE 7.5 (Continued)
PIPE DRAFilNG AND DESIGN
142
7. FLOW DIAGRAMS ANO JNSTRUMENTATJON
(e)
VAPOR OUTLET
HEATING MEDIUM SUPPLY
UQUID INLET HEATING MEOIUM RETURN
BOTIOMS OUT
KETTLE- TYPE RESOi LER HORIZONTAL (BOX) HEATER
VAPOR OUTLET
HEATING MEDIUM SUPPLY
HEATING MEOIUM RETURN
LIQUID INLET
VERTICAL HEATER FIGURE 7 .5
THERMO-SYPHON REBOILER
(Continued)
PIPE DRAFI1NG AND DESIGN
143
FLOW PLAN ARRANGEMENT
(d)
CENTRIFUGAL PUMP w /ELECTRIC MOTOR
RECIPROCATING PUMP w /ELECTRIC MOTOR
CENTRIFUGAL PUMP w /DIESEL ENGINE
. ºr--1·-CENTRIFUGAL IN-UNE PUMP w/ELECTRIC MOTOR
COMPRESSOR w/ ELECTRIC MOTOR
ROTARY (GEAR) PUMP w /ELECTRIC MOTOR FIGURE 7.5 (Continued)
PIPE DRAFTING AND DESIGN
144
7. FLOW DIAGRAMS ANO l?-:STRUMENTATION
(e)
n
-:/ () "
/-
(
FIXED ROOF STORAGE TANK w/AGITATOR (ELECTRIC MOTOR)
<,
(
----
..... <,
<;
ROOF ORAIN
--------/
<,
'
FOAM UNE CONNECTION
<,
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r-,
)
FIXED ROOF STORAGE TANK w/FLOAT GAUGE
11 11
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11 11 :::.U.=::
<,
MIX TANK
FLOATING ROOF STORAGE TANK FIGURE 7.5
(Continued)
PIPE DRAFTING ANO DESIGN
145
FLOWPl.N\ ARRANGEMENT
LINE SYMBOLS
VALVE SYMBOLS
/7/
BALL VALVE
7
7/
7
7/ 7 7/
7
7/
7
INSTRUMENT AIR UNE
BUTIERFLY
)(
VALVE
)(
INSTRUMENT
N N
CHECK VALVE
)(
)(
)(
)(
CAPILLARY TUBING
INSTRUMENT ELECTRICAL LEAD
PIPE
CONTROL VALVE
C>
GATE VALVE
MISCELLANEOUS SYMBOLS
~
1~
~T~
GLOSE VALVE
~?~
ORIFICE FLANGE ASSEMBLY
SPECTACLE BLIND
(CLOSED)
SPECTACLE BLIND
(OPEN)
PLUG VALVE ~
PIPING
PRESSURE SAFETY VALVE FIGURE 7 .6 Aow diagram piping symbols and abbreviations.
PIPE DRAFilNG AND DESIGN
SPECIALITY ITEM
146
7. FLOW DIAGRAMS ANO l?-:STRUMENTATION
CHAPTER 7 REVIEW QUIZ 1. List five items shown on the process flow diagram.
2. List five items shown on the mechanical flow
diagram.
6. Identify the following instrument abbreviations: a. LG
b.
~ d. e. f. g. h. i.
j.
_
FA.
_
TI PC.
_ _
LC PSV HCV LAH. LAL.
_ _ _ _ _
TRC
~
EXERCISE INFORMATION 3. List the four basic instrument groups.
4. Describe the functions of the five instrurnent types.
Use the instructions included in Figure 7.7 to create the flow diagram symbols with AutoCAD as shown. BLOCK each symbol individually, without text. Place the base point in the location specified. Give the symbols a concise, yet descriptive name. SAVE the drawing as FLOW SYMBOLS.
Drawing Exercises 7, 1-7 ,6
5. What type of instrurnent is used to maintain a certain liquid level?
Recreate the flow diagrams as shown, usíng the symbols in Figure 7.7 where applicable. Symbols representing other pieces of mechanical equipment can be developed on an as-needed basis. Although mechanical equipment is not drawn to scale, it should be proportional to the other symbols used in the drawing.
PIPE DRAFTING ANO DESIGN
147
EXERCISE INFORMATION
FLOW DIAGRAM
SYMBOLS
TO ORAW FLOW OIAGRAM SYMBOLS, SET GRIO TO .125" ANO SNAP TO .0625". THE .125" GRIO REPRESENTED BELOW HAS BEEN ENLARGED FOR BETTER VISUALIZATION. DRAW ANO BLOCK EACH SYMBOL. SYMBOL NAME ANO INSERTION BASE POINT (}8t) HAVE BEEN INCLUOED FOR PROPER IOENTIFICATION.
[NAME]
~~~---16 [GV]
[GBV]
[CKV]
[FA]
GATE VALVE
GLOSE VALVE
CHECK VALVE
FLOW ARROW
~[ cv J
CONTROL VALVE
ORIFICE
FLANGE SET
----+------++*+~-----'-------+-~
[HTIC]
[PSV]
[VTIC]
PRESSURE SAFETY VALVE
FOR VERTICAL INSTRUMENT AIR UNES
[CA]
[IB]
[ORIF-FLG]
INSTRUMENT BUBBLE
FIGURE 7. 7 Aow diagram exercise symbols.
PIPE DRAFilNG AND DESIGN
FOR HORIZONTAL I NSTRU M ENT AIR LINES
[RED] REDUCER 1----+--+------i
H-501
RECYCLE GAS HEATER t
t
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r
r r r
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r TO PILOT
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NITROGEN INJECTION PUMP 3 GMP O 5800 FT TDH 600 RMP O 8 HP A1MOS.
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EXERCISE 7 .3
02-E-201
02-V-203 FRACTIONATION COLUMN 4'-9" 00 X 18'-9" T/T DES. 375# @ 750ºF
PROOUCT CONDENSER
02-39-A 15-6" 4" 02-28-A15-6"
FEED
COOUNG WATER SEE UTIUlY Fl.OW DIAGRAM
02-E-201
02-34-A15-12"
02-29-A15-6"
7
02-38-A
15-6"
02-37-A 15-4" -IH
02-V-203
6" 02-35-A15-6"-IH
02-P-202 A&B 12
EXERCISE 7 .4
REFLUX PUMPS HP@ 4200 RPMs
03-V-303
03-H-304
03-FS-305
HEATER
FLARE STACK
SEPERATOR 36"0.D. X 19'-Q" T/T
03-33-A15-4"
PRODUCT STORAGE
03-32-Al 5-6"
Yows
FACILITY LOADING/ UNLOADING
03-18-A 15-8"
03-FS-305
03-20-A15-10"-IH
HOT OIL SUPPLY
,-----11----.-----!SEE
UTILfTY
FLOW DIAGRAM
03-31-A15-12" -IH
FUEL GAS
>----------t
HOT OIL RETURN SEE LITILfTY
FLOW DIACRAM
03-30-AlS-6"
10" 10"
03-19-A15-10"-IH 355'
10" 10"
12"
03-H-304
12"
03-P-301A & 3018 HOT Oll PUMPS
EXERCISE 7 .5
04-E-404 FRACTIONATOR REBOILER
04-V-401 fRACTIONATOR
04-CT-406
04-E-402A&B
COOUNG
PROOUCT CONOENSORS
TOWER
04-21-A15-8•
.. ..
04-E-402A
o
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04-E-4028
J
04-P-405A
04-P-4058
~
04-47-CJ0-4.
04-P-405A & 04-P-4056 COOLING WATER SUPPLY PUMPS
EXERCISE 7 .6
CHAPTER
8 Codes and Specifications As anyone who has ever played a game can te~ you, there are specific rules that must be followed if the game is to be played correctly. The same holds true for building a piping facility. Just as the rules of a game establish the basic guidelines for acceptable play, codes and specifications establish guidelines for piping facilities to ensure everything from quality construction to worker safety. Codes are a broad-based set of guidelines that govem the total scope of a project. Cedes originate from a number of sources. Sorne sources are governmental agencies such as OSHA and the EPA. Others are organizations, institutes, societies, or associations such as American National Standards lnstitute (ANSI) and American Society of Mechanical Engineers (ASME). Toe ASME has developed the Code far Pressure Piping 831 that govems the engineering of petroleum re~eries, chernical, pharmaceutical, and related processmg plants and the requirements necessary for their safe design and construction. Specifications, or specs, on the other hand, ~e de~eloped as a specific set of guideline~ for the e~~eenn?' design, fabrication, and construction. of a p1p~g fácility. Engineering specifications establish the basis ~om which the final plant design is produced. Broken ínto groups specific to the various des~~ disc!p.lines needed for a particular project, such as p1pmg, civil, structural, or electrical, specs will include guidelines on a number of tapies including initial site selection, pr?curem:nt guidelines for piping materials and m~aruca_I eqmpment, as well as equipment hydrostatíc testing and comrnissioning guidelines. Written to maintain cons~tency and uniforrnity throughout all phase~ of a pr?Ject, engineering specifications are very detailed. While codes can be as broad as a statement indicating that a11 piping components must conform t~ AS~ standa.rds, specs are so detailed that they may include mstruc~ons to the drafter stating that dimensions are to be wntten in feet and inches with precision to the nearest Yt/. As we look at codes and specs, remember that they have been developed through years of trial, application,
and error. When something purchased did not fit, something built broke, or something heated ble:W up, som~ne made a note of the mistake, remembered ít the next time a similar situation occurred, and made it an operational procedure. Eventually, the operational procedure evolved into either a piping code or engíneeríng specification.
CODES Though you may not be familiar with codes specific to pípíng facilities, you are familiar with a structure to which codes also apply: the typical house or apartment. Codes have been written coneerníng door sizes, window sizes, lumber dimensions, electrical requirements, etc. Take windows as an example. National building codes state, when needed for emergency egress, in case of a fire, windows are placed a maximum of 40" above the floor, in habitable roorns. Additionally, national building cedes mandate that windows in.sleep~g.roorns must have a net glazing area of 5.7sqft with a nurumum opening height of 2'-0" anda width of 1'-8". Toe cedes established by various governmental agencies affect everyone on a daily basis. Cedes exist that mandate safety requírements for automobile manufacturers, the use of fire retardant fabrics in clothing, and even acceptable radiation levels for rnicrowave ovens. As you can see, codes affect comrnon, everyday life. Though you may be unaware of them, codes impact each of us in a very personal way. Codes for piping facilities have been implemented in a similar fashion. Regulations have been established that govem pressure and temperature limits, material composition and stress allowances, worker safety,emergency evacuation procedures, and many, many other tapies. A partial list of the ASMEcedes written for piping facilitiesis shown in section 2.01 of the General Piping Specifications.
SPECIFICATIONS As previously mentioned, engineering specifications stipulate specific details for engineering, design,
154
C, 2012 Ehcvic-r lnc.
Ali rlghts rcserved.
155
GENERAL PIPING SPECIFICATIOKS
fabrication, and construction of a facility. Piping specifications in particular are used by numerous groups whose goal is to see a piping project through to completion. Engíneers, designers, and drafters will use piping specs to establish sizes, pound ratings, and dimensions of pipe and equipment. Stress calculations are made from information provided in the Specs to ensure that columns, beams, and supports withstand the loads and forces placed on them. Purchasing personnel need Specs to ensure proper pipíng materials and mechanical equipment are bought. Welders and fabricators use Specs to erect structures, supports, and route the proper size pipe. Piping Specs also provide the workers who install instrumentation controls with the proper temperature and pressure calibration settings. When applied to a piping facility, piping specifications become quite lengthy and are very detailed. General Piping Specifications, as they are known, comprise volumes of printed material, often seeming to be never-ending, The General Piping Specifications that follow are an abbreviated sample of a typical specification document.
GENERAL PIPING SPECIFICATIONS l. SCOPE 1.01 This Specification covers the materials and pro-
cedures for all process and utility piping.
3. DRAWING AND PROCEDURES 3.01 All piping drawings shall be complete and in sufficient detail to clearly indicate all clearances, intersections, anchors, guides, supports, expansion provisions, and connections to associated mechanical equipment. 3.02 All piping drawings shall show dimensions in feet and inches. Inches shall be used when the dimensions are less than 1 0 Dimensions will be to the nearest JI¡{. 3.03 lntersecting coordinates shall be used to position all mechanical equipment, pumps, pipe supports, structures, and buildings. Ali drawings are to be CAD generated or plotted from an approved 3D modeling software package. 3.03.1 Pipe shall be dimensioned from coordinates to show location. Elevations shall be used to indicate height measurements. 3.04 All piping 12" and below will be shown singleline and piping 14" and larger will be shown doubleline, except in congested areas where double-line work is required for clarity. Standard symbols shall be used throughout. Drawings will be plotted to 3¡~' = l"-0'' scale, except details or where needed for clarity. 3.05 Each pipeline shown on drawings shall be clearly marked with a line number. The line number will provide Unit number, Pipe number, Piping Specification class, and nominal pipe size. The following example illustrates the approved line number: 11
11•
01-20-AlS-10"-IHwhere 01 is the Unit number
2. CODE REQUIREMENTS 2.01 Piping shall be in accordance with the following applicable ASME codes: ASMEB31
Code for Pressure Piping
ASME B31.1-2010
Power Piping
ASME B31.3-2008
Process Piping
ASME B31.4-2009
Pipeline Transportation Systems
ASME B31.5-2010
Refrigeration Piping and Heat Transfer Components
ASME B31.8-2007
Gas Transportation and Distribution Pipíng Systems Boiler and Pressure Vessel Code
ASME BPVC-2010
2.02 Stress relieving shall conform to the p1pmg code. The stress relieving method used will depend on job location, quantity, and available tools: but the preferred post-heat treatment method shall be furnace treatment for a11 "shop" fabricated piping and exotherrnic/ stress relieving type packages (or equal) for field assembly welds and field fabricated piping.
20 is the Line nurnber A15 is the Pipe Specification class 10" is the nominal pipe size IH is insulate for heat conservation
A typical line number is shoum in Figure 8.1. 4. PIPING 4.01 Piping rnaterials shall be in accordance with piping material specifications and any deviations shall be noted on the drawings. 4.02 All piping, as far as practicable, shall be routed overhead on pipe stanchions, or pipe sleepers, and shall be routed the shortest possible run and require the minimum number of fittings: pipe configurations also shall be free from appreciable vibration with suitable expansion provided for hot lines. 4.03 All nongalvanized steel underground lines shall be coated and wrapped in accordance with engíneering specifications. 4.04 All operating valves 6' -O'' above Grade or platform shall be chain operated. Sorne of the valves not to be considered as operating valves are branch line block
PIPE DRAFTING AND DESIGN
156
8. CODES A."lD SPECIFICATIONS
02-104-A 15-6"-ST (2-1 / 4")
t
__J ~
Unit Number Line Number Specificotion Closs Heot Trocing Symbol
Nominal Pipe Size
L
No ond Size ~f T rocers
lnsulotion
ET - Electric T roced SJ - Steom Jocketed ST - Steom (w/trocers)
IC IH IS PP -
Symbol
Cold Hot Sofety Personnel Protection
FIGURE 8.1 Line number.
valves from header, by-pass valve and block valves on control manifold stations, level controllers, main header blocks on all utility services, and block valves on exchangers and coolers. 4.05 Expansion or contraction shall be considered for each line. Cold spring shall be considered for each line. Cold spring shall be used where it is beneficial and in accordance with the ASA Code for Pressure Piping and noted on spool drawings. 4.06 Slíp-on flanges may be substituted for weld neck flanges to suit space limitations where allowed in the specifications. In other specifications, slip-on flanges may be used only when approved by the design supervisor. 4.07 Pipe sizes of l1A11, 2W', 31h 5 and 7" shall not be used except as required for equipment connections. 4.08 Basket type with 10-mesh screen start-up strainers shall be used in all pump suctions. 4.09 Clips, lugs, anchors, guides, etc., shall be installed in field after erection on standard piping. For any special alloy where field welding would have adverse effect on the material, all attachments shall be installed by shop fabricator. 4.11 When couplings are used for thermometer and thermocouple well connections, the inside surface shall be free of any weld metal and the opening shall be clear and free to receive a well. 4.12 Steam tracing shall be installed in accordance with job standards. 4.13 Pipe supports spacing shall be 20'-0" maximum with píck-up supports as required for lines 3 and smaller. 11,
11,
11
5. INSTRUMENTSAND INSTRUMENT CONNECTIONS 5.01 Liquid level controllers and gage glasses shall be located so as to be accessible from grade, ladder, or platform. 5.02 Pressure gage connections shall be % 11•
5.03 Test connections shall be%". 5.04 Temperature instruments such as TW, TI, TIC, TRC, etc., shall have 1" NPT. 5.05 TW and TI connections in pípíng shall be located 45° off centerline or in the horizontal. 6. VENTS AND DRAINS 6.01 Ali lines shall have high point vents and low point drains shall be 3.4" couplings with pipe plugs, except in specifications covering materials such as aluminum in which case they shall be flanged. 6.02 Any vent or drain required for plant operation shall be sized and shown in the flow diagram. 7. ORIFICES 7.01 Generally, the mínimum requirements for orifice runs shall be in accordance with the AGA-ASME Standards. Orífice taps shall be vertical for air and gas service and shall be on the horizontal for liquid and steam service. 8. CLEARANCES AND SPACING 8.00 Roadways 8.01 Mínimum clearance over main roadways shall be 18'-0" to the lowest projection. 8.02 Mínimum clearance over secondary roadways is 14'-6" to the lowest projection, 8.03 Mínimum width of secondary roadways is 10'-0 excluding 3' -0" shoulders. 11,
8.1.0 Walkways 8.1.01 Headroom beneath main overhead pipe rack shall be a mínimum of 11 '-O". Special attention shall be given to instrument and electrical trays along with any lines that drop from bottom level of pipe rack, to maíntain, mínimum clearance, 8.1.02 Maíntain a mínimum headroom clearance over aisleway of 7' -0". 8.1.03 Maintain mínimum headroom clearance of 7' -6" inside buildings and for miscellaneous pipe supports.
PIPE DRAFTING ANO DESIGN
157
GENERAL PIPING SPECIFICATIOKS 2'-6" (8.2.01)
~- 135'-6" ~)
PLATFORM ELEv.
114°-6"
PLAN
~ é..i.__T_..~~~-;,-;r,-,!""'TI "'
04-109-A 15-14"
ncv.
(J.04 & J.05)
12•·-o·
í
b
(3.03.1)
H.P. PAVING
ELEVATION FIGURE 8.2 Application of engineering specifications.
8.1.04 Clear passageway between equipment or equipment piping and adjacent equipment shall be 2' -6" mínimum. Exception: Horizontal clear space between exchanger flanges shall be a mínimum of 18".
8.2.0 Platforms 8.2.01 Maintain mínimum platform width of 2' -6". 8.2.02 Maintain nurumum headroom clearance above platforms of 7'-0". 8.2.03 Platforms shall be placed 2'-6" below the centerline of manways.
PIPE DRAFTING AND DESIGN
158
8. CODES A."lD SPECIFICATIONS
8.2.04 Maximum vertical distance between platforms (ladder length) is 30'-0 8.2.05 Cages are not required for ladders 8'-0 long or less or ladders that end 20' -0'' or less above the high point of pavíng. 8.2.06 Platforms shali be provided for manways that have a centerline 15' -0 or higher above high point of paving. An example of how clearance and spacing specifica tions are applied to piping drawings is represented in Figure 8.2. 11•
11
11
9. INSULATION ANO PAlNTING 9.01 All hot insulated lines 21h'' larger shall be on 3" mínimum heíght insulation shoes. All low-temperature pipíng will rest on the insulation with a steel cradle outsíde of the insulation to distribute the load at the point of support. 9.02 Insulation thickness for piping is indicated on the pipeline list. All insulation materials shali be instalied in accordance with insulation specifications. 9.03 All paintíngs shall be done in accordance with paintíng specifications. 10. FABRICATIONTOLERANCES 10.01 Flange bolt holes shall straddle the vertical, horizontal, or North-South centerline unless otherwise noted. Rotation of flange bolt holes shali not exceed ){/ measured across the flange face parallel to a centerline and between the holes nearest to it. 11. SHIPPING LENGTHS 11.01 Shop fabricated pipe shali be prefabricated
in the number of pieces shown on the spool drawing unless otherwise approved in writíng. If piece mark numbers are not shown on drawings, piping shall be prefabricated in as few pieces as possible, consistent with raíl or truck shipment, to mínimize field weldíng. Field welds shall be straight butt welds unless otherwise specifically shown or approved. 11.02 Toe fabricator shall provide protectíon for ali flange faces, male threaded connections, plugs for all female threaded connections, covers for all open pipe, etc., to prevent damage during shipment and storage as noted in the Weldíng Specifications. Both shop and field shall ensure that flange faces are protected from corrosion or rust, with extreme care taken on RTJ and T&G flanges. 12. PIECE MARKING ANO SHOP PAINTING 12.01 Each shop fabricated spool piece shall have a mark number assigned. Toe fabricator shali paint the number on the piece, or if another method of identification is to be used, written approval must be obtained.
12.02 Toe fabricator shall be supplied with an original of each spool. The fabricator shall complete the spools with mark numbers and field weld locations and return. 12.03 Shop-fabrícated pipíng shali be cleaned of all rust, mili scale, weld slag and splatter, and primed before shipment. Unless otherwise specified, the primer shall consist of one coat of zinc chromate. 13. TESTING 13.01 Where practical, ali lines shall be hydrostatically tested in place. Testíng shall be in accordance with ASME Code for Process Piping, latest revision. 13.02 Where water may have a deleterious effect on piping or equipment, the system shall be tested with air and soap suds. 13.03 Lines ventíng or draíning to atmosphere shall not be tested. 14. COLOR CODE 14.01 Toe following color code shall be used to assist the construction department with a method of identífícation for valves and other piping materials. 14.02 For standard steel, bronze, cast malleable, and wrought iron the field material receiving group can best code the material as received. 14.03 Special carbon steel and any alloys shali be color coded by the manufacturer, vendor,or fabricator. Color
Specification
Black
WD12
Blue
AlS
Green
WS12
Oran ge
C30
Red
PA12
White
IA12
Yellow
515
An example of how engineering specifications are applied to piping drawings is presented in Figure 8.2.
SPECIFICATION
CLASSES
As extensive as the General Piping Specifications are, they should not be considered all encompassing. Engineering specifications are divided into groups, or classes, developed especially for particular services, Classes are categorized generaliy by the commodity flowing withín the pipe and its associated pressure and temperature. Specification classes take into account
PIPE DRAFTING ANO DESIGN
159
ABBREVIATIONS
whether the commodity is a gas or liquid, including design and operating temperatures and pressures, even corrosiveness. Table 8.2 is a sample of a Piping Specification Class Directory. It includes the class designation, flange type and ratings, material, and service commodity type. Specification classes use service parameters to establish flange pound ratings, pipe wall thickness, pressure and temperature limits, as well as the type of pipe and fitting connections to be used, that is, screwed, socketweld, butt-weld, flanged, etc. Classes are extremely detailed. They specify which manufacture to purchase valves from, as well as the specific manufacturer's model number to be used. Classes specify the material gaskets will be made of and whether branch connections are to be made using straight tees, reducing tees, or stub-ins. Specification classes also stipulate corrosion allowance values. Corrosion allowance is the amount of surface material allowed to be eroded by the commodity within the pipe while permitting the pipe to remain usable for the particular service for which it is installed. All encompassing, specs even dictate what color to paint the pipe. Sorne of the specification classes that were listed in Table 8.1 are presented in Figure 8.3a-f and are to be applied to the various assignments and projects throughout this text. Use them as a reference to answer specific questions relating to the design and drafting procedures needed to complete Units 01, 02, 03, and 04. As with all engineering specifications, íncludíng the examples in this text, they should only be used with the project for which they are written and should not be considered typical for every project.
ABBREVIATIONS As a pípíng facility becomes more complex, so do the pípíng drawings. Facilities such as multistoried structures, specialized refining systems, and complex equipment arrangements compound the crowdedness of a drawing. To alleviate the crowded conditions, abbreviations should be used to reduce the space requirements of callouts and notes. The following compilation is an alphabetical listing of many common abbreviations
TABLES.! Piping Specificatíon Class Directory Class
Rating
Material
Service
AlS
lSO#RF
Carbon 5teel
Process
AlSC
lSO#RF
Carbon 5teel
Caustic
AlSP
lSO#RF
Special Carbon Process ( -20 to -SOºF) 5teel
AlSF
lSO#RF
Carbon 5teel
Freon
C30
300#RF
Carbon 5teel
Process
C30C
300#RF
Carbon 5teel
Caustic
C30P
300#RF
Special Carbon Process ( -20 Steel to -SOºF)
CW15
lSO#RF
Carbon 5teel
Cooling Water
F60
600# RF
Carbon 5teel
Process
F60P
600#RF
Carbón 5teel
Pipeline
IP12
125#Scrd
Carbón 5teel (Galvanized)
Instrument Process Piping
IA12
125#Scrd
Carbon 5teel (Galvanized)
Instrument Air Headerand Utility Piping
1512
125#Scrd
Carbon 5teel (Galvanized)
Instrument Air Signal Piping
PA12
125#Scrd
Carbon Steel (Galvanized)
Plant Air
R30
300#RF
Carbon 5teel
175# 5team and Condensate
515
lSO#RF
Carbon 5teel
Low Pressure Steamand Condensate
UAlS
150#
Carbon 5teel
Utility Air Header
WD12
125#Scrd
Domestic Water
W512
125#Scrd
Carbon 5teel (Galvanized) Carbon 5teel (Galvanized)
Service Water
found on p1pmg arrangement drawings, elevations, details, flow diagrams, and/or isometrics. A complete listing is almost impossible to assemble, as engineering companies and their clients often develop abbreviations that are unique to specific projects.
PIPE DRAFTING AND DESIGN
160
8. CODES ANO SPECIFICATIONS
(a)
A15
PIPING PO UNO RATING CORROSION ALLOWANCE
RF
150#
. 05"
ITEM
SPECIFICATION MATERIAL:
CONDITIONS:
PSIG 'F
OPERATING
200 350
175 275
DESCRIPTION
WEIGHT/ RATING EX. HVY. STO. WT. STO. WT.
Fittings
1/2"-11/2" 2" 3"-24" 1/2"- 2" 3"-24"
Flonges
1/2"-11/2" 2" 3"-24"
150# 150# 150#
VAL VES
SIZES IN INCHES
WEIGHT/ RATING
Gate
1/2"- 2" 3"-24"
150-800 150
CAST CARBON
Globe
1/2"- 2" 3"-24"
150-800 150
CAST CARBON
GASKETS BRANCH CONNECT.
SEAMLESS-PLAIN ENOS SEAMLESS-PLAIN ENOS SEAMLESS-BEVELED ENDS
3000#
FORGED STEEL SOCKET WELD
STO. WT.
Flexitallic
style
STEEL
DESIGN
SIZES IN INCHES
Pipe
CAR BON
FORGEO STEEL BUTT WELD FS FS FS -
RAISED FACE SOCKET WELD RAISEO FACE SOCKET WELD RAISED FACE WELD NECK
DESCRIPTION FORGED CARBON STEEL STEEL
FORGED CARBON STEEL
-
STEEL
END TYPES SWE RF SWE RF
150#, 304SS: 1 /8" thick
UNE SIZE 2"-BELOW
USE A TEE USE A TEE ANO SWAGE ON SIZES 2" & SMALLER
3"-ABOVE
STUB-IN
WHEN LESS THAN LINE SIZE
150#
FIGURE 8.3 (a) A15 Class Piping Speci.fication; (b) C30 Class Piping Specification; (e) IA12 Class Piping Specification; (d) PA12 Class Piping Speci.fication;(e) 515 Oass Piping Specification;(f) WS12 Class Piping Specification.
PIPE DRAFI1NG AND DESIGN
161
ABBREVIATIONS
(b)
C30
PIPING POUND RATING
RF
3QQ#
CORROSION ALLOWANCE
ITEM Pipe Fittings
MATERIAL:
CONDITIONS:
.05" 1/2"-
1/2" 2" 3"-24"
r
VALVES
SIZES IN INCHES
WEIGHT/ RATING
1/2"-
150-800
Globe GASKETS BRANCH CONNECT. FIGURE 8.3
2"
2"
SIZE
RAISED FACE SOCKET WELD RAISED FACE SOCKET WELD RAISED FACE WELD NECK
DESCRIPTION FORGED
CARBON STEEL
CAST CARBON
150-800
CAST CARBON
style
-
300#,
RF SWE
STEEL
RF
304SS:
1 /8" thick
USE A TEE
2"-BELOW
USE A TEE ANO
3"-ABOVE
STUB-IN
WHEN
SWAGE ON SIZES LESS THAN
UNE
(Continued)
PIPE DRAFilNG AND DESIGN
2" & SIZE
END TYPES SWE
STEEL
FORGED CARBON STEEL
300
Flexitallic LINE
FS FS FS -
300
3"-24"
WELD
FORGED STEEL BUTT WELD
300# 300# 300#
3"-24" 1 /2"-
350
FORGED STEEL SOCKET
3000#
1/2"-11/2" 2" 3"-24"
Gate
300
425
SEAMLESS-PLAIN ENDS SEAMLESS-PLAIN ENDS SEAMLESS-BEVELED ENDS
STO. WT.
Flanges
OPERATING
375
DESCRIPTION
EX. HVY. STO. WT. STO. WT.
3"-24"
CAR BON STEEL
DESIGN
PSIG 'F
WEIGHT/ RATING
SIZES IN INCHES
1/r-
SPECIFICATION
SMALLER
300#
162
8. CODES ANO SPECIFICATIONS
(e)
IA12
PIPING POUND RATING CORROSION ALLOWANCE
125#
MATERIAL: CONDITIONS:
.05"
SPECIFICATION
PSIG T
ITEM
SIZES IN INCHES
WEIGHT/ RATING
Pipe
1/2"-11/2" 2" - 6'º
EX. HVY. STO. WT.
CAR BON
STEEL
DESIGN 200 150
GALVANIZED
OPERATING
DESCRIPTION SEAMLESS-THREAOED-GALVANIZED SEAMLESS-THREAOED-GALVANIZED
Fittings
1/2" - 6"
3000#
FORGEO STEEL-THREADEO-GALVANIZEO
Flan ges
1/2" - 6"
150#
FORGED STEEL-THREADED-FLAT FACE
VAL VES
SIZES IN INCHES
Gate Globe
WEIGHT/ RATING
1 /2"- 2" 3"-6"
125 125
1 /2"-
125 150
2"
3"
DESCRIPTION CAST BRONZE
END TYPES
CAST BRONZE
SE FF
CAST BRONZE
SE
CAST BRONZE
FF
GASKETS 150#, 1 / 16" thick ASBESTOS- FULL FACE with BOLT HOLES BRANCH CONNECT. FIGURE 8.3
UNE SIZE 4"-BELOW
USE A TEE USE A TEE ANO SWAGE ON SIZES 6" & SMALLER
(Continued)
PIPE DRAFI1NG AND DESIGN
125#
163
ABBREVIATIONS
(d)
PA12
PIPING PO UNO RATING CORROSION ALLOWANCE
125#
. 05"
ITEM
MATERIAL: CONDITIONS:
SIZES IN INCHES
Fittings
1/2" - 6"
3000#
Flonges
1/2" - 6"
150#
SIZES IN INCHES
WEIGHT/ RATING
DESCRIPTION SEAMLESS-
STO.
SEAMLESS-THREADED-GALVANIZED
WT.
1/2"- 2" 3"-6"
125 125
Globe
1/2"- 2" 3"
125 150
BRANCH CONNECT.
OPERATING
EX. HVY.
Gote GASKETS
GALVANIZED
200 150
WEIGHT/ RATING
1/2"-11/2" 2" - 6"
CAR BON STEEL
DESIGN
PSIG 'F
Pipe
VAL VES
SPECIFICATION
THREADED-GALVANIZED
FORGED STEEL-THREADED-CALVANIZED
FORGED STEEL-THREADED-FLAT
DESCRIPTION
FACE
END TYPES
CAST BRONZE
SE
CAST
BRONZE
FF
CAST BRONZE
SE
CAST
FF
BRONZE
150#, 1 / 16" thick ASBESTOS- FULL FACE with BOLT HOLES LINE SIZE
USE A TEE
4"-BELOW
USE A TEE AND SWAGE ON SIZES
FIGURE 8.3 (Continued)
PIPE DRAFTING AND DESIGN
6" &
SMALLER
125#
164
8. CODES ANO SPECIFICATIONS
(e)
S15
PIPING POUND RATING CORROSION ALLOWANCE
RF
150#
.05"
ITEM
SPECIFICATION MATERIAL: CAR BON
CONDITIONS:
175 275
200 350
DESCRIPTION
WEIGHT/ RATING
SIZES IN INCHES
OPERATING
DESIGN
PSIG T
Pipe
1/2"-11/2" 2" 3"-24"
EX. HVY. STO. WT. STO. WT.
SEAMLESS-PLAIN ENOS SEAMLESS-PLAIN ENOS SEAMLESS-BEVELEO ENDS
Fittings
1 /2"- 2" 3"-24"
3000# STO. WT.
FORGED STEEL SOCKET WELO
Flonges
1 /2" - 1 1 /2" 2" 3"-24"
150# 150# 150#
VAL VES
SIZES IN INCHES
WEIGHT/ RATING
1/2"-
150-800
Gote Globe STEAM TRAP
GASKETS BRANCH CONNECT. FIGURE 8.3
2"
3"-24" 1/2"-
FORGED STEEL BUTT WELD FS - RAISED FACE SOCKET WELD. EX. HVY. BORE FS - RAISED FACE SOCKET WELD. STO. WT. BORE FS - RAISED FACE WELD NECK, STO. WT. BORE
DESCRIPTION
2"
Flexitollic UNE SIZE
STEAM
style
RF SWE
FORGED CARBON STEEL
150 125#
SWE
CAST CARBON STEEL
150-800
1/2"
END TYPES
FORGED CARBON STEEL
150
3"-24"
-
CAST CARBON STEEL
RF
FORGED ALLOY STEEL
SCRD
150#,
304SS:
1 /8" thick
USE A TEE
11/2" -BELOW USE A TEE ANO SWAGE ON SIZES 2" & SMALLER 2"-BELOW USE A SOC-0-LET ON SIZES 3" & LARGER 3"-ABOVE
STEEL
STUB-IN WHEN LESS THAN UNE SIZE
(Continued)
PIPE DRAFI1NG AND DESIGN
1 50#
165
ABBREVIATIONS
(f)
WS12
PIPING POUND RATING CORROSION ALLOWANCE
125#
. 05"
SPECIFICATION
MATERIAL: CONDITIONS:
PSIG 'F
CAR BON STEEL
DESIGN
GALVANIZED
OPERATING
200 150
ITEM
SIZES IN INCHES
WEIGHT/ RATING
DESCRIPTION
Pipe
1/2"-11/2" 2" - 6"
EX. HVY. STO. WT.
SEAMLESS-THREADED-GALVANIZED SEAMLESS-THREAOED-GALVANIZEO
Fittings
1/2" - 6"
3000#
Flan ges
1/2" - 6"
150#
VAL VES
SIZES IN INCHES
WEIGHT/ RATING
Gote
1/2"- 2" 3"-6"
125 125
Globe
1/2"- 2" 3"
125 150
GASKETS BRANCH CONNECT. FIGURE 8.3
150#,1/16" LINE SIZE 4"-BELOW
FORGEO STEEL-THREAOED-GALVANIZEO FORGED
STEEL-THREAOEO-FLAT
DESCRIPTION
FACE ENO TYPES
CAST BRONZE
SE
CAST BRONZE
FF
CAST BRONZE
SE
CAST BRONZE
FF
thick ASBESTOS- FULL FACE with BOLT HOLES
USE A TEE USE A TEE ANO SWAGE ON SIZES 6" & SMALLER
(Conlinueá)
PIPE DRAFilNG AND DESIGN
125#
166
8. CODES A."lD SPECIFICATIONS
PIPING ABBREVIATIONS A A A ACCUM AL ANSI API ASSY ASTM ATMOS AUX AVG AZ
Alarm Anchor Accu.mulator Alu.minu.m American National Standards lnstitute American Petroleum Institute Assembly American Society for Testing and Materials Atmosphere Auxiliary Average Azimuth
B B BB BBE BBL BC BD BE BF BL BLDG BLE BOM BOP B&S BSE BTU BV BW
Beveled Bolted Bonnet Bevel Both Ends Barrel(s) Bolt Circle BlowDown Beveled End(s) Blind Flange Battery Limits Building Bevel Large End Bill of Materials Bottom of Pipe Bell and Spigot Bevel Small End British Thermal Unit Ball Valve Butt-weld
e CB CHKV Ch.Op. CI CL
co
COL COLS CONC CONO CONN CORR CPLG
es es
Catch Basin CheckValve Chain Operator Castlron Oearance CleanOut Column Columns Concentric Condensa te Connection Corrosion Coupling Carbon Steel Cast Steel
es ese eso
CTRLV CWR
cws
Cold Spring Car Seal Closed Car Seal Open Control Valve Cooling Water Return Cooling Water Supply
D DA DF DIA DIM DISCH DR DW DWG DRWN
Directional Anchor Drain Funnel Diameter Dimension Discharge Drain DummyWeld Drawing Drawn
E E ECC EL ELL ELEV EQUIP ERW EXCH EXIST
East Eccentric Elevation Elbow Elevation Equipment Electric Resistance Welded Exchanger Existing
F FA FBO FDN FE F/F FF FF FI FIC FIG FLR FLDFAB FL FOB FOT FR FRC FS FS
rr
FW
PIPE DRAFTING ANO DESIGN
Flow Alarm Furnished By Others Foundation Flow Element Face-to-Face
Flat Face Full Face Flow Indicator Flow Indicating Controller Figure Floor Field Fabricate Flan ge Flat on Bottom Flat on Top Flow Recorder Flow Recording Controller Field Support Forged Steel Foot orFeet Field Weld
167
PIPING ABBREVIATIONS
G G GAL GALV GPH GPM GR GaV GIV
L Gauge or Gage Gallon(s) Galvanized Gallons Per Hour Gallons Per Minute Grade Gate Valve Globe Valve
H HCV HDR HIC HLL HOR HP HPFS HPP HR HR HTR HVAC HVY HYD
Hand Control Valve Header Hand Indicating Controller High Liquid Level Horizontal High Pressure Hígh Point Finished Surface High Point Paving HangerRod Hour Heater Heating, Ventilating, and Air Conditioning Heavy Hydraulic
I IA IA IC ID IDD IET IGT IH IN INS INST INV IPS IS ISA ISO ISO IST
lnstrument Air lnsulation (Anti-sweat) lnsulation (Cold) lnside Diameter lnside Depth of Dish Electric Trace Glycol Trace lnsulation (Heat Conservation) Inch(es) lnsulate or lnsulation lnstrument(ation) Invert Elevation lron Pipe Size lnsulation Safety lnstrumentation Society of America Intemational Organízation for Standardization Isometric Steam Trace
J
JCT JS JT
Junction JackScrew Joint
L LA LAH LAL LBS LC LC LG LG LI LIC LLL LN LO LP LPG LPT LR LR LRC LS
Level LevelAlarm Level Alarm-High Level Alarm-Low Pounds Level Controller LockClosed Level Gauge Level Glass Level Indicator Level Indicating Controller Low Liquid Level Llne LockOpen Low Pressure Liquefied Petroleum Gas LowPoint Level Recorder LongRadius Level Recording Controller Level Switch
M mm M M&F MATL MAX MECH MFG MFR MI MIN MIN MISC MK MW MW
millimeter Meter Male and Female Material Maximum Mechanical Manufacturing Manufacturer Malleable lron Mínimum Minute Miscellaneous PieceMark Manway MiterWeld
N N NC NEC NEG NIP NLL NO NO NOM NOZZ NPS
PIPE DRAFTING AND DESIGN
North Normally Closed National Electric Code Negative Nipple Normal Liquid Level Normally Open Number Nominal Nozzle Nominal Pipe Size
168 NPSH NPT NTS
8. CODES A."lD SPECIFICATIONS
Net Positive Suction Head National Pipe Thread Not to Scale
REY REY RF
RJ RPM RS RTJ
o OAL OD OH OPP OS&Y OVHD ows
Overall Length Outside Diameter OpenHearth Opposite Outside Screw and Yoke Overhead Oily Water Sewer
s
p PA PA Pe PCY PdRC PE PI PI PIC P&ID PLE PO POE POS pp PR PRe PS PSE PSI PSIA PSIG PSY PT
Pipe Anchor Pressure Alarm Pressure Controller Pressure Control Valve Pressure Differential Recording Controller Plain End Point of Intersection Pressure lndicator Pressure lndicating Controller Piping and InstrumentDiagram Plain Large End PumpOut Plain One End Positive Personnel Protection Pressure Recorder Pressure Recording Controller Pipe Support Plain Small End Pounds Per Square lnch Pounds Per Square lnch Absolute Pounds Per Square lnch Gage Pressure Safety Valve Point
Q QTY QUAD QUAD
Quantity Quadrant Quadruple
R R REe'D RED REF REINF REQ'D
Radius Received Reducer Reference Reinforce Required
Reverse Revision Raised Face Ring-TypeJoint Rotations Per Minute RisingStem Ring TypeJoint
s se SeH SeRD SECT SH (SHT) SMLS so so SOL SP SPGR SPEe SQ SR STO STL STM SUCT SUPT sw SWG SWP SYS
South Sample Connection Schedule Screwed Section Sheet Seamless SlipOn SteamOut Sock-o-let Set Point Spedfic Gravity Spedfication Square Short Radius Standard Steel Steam Suction Support Socket-Weld Swage Standard Working Pressure System
T T TA Tan TBE Te Te Y TE TEMP T&e T&G THRD TI TIC TLE roe TOG TOL TOS
PIPE DRAFTING ANO DESIGN
Steam Trap Temperature Alarm Tangent Thread Both Ends TemperatureController TemperatureControl Valve Threaded End Temperature Thread and Coupled Tongue and Groove Thread Temperature lndicator Temperature lndicatingController Thread Large End Top of Concrete TopofGrout Thread-o-let Top ofSteel
169
CHAPTER 8 REVIEW QUIZ
TR TRC TSE Tff TW TW TYP
Temperature Recorder Temperature Recording Controller Thread Small End Tangent to Tangent Temperature Well Thermowell
CHAPTER 8 REVIEW QUIZ 1. Explaín the difference between codes and
specífications.
Typícal
Using information found in the General Piping Specifications, answer the following questions.
V UA
us
Utility Air Utility Station
3. Piping drawings are drawn to which scale?
V VA VA VB
ve
VERT VF VOL
vs
Valve Vent to Atmosphere Vortex Breaker Vitrified Clay Vertical Vent to Flare Volume Vent to Stack
w
WB WE WLD WN WOG WOL WT
with West Welded Bonnet WeldEnd Weld WeldNeck Water, Oil, Gas Weld-o-let Weight
X XH
xs XXH xxs
4. What is the mínimum headroom clearance of a
secondary roadway?
s.
What is the mínimum headroom clearance over an aisleway?
6. Ali operating valves
platform shall be chain operated.
w w/
2. Dimensions are provided on drawings to the nearest of an inch.
above Grade or
7. What is the mínimum width of a platform? 8. What is maximum vertical distance between
platforms?
9. What type of "start-up" strainers are used at ali
pump suctions?
10. All lines shall have vents and drains. What size is
ExtraHeavy Extra Strong Double Extra Heavy Double Extra Strong
the vent and drain connections?
PIPE DRAFTING AND DESIGN
CHAPTER
9 EquipmentLayout
PLANT COORDINATE SYSTEM Plot Plans, Foundation Location Plans, Equipment Location Plans, and Pípíng Arrangement drawíngs use the plant coordinaie system method of arranging and positioning drawing elements. Universally recognized throughout the pípíng industry, the plant coordinate system uses intersecting grid lines, similar to the Cartesian coordinate system, drawn relative to an established north direction, to locate buildings, structures, steel columns, concrete foundations, mechanical equipment, and pipe configurations. Toe grid lines, which originate from a designated control point, are drawn parallel to north/ south and east/west axes (Figure 9.1). Toe control point, more commonly known as a bench mark, is a permanent marker erected at a specified location somewhere within the proposed facility. It is often located so that it cannot be accidentally damaged or destroyed. Toe control point is the precise location from which the intersecting north/south and east/west grid lines oríginate. From this point, the grid lines are measured incrementally and labeled with numerical values known as coordinates. Toe control point, therefore, becomes the primary reference point for the entire facility. By labeling the control point with a positional value of O' ·-O", 0' -0 and using a North Arrow to establish orientation, the numencal values assigned to the coordinates allow for exact positioning of all facility components. Each facility component will be precisely located using two intersecting coordinates. Coordinaies indicate the distance and direction the particular structure, foundation, or piece of mechanical equipment measures from the control point, Toe North Arrow typically points up, or toward the top of the drawing sheet, and creates directional bearing for the facility. As an altemate orientation, the North Arrow may point to the right on the drawing. Assuming the North Arrow points up, horizontal lines drawn above, or north of, the O'-O", 0'-0' originare designated as North coordinates and are labeled to indicate their linear 11
distance from the control point, for example, N. 10 -0 Though these lines are drawn in an east/west alignment, they are labeled as North coordinates because they measure distance from the control point northward. Vertical lines drawn to the right of O'-O', O'-O' are designated as East coordinates and are labeled as such, for example, E. 20' -O'. Lines drawn to the south and west of the control point will have S. or W. designations, respectively. Piping Arrangement drawíngs are often severely overcrowded with extensive amounts of graphical symbols and written information. Toe use of coordinates reduces the amount of written information and simplifies the drawing by minimizing the use of location dimensions. Figure 9.2 demonstrates the use of coordinates to label the positions of mechanical equipment. Toe format used to identify plant coordinates will vary with each design project. Sorne projects use feet and inch designations, whereas others may use decimals of a foot or millimeters. No matter the format, coordinates are preceded by the letters N, S, E, or W, except for 0 -0 Toe projects in this text will use feet and inches measurements. As mentioned previously, the use of coordinates eliminates the need for excessive dimensions. However, when location dimensions are required on drawings, they use a known coordina te as a datum, usually the centerline of a column, foundation, or piece of mechanical equipment. Whatever the unit of measurement, one rule to remember is: Horizontal length dimensions are found by adding or subtracting coordinases. Figure 9.3 allows you to see the amount of space required to include linear dimensions on a drawing and how the use of coordinates can free a significant amount of drawing space. 1
11•
1
11•
PLANT ELEVATIONS Similar to the way a plan view drawíng has a control point to help establish horizontal dimensions in a piping 170
C, 2012 Ehcvic-r lnc. Ali rlghts rcserved.
171
PLANT ELEVATIONS
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N. 50'-0" 1 N. 40'-0"
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.i. .i. 1 FIGURE 9.1 Plant coordinate system.
facility, a control point is also needed to establish vertical dimensions, or elevation, in the facility. Elevation, as it is traditionally known, is the vertical distance an object rises above sea level, such as the height of a mountain. But in pípíng facilities, elevation is used to designate the heíght an object measures from the ground. In Piping terminology, the ground is referred to as Grade. It is from Grade that all elevation references are based. But rather than using numbers based on the actual height the ground measures above sea level, many facilities use an arbitrary Grade elevation of 100'-fJ', as a matter of convenience. In all petrochemical facilities, pipes are installed
both above and below Grade. The use of 100'-O'' as the control point of reference prevents the use of negative numbers when dimensioning pipes below Grade. This simplifies the mathematical calculations that the interpolation of positive and negative numbers may cause. Very few actual dimensions are shown on pípíng section or elevation drawíngs. However, numerous callouts are placed on drawings to convey elevation information to the reader. Sorne of the callouts and corresponding terms are shown below. See Figure 9.4 for examples of the plant elevation system.
PIPE DRAFTING AND DESIGN
172
.
9. EQUJPMENTLAYOUT
o
1
o N. 50'-0" N. 40'-0"
~~
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S. 20'-0"
s. 30'-0"
s. so'-o" FIGURE 9.2 Using coordinates to locate mechanical equipment.
Piping Terminology
Piping Callout
Grade elevation
GRADE EL.100'--0"
High point of paving
H.P PAVING100'-0"
Centerline elevation
t EL.102'-0"
Top of concrete
T.O.C. EL.101 '-O"
Top of steel
T.O.S. EL. 112' - O"
Bottom of pipe
B.O.P. EL. 112' - O"
Face of flange
F.O.F. EL. 105' - O"
Top of platform
T.O. PLAT. EL.137'-6"
Toe repeated use of coordinates and elevations makes it imperative that correct numbers be used to calculate accurate dimensions. To avoid inadvertent mixing of coordinate and elevation values, follow this simple guideline: Use only coordinates to calculaie horizontal dimen sions and use only elevations to calculate vertical dimen sions. By adding or subtracting coordinates, horizontal distances between steel supports, concrete foundations, and mechanical equipment can be determined. Knowing when to add and when to subtract can be confusing, however. A basic rule to remember when calculating horizontal distances is: Subtract like coordinates and add unlike coordinates. This basic rule is illustrated in Figure 9.5.
PIPE DRAFTING AND DESIGN
MATCH
LINE
W.30' -O"
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INV. ELEV. 97' -3"
175
PLANT ELEVATJONS
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RU~~S~A~cf BETWEEN VESSELS V-3 ANO V-6 ~ FOU~ BY AOOING W.18'-0" + E.26'-0" = 44'-0".
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RULE NO. 1: TO FINO THE OISTANCE BETWEEN TWO COOROINATES LOCATEO IN THE SAME QUAORANT, SUBTRACT I THE SHORTER COOROINATE FROM THE LONGER COORDINATE. 1 RULE NO. 2: TO FINO THE OISTANCE BETWEEN TWO COOROINATES LOCATEO IN DIFFERENT QUAORANTS, AOO THE COOROINATES TO EACH OTHER.
S.32'-0"
__ _J_ __ MATCH UNE S.40'-0"
FIGURE 9.5 Horizontal dístance calculations with coordina tes.
PIPE DRAFilNG AND DESIGN
_J
176
9. EQUJPMENT LAYOUT
Calculating vertical dimensions is somewhat easier. Simply subtract the lower elevation from the hígher elevation to determine the distance between the two. However, you must be certain that elevations of the same type are used. For example, always use two "Centerline" elevations, not one "Centerline" and one "Bottom of Pipe" (BOP).You must convert BOPelevations to Centerline elevations before subtracting. This is accomplished by adding one-half the actual outside diameter (OD) of the pipe to the BOP elevation, before subtracting. Also, be aware that lines installed below Grade are labeled using Invert elevations. Invert elevations identify the inside BOP elevation, that is, the distance from the bottom inside of the pipe to the ground above it. Figure 9.6 illustrates the use of elevations to calculate vertical dimensions.
SITEPLANS Toe civil/ topographic drafting department of a company prepares the Site Plan for the piping facility. A Site Plan is an overhead, or top, view drawn to show the overall appearance of the facility site and adjacent area. Site Plans can a1so be modified overlays of aerial photographs or ímages captured from orbiting satellites. Site Plans rnay include roadways, railways, harbors, shíp channels, aircraft landing zones, office buíldíngs, and recreation areas. Drawings of thís size do not show significant detall. Detailed areas of the facility are usually denoted by rectangular outlines with notes or titles describing the area's purpose. Mechanical equipment within the facility is typícally too small to be represented on a Site Plan. Therefore, the complete facility is usually divided into smaller areas called Units. Each Unit can then be drawn separately on drawings called Unit Plot Plans.
UNIT PLOT PLAN Unit Plot Plans are generally defined by imaginary lines called Battery Limits. Battery limits are used to establish a unit's perimeter boundaries. Toe Unit Plot Plan is usually drawn to small scale, such as l" = 10', l" = 20', or 1" = 30'. Unit Plot Plans show the location of a11 the buildings, mechanical equipment, pipe racks, tank farms, and other items of importance in the unit. True North and Plant North are also shown as actual and theoretical points of orientation.The purpose of this drawing is not to show the detall, but rather, the arrangement of various components to be erected in the Unit. Toe piping group is typically responsible for the development of the Unit Plot Plan. Unit Plot Plans are developed using the Mechanical Flow Diagram, client specifications, codes, and input from the client's
engineers and the plant manager who will ultimately oversee the operation of the facility. Figure 9.7 shows an example of a Unit Plot Plan.
EQUIPMENT LOCATION DRAWING To arrange and adequately space a1l the components required in the Unit, the piping group will use the approved Plot Plan to assign coordinate positions to vessels, pumps, heaters, exchangers, pipe supports, and control rooms and develop the equipment location drawing. Keeping in mind there will be plant operators and maintenance personnel in the facility 24 hours a day, adequate arrangement and spacing of components within the facility becomes important. Equipment location depends on a number of factors, including piping codes, space availability, worker accessibility as well as client preferences. All pieces of mechanical equipment to be installed within the facility are positioned usíng two intersecting coordinate lines, one North/South and one East/West. These intersecting coordinates define the precise position of a11 vessels, pumps, exchangers, etc., by locating the centerline of its foundation. When locating equipment such as exchangers and reboilers, that have a foundational support on each end, at least one of the equipment's supporting foundations must be located with coordinates. By using the plant coordinate system, it is impossible for any other component in the facility to have the same pair of intersecting coordinates. Figure 9 .8 provides an example of an Equipment Location drawing.
FOUNDATION LOCATION DRAWING Toe structural drafting departrnent uses information provided on the Equipment Location drawing to show the position of foundations for mechanical equipment, structural supports, and control buildings. On Foundation Location drawings, foundations that are to be built above Grade are drawn as solid lines and spread footings. Toe portion of the foundation that lies below Grade is shown as hidden lines. Figure 9.9 shows an example of a Foundation Location drawing.
PIPING DRAWING INDEX Toe Piping Drawing lndex is developed from the Plot Plan. This drawing divides the Plot Plan into smaller drawing areas, usíng Match Lines. Match Lines are lines drawn and labeled that allow the smaller drawing areas to be pieced together to form the larger Plot Plan, similar to a puzzle. Larger areas are divided in such a way as to keep related pieces of mechanical
PIPE DRAFTING ANO DESIGN
(,) F/F ELEV. 130' -O"
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NOTES: 1. TO FINO THE OISTANCE BElWEEN TWO OIFFERENT ELEVATIONS, SUBTRACT TliE LOWER ONE FROM THE HIGHER ONE.
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2. WHEN CALCULATING THE OISTANCE BElWEEN A CENTERUNE ((ü ELEVATION ANO A BOTIOM OF PIPE (BOP) ELEVATION, CONVERT TliE BOP TO A i BY AOOING ONE-HALF OF THE O.O. TO THE BOP THEN, SUBTRACT THE LOWER CENTERUNE ELEVATION FROM THE HIGHER CENTERUNE ELEVATION.
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178
9. EQUJPMENT LAYOUT
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equipment on the same drawing if possible. These drawing areas are given a drawing number for easy identification and then assigned to various designers on the project. Duríng the design phase, it is crucial that designers interface with those working on adjacent
drawing areas. Toe position, size, and pound rating of lines entering or leaving an area and continuing into an adjacent area must be properly noted and located on all related drawings. Figure 9.10 is a sample Piping Drawing Index.
PIPE DRAFTING ANO DESIGN
PJPIJ',;G DRAWJNG
179
JNDEX
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PIPE DRAFilNG AND DESIGN
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9. EQUJPMENTLAYOUT
CHAPTER 9 REVIEW QUIZ 1. Define plant coordinate system.
B.O.P. EL.
F./F. EL.
2. Name the three units of measurement by which coordinates can be labeled.
5. Use only coordinates to determine ____ dimensions. 6. Use only elevations to determine ____ dimensions.
_ _
3. What is the typical arbitrary value for the elevation of Grade?
7. Define Battery Limits.
4. Define the following terms. H.P.Paving
8. Name three factors that influence the arrangement and spacing of mechanical equipment.
T.0.C. EL.
9. How are above-grade foundations represented on a Foundation Location drawing?
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10. What is a Match Line?
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10 Piping ArrangementDrawings, Sections, and Elevations ARRANGEMENT DRAWINGS Toe Pípíng Arrangement drawing is the most sígnífíc~t draw":1g developed by a piping designer. This plan view drawíng, also known as the Piping Layout drawing, is a major source of information used in the fabrication and erection of the piping facility. And when using the traditional, manual method of desígn, information on the Arrangement drawing aids in the development of the piping model and isometric drawings. Toe Piping Arrangement drawíng evolves from the Foundation Location and Equipment Location drawíngs. lt shows all mechanical equipment, including vessels in the unit and the pipes connecting them, including manholes, ladders, platforms, cages, and davits. It identifies a11 structural steel supports such as the main and miscellaneous pipe racks, equipment structures, columns, braces, and any fireproofing they may have. Once locations for foundations and mechani~1 equipment have been established, piping configurations are added to the drawing with the aid of symbols that represent fittings, flanges, and valves. Written information placed on the Arrangement drawing includes mechanical equipment coordinates, identification numbers, elevation callouts, line numbers, flow arrows, and dimensions establishing pipe locations. Instrumentation symbols are included to indicate type, position, and orientation for accessibility by plant personnel. Ladders and platforms are also shown on equipment and structures that have them. A nozzle schedule is included that contains detailed information about a11 pípíng and instrument connections for every piece of mechanical equipment. Information such as nozzle number, size and pound rating, orientation, elevation, and projection is also included. With so much required information on a drawing, it is easy to understand why the Piping Arrangement drawing must be neat, accurate, and legible. Toe development of 3D
modeling software programs has had a significant effect on the process and procedure relating to the development of the Piping Arrangement drawing, as will be discussed in a later chapter.
RESPONSIBILITIE S OF THE PIPING DESIGNER Only after many years of experience does the drafter become a piping designer. Toe time invested in learning company specifications, layout procedures, and mechanical equipment requirements makes the designer a valuable employee. As the Arrangement drawíng is being developed, a piping designer should, among other things, consider the following: How can the drawing be simplified? Has each pipe been routed in such a way as to allow for construction, repairs, and equipment maintenance? How will construction, repairs, and routine maintenance be p~rformed in this unit? Has enough room been provided for access between mechanical equipment? Foremost on a designer's mind should be the safety and protection of plant operators and maintenance personnel.
INFORMATION SOURCES FOR PIPING ARRANGEMENTDRAWINGS A piping designer must assemble the various reference drawings and documents needed to lay out the Piping Arrangement drawing. These may include: • Mechanical Flow diagram; • Plot Plan; 186
C, 2012 Ehcvic-r lnc. Ali rlghts rcserved.
PIPING ARRJ\l\GEMENT DRAWING LAYOUT
• Foundation or Mechanical Equípment Location Plan; • Piping Drawing Index; • mechanical equipment (vendor) drawings and foundation drawings; • Pipíng Specifications; • Pipe Line List; • list of special requirements, if any, for the project. Toe construction document includes all the drawings and documentation that relate to the fabrication, erection, commissioning, and operation of the process facílity. These will include as-builts, equipment certification and nameplate information, operating manuals, testing procedures, field changes, and possibly photographs of the completed construction.
LAYOUTPROCEDURES To develop a Pípíng Arrangement drawing, the desígner must be familiar with company and client job specifications and requirements of the current project. Many different layout and design techniques can be used depending on client requirements, company policy, budget limitations, manpower, and available computer software. Piping Arrangement drawings are quite complex and congested. Therefore, a systematic layout procedure is recommended to ensure all necessary items are included. Toe following are the recommended procedures for layout of Pípíng Arrangement drawings: 1. Define proposed area outline or draw Match
2. 3. 4.
5. 6.
Lines. Fill in drawing number and title block information. Place a North Arrow in upper right-hand comer of the drawing. Locate foundations for buildings, pipe rack columns, and mechanical equipment from the coordinates used to develop the Foundation Location drawing and dimensions provided on the Equipment Foundation drawing. Draw equipment foundations. Lay out mechanical equipment.
NOTE: • Show only enough detall on mechanical equipment outlines to provide a generalized description. • Represent mechanical equipment centerlines, outlines, and foundations with thin dark lines. • Show all piping and instrumentation connections (nozzles, couplings, etc.) on mechanical equipment. 7. Prepare a study drawíng of each individual piping configuration in the facility. This procedure will
8.
9. 10. 11.
12. 13. 14.
15. 16. 17.
187
allow the designer to explore all requirements necessary for design, operation, and maintenance prior to the final layout. Lay out the pípíng system as shown on the study drawíng. lnclude instrumentation connections on the piping configuration. Note that every piping facility has different process, mechanical, and instrumentation requirements. It would be extremely difficult to establish set rules and procedures for methods of piping development. Each line on the layout is, in itself, a special design problem and must be dealt with accordingly. Add platforms, ladders and cages, pipe guides, anchors, supports, and hangers as required. Include line numbers, codes, specs, specíalty item numbers, and callouts. Place locating dimensions for piping. Label coordinates for mechanical equipment, pipe supports, etc., if required for job. Add instrument balloons and callouts. Include nozzle schedules and notes as required. Complete drawing. Add Match Line, Area Limit, and Battery Limit callouts, reference details, and Section or Elevation cutting plane symbols. Print/plot the completed drawing and check your work. Correct any mistakes you find before releasing the drawing to your instructor or supervisor.
PIPING ARRANGEMENT DRAWING LAYOUT This section provides a detailed explanation of the procedural steps to lay out the single-line representation of the Piping Arrangement drawing of Unit-01 shown in Figure 10.1. Toe double-line altemative of Unit-Ol is shown in Figure 10.2. These procedures will simulate those undertaken on any design project by an actual engineering company. To simplify the layout procedures and consolidate the reference drawings and other related information, a copy of the Foundation Locatíon drawing, Equipment Location drawing, Main pipe rack, miscellaneous pipe supports, equipment vendor drawings, Elevation, and the structural drawings are provided in this chapter. Toe following procedures present the recommended method of developing a Piping Arrangement drawing with a 2D CAD software program. When using a drafting software program, such as AutoCAD, the drawings are typically created full size and then placed into the appropriate border at %" = 1 '-O" (0.03125)scale. When the initial drawing is developed, full-scale layouts are used to create various "sheets" of the facility at any desired scale.
PIPE DRAFTING AND DESIGN
188
10. PIPING ARRANGEMENT DRAWU\GS, SECTION"S, ANO ELEVATIONS
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Procedures 1-3: Drawing setup: Location of area and Unit boundaries, Title Block, and North Arrow. References drawing: Foundation Location plan and Company drawing standards Set the following: • UNITS Length: Type-Architectural Precision: Yi6" Toe visibility of various linetypes will require different values when viewing the drawing in model space and paper space. • LTSCALE Set to 32 A value of 32 will make the linetypes visible in Model Space and a setting of 1 will make them visible in Paper Space. • Create the following layers with corresponding colors, line types, and line weights:
Layername
Color
Line type line weight control
Match Lines
Black/White
Phantom 0.70mm
Centerlines
Black/White
Center default
Foundations
Yellow
Continuous default
Steel
Cyan
Continuous default
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Oran ge
Continuous 0.30mm
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Blue
Continuous 0.53mm
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Cyan
Continuous default
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Red
Continuous default
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Black/White Black/White
Continuous default Continuous default
• Make Match Lines the current working layer. • OBJECT PROPERTIES Set COLOR Control, LINETYPE Control, and LINEWEIGHT Control to "Bylayer" in the Object Properties toolbar. • Draw a rectangle SS'-O" wide and 40' -O" deep to represent the Unit-01 boundary Match Lines. Toe lower, left comer of the rectangle will be at the O' -O'', O' -O" origin. Use Figure 10.3 as a reference to lay out the Unit-Ol's perimeter from the 0'-0'', 0'-0'' origin. Procedure 4: Lay out the centerlines for the main pipe rack and equipment foundations.
Reference drawing: Equipment Location plan Set the following: • Make Centerlines the current working layer. • Use OFFSET to create lines parallel to the North and West Match Lines that will represent the intersecting coordinates of the main pipe rack, miscellaneous pipe supports, and mechanical equipment centerlines. • Change the intersecting lines to the Centerlines layer. • TRIM or use the line's Grips to shorten the intersecting lines that will represent the various equipment and structural support's foundation centerlines. Once the foundation centerlines are completed, your drawing should appear as shown in Figure 10.4, without the text. Procedure 5: Drawing pipe rack and equipment foundations. Reference drawing: Foundation Location drawing (Figure 10.5) and foundation drawings for individual pieces of mechanical equipment (Figures 10.6-10.10) and the Main Pipe Rack and Miscellaneous Pipe Support drawings (Figures 10.11-10.14). • Make Foundations the current working layer. • Use the appropriate commands to draw mechanical equipment, pipe rack, and pipe support foundations from coordinates and dimensions shown on the Equipment Foundation drawings. Your drawing should appear as shown in Figure 10.5 when procedure 5 is completed. Procedure 6: Equipment layout. Reference drawings: Mechanical equipment vendor drawings Use dimensions provided on the mechanical equipment vendar drawings to lay out the mechanical equipment as represented in Figure 10.15. Toe equipment vendar drawings are shown in Figures 10.16-10.21. • Make Equipment the current working layer. • Draw ali mechanical equipment with the necessary commands. Toe dimensions needed to draw and orientate the ladder and platforms for 01-V-101 are supplied with vendar drawings. Toe dimensions needed to draw the cages are shown in Figures 10.40 and 10.41. Change the linetype of those portions of the foundations located below the mechanical equipment from "continuous" lines to "hidden" lines. • Make Steel the current working !ayer. • Use the necessary commands to draw the main pipe rack and miscellaneous pipe supports. Toe dimensions needed to draw and orientate the steel columns are provided in the section and detail drawings in Figures 10.11-10.14. Change the linetype
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ca""
10
..., z o ;;!
>
¡g
111
o
>
s'
ám
21
~ ~'"i
~
s
roe a. ioro:
~ o
IB C)
5/16"
,,o·o·
Wl2,c.f6
z
H.P. PAVING 100'-0"
~ zo ..... ~o ~
5/16"
OETAIL
1C
DETAIL
1E Noto· NQT TO $CALE
MAIN PIPE RACK: CONNECT/ON FIGURE 10.13
Main Pipe Rack: Connection details lA-E.
DETAILS
1A[ N
o .....
N
o
N
,ª'b 1 ti 1b -iª"ti r I I12 ,1s.. I 8"
12 ..
9 7/8"
8"
1
I
t
W8xJ1
W1 Ox39
12"
~¡
t
W12x45
W12x65
8:,:
DETAIL 1A W12x6S
STRUCTURAL SHAPE SIZES
:l:! "O m
o ~
=l
tí
UPS1 J6's·
.
o
el .1 o
W8xJ1 TYP.
:!l:.;
so
>
.
o 1
;,,
.
o
~~:.;
TOS EL 114'0" W12x4S
PLAN
TOS EL 112•o• W12x615
m
l'[l
TOS
C)
z
e:
t
----- -----5--.o·--o-=--·
UPS2 16·o·
~
PS1 tW.40'o• PS2 w.20·o· PSJ
110'o•
TOS
a.
TOS fL 110'0" W12x4S
110·o·
W10xJ9 TYP. W12x6S (TYP.)
DETAIL 1C
o
.!.
PffRIO(:
ClHICCIDI DETAlS IA f
TOC EL 101'0" H.P. PAVING 100'0"
SECTION A-A
ELEVATION
Note· NOT TO SCALE
UNJT-01
PIP[
RACK
WITH MtSC[LLAN[OUS PtP[
FIGURE 10.14 Unit--01Pipe Rack with Miscellaneous Pipe Supports 1 and 2.
SUPPORTS
1
ANO
2
-
'Ti C)
~
.... o
t
;...
UNIT-01 PS-
-----
AREA LIMIT
V\
.si e:
i' ;:!. "' 5' ea.
:i
o :,
o. ¡;¡
s :,
~
ca""
o
o
º1
s'
21
wl z ::::¡
~ ~ o
IB C) z
w.
1
111
o
01-y-101
1
26'-0º
lO
I~ 1 z !::: 2 :::::¡
J:
~,
o
~
,~
01 E-102
~ w.
18'-0º
MPS-2
NI
1
o 1
O:'. <(
!:::
o
=>
!:::
z
1
z
1 => 1
01-v-102 ~.87-6º
UNIT-03
MATCHLINE -
o' -o"
_J
;;! "O
~ >
¡g >
á ~ ~--i
s
~ ~ .... ~o ~
N
i
NOZZLE SCHEDULE NOZZLES "N1"&"N5"
NOZZLE "N2"
1'-51/."
1'-81! •
H
MK
1
-
NOZZLES "N4"&"N6"
~
t=LIT-=t :l:! "O m
t~-=t 10"
s'
, ,,..
1%" ~
s"
NOZZLE
o ~
300#
RF
2'-8"
812.8
N2 REBOILER RETURN
12"
.JOM
300#
RF
2'-8"
N3
FEED INLET
8"
300#
RF
2'-8"
N4
REFLUX
4"
20J.2 101.6
812.8 812.8
300#
RF
2'-6"
162.0
N5 OVHD.VAPOR OUT
10"
251.0
300#
RF
2'-8"
812.8
NOZZLE "N7"
N6
P.S.V.
4•
RF
N7
VENT
2·
101.6 50.8
300#
61/i"
300#
RF
so
IMP.
L.G.CONN.
2
3/4"
19. I
3000#
CPLG
MANWAY
2
18"
151.2
300#
RF
METRIC
p 31
"O
2·-10"
86.J.6
~o ~z o
2:.U,_
re
~-1
;
270'
270'
225'
>
8
BOTTOM OUT
DETAILS
=l
tí
PROJECTION
251.0
N1
11s·r1H~ ~ a·
4:.U-
RATING FACE
10·
21
3"(TYP.7)
NOZZLE "N3"
SIZE METRIC
~
~
NO. IMP.
1='Ef~ Í= ,-1,·-0:J ~. 171,·
SERVICE
225'
z
.@
g (/]
m
l'[l
~
C)
z
y,
o·
180'
o·
180'
>
ze,
"'¡;:;
;;i
""z 5 (/]
135'
PLATFORM
/ 115'
90'
DEPROPANIZER FIGURE 10.16
Depropanizer 01-V-101 Sheet 1 of2.
NO.
1
01-V-101
135' 115·
90'
SHEET
PLATFORM NO. 2
1 of 2
N
MK
e:==-
SERVICE
NO.
Nl BOTTOM OUT N2 REBOILER RETURN 1 N3 FEED INLET N4 REFLUX N5 OVHD.VAPOR OUT P.S.V. N6 VENT N7 1 L.G.CONN. C1&2 2 MI MANWAY 2
NOZZLE SCHEDULE SIZE RATING FACE IMP. METRIC 254.0 300# RF 10" 300# RF 12" 304.8 300# RF 8" 203.2 4• 101.6 300# RF 300# 10" 254.0 RF 4• 300# 101.6 RF 2· 300# 50.8 RF 3/4" 19. I 3000# CPLG RF 18" /51.2 300#
PROJECTION IMP. METRIC 2'-8" 812.8 2'-8" 812.8 2'-8" 812.8 2'-6" 162.0 2'-8"
812.8
2·-10·
863.6
NOTE:
NOZZLE
ORI ENTATION
1. THE NOZZLE DIMENSIONS SHOWN ON THE EQUIPMENT DRAWING DO NOT INCLUDE 1 '-0" CONCRETE FOUNDATION. TAIL DIMENSIONS ARE FROM BOTIOM OF BASE PLATE.
36' -o• TAN~NT TO TANGENT
12 SPACES ot 2'-0" • 24'-0" {13 TRA'l'S )
DEPROPANIZER FIGURE 10.17
Depropanizer 01-V-101 Sheet 2 of 2.
01-V-101
SHEET
2 of 2
NOZZLE SCHEDULE NOZZLE "N1"
NOZZLE "N2"
w
i~
5/8J
,~-=ta·
1 7/8"1n
8"
kci
3"(TYP.) NOZZLE "N4"&"N5"
125"-t; 'H~
8"
NOZZLE "N3","N6"&"N7"
7/8"i1 L¡:
MK
SERVICE
NO.
SIZE
RATING
IMP.
METRIC
NOZZLE
8"
203.2
300/1
RF
2'-8"
812.8
N2
UQUID OUT
10·
25M
300/1
RF
2'-8"
812.8
300/1
RF
2'-6"
300/1
RF
2'-8"
162 812.8 812.8
N3
DRAIN
2·
N4
VAPOR OUT
4•
50.8 101.6
NS
RELIEF
4•
101.6
300"
RF
2'-8"
N6
LEVEL GAGE
2·
50.8
300"
RF
2'-6"
162
N7
LEVEL GAGE
2·
50.8
300/1
RF
2'-4"
111.2
C1
VENT
1•
25.I
6000/1
M1
MANWAY
18"
157.2
300"
CPLG W/PLUG RF
2·-10·
,
!ti¡---+'11, ,:t 1
1
j
I
1
FIGURE 10.18
METRIC
LIQUID IN
DETAILS
DEPROPANIZER
PROJECTION IMP.
N1
2·~
4•-1-1-
FACE
REFLUX
DepropanizerRefluxAccumulatorOl-V-102.
ACCUMULATOR
1
1
1
1
I
,,
' .,,.
01-V-102
86J.6
A ñ 1--g-4•. 1=°H~·· jai:t· · :W-t4 µ2:.j NOZZLE "A"&:"B"
1·
NOZZLE
r1 11 •
17¡8·
MK
SERVICE
NO.
SIZE
11/4.
4
3"{1YP.7)
NOZZLE "O" 1'-81/ • 2 1• 1
J=·
NOZZLE SCHEDULE
NOZZLE "E"
"e"
. V.
NOZZLES "F"&:"G"
s1h"
e o
G V
ri~s·
2:.....1-l--
NOZZLE
B
E F
%=i_11
LQ=t8" 11·-0·1
A
HEAT MEO OUT HEAT MEO IN LIQUIO IN VAPOR OUT PROOUCT OUT GAGE COLUM GAGE COLUM TW/VENT
1 1 1 1 1 1 1
RATING FACE
IMP. 6' 6'
METRIC !SU !SU
10" 12" 4"
25M .JOM 101.6
2" 2" 1"
50.8 50.8 25./
8
1
1
1
PLAN
SEE DETAil "A" 26'-0"
D
10·-o·
B
1:r-4· 2'-5"
...
3 1/2"
V
:
ci
s·
-1---
c::!::b!:,
1·-21
1 '-6
-l-4--10·
1s·-o·
2'-4" 1
2·-2·
2'
Jt $_
ir
U]
2·
>-=--
r;--~ !¡ -~ ,~, :-t
ELEVATION
DEPROPANIZER FIGURE 10.19
Depropanízer Reboiler 01-E-101.
C
REBOILER
1
1
,f
'::-i-{AXf) ©D
2·-a·
2'-1Lj
1
F~
609.6 609.6
DETAil "A"
~~
r :\ ~, JJ--IT------"' ----.--~ -----rr . .___ _ ----li'i /
66M
3 ,;2·---1rr 1;2·--in=2·
DETAILS
1
G
2'-2" 2'-0" 2·-0·
CPLG W/PLUG
6000#
1/ 11 'f,!.. ~'-----,1+1 I:-, : 1: 1 ;-1 - - -----H(W)+H--\
RF RF RF RF RF RF RF
150# 150# 300# 300# 300# 300# 300#
PROJECTION IMP. METRIC 1'-8" 508 1'-8" 508 2·-2· 66M 2·-2· 66M
A
RIGHT
01-E-101
END VIEW
N
o
00 NOZZLE SCHEDULE NOZZLE "A"&"B"
1.A_1_
NOZZLE "C"
NOZZLE "D"
1 7/8i_fl
1 5/8"L~
rB'
T~_L
,·~---,-
~L
Jrr8"(TYP.)
NOZZLE
I
i
I
150#
RF
1'-8"
B
C.W.OUTLET
1
6"
!5U
150#
RF
1'-8"
508 508
VAPOR IN
1
10·
2~
300#
RF
1'-8"
508
1
8"
203.2
30D#
RF
1'-8"
508
8
1"
25.I
6000#
UOUID
OUT
TW/VENT
··~$"
-
1
~-
31/2"t
SEE DETAil "A"
24'-o"
'-4
e
18'-10"
B
-
2'-8"
1'
3 1/2"
1 \.1
~,-
--~g -!l},·-o· 8" -,--
~
1s·-o·
ELEVATION
DEPROPANIZER FIGURE 10.20
Depropanizer Condenser 01-E-102.
V
____.___ -r;
-
ri
J. L
1
1
+1
f..
J r_ t-t
"l r
@
CONDENSER
DETAil "A"
-1'-2"
1' -'--
2
A
2·
U]
' .__
'
CPLG W/PLUG
1 1/2"
/'."
1
1
PLAN
METRIC
!5U
V
-
PROJECTION IMP.
6"
1
, 1,
RATING FACE METRIC
1
1
1 \ 1
SIZE IMP.
C.W.INLET
D
DETAILS
NO.
A
e
~
3"(TYP.)
SERVICE
MK
2"
3
.
., CIO
1
~ 1
-
o' '-
EN:-:.1
01-E-102
NOZZLE "8"
NOZZLE "A"
NOZZLE SCHEDULE NO. SIZE
MK
SERVICE
A
SUCTION
a·
8
DISCHARGE
6"
IMP.
1'-3"
LM
,51sit:'.r
RATING FACE
METRIC
2(JJ.2 152.4
l.q NOZZLE
ca""
111
o
DETAILS
8"
co 1 N
s'
21
~ ~ o
IB C)
1 O" ----,
z
1 '-6" 1 '-6" HP PAVING 100' -0"
2"
ELEVATION
DEPROPANIZER
PUMPS
FIGURE 10.21 Depropanízer Pumps P-101Aand P-lOlB.
END VIEW
P-101A
& P-1018
300# 300#
RF RF
210
10. PIPING ARRANGE.~ENTDRAWIKGS,SECTIONS,ANO ELEVATIONS
of those portions of the beams, columns, and foundations that are hidden from "contínuous" lines to "hidden" lines. • When procedure 6 is completed, your drawing should look like Figure 10.15. Procedures 7 and 8: Development of pipe line configurations for Unit-Ol. Reference drawings: Mechanical Flow Diagram, equipment vendor drawings, and Piping Specifícations. In procedures 7 and 8, the step-by-step routing of each pipe confíguration from beginning to end will be described relative to the commodity flow direction. That is, the written explanation of the development of each pipe confíguration found in Unit-01 will dictate the sequential placement and orientation of fittíngs, flanges, and valves as it follows the direction of the flow of the commodity within the pipe. Toe written descriptions of the confígurations will not include exact placement or size dimensions of the fittings, flanges, or valves required for the layout. Toe dimensions that are needed to place the pipe on the arrangement drawing in its proper location and orientation can be found on the various dimensioning charts and vendor drawings found in this chapter and in the appendix. The 30 modeled, isometric view of each line is shown in the upper right comer of the drawing associated with each pipe. This view will be especially beneficia! to help visualize the routing and placement of pipe components needed to accurately depict the lines on the arrangement drawíng. • Make "Pipe" the current working layer. • Use the UNE command to draw all lines. Pipes 14" in diameter and larger are drawn double-line with actual OD dimensions havíng Default lineweight. Toe centerlines for double-line pipes are represented as a Center linetype. Draw all single-line pipes, those 12" in diameter and smaller, with a 0.53 mm lineweight. Toe fitting, flange, and valve symbols created in the previous chapters can be inserted into their appropriate locations.
Routing Con.figurations for lines 01-1-C30-8" through Ol-16-C30-2" As shown in Figure 10.22, line Ol-1-C30-8" enters Unit-01 from the Loading Facility on the west end of the Main Pipe rack having a centerline elevation of 110'-4o/il'. After the line travels 14'-0" into Unit-Ol, from Match Line W. 40' -O', an elbow flat-turns the line north toward vessel 01-V-101. 01-1-C30-8" travels north before it turns up and into nozzle N3 of 01-V-101at EL. 125'-0".
A 300# gate valve is located fitting make-up below nozzle N3. Its handwheel is oriented toward the west. Figure 10.23 provides the Plan and Elevation views of the depropanizer, 01-V-101 and the kettle reboiler, 01-E-101. Also shown is their associated pipíng, lines 01-2-C30-10''-IH and 01-3-C30-12"-IH. Line 01-2-C30-10''-IH starts at nozzle Nl of 01-V-101. Begin at nozzle Nl with a flange and an elbow that are welded together. Toe elbow is welded onto the flange so that it points north. A straight run of pipe travels north and another elbow flat-turns west into nozzle C of 01-E-101.After a short run of pipe, an elbow turns up and a flange connects to nozzle C. A 2" drain drops out of the bottom of 01-2-C30-10"-IHand connects to the oily water sewer. lt is located 10' -8" south of the centerline of nozzle C; its handwheel points north. Line 01-3-C30-12"-IH rises out of the top of Ol-E101 at nozzle D with a flange and short vertical length of pipe. An elbow is attached that is oriented south. Another short run of pipe travels south until an elbow flat-turns west into 01-V-101, at nozzle N2. Notice in Figure 10.24 that nozzle NS is oriented on vessel 01-V-101 at a 45º angle, pointing toward the northeast. Line 01-4-C30-10'' comes out of nozzle NS fitting make-up at EL. 141'-0'', where an elbow turns down alongside the vessel. A long, vertical drop descends to centerline elevation 110'-5%'', where it turns east. A short, easterly run of pipe will align Ol-4-C3010'' with the centerline of 01-E-102, where it flat-turns north, toward nozzle C. As the line travels north, it rests on a Miscellaneous Pipe Support-2, then it turns down into nozzle C of 01-E-102. Lines that drop such a long distance down the side of a vertical vessel, as Ol-4-C3010" does, typically require pipe supports and/ or pipe guides. Toe support used in this particular situation is a trunion, which is welded to the side of a vessel. Figure 10.25 shows a typical trunion pipe support. Line 01-5-C30-8" transports condensed vapor from condenser 01-E-102 to the overhead accumulator 01-V102. 1t attaches to nozzle D, which comes off the bottom of 01-E-102 and travels to nozzle Nl on 01-V-102. This 300# line drops out of nozzle D fitting make-up and turns east for 2'-7", where it tums up. After a vertical run of pipe, an elbow turns the confíguration south to rest on Miscellaneous Pipe Support-2 at elevation 110'O''. Toe pipe continues south to align with nozzle Nl of 01-V-102. Once aligned with nozzle Nl, an elbow tums up toan elevation that is fitting make-up when measuring against the flow, or backward, from nozzle Nl of 01-V-102. Toe pipe runs east before turning up into Nl (see Figure 10.26). Lines 01-6-C30-10'' and 01-7-C30-6"/4" are suction and discharge lines for pumps 01-P-lOlA and 01-P-lOlB, respectively. Line 01-6-C30-10",the suction line, is a 10" confíguration that drops out of the bottom of Ol-V-102
PIPE DRAFTING ANO DESIGN
UNIT-01
MATCH
UNE
W.
-N-
----
40'-0"
01-1-CJ0-8'
V-101 25'-()'
lf.
l'S1
e,
PLAN
:1'1
\
~
~
1
tas:
EL 112'()'
----
t
01-1-c.J0-8'
1'$1
.Y::1í!1.. 1 1
ros.
El 111'().
1
ros.
El 110'().
1
_J_, H. P. PAVINC 100'-0"
SECTION FIGURE 10.22 Line 01-1-C30-8".
"A-A"
SECTION
"B-B"
N
...... N
~
N _.,
@
,-r--~~~-=-=--,--=-:;---,-,--,------,::--~~-------+---r-1@) ~ .3-C:30-12"-IH
@
E-102 -W. .3.3'-6"
2-C.30-1 O" -IH
V-101 W.26'-0"
PLAN
l
- +-----
.3-C.30-12"-IH EL. 113-:_0 ..
® E-102
EL.102' -.3" H.P. PAVING
SECTION FIGURE 10.23
"A-A"
Unes 01-2-00-10"-IH and 01-3-C30-12"-IH.
SECTION
"B-B"
-NPLAN
1 1
1
i
I
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
V-101
t
1
V-101
1
t 1
1
SECTION "A-A" FIGURE 10.24
Line01-4-C30-10".
SECTION "B-B"
214
10. PIPING ARRANGE.~ENTDRAWIKGS,SECTIONS,ANO ELEVATIONS
Exiting the 6 X 4" tee to the west, the line becomes 01-7-C30-4". From the center of the tee, a 14"-lOW' run of pipe ends with an elbow that turns down 2'--0''. Below that elbow another one turns north, out of the rack. This section of pipe has an orífice flange assembly positioned 3'-0" from the north end of the run. Long runs of pipe that have an orifice flange assembly, such as this one, are known as meter runs. Toe precise positioning of the orifice flange within the meter run is based on a formula that will be discussed in greater detail in Chapter 12. Line 01-7-C30-4" then turns down into control valve manifold FCV-1, also discussed in Chapter 12. Toe control valve manifold, also known as a "control station" or "control set," keeps the line in a north orientation as it runs along the east side of 01-V101. Toe line rises up, out of the FCV-1 control manifold, when it is aligned with the centerline of 01-V-101, eventually attaching to nozzle N4 at EL. 139' -O". Toe Plan and Section views of control station FCV-1 can be seen in Figure 10.29. Line 01-9-C30-4" drops out of the bottom of 01-E-101 connected to nozzle E, fitting make-up. The line turns east befare rising to centerline elevation 110'-2%". Once at this height, an elbow turns south, travels 6'-8", and drops down into control station TCV-1. This control station is similar in size and appearance to the one used in line 01-7-C30-4". Toe control station runs in an east to west direction and lies 2' -O" to the north of the centerline of the pipe rack. Toe handwheels of the block valves point south. Use the dimensions in Figure 10.30 to represent the control station on your drawing. Toe west end of the control station rises to centerline elevation 110' -21.4", turns south, and runs below the pipe rack as it rests on Column B on the Main pipe rack. Toe line then rises up through the rack, turns east, and travels through Unit-01 into Unit-03. As shown in Figures 10.31 and 10.32, lines 01-10-A15-6"-IH and Ol-ll-A15-6"-IH are heating medium return and supply lines, respectively, for 01-E101. Line 01-10-A15-6"-IH, the heating medium return line, is a simple line dropping out of 01-E-101 from nozzle A fitting make-up. Toe bottom elbow turns the line west for a short distance, then up, fitting make-up into a block valve, whose handwheel is oriented north. Toe line continues vertically to EL. 110' 6o/il', where it turns south, rests on Miscellaneous Pipe Support-1 (with a pipe shoe), then runs toward the Main pipe rack. Line 01-10-A15-6"-IH will rest on Column B as it enters the Main pipe rack. Once below the rack, the line turns up and stubs (stub-in) into line 19-A15-10"-IH. Line 01-11-A15-6"-IH is the heating medium supply line for 01-E-101. It drops out of the heating medium supply header, 20-A15-10''-IH with a stub-in. After dropping out of 20-A15-10''-IH, an elbow turns the line north where it rests on Column B with a pipe shoe. 11
FIGURE 10.25 Trunion pipe support.
from nozzle N2. After a vertical drop to centerline elevation 108'-9", an elbow turns south. After a short southerly run, the line tees to align with the centerline of pumps 01-P-lOlA, to the east, and 01-P-lOlB, to the west. Once the east and west branches align with the centerline of the two pumps, an elbow turns down into a vertical run. Within each of these vertical drops is a gate valve that has been installed with its handwheel rotated 45º to the southwest. Attaching fitting make-up to the bottom of the valve is a flange and elbow that turns south. A 10'' X 8" eccentric reducer is installed with the flat side on top, as indicated by the FOT abbreviation, befare the line connects to the pump suction nozzle A of 01-P-lOlAand 01-P-lOlB with a flange (see Figure 10.27). Line 01-7-C30-6" /4" shown in Figures 10.28 and 10.29 is a long line that connects the discharge nozzles of pumps 01-P-lOlA and 01-P-lOlB to nozzle N4 on vessel 01-V-101. Rising vertically out of the pump discharge nozzle B, the configuration is a 6" NPS. A check valve, which is attached to the discharge nozzle, precedes a block valve, whose handwheel has been rotated 45º to the southwest. A short vertical run of pipe is installed befare two elbows, whose centerline elevation is at EL. 108'-5", turn toward each other. Equidistant between the two pumps, the line tees with the branch oriented up to create another vertical run. At a centerline elevation of 110'-3o/il', an elbow turns south, travels 3'-2", tums up 2'-0" into the Main pipe rack, and tees again, branching in the east and west directions. A 6 X 4" eccentric reducer (FOB) is welded to the west side of the tee. All piping components attached to the east side of the tee are part of line 01-8-C30-6", which continues down the pipe rack into Unit-03. 11
PIPE DRAFTING ANO DESIGN
ís
~~!J ~~1 ¡;,¡<.;;,~~
®
N
-
E-102
OVERHEAO
w. ,e·o· CONOENSER-
@
~·<::,
~t:' ~~
,,
~
ca""
!¡;:~
s'
~
~I~
111
o
21
o
'·'
~
_J
~
1/
,/c:5
0/8 ;;!
z o "O
@
>
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ám
~ ~..;
PLAN
~
s
~ o
~ zo .... ~o ~
IB C) z
T.O.S. El. l /0'-0"
H. P. PAVINC 100'-0"
SECTION "A-A" FIGURE 10.26
Line Ol-5-C30-8".
SECTION
"B-B"
N
.....
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10. PIPING ARRANGE.~ENTDRAWIKGS,SECTIONS,ANO ELEVATIONS
Toe pipe will continue north, cross Miscellaneous Pipe Support-l and into a meter run. Precise positioning of the orífice fiange assembly, FE-1, must be established at this time. Because there is adequate upstream clearance to locate the assembly, its position will be established based on the required downstream distance. Using the guideline of 6 pipe diameters downstream, a mínimum straight-run pipe distance of 3' -O" (6 pipe díameters X 6 pipe size = 36") is required to the first weld. To locate the center of the orífice fiange assembly, add 3'-0" plus 9", the center-to-end dimension of a 6 elbow, which totals 3' -9 This 3' -9'' total dimension establishes the position of the orifice flange assembly from the center of the elbow on the downstream side. From the north end of the meter run, the line drops down into control station FCV-1. Toe control station runs south to north and lies on the west side of 01-E101. Out of the north end of the control station, the elbow is rolled at a 45° angle to the northeast where it drops into nozzle B ofül-E-101. This layout conforms to the basic rule of piping for exchangers: hot stream in the top, cold stream out the bottom. As the hot oil goes through the tube bundle of the kettle reboiler, it loses its heat and begins to cool. Line 01-10-A15-6 -IH picks up this stream at nozzle A of 01-E-101 and pipes it back to the pipe rack to be returned, vía the heat medium return header, to the fired heater 03-H-304 on Unit-03 for reheating. Both lines 01-10-A15-6"-IHand Ol-11-A15-6"-IHare 6" lines that branch from a 10" header. To determine the type of branch connection to be made, we must follow Piping Specification Class A15. A15 mandates that a stub-ín be used to make the branch connection on these lines. Notice these are liquid lines. Toe typical procedure for branchíng lines with a liquid commodity is to branch off of the bottom of the rack headers. If these lines contained steam, we would rise off the top of the header pipe to avoid getting condensate in the line. As shown in Figure 10.33, line Ol-12-C30-4"rises fitting make-up off the top of 01-V-102 from nozzle N4 with an elbow turning west. Another elbow turning down routes the pipe through a control station PCV-1. Toe control station runs parallel to the north/ south centerline of 01-V-102. Because Ol-12-C30-4" has the same pipe diameter and pound rating as 01-9-C30-4", the measurements required to lay out control station PCV-1 can be derived from TCV-1 in Figure 10.30. Toe south end to the control station rises to a centerline elevation of 110'-2W' and turns south. A dummy support is required to support the southerly run of pipe from column B in the pipe rack. A further explanation of dummy supports and their required pipe size is shown in Chapter 11. From the dummy support, 01-12-C30-4" turns up, then south again and drops into the 8 fuel gas line, 17-A15-8"in the pipe rack. 11
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Line 01-13-A-15-6",shown in Figure 10.34, is designed to transport waste gas from 01-V-102 to the fiare stack. Line 01-13-A-15-6" rises off the top of 01-V-102, connected to nozzle NS. A gate valve, whose handwheel is oriented east and is bolted to NS, precedes the pressure safety valve, PSV-2, which has a 4"-300# inlet and a 6 -150# outlet. Coming out of PSV-2, the line travels south, where it drops down onto column B at TOS EL.114'-3o/tl'. An elbow turns the line south again where it rolls down and east to stub into the top of 18-A15-8", the fiare header at a 45° angle. Toe 8" fiare header then travels off-site to the fiare stack 03-FS-305,in Unit-03. Lines 01-14-A15-6" and 01-15-AlS-6" are cooling water return and supply lines, respectively. They are used to circulate the cooling water between 01-E-102 and cooling tower 04-CT-406. Line 01-14-AlS-6" is the cooling water return line. This pipe will circulate the cooling water that has been heated in 01-E-101 back to 04-CT-406 to reduce its temperature. Ol-14-A15-6" rises off the top of 01-E-102 at nozzle B with a gate valve whose handwheel is oriented to the west. After a short vertical run up and out of the valve, the line turns east then immediately south, fitting make-up, As the line travels south, it will rest on Miscellaneous Pipe Support-l then further south to rest on Column B at centerline elevation 110'-3o/i6". From there it runs below the Main pipe rack and turns up to stub into the cooling water return header 21-AlS-10". Line 01-15-A15-6"is the cooling water supply line. It routes water that has been cooled in cooling tower 04-CT-406back to 01-E-102. This line drops out of the bottom of 22-AlS-10", the cooling water supply line to centerline elevation 110'-3o/tl' and turns north. When the pipe aligns with nozzle A of 01-E-102, it drops down to EL. 109'-OVi/' and turns west. When it reaches the centerline of 01-V-102, it turns up into a block valve. Toe block valve, whose handwheel is oriented west, is bolted directly to nozzle A. See Figures 10.35 and 10.36 for Plan and Elevation views of lines 01-14-A15-6"and 01-15-AlS-6". Line 01-16-C30-2" is a short drain line dropping out of the bottom of 01-V-102. This 2" line is attached to nozzle N3 and drops straight below the nozzle into a drain funnel. A block valve is located at centerline elevation 104 -6 Its handwheel is oriented to the east (see Figure 10.37). Toe level gauges and level controllers depicted in Figures 10.38 and 10.39 are mounted on a bridle attached to vessels 01-E-101 and 01-V-102, respectively. Toe level gauge and level controller are installed so an operator can easily monitor and control the normal liquid level of each vessel. Toe normal liquid level of 01-V-102, the overhead accumulator, is typically controlled to be level with the centerline of the accumulator. Toe normal liquid level of 01-E-101, the kettle 11
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230
10. PIPING ARRANGE.~ENTDRAWIKGS,SECTIONS,ANO ELEVATIONS
reboiler, is usually one-half the weir height. The weir, in this application, is a vertical plate inside the kettle reboiler that serves as a dam to keep the tube bundle submerged under liquid. As the liquid level increases, the excess liquid will flow over the weir and be drawn out through nozzle E, which is line 01-9-C30-4". Procedure 9: Platform, ladder, and cage layouts Reference drawing: Vendor drawings • Make Platforms, Ladders, and Cages the current working layer. • The size and location dimensions for the platforms, ladders, and cages are established from dimensions provided on the vendor drawings for 01-V-101. Figures 10.40and 10.41 provide an enlarged view of 01-V-101describing platforms 1 and 2, respectively. Use dimensions provided in these figures to place the platforms, ladders, and cages on 01-V-101in your piping arrangementdrawing. Procedures 10-15: Placement of line numbers, callouts, coordinates, and dimensions Reference drawing: Flow diagram, pipe line list, [ob specifications Key information about a piping facility is not always depicted graphically. Sorne information must be communicated in written form. Certain components of a drawing such as dimensions, coordinates, elevations, line numbers, fitting and equipment callouts, and design and fabrication notes can only be represented as written infonnation. The arrangement of information and reference notes on an Arrangement drawing usually requires preplanning and proper placement to achieve a good sense of balance on the drawing. This inforrnation must be arranged logically and in a clear legible manner. Therefore, interferences among reference notes, dimensioning, and object line work must be kept to a minimum. The following items must be included on piping arrangementdrawings: • CompletedTitle Block information. • North Arrow. Place the North Arrow in the upper right comer of the drawing. It should point up or toward the right. • Coordinates for match lines, area limits, battery lirnits, mechanical equipment, and structural support foundations, all pump suction and discharge nozzles. • Labels for angular degrees of orientation (30º, 45º, etc.) to indicate orientation of all vertical vessel nozzles. • Tag numbers (Nl, N2, N3, etc.) for all nozzles on mechanical equipment that corresponds to the vessel outline drawings, mechanical equipmentvendor drawings, and nozzle schedule. • Show mechanical equipmentnumbers and title information.
NOTE: To avoid congestion on a drawing, extend cenier lines away from the equipment symbol and label the equip ment's description and coordinates in an open area of the drawing. • Labels for all pipe lines with the following infonnation: line number; flow direction: insulation symbol and thickness; steam, heat, or electrical tracing if required. • Place a reference note somewhere within the area lirnits of the drawing to indicate the finished Grade or High Point of Paving elevation. • Label all instrumentationper the Mechanical Flow diagram. All instrumentationshould be accounted for one time in either the Plan view or Section view. Use W' diameter instrument bubble. • Label for the Top Of Platform (TOP) elevation on the Plan drawing. • Reference notes to describe the following: piping specialty items; reducers and reducing tees; out of spec flanges; any nonstandard ítem not covered in piping spec; vessel davits; chain operatorsfor valve handwheels; pipe guides, supports, anchors, and hangers. • Cutting Plane callouts that identify the name and direction of the section or elevation to be drawn. • Labels for lines running through a pipe rack to specify the commodities they contain. NOTE: For clarity and neatness, group similar callouts together in one common locaiion where possible (see Figure 11.2). • Identificationfor any rniscellaneous items. Locate and describe as required. As a general rule, drawing notes and callouts are drawn 0.125"tall. When the drawing is created full scale, as with AutoCAD, the actual text height is determined by multiplying the desired text height by the drawing's scale factor. Scale factor is established from the desired plot scale of the drawing, in this case, %" = 1 '-O". To find the scale factor, find the decimal equivalent of %", then divide that into 1 '-0" (12''). For example, 3 divided by 8 equals 0.375. Then, 12" divided by 0.375 equals 32. When applied to text height: 0.125 (text height) times 32 (scale factor) equals 4 Therefore, all text in the full-scale drawing should be a rninimum of 4" tall. Ultimately, when placed in the appropriate border to % = 1'-0" scale, the result would be text 0.125"tall. All notes should be read from the bottom of the drawing. Information such as coordinate labels for match lines, area lirnits, or battery limits, line numbers, and equipment names, coordinates, and elevations
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PIPING SECTIONS ANO ELEVATIONS: WHAT ARE THEY1
should be labeled parallel to the ítem to which they apply. This may result in notes being read from the bottom or the right side of the drawing. No written informa iion should be read from the left side of a drawing.
DIMENSIONING Developing drawings with a high degree of dimensional accuracy is of primary importance. Good dimensional arrangement and placement enhances a drawing's effectiveness. Clear, concise, well-placed dimensions not only reflect a well-thought-out drawing, they also simplify comrnunication, which minimizes checking and reduces drawing revisions.
Dimensioning Guidelines When placing dimensions on a drawing, apply the following guidelines to maximize the use of the limited space on a drawing. General dimensioning guidelines include the following: • Avoid duplication of information. Do not repeat dimensions or notes in each view of a piece of mechanical equipment. • Dimensions on plan drawings are to be placed within the drawing's limits, that is, match lines, drawing limits, area limits, battery limits, etc. • Dimension lines should be in a continuous string. Avoid staggered or offset dimensions. • Group dimensions outside of a detailed area, where possible. Avoid crossing elements of the drawing with dimension or extension lines. • Avoid placing dimensions between coordinates. • Place dimensions for horizontal lengths on a plan drawing. Dimensions for vertical lengths should be shown on sections or elevations. • Dimension a11 pipíng from centerline to centerline, centerline to face-of-flange, or face-of-flange to faceof-flange; do not dimension to welds. • When required., include gasket thickness in dimensions. Indicate gasket location relative to flange extension lines with gasket symbol (tick mark). • Provide spacing dimensions (between centerlines) of lines in a pipe rack. Do not place a continuous string of dimensions completely across the pipe rack if the pipe rack's supporting column coordinates are provided. • lndicate TOS or BOP elevation of lines in the pipe rack. • Dimensioning should be minimal. Provide only those dimensions, coordinates, and elevations required to draw and check piping isometrics or spools. Avoid referral to other drawings such as vessel drawings, vendor drawings, plot plan, etc.
233
• Show all angular offsets. Indicate the degree of offset and plane direction (horizontal or vertical). Procedure 16: Checking your work R.eference drawing: All available information and drawings Now that the drawing is complete, it must be reviewed carefully. A plotted copy of the drawing will be required. If the drawing was created manually on vellum, mylar, or other reproducible medium, a blueprint must be obtained. If the drawing was computer generated, a copy of the drawing must be plotted. Although the drawíng will be thoroughly checked by your instructor or supervisor for completeness and correctness, a drafter should always review the drawing to check for any errors, deletions, or inaccuracies. It may be necessary to systematically review the layout procedure in one's mind to duplicate the sequences used to develop the drawing. Equipment location and size should be verified. Fitting and flange dimensions must be confirmed and valve handwheel orientations must be reviewed. It is also the drafter's responsibility to assure the drawíng was developed in accordance to any and all client or company specifications and governing federal regulations. Procedure 17: Drawing release Once you have checked and corrected your drawing, it is customary to indicate the "Completed Date" in the drawing Title Block. Sorne companies may also require that a drafter initial the drawing as an affirmation this is his or her work. Plot a new copy of the drawing to provide to your instructor or supervisor. The drafter may also elect to make an additional copy of the drawing to use as future reference.
PIPING SECTIONS ANO ELEVATIONS: WHAT ARE THEY?
As previously mentioned, plan view drawings, such as the Piping Arrangement drawing, provide horizontal dimensions that establish a facility's width and depth measurements. An occasional note or callout is the only reference to heíght measurements found on plan drawíngs, To supply more detailed information on height measurements, drawings called Sections and Elevations are developed. Height is the most important dimension on section and elevation drawings. Although these two terms have come to have synonymous meaníngs, they are conceptually different. The word elevation has a literal meaning of "height above sea level." Both sections and elevations provide height measurements from an object to the ground (Grade). The primary difference is that elevation drawíngs provide a view of the exterior features of a facility,
PIPE DRAFTING AND DESIGN
234
10. PIPING ARRANGE.~ENTDRAWIKGS,SECTIONS,ANO ELEVATIONS
whereas section drawings represent interior components of a facility that may not be visible from an exterior viewpoint. Comparing this to the features of a house, an elevation represents what the house looks like from the street, whereas a section míght show how the furniture in a room is arranged, what type of wallpaper is on the walls, how many pictures are hanging on the walls, or how much attic space is provided above the ceiling. Height References Section and elevation drawíngs are the standard on which vertical measurements for foundations, platforms, steel supports, nozzles, and centerlines for mechanical equipment and pipe are shown. As mentioned in Chapter 9, the ground, or Grade, is often gíven an arbitrary value called a datum elevation. Since the use of the exact height above sea level dimension is not practícal, a .da~ elevation of 100'-0" is typícally used. A1l height dime~1ons are ref~renced from this 100'-0'' setting and are assigned elevation names to describe their type and location. Elevation names for items above Grade can appear in various forms, such as Centerline (1) Top Of Steel (TOS), Top Of Concrete (TOC), Bottom Of Pipe (BOP), or face of flange (FOF or F/F). Elevation names for items below grade are referred to as invert (INV) eleva tions. Toe obvious need for the drawing of sections and elevations is to show piping tie-ins to mechanical equipment, calculate lengths for vertical piping runs, check for interferences, verify lines are properly supported, confirm worker and operator access clearances, and establish sufficient overhead clearance requíred for equipment installation, maintenance, or removal.
between the plan and section views possible. See Figure 10.42 for three examples of cutting plane callouts. Named Elevations Similar to the way section drawings are identified, so too must elevations be identified for reference purposes. Toe North Arrow, which is placed on the plan view for proper orientation, is also the basis from which the elevation views are named. If an elevation view is named the North Elevation, it means that the drawing is looking at the fadlity from the north direction as specified by the North Arrow on the plan view. If it is labeled as an East Elevation, then it is looking at the fadlity from the east direction. See Figure 10.43 for the North, South, East, and West Elevation orientations for Unit-01. . ~pending on the direction from which the fadlity lS viewed, only one horizontal dimension, either width depth, is required to locate equipment, foundations, pipe racks, etc., on an elevation drawing. This is unlike plan view drawings that require two intersecting coordinates to locate items. Coordinates for Match Lines, Area Limits, and Battery Limits taken from the Piping Arrangement drawing are used to establish boundaries on the right and left sides of section and elevation drawings. With only one locating coordinate, mechanical equipment can be positioned from the right or left drawing boundaries. It is recommended that all locating measurements be made from either the right boundary or the left boundary to avoid misplacement of mechanícal equipment and other components. Figure 10.44 shows how the alignment of the Plan and Elevation ~ews.can make coordinate location quicker by projectmg width measurements from the Plan view down into the Elevation view.
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Where to Begin? Sections come from the Piping Arrangement drawing. Once buildings, mechanical equipment, and structural s_upportfoundations have been established and pipe, fittings, valves, and instrumentation have been represented on the plan view drawing, sorne indication of the location of an intemal, vertical view of the facility is needed. Toe cutting plane is such an indicator. Toe cutting plane callout can be represented in a number of ways. One can resemble a large letter "L" with an arrowhead on one end. Toe direction the arrowhead points indicates the direction from which the facility is being viewed. This "point of view" is the direction from which the section ~ be drawn. Two cutting planes are spaced a specified distance apart to represent the horizontal extents of the sectional view. Since multiple cutting planes can be used to reference different views, labeling the cutting planes is necessary. Section views will have different sheet numbers, so labeling the cutting plane makes referencing
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PIPE DRAFTING ANO DESIGN
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PIPE LU-:E
Vendor drawings are used to establish sizes of mechanical equipment. Nozzle schedules and dimensioning charts provide location, size, and pound ratings for equipment nozzles and their mating flanges. Pipe routings, fitting rotations, and handwheel oríentations on the arrangement drawings are interpreted and rendered accordingly on the Elevation. Although fitting, flange, and valve symbols are the same for plans, sections, and elevations, the rotation and orientation of the symbols will vary. Representation of an elbow that turns down on a Piping Arrangement drawing will be drawn differently when viewed from above than when viewed from the side, as in an elevation drawing.
DETAIL DRAWINGS Although a simple note or callout can be sufficient in conveying information to a reader, an actual drawing representation will provide much more detailed information. One case in point is the TOS callout. I
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237
and suction and discharge nozzles on pumps, turbines, and compressors. Indicate high point of finished grade (datum elevation). Mark top of grating or plate on platforms. Include Bottom Of Pipe (BOP) elevation for pipe lines on shoes. Provide centerline elevation of relief valves.
Toe following list contains sorne OON'TS relating to the dimensioning of plan, elevation, or section drawings. DONOT
• Dimension from underground lines to aboveground lines. • Dimension from lines running at one elevation to lines running ata different elevation within pipe racks or other areas. • Dimension to the center of a valve, except with small-bore screwed or socket-weld valves. • Dimension piping from electrical cable trays, conduit, or instrument tray runs. • Dimension interna} equipment piping to external piping. • Dimension piping from outlines of buildings, structures, or mechanical equipment. • Dimension "fitting make-up" installations. • Dimension the lengths of standard piping components such as elbows, tees, reducers, etc.
PIPELINE LIST Toe Pipe Line List is a compilation of the named lines that exist in a facility. Developed early in the design phase, the Pipe Line List contains valuable information used by many disciplines throughout the project's development. Toe Pipe Line List will indicate each pipe' s number, specification class, and nominal pipe size. It will also specify what Unit the pipe is in, which pieces of mechanical equipment it is attached to, and if the pipe is insulated or not. Toe commodity in the pipe is shown, along with its design and operating temperature and pressure. Figure 10.46a and b lists a11 the pipes included in Units 01-04.
PIPE DRAFTING AND DESIGN
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250
255
210
300
275
250
245
300
275
250
230
300
275
250
245
300
150
245
125
300
150
240
118
§
LIST UNIT
a: No.
b:]I b:]I boi b~
14
15
16
1 N
russ
SIZE uL
A15
A15
C30
s
b~
b:]I
UNrT-03 AREA UMITS/ STORAGE
300
150
01
240
118
b::E:
300
150
04
E-101
PROOUCT STORAGE
240
118
b:]I
150
500
01
E-101
UNrT SUPPLY HEAOER (01-19-At~IO•-ft)
100
400
150
500
100
400
V-102
FUEL GAS HEAOER (01-17-AIH)
310
150
280
118
b~
300
275
01
V-102
Fl.ARE HEAOER (OH&-Al~81
250
230
b~
...Q!..
b~
.
DESCRIPTION
6"
COOUNG ~ WATER L RETURN
E-102
6"
COOUNG ~ WATER L SUPPLY
UNIT SUPPLY HEAOER (01-22-Al~IO)
2"
N
HOT OIL
8"
UNrT-01 ~ PROPNt: V AREA UMrTS/ LOAOING
o
L
V-102
18
19
A15 10·
20
2 HEATING A15 10· 1 IIEDIIJII L H SUPPLY
21
UNrT-01 N COOUNG A15 10· O WATER L AREA UMrTS/ SUPPLY FUTURE
22
N COOUNG A15 10· O WATER L RETURN
"
"~
UNIT SUPPLY HEADER (Ol-21-.11~10) E-102
ows
UNrT-01 2' HEATING 1 IIEDfJM L AREA UMrTS/ H REl\.lRN FUTURE P-301A P-3016
COOUNG TOWER 04-CT-406
DESGN DESGN ·r PSIG OPER. PSIG
my.
100
100
40
75
100
125
40
95
-
-
-
UNrT-03 AREA LIMrTS/ STORAGE
150
500
80
180
Fl.ARE STACK
100
150
40
118
HEATER 03-H-304
150
500
100
400
UNIT-01 AREA LIMrTS/ FUTURE PROOUCT CONOENSER 04-E-402A&B
150
500
100
400
100
100
60
75
UNrT-01 AREA UMITS/ FUTURE
100
125
40
95
UTILITY STATION No. 1
100
125
90
100 125
LCWlt«:/LWW)I«: 03-FS-305
2•
UNIT-01 N INSTR V AREA UMrTS/ O AIR CTRL BLDG
24 PA12 2·
UNIT-01 N UTIUTY V AREA UMrTS/ O AIR CTRL BLDG
UTIUTY STATION No.1
150 100
100
3•
UNIT-01 N SEIMCE AREA UMrTS/ O WATER L CTRL BLDG
UTIUTY STATION No.1
90
125
50
100
UNIT-01 AREA UMITS/ UWllNCftjNUWllNG
75
320
50
298
23 IA12
01
b~
·-
UNrT-01 HC A15 10· N o FLARE V AREA UMrTS/
03
118
Vlf
A15
.si,
b~
17
01
240
E-101
No.
UNE
01
150
UNIT SUPPLY M L HEADER 1 llllll H SUPPLY {01-20-Al~IO'-ft)
N HYOROO CARBOH V
my.
UNE
300
2 HEATING
~ PROPANE L
DESGN DESGN ·r PSIG OPER. PSIG
25 WS12
26
SIS
3•
2'
50# ~ STEAM V
UNrT-03 AREA UMrTS
SHEET 1 of 2 FIGURE 10.46
(a) Pipe Line List-sheet 1 of 2.
(b)
!
PIPE ~
DESCRIPTION
YII' UNE UNIT s COIIMOOflY ,. No. No. ctASS SIZE ~ UQ " UNIT-03 PROV ~NG/UNLOMJING AREA UMITS/ 27 A15 14" ~ DUCT UNIT-02 FEED L 02-V-203 UNIT SUPPLY N COOLINC HEADER 02-E-201 28 A15 10· O WATER L SUPPLY (01-22-A15-101
~ ~~
300
250
255
210
100
100
40
75
UNIT SUPPLY HEADER (OH1-A15-101
100
125
40
95
HEATER 03-H-304
150
500
80
180
P-301A P-3018
150
500
100
400
OJ-V-303
FLARE STACK 03-FS-305
100
150
40
118
UNIT-03 AREA LIMITS
03-V-303
~~g~&
....2.!.. ~~ 02
~....2.!..
29
A15
6"
N COOLINC O WATER L RETURN
02-E-201 FUEL GAS HEADER {01-17-A15-81
~]I
30
A15
6"
N FUEL o GAS
~]I
31
A15
12·
2' HEATINC 1 MEOIUM L H SUPPLY
,_~
32
A15
6"
N
~]I
33
A15
4•
o
~:][
34
A15
12·
/\-
~:][ ~:][ ~~ ~~ ~:][
·~
35
36
37
A15
C30
A15
6"
4•
4•
o
N
39
A15
A15
s· s·
V
Fi1~E V
~ =~-L ~ HYDRO- L H CARBON
2'
HYDRO~ CARBON L
2 1
H 38
~~E
V
=~-L
N HYDRO- L O CARBON N HYORO- V O CARBON
D~~ft,N DElGN OPER. OPER. PSIG "F
HEATER 03-H-304
UNIT-02 AREA UMITS/ PRODUCT STORAGE 02-V-203 02-P-202A 02-P-2028 02-36-Cl0-6"-IH
02-E-201
02-V-203
02-V-203 02-P-202A 02-P-2028 02-37-A15-4"-lH
02-38-A15-6"-lH
02-V-203
02-E-201
100
150
40
118
300
150
240
118
300
150
240
118
150
500
100
400
150
500
100
400
310
150
280
118
300
275
250
230
LINE
!
LIST ~
UNE UNIT s
b::E: b::E:
40
41
C30
·-
2' 12· I H'IDRO- L H CAA80N
8"
03
365
310
500
H
280
400
PRON DUCT O FEEO
300
250
255
210
V L
N H'IDRO- V O CAA80N L
43 C30
b::E:
44 C30 10· ~ REFLUX V
-"'-~ 04
I[
04-V-401
04-E-404
03-27-~u·
03-8-C30-6"
04-V-401
04-E-404
04-V-401
04-V-401
04-V-401
150
40
118
2 HEATING 1 llfOOM L OJ-19-A15-10"-H H RO\JRH
b::E: 46
A15
6"
2 HEATINC 1 llfOOM L H SUPPLY
04-E-404
OJ-20-A15-10"-H
47 C30
4•
N HYOROO CIR90N L
04-E-404
03-9-C30-4"
03
b::E: 48 b::E: 49 b::E b04 b]I
50
51
52
C30
A15
A15
A15
A15
8"
PRO~ DUCT FEEO
8"
N COOUNG O WATER L RETURN
8"
COOUNG ~ WATER L SUPPLY
8"
COOUNG ~ WATER L SUPPLY
04-CT-406
~ PROP~E V
FUEL GAS HEADER (01-17-A15-81
s·
L
04-E-402A 04-E-4028 04-E-402A 04-E-4028 04-22-A15-8"
118
100
6"
04
150
240
04-E-4028
A15
b]I
300
04-E-402A
45
03
D~~liN DE.iGN OPER. OPER. PSIG "F 500
b::E:
4•
"
"~
280
C30 10· 1 H'IDRO- L CAA80N
42 C30
DESCRIPTION
310
2
03
b::E:
w
04-E-404
03-27-CJ0-14"
04-CT-406 04-E-402A
150
500
100
400
150
500
100
400
300
150
240
118
100
125
40
95
100
125
90
100
100
100
04-E-4028
100
75
04-P-405A
100
100
04-P-4058
100
75
FLARE STACK 03-FS-305
150
500
80
180
SHEET 2 of 2 FIGURE 10.46 (b) Pipe Llne List-sheet2 of 2.
EXERCISES: PLANS, ELEVATIONS, AND SECTIONS
CHAPTER 10 REVIEW QUIZ 1. What is a piping arrangement drawing?
241
7. What is the mínimum height of text used on piping drawings that are going to be placed in a border at %" = l'-0' scale?
2. What is a nozzle schedule?
8. Explain the difference between section and elevation views.
3. Name five reference drawings or documents needed by a piping designer to lay out the piping arrangement drawing.
9. Define datum elevation.
10. What is the most important measurement shown on section or elevation drawings? 4. To what scale are full-scale pipíng drawings placed inside a border?
5. How is scale factor determined?
EXERCISES: PLANS, ELEVATIONS, AND SECTIONS Chapter 1 O Drawing Exercises
6. Which drawing is used as a reference drawing when locating centerlines for pipe racks and equipment foundations?
Exercise 10-1. Using the layout procedures discussed in this chapter, develop the piping arrangement drawíng of Unit--01 as shown in Figure 10.1. Exercise 10-2. Draw Section A-A of Unít-Ol as shown in Figure 10.45.
PIPE DRAFTING AND DESIGN
CHAPTER
11 StandardPiping Details
Any project having the complexity of a piping facility will undoubtedly have many components that are used repeatedly throughout the facility. In an attempt to reduce the volume of drawíngs produced, many companies employ the use of standard piping details. Toe standard piping detall is a drawing that depicts an item or items that are used with such frequency and having such consistency in their installation procedure that a single drawing can be created and duplicated for use to represent their installation in almost every situation. Situations in which standard piping details are most likely to be used are for the support, anchoring, guiding, and spacing of pipe. This chapter discusses the methods and devices used in these applications.
PIPE RACK SPACING Arrangement and posítioning are important factors in the layout of a piping facility. Space is limited. Area and boundary limits force conservation of space. Arranging equipment throughout the unit in an orderly and sequential fashion is a necessity. Therefore, proper spacíng and arrangement of pipe in the pipe rack requires special attention. A pipe rack has a defined width; therefore, working within the allotted space makes spacing crucial. Not only must pipe be arranged to take up a minimum amount of space, but also allowanees should be made for any pipe that might be added in the future. Line spacing dimensions are based on a clearance of l" between the outside diameter of the largest flange and the outside diameter of the adjacent pipe. Toe minimum spacing between any two lines is 4". If either of the lines is insulated, the thickness of the insulation must be added. When lines are placed adjacent to a building, wall, column, or other structure, a minimum clearance of 2'-0" is required from the outside diameter of a flange. Pipes having orifice flanges will require a larger minimum clearance than indicated on the charts
because of the valve taps and connecting instrumentation. Typically, a minimum clearance of 2' -O'' is used on either side of a pipe having orifice flanges. Figure 11.1 shows the requirements for establishing the minimum clearances for line spacíng, Toe Line Spacing Chart shown in Table 11.1 provides the minimum clearances between the centerlines of two pipes without insulation. Toe expanded chart provides centerline-to-centerline measurements for pipes of various sizes and pound ratíngs. If a pipe is insulated, the insulation thickness specified on the Line List (found in Chapter 10) is added to the chart dimension to determine the total line spacing measurement. To use the chart, find the desired size of pipe in the appropriate pound rating sections. Once the two pipe sizes and pound ratings are found, follow the row across and the column down. Toe number at the intersection of the row and column is the centerline-to-centerline spacing between the two pipes. Toe numbers shown in the Line Spacing Chart are in inch values. For example, the spacíng requíred between a 10''-lSO#pipe anda 6''-300# pipe is 13".
DRAWING PIPE IN THE RACK When representing pipe in a pipe rack, the careful arrangement and organízation of names, dimensions, and line numbers will make the drawing easier to read. Figure 11.2 shows a pipe rack that has been well organized. Notice how the alignment of notes, dimensions, and other callouts makes the drawing easy to read. Toe following guidelines will help you organize your drawing: 1. Keep flow arrows the same size and aligned. 2. Line numbers should be left justified when possible.
3. Pipe commodity should be identified on utility lines only. 4. Line spacing dimensions should align across the pipe rack from one pipe support column to the other.
242
C, 2012 Ehcvic-r lnc. Ali rlghts rcserved.
243
PIPE FLEXIB!UTY
-@e---~-
COLS.
P.S.
-~
101-C30-1"
---
104-C30-2"
111
-
1
1
1
1"
103-A 15-6" -
-
---
~
--
1
105-A15-12" -
1 1 1
-
102-C30-14"
;,
-
-
1 1 1
108-A15-10"
-
1 1
'-
1
1
1
1
"
V
-
111
--
1 .....
1
-
1"
-
r-,
-
1 1
rfüh
-
-
~~I
1 1
4" mm.
i----_ -
-
1 ,, 1" -
1 1 1 1 1
1 1
-
V
1 1 1
1 11
-
BUILDING, NOTE: DWG NOT TO SCALE
FIGURE 11.1
Line spacing dearance requirements.
This allows coordinates for each pipe to be calculated since each pipe support column is positioned using a coordina te.
PIPE FLEXIBILITY A major concem when arranging pipe in a rack is the amount of expansion and, to an extent, contraction that occurs when a cold pipe is heated to its normal operating temperature. Because the dimensions provided in the line spacing chart do not account for expansion of a pipe during the start-up of a unit, consideration must be gíven to the amount of expansion a pipe will undergo as its temperature begins to rise. Linear expansion correlates to the direction of flow. In other words, a pipe will grow in the same direction as the commodity flows. If the expansion of a pipe will result in its interference with an adjacent pipe, line spacing will have to be increased. If the normal expansion of a pipe will not result in interference, line spacing will not be affected.
Remember, space in the rack is limited. Overspacing must be avoided. Figure 11.3 provides two illustrations where additional line spacing may be required. The interference occurring at Point 1 is a result of linear expansion. Lines 103 and 104 have similar spacing in the rack Both pipes drop down in the rack then tum west to rest on a support beam before they exit the pipe rack and presumably attach to a piece of equipment. Using the spacing dimension provided in the Line Spacing Chart, 8" is required between the pipe's centerlines when they tum west, Assume additional calculations indicate line 103 is expanding 2" to the south and line 104 is expanding 2" to the north. By adding onehalf the OD of line 103 (21A'') and one-half the OD of line 104 (21A'') and the 2" of expansion for each pipe, for a total of 8W', (21A'' + 21A" + 2" +2" = 8W') it is obvious an interference, or clash, between lines 103 and 104 would occur. To avoid this interference, two altematives are feasible: 1. Increase the spacíng between the two pipes if the ends of the pipe where they attach to the pieces of
PIPE DRAFTING AND DESIGN
244
11. SfAi'IDARD PIPING DETAII.S
TABLE 11.1 Line Spacing Chart
30011 PIPE SIZE
"""o
l.{)
,....
16 14 12 10
150/1 P1PE
6
4
3
2
2
15 14 13 11 10 9
8
7
6
2 14 13 12 11
3
16 15 13
8
7
4
16 15 13 12 11
10 9
6
18 16 15
8
19 17 16 15
10 20 18 17
6
4
3
2
9
8
7
6
6
6
3 15 14 13 11 10
9
8
7
8
7
4 15
14 13 12 10 9
8
14 12 11 10 9
8
8
12 11
16
9
10
9
14 13 12 11
11
13
12 11
SIZE
"""o
l.{)
,....
16 14 12 10 8
6 17 15 14 13 12 10 8
18 16 15 14 13
10 19 17 16 15
12 21 19 18 17 15 14 13 13 12
12 20 18 17
14 21 20 19 17 16 15 14 14 13
14 20 19
16 22 21 20 19 18 17 15 15 14
16 21
30011 PIPE StZE
"""oo
l'0
16 14 12 10 8
6
4
3
2
2
15 14 13 11
10
9
8
7
6
3
16 15 13
12
11
9
8
7
4
16 15 14 12
11
10
9
6
18 16 15 14 12 11
8
19 17 16 15 13
10 20 18 17
16
12 21 19 18 14 21 20 16 22
equipment allow it. If this is not possible, use the next altemative. 2. Cold spring lines 103 and 104 1". Cold spring is an installation technique that requires the length of the pipe that is expanding to be cut short by a distance equal to one-half of the length of expansion. In this case, 1" for each line. When trying to solve the interference problem occurring at Point 2, a similar approach can be taken. Either add 2", the amount of linear expansion, to the line spacíng dimension or cold spring (shorten) line 101 one-half
the linear expansion amount, l" in this case, to the west and add l" to the line spacing dimension, for a total adjustment of 2".
PLANNING FOR HEAT EXPANSION Thermal expansion will have an effect on pipe, pipe supports, and even on process commodities. Toe amount of expansion caused by rising temperatures
PIPE DRAFTING ANO DESIGN
-- _-------------_ ---=i N PLANNING FOR HEAT EXPANSION
1
t.{)
~
e.o ~I
I
o.
c::=--
z~
.In ~z
.In . ~z
2
~.
~.
--+-P.S. E.
42-CW15-6" 27-C30-4" 107-A15-8" 178-IA 12-3" 22-UA15-2" 33-C30-1 O"
CQ~ _ 175'-0" COOLING WATER
INSTRUMENT UTILITY AIR
AIR
Pipe rack drawing organization.
,.,..,
No
N
N:
·º
zo .L{)I vil~ . z
~
l
*---TOS ELEV 116'-o"--.ffi-
---
--4-1-t·---
104-A 15-4" 1
¡
1
1
L{)
01 :z o,
e,
FIGURE 11.3
'o
o.
z~
-~---
FIGURE 11.2
'o
245
,
TOS ELEV
it~ 1
P.S. COL "A"
E.205'~
101-A15-14" ~ 102-C30-6" 1_1_1_---'-10;:;..;3;;...-.....;.A...;..;1"""5;....-_4;...." __
\e=-•
:1-----'I~
1 11
112'-o"
1
¡
1
t
P.S. COL "B"
E.215'~
Pipe expansion.
can be quite significant on long runs of pipe, especially those in a pipe rack. To absorb the expansion of pipe in a rack, pipe loops are often incorporated. Figure 11.4 shows a pipe loop as a Ushaped routing of the line designed to contain the expansion of the pipe. Loops are typically located near the rnidpoint of a long run of pipe. Expansion will cause the two ends of the pipe to
grow toward one another resulting in the distortion of the loop as shown in Figure 11.5. When multiple loops are placed at the same location, as shown in Figure 11.4, adequate line spacing requires the deflection of each loop be calculated to avoid interference. Lines resting on Tsupports must be designed carefully as well. lf a line is positioned too clase to the end
PIPE DRAFTING AND DESIGN
246
11. SfAi'IDARD PIPING DETAII.S
...
..
107-C30-8" 106-A15-8"
,,
\
\
'
\ \ \ \ \ \
X FIGURE
11.4
'
\
1
'
_ __ ... . .
FIGURE 11.5
-.
I --•
'·{
•
\ \ \-+--o-~ \ \ \ \ \ \ \ \ \ \ \ \
FIGURE 11.6
Pipe loop distortion.
111
•
)
1
1
FIGURE 11. 7
,, ........
•
TREAT ONE PIPE AS HOT AND THE OTHER AS COLO WHEN CALCULATING UNE SPACING FOR TWO PIPES EXPANOING IN THE SAME OIRECTION.
y 1
Texas, /ne., Bayport, Texas.
t"•
•
1 1 1 1 1
1
\
.. 1,
105-A15-6"
)
1
Pipe expansión loop. Courtesy of Nisseki Chemical
''
-G)
1 '-•
)
1
1
Hot and cold line spacing.
of a support, expansion may push the pipe off the support (see Figure 11.6). Situations like this may require a cold spríng ora longer Tsupport. When multiple lines resting adjacent to one another tum in the same direction, attention must be given to the fact that one line can grow while the other does not. In Figure 11.7 assume lines 105 and 106 are both expanding at the same rate and in the same direction. As they both grow, adequate line spacing will be maintained. But what if line 106 was a cold line and did not grow at the same rate as line 105? Expansion from line 105 would cause interference with line 106. To avoid this, the line spacing dimensions X and Y in Figure 11.7 must be calculated to reflect the conditions of one line beíng hot and the other cold. Calculations using the hot/ cold scenario will guarantee adequate spacing at all times.
108-C30-1 O"
•
- ~~-
-
PIPE ANCHORS
-+-+-t-
PREVENT PUSHING A PIPE OFF A SUPPORT, BY NOT ROUTING THE PIPE NEAR THE ENO OF AN OPEN SUPPORT. Pipe expansión on T-supports.
Expansion is not the only force that can alter the alignment of a pipe. Vibration, commodity turbulence, and other extemal forces, such as wind, cause a pipe to move. Often restriction of a pipe's movement becomes necessary. To prevent movement or to control the direction of movement, pipe anchors are often used. Two types of pipe anchors exist: fixed and directional. Fixed anchors are used in locations where all movement of a line must be prevented. Toe most common way to anchor a pipe is to weld the pipe directly to a support or structural member. Structural angles, approximately 12" long, are laid parallel to the pipe where it crosses a structural support and are then field weld (FW) to the pipe and structural support. See Figure 11.8. If the pipe
PIPE DRAFTING ANO DESIGN
247
PIPESPA1'S
FW
FW
BOLTEO CLAMP
UNINSULATED PIPE 4" & SMALLER //
,,,.; BOLTED CRADLE SHOE
//
-++\\
Fw---.¿(.~\.
UNINSULATED
<,
INSULATION
PIPE 6" & LARGER
FIGURE 11.8 Pipe anchors.
to be anchored is insulated, a pipe shoe is attached to the structural support. Shoes will be discussed later. Directional anchors are used to force movement in one direction, along a pipe's lineal axis, while prevent it from occurring in a perpendicular direction. Directional anchors are often used to direct a pipe's movement away from buildings, structures, or pieces of equipment. Figure 11.8 depicts the anchoring of uninsulated pipe.
PIPE INSULATION SHOES Pipe is insulated to prevent the heat loss or to ensure worker safety. Anchoring lines with insulation requires special preparations because resting insulated pipe directly on structural support damages the insulation. To protect insulation on pipes 3" and larger, pipe shoes are attached to the pipe at the locationwhere it rests on a support. Depending on the governing pipe specilication, shoes can either be welded or bolted. Welded shoes are approximately 611 long and are made from 3" tal! structural tees or 6 wide flanges that have been cut into halves and then welded to the bottom of a run of pipe. Bolted shoes resemble a cradle that the pipe rests in. A U-shaped strap is placed over the pipe and is bolted to the cradle to secure the pipe to the shoe. Because of the expense to x-ray and post-heat treat all welds, bolted shoes are a common occurrence. See Figure 11.9 for an example of welded and bolted shoes. Pipe smaller than 3" typically has insulation thin enough to be cut away 11
BEAM
WELDED T-SHAPE SHOE FIGURE I 1.9 Pipe shoe.
from the pipe at the poínt where the insulation would rest on a support. Therefore, no shoes are required.
PIPEGUIDES When total restriction of pipe movement is not required, pipe guides are used. Pipe guides confine movement along the pipe's lineal axis. Used primarily to maintain proper line spacíng in a pipe rack, pipe guides prevent lateral or sideways movement. Unlike the pipe anchor, which is welded to the pipe and structural support, the guide allows pipe to slide lengthwise between two angle shapes (see Figure 11.10). When a pipe is supported on shoes, the angle shapes are positioned on either side of the shoe (see Figure 11.11).
PIPESPANS Toe proper design of any pipe configuration must take into account the limitations of the pipe itself.
PIPE DRAFTING AND DESIGN
248
11. SfAi'IDARDPIPING DETAII.S
FW
FW
UNINSULATED PIPE 4" & SMALLER
6" LONG ANGLE
FW /
',
<:.:.......GUIDES/
FW
FW FIGURE 11.11 Pipe shoe with guides.
UNINSULATED PIPE 6" & LARGER FIGURE 11.1O Pipe guides.
Depending on the pipe's diameter and wall thickness (schedule), a pipe can only span a specified distance befare it begins to deform. For pipes installed horizontally, this deformation is called deflection. Deflection is the amount of sag or droop that is allowed in a run of pipe befare it adversely affects commodíty flow. If a pipe is not properly supported, it will sag to the point where the commodity flowíng inside will either slow down, thereby reducing the efficiency of the unit, or it may collect or pocket in the low point of the run of pipe. Toe Allowable Pipe Span chart shown in Figure 11.12 provides "Recommended" and "Maxímum" pipe spans and deflection amounts for carbon steel pipe filled with water for various sizes and schedules of pipe. The left side of the chart is for uninsulated pipe 200ºF and below. Toe right side of the chart is for insulated lines 201-599ºF.
PIPE SUPPORTS On long, vertical runs of pipe, it is crucial not to exceed load allowances on mechanical equipment nozzles. To avoid ripping a nozzle off the top or side of a vertical vessel, pipe supports are used to keep the shear forces within acceptable limits. A pipe's síze, both diameter and length, wall thickness, pound rating, and insulation thickness all contribute to the load on a nozzle. Additionally, movement in the form of vibration, wind, and thermal expansion contribute to nozzle stresses
that must be controlled. Pipe supports are designed to be positioned at precise points to relieve the high loads and stresses that are exerted on equipment nozzles. On longer drops of pipe, guides are employed to further control movement. Figure 11.13 depicts various scenarios where pipe supports and guides are located.
FIELD SUPPORTS Once a pipe drops out of the rack, support must be provided to relieve weight stresses that heavy piping systems can place on nozzles, weld joínts, and other critical points. Nozzles and welded joints are not designed to carry heavy loads. Extreme loads placed on a nozzle could result in the nozzle being pulled off the vessel or piece of equipment. Lateral forces applied to weld joints could have the same result. Field supports can be at ground level, in a pipe rack or anywhere where structural support is not provided. Figure 11.14 shows a field support being used to carry the load that would otherwise be placed directly on a horizontal stub-in branch connection. The base support is a type of field support that rests on the ground, platform, or other stationary surface and is used to support control stations and other pipes routed no more than 2 -0' above Grade level. As seen in Figure 11.15, sorne base supports are "dummy" welded to the bottom surface of an elbow to provide support. Also known as a "base ell support," base supports can be "fixed," adjustable, or spring loaded depending on their specific need. Figures 11.16 and 11.17 represent "fixed" and adjustable base supports. Typically identified on a drawíng as no more than a note, such as FS-1 or FS-2, base
PIPE DRAFTING ANO DESIGN
1
1
..., G')
--
~
ALLOWABLE PIPE SPANS
N
USING CARBON STEEL (ASTM 106-Gr. B) PIPE FILLED WITH WATER
~
[
"'
io
.""
200'F ANO UNDER-LIMITING STRESS = 7600 PSI (UNINSULA.TED)
<:r
.¡;·
.g>
:, "' ~ ...,..
,
w
w
vi w o..
:::>
N
a::
...J
o w I ü
(/)
'é
é'
RECOMMENDED
.
201'F TO 599'F-LIMITING STRESS = 6175 PSI (INSUlATEO)
'é
MAXIMUM
~ SPAN DEFL. SPAN DEFL. ~
'
65% OF MAX 75% OF MAX
é'
RECOMMENDED SPAN
DEFL.
.
MAXIMUM SPAN DEFL.
~
'
65% OF MAX 75% OF MAX
~ o
6"
40
36'-9"
1 ..
41'-3"
z
8"
40
41'-6"
1 ..
46'-o" 1 o/,16..
30'-o"
34'-6"
36'-o"
1 O"
40
45'-9"
1 ..
50'-6" 1
Yt
32'-9"
37'-10"
40'-6"
12" STD
49'-0"
1 ..
53'-0" 11a"
34'-6"
39'-9"
43'-6"
14"
30
50'-9"
1 ..
54'-6"
o/,16..
35'-6"
41 '-o"
45'-6"
34" 34" 34" 34" 34" 34" 34" 34"
16"
30
53'-3"
1 ..
56'-0" 1 \"
36'-3"
42'-0"
45'-6"
5/s" 4 7'-3"
34" 34"
1 Y," 16
37'-4"
43'-0"
47'-6"
5/s" 48'-9"
\Y,,, 16
31 '-9"
36'-7"
X"
38'-3"
44'-o"
4 7'-6"
~"
50'-o"
sis"
32'-6"
37'-6"
40
22'-6"
1 ..
26'-3" 11~ 16..
17'-2"
40 4" 40
27'-6"
1 ..
32'-o"
20'-9"
30'-9"
1 ..
35'-3"
Ya" 1 %" 1 %"
""ca
2"
s'
3"
111
o
21
~
IB C)
18" STD
51'-9"
20" 20
53'-9"
34" 34"
57'-6"
1
1
58'-9'' 1 16
19'-8"
18'-6"
24'-o"
23'-6"
22·-11"
26'-6"
26'-6"
26'-10"
31 '-0"
32'-0"
18'-9"
34"
24'-6"
7/s"
16'-o"
28'-o"
1~" 16
18'-2"
21 '-0"
33'-3"
1~"16
21 '-7"
25'-0"
37'-6"
17< .. 16
24'-5"
28'-0"
42'-0"
17< .. 16
27'-3"
31 '-6"
44'-3"
17< .. 16
28'-9"
33'-3"
29'-9"
34'-3"
30'-8"
35'-6"
45'-9"
12'-2"
14'-o" 18'-4"
~
"'ro Vl
e.,,
i
250
11. STANDARD PIPJNG DETAJLS
L,___...__---4
SHORT RADIUS ELBOW FOR UNES 10" ANO LARCER. LONG RAOIUS ELBOW FOR UNES 8" ANO SMALLER.
~PP2R,~T~-t:,~=6="~M~IN::j.
1·-0·
SUPPORT l:====::!::t::!:~6:...." t-MIN.--r=-: --
MIN.
SPECIALLY DESIGNEO SUPPORTS ARE REOUIRED WHEN THIS DISTANCE EXCEEOS 1 '-8".
CUIDE ELEVATION OETERMINEO FROM TYPE SPECIFlEO ON ORAWINC.
CLIENT DETERMINES IF THESE OROPS ARE ELBOWS OR SENOS.
1·-0· MIN.
STACCER SUPPORTS & CUIDES TO PROVIOE AOEOUATE CLEARANCE.
OFFSET SENOS TO BE USEO ON SCREWEO UNES.
SUPPORT
-f..= - --
CLIENT DETERMINES IF THESE DROPS ARE ELBOWS OR SENOS.
E::
6" MIN.
- r-1~==:::::l 1·-0· 1'-0"
MIN.
MIN.
FIGURE 11.13
Vertical pipe supports and guides.
supports differ in size, attachment methods, adjustability, and load capacity. When the vertical distance from pipe to Grade makes the base support inappropriate, a support fabricated from a steel angle or structural channel is used. These "channel" supports are generally bolted or welded to structural steel or concrete columns. They are typically less than 2'-6" in length and, with a load capacity of 500 pounds, are used only on pipe 12" and smaller. Figure 11.18 depicts the use of channel supports.
DUMMY SUPPORTS The dununy support, or dummy leg, as it is also known, is used to support pipe that would not otherwise be supported due to its short length or change in direction. The dununy Ieg is a piece of open pipe welded to the outside of an elbow. The piece of open pipe acts as a continuation of the pipe's axis, thereby allowing it to extend across a horizontal structural support (see Figure 11.19). The sizing chart shown in Figure 11.20 provides the required "leg" pipe diameter and the offset
PIPE DRAFI1NG AND DESIGN
251
PICK,UP PIPE SUPPORTS
FIGURE 11.14 Field support. Courtesy of Nisseki Chemical Texas, lnc., Bayport, Texas.
placement dimension required to maintain a common Bottom Of Pipe elevation.
HANGERRODS Hanger rods are the standard supporting devices used when a pipe, or pipes, must be supported from above. Hanger rods are suspended from overhead lines or structural supports. Two major styles of hanger rods are used. One is designed to support a single pipe and the other is intended to support multiple lines. Used on lines up to 24" in diameter, and havíng a load capacity of 4,800 pounds, the single pipe hanger uses a rod and clevis to provide support (see Figure 11.21). The charts shown in Figures 11.22 and 11.23 represent an HR-1, which is used on uninsulated pipe and an HR-2, which is used on insulated pipe. When several lines require support, the multiline hanger is used. Often called a trapeze, it uses a length of steel angle suspended by two
FIGURE 11.15 Base support. Courtesy of Nisseki Chemical Texas, !ne., Bayport,Texas.
metal rods at the ends to provide support to the group of lines simultaneously (see Figure 11.24). The trapeze can vary from 3'-0" to 10'-0" long from center to center of the rods with the shorter length carrying a maximum load of up to 4,900 pounds.
SPRING HANGERS Lines having significant growth, due to expansion, prevent the use of a stiff support such as a hanger rod or trapeze. These lines require the use of spring hangers. Spring hangers allow expanding pipes room to grow without placíng stress on the supporting rod (see Figure 11.25).
PICK,UP PIPE SUPPORTS In most píping facilities, structural column spacing in the pipe rack is 25' -0". For large-diameter pipe,
PIPE DRAFTING AND DESIGN
252
11. SfAi'IDARD PIPING DETAII.S
/
* 1/4
STEM
11
NOMINAL PIPE SIZE
THREADED FLAT FACE FLANGE
2" & BELOW 3"
USE 4" MIN. PAD IN UNPAVED AREAS. PAD NOT REQUIRED IN PAVED AREAS.
*
FIELD
WELD
CONTINUOUS
* *
**
& 4"
6" & ABOVE
DUMMY WELD
STEM
SIZE
1" PIPE 2" PIPE 3" PIPE
FIELD THREAD
BASE SUPPORT - TYPE A (FS-1) FIGURE 11.16 Basesupport-TypeA(FS-1).
spanníng this distance poses no problem. Smallerdiameter pipes, however, do not have the strength necessary to span this distance and will sag between supports. These sags or pockets can become so severe that they can prevent commodity flow. Pickups are designed to use the larger pipes to support the smaller pipes. Using a length of steel angle attached to the larger-diameter pipe with U-bolts allows the smalldiameter pipes to be supported at their weakest point
(see Figure 11.26). Pick-ups can span up to 10' --0" and carry a load of 1,200 pounds. The various guides, supports, and anchors discussed in this chapter play a significant role in the overall design of a píping facility. Each one requires special analysis and calculations to be properly installed. Most companies have strict guidelines governing the use of these items. Only designers with years of experience should make decisions on when and where to use these devices.
PIPE DRAFTING ANO DESIGN
253
PICK,UP PIPE SUPPORTS
BOLT WITH HEX NUTS
* ~,,
CONTINUOUS DUMMY WELD
FIELD FAB BRACKET
f-
I
C)
w I
w _J
STEM
OJ <(
THREADED FLAT FACE FLANGE
f-
(J) ~ ~
USE 4" MIN. PAD IN UNPAVED AREAS. PAD NOT REQUIRED IN PAVED AREAS.
*
FIELD
o
**
**
WELD
NOMINAL PIPE SIZE
STEM SIZE
2" & BELOW
1" PIPE
3" & 4"
2" PIPE
1
6" THRU 14"
3" PIPE
1
FIELD
<(
THREAD BRACKET SIZE
BOLT SIZE ~,, X 1
o"
2"
X
2"
X
Y4"
Ys" X Yr x
12"
3"
X
3"
X
~16"
12"
4 ..
X
3"
X
r 8"
BASE SUPPORT - TYPE B (FS-2) FIGURE 11.17
Base support-Type B (FS-2).
PIPE DRAFilNG AND DESIGN
254
11. STANDARD PIPJNG DETAJLS
ffl=¡ 2' -0"
1
--r•
2' -6"
MAX
6 [8.2
[
[
1
MAX
2'-6"
(TYP)
MAXIMUM LOAD 500# FIGURE 11.18 Channel supports.
ELBOW TURNING UP FIGURE 11.19
ELBOW TURNING
Dummysupport.
PIPE DRAFI1NG AND DESIGN
DOWN
1
1
MAX
:J
255
PICK,UP PIPE SUPPORTS
DUMMY
DS-1
SUPPORT
SEE NOTE 4
PIPE DIA.aa'X'
1
1/4" PLATE PLUG
/.»
18 ~ WEEP HOLE TYP.
UNE SIZE
2" 3" 4" 6" 8" 1 o" 1 2" 14" 1 6" 18" 20" 24"
FIGURE 11.20
'A' DIM 1/4"
gA,, 16
1/2"
11A6 1" 11A6 21A6
P/a" 25/s" 35/s" 35/s" 55/s"
'X'
DIA 11/2" 2" 3" 4" 6" 8" 8" 1 o" 1 O" 1 o" 1 2" 1 2"
NOTES: 1. DUMMY-WELD EXTENSIONS ARE SCH. 40 PIPE UNLESS OTHERWISE NOTED. 2. PIPE FABRICATOR TO SUPPLY DUMMY-WELD EXTENSIONS. 3. ON STRESS RELIEVED LINES, DUMMY-WELD EXTENSIONS ARE WELDED TO PIPE BEFORE STRESS RELIEVING. 4. DUMMY-WELD: DO NOT CUT HOLE IN PIPE, USE LINE-CLASS WELDING RODS. 5. MATERIAL: LINE-CLASS.
DS-1 dummy support sizing chart,
CLEVIS
FIGURE 11.21
Rod and clevis.
PIPE DRAFilNG AND DESIGN
256
11. STANDARDPIPJNG DETAJLS
HANGER
HANGER ROO - HR-1
ROO - HR-3
FW
,.......
z-
,,...._
(SEE NOTE
z -
N
w
..... o z
2 ::
w w
X
w
2
1-
:
w w
X
(/) .....,
::
N
o
z
(/)
<:»
CLEVIS
CLAMP HR-1
HANGER DATA
"X" DIM.
MAX. ALLOWABLE HANGER LOAD #(lbs)
CLEVIS SIZE
PIPE SIZE
2
11/2'& 2"
91/i
250
3
3"
101/i'
350
4
4"
111/i'
400
6
6"
1 '-21/i'
1940
8
8"
1 '-5"
10
1 o"
12
12"
14
14"
16
16"
2'-0"
18
18"
2'-2"
HR-3
HANGER DATA
HXU
MAX. ALLOWABLE HANGER LOAD #(lbs)
CLAMP SIZE
PIPE SIZE
OIM.
2
2"
1 ·-10"
610
3
3"
1·-101/i'
1130
4
4"
1 '-11"
1130
6 8
6"
2'-2"
2555
2000
8"
2'-4"
2555
1 '-61/i'
3600
10
10"
2'-5"
2890
1 '-8"
3770
12
1 2"
2'-6"
2890
4200
14 16
14"
2'-81/i'
3835
4600
16"
2'-91/i'
3835
4800
18
18"
2'-101/i'
3835
1 ·-1
o 1/i'
NORMALLY USED ON UNINSULATED PIPE.
NORMALLY USED ON INSULATED PIPE TO 750'.
NOTES:
NOTES:
1. LOADS EXCEEDING 5001bs. AT ATIACHMENT SURFACE SHALL BE SUBMITIED FOR APPROVAL. 2. WHERE EXPANSION CAUSES HORIZONTAL MOVEMENT, "X" DIMENSION MUST BE CALCULATED.
1. LOADS EXCEEDING 5001bs. AT ATIACHMENT SURFACE SHALL BE SUBMITIED FOR APPROVAL. 2. WHERE EXPANSION CAUSES HORIZONTAL MOVEMENT, ''X'' DIMENSION MUST BE CALCULATED.
FIGURE 11.22 Hangerrod HR-1 data.
FIGURE 11.23 Hanger rod HR-3data.
PIPE DRAFI1NG AND DESIGN
257
PICK,UP PIPE SUPPORTS
FW
FW
__ FIGURE 11.24
.....___....,-
Trapeze,
FIGURE 11.26
FIGURE 11.25 Spring hanger. Courtesy o/ Nisseki Chemical Texas, lnc., Bayport, Texas.
PIPE DRAFilNG AND DESIGN
Pick-up support.
258
11. STANDARD PIPJNG DETAJLS
CHAPTER 11 REVIEW QUIZ
6. What is a pipe shoe?
1. Why is line spacing critical?
7. Explain the difference between a pipe anchor and a pipe guide. 2. What is the minimum spacing between lines?
8. What is the function of a dummy Leg? 3. Define cold spring.
9. What is pipe dejlection? 4. What is a pipe expansion loop?
10. What are pickup supports designed to prevent? 5. Name two types of pipe anchors.
PIPE DRAFI1NG AND DESIGN
CHAPTER
12 Piping Systems
Within every piping facility, there are specific pipíng systems that perform specialized functions. These systems vary in their importance to the overall operation of the facility and can range from vital to peripheral. These systems can be complex in design or simple in function. The systems described in this chapter are examples of those commonly found in many pipíng facilities.
PLANT UTILITIES Every piping facility is designed for a definite purpose. Most commonly the purpose is to produce a product that can be sold for profit. To achieve the intended purpose of the facility, certain components are incorporated into its design. Plant utilities are among these. By design, they are not the profít-producíng products. However, plant utilities provide services that are essential to the efficient operation of the facility. Utilities include systems such as water, steam, condensate, fuel oil and gas, fiares, and air. Each utility is shown on the píping arrangement drawíng and is designed according to their specific duty, independent of process piping.
Water Systems Often overlooked, water systems play an important part in a piping facility's successful operation. Water systems can include cooling water, boiler water, plant water, utility water, and emergency water. Cooling Water
Cooling water flows through a closed piping system that circulates water through various pieces of equipment. Exchangers and condensers require chilled water to reduce the temperature of the process commodity. As water circulates through the shell of an exchanger, heat is transferred from the process commodity to the
cooling water. To maintain its effectiveness, the coolíng water is piped to a cooling tower where the heated water is aerated to reduce its heat gain. After the heat has been removed from the cooling water, the chilled water travels back to the exchanger and repeats the process. Boiler Water
Boiler water is the piping system that delivers feed water to all steam-generating equipment in a facility. Steam is generated by boilers, heaters, and even nuclear reactors, and is used in a wide variety of piping facilities. Emergency Water Designed specifically for worker safety, emergency water systems include eye wash and emergency shower stations. Emergency shower stations are provided in all areas where maintenance and operational personnel are subject to hazardous leaks or spills. Eye wash stations are also provided for situations where physical injury may be caused by chemical sprays or hazardous fumes.
Steam and Condensate Steam has a number of uses in various piping facilities. Made by on-site equipment, steam is relatively inexpensive. Many utility companies use steam as their source for powering huge generators to produce electricity. Multistoried buildings use steam to heat a building's occupied areas during winter months. Cargo ships once used steam as their primary source of power. In petrochemical facilities, steam is used to power the steam turbines used as drivers on pumps and compressors. Superheated steam is steam that is heated to a temperature that is above the saturation temperature for its designed pressure. In petrochemícal facilities, superheated steam is also used as stripping steam. Stripping
259
C, 2012 Ehcvic-r lnc.
Ali rlghts rcserved.
260
12. PIPIKGSYSTEMS
steam is used in fractionation columns to enhance the effectiveness of the fractionation process. In situations where heat tracing is required, steam is used to maintain constant temperatures and prevent commodities with slow flow characteristics from freezing. Duríng shutdowns, steam is used as a means of cleaning parts and equipment. Condensate is the visible evidence of steam cooling and therefore condensing. In its purest form, steam is invisible. Only when just-saturated steam cools and becomes heavy with water vapor is it visible. Condensate is undesirable in certain situations so it must be removed from steam lines. When moved under extreme pressure, condensate can be damaging to equipment such as turbine impellers. Condensate is separated from the steam by traps. Steam traps are placed at pocketed low points and at the dead ends of steam headers to collect condensate. Condensate is then piped back to fi.red equipment where it is converted back into steam.
Fuel Oil and Fuel Gas These commodities are used as fuel for heat sources such as fi.red heaters and boilers.
Fiare Systems
FIGURE 12.1
Toe most noticeable piece of equipment in use, especially after dark, is the fiare where waste gases and vapors are burned. Fiare systems collect gases created during start-ups and those released from pressure safety valves and route them to the fiare stack to be burned. Flare stacks are typically located upwind of process units and are placed a minimum distance of 200' from the closest piece of process equipment, storage tanks, or cooling towers. Figure 12.1 depicts a typical fiare stack.
Air Systems Another plant utility that is essential to the operation of the facility is its air system. There are two types of air systerns: utility air and instrument air. Utility air Utility air is compressed air piped throughout the facility to power pneumatic tools and equipment. Impact wrenches, grinders, and other pneumatic tools are commonly used duríng normal plant operations. During times of a shutdown, scheduled maintenance and repairs require workers to loosen nuts and bolts that have not been removed for quite sorne time. Power-driven tools are the only efficient means of timely maintenance.
Fiare stack. Courtesy of Nisseki Chemical Texas, !ne.,
Bayport, Texas.
Instrument air lnstrument air is also a compressed air system, but with a much different task. lnstrument air is used to operate all pneumatic monitoring and controlling instruments in the piping facility. Pneumatic instruments such as control valves, recorders, and indicators require an urtinterrupted feed of air to provide continua! monitoring and operational control. Routed through small-bore pipe and tubing, the compressed air in an instrument air system has been dried and purified to remove all moisture and any airborne particles to prevent damage to the instruments.
CONTROL VALVE MANIFOLDS Controlling the commodity traveling through pipe and equipment and the accessibility of the controlling apparatus are two major concerns in any piping facility. Toe control valve manifold addresses both of these concerns. Toe control valve manifold, or manifold control station, is a series of valves and fittings that make use of an automatic valve to control and monitor the flow of a commodity through the pipe. Por convenience
PIPE DRAFTING ANO DESIGN
261
CONTROL VALVE MANIFOLDS
FIGURE 12.3
FIGURE 12.2 Control valve manifold. Courtesy of Nisseki Chemical Texas, lnc., Bayport, Texas.
and accessibility, the control valve manifold is usually placed 2'-0 off the ground or 2'-0" above the floor of a platform. Toe photograph in Figure 12.2 shows a typical control valve manifold arrangement. Notice the different types of valves used in manifold control station shown in Figure 12.2. Four different valves are used in the typical control valve manifold. Toe main valve in the center of the configuration is the control valve. It has a throttling body type, typically a globe or similar body type, and uses a pneumatic or hydraulic actuator to automatically regulate the commodity's rate of flow. Toe valves installed to the right and left of the control valve are called block valves. A block valve is just a descriptive name given to the gate valves that are used to stop the flow of the commodity through the control valve duríng times of repair or replacement. When the block valves are closed and the control valve is removed, the commodity must still be regulated. This is done via a bypass valve. Toe bypass valve is either a globe, plug, or ball valve body style located 11
Control valve manifold drawing.
on the horizontal bypass line found above the control valve. Toe bypass line ties the left and ríght sides of the manifold station together. Toe bypass valve, which is one line size smaller than the main pipe, is normally closed and is installed as close as possible to the inlet side of the manifold. When the block valves are closed, the bypass is opened to allow the flow to circulate through the manifold, thus performing the same function as the control valve, the only difference being that the bypass valve is manually operated. The fourth valve type is the drain valve. lt is the small valve shown below the left reducer. The drain valve is opened after the block valves have been closed and before the bolts have been loosened on the flanges that sandwich the control valve. Toe drain allows the commodity trapped below the two block valves to be captured and disposed of without a spill occurring. Figure 12.3 depicts the graphical representation of the control valve manifold shown in Figure 12.2. When drawing the plan view of a control valve manifold on a piping arrangement drawíng, minimal information is provided. Figure 12.4 shows the plan view of a typical control valve manifold. Notice only the overall length and the centerline elevation are provided. An instrument bubble is shown to aid in the identification of the control valve. Handwheel orientation of the block valves must be shown so representation can be made on isometric drawings. If, for
PIPE DRAFTING AND DESIGN
262
12. PIPIKGSYSTEMS
clearance purposes, handwheels of the block valves are oriented with an offset angle, the angle of offset must be shown on the arrangement drawing. Control valve manifolds can have various configurations depending on the placement of the block valves. Care must be taken to orient the handwheels away from the equipment and other obstructions. When larger pipe sizes are used, valve handwheel lengths can become quite long. Avoid orienting handwheels into
4'-3 1/8" co
co
+ 11,
FIGURE drawing.
12.4
Control valve manifold on piping arrangement
aisleways, roadways, and exchanger tube-pulling zones Figure 12.5.
UTILITY STATIONS Organization is essential to quality design. Organizing a piping facility with maintenance in mind is crucial to efficient plant operation. Small independent maintenance centers called utility stations are located throughout a piping facility. Utility stations provide maintenance and operational personnel with centralized locations to find water, air, steam, and occasionally nitrogen. Utility stations are placed throughout a facílity in such a manner to allow a utility hose 50'-0" long to cover designated areas. A typical utility station is shown in Figure 12.6. Water and steam are typically found only at utility stations located at grade level. These utilities are necessary for equipment that must be washed or steamed clean. Utility air is a service required at all stations in areas where pneumatic power tools are used. Manways are located at the hígher elevations of vertical vessels. Utility stations must be positioned so utility hoses can easily reach them. Nitrogen may be required in specific areas where instrument lines must be purged during times of maintenance or repaír, Figure 12.7 represents a typical utility station as it may appear on a piping arrangement drawing and
6"
4"
6"x4"
RED. TEE
RED. TYP. FIGURE 12.5
Control valve manifold, alternate configuratíon.
PIPE DRAFTING ANO DESIGN
263
METERRUNS
Figure 12.8 depicts the same utility station in an ísometric view.
METERRUNS
FIGURE
12.6
Utility station. Ccurtesy of Nisseki Chemical Texas,
lnc., Bayport, Texas.
INSTRUMENT (
l
AIR
PLANT AIR SERVICE WATER LP
STEAM
.
Developing a piping system that incorporates smooth and consistent flow characteristics is imperative in any piping facility. Toe ability to measure the rate of flow of a commodity is necessary at various stages throughout a facility. Rate of flow is simply a measurement of the amount of commodity flowing through a pipe in a specified amount of time. Toe most common way to achieve this is through a section of pipe referred to as a meter run. A meter run is the name gíven to a straight run of pipe that uses a set of orifice flanges to measure the rate of flow. Recall from the discussion in Chapter 4, orífice flanges have valve taps that allow monitoring equipment to be attached, which records the differential pressure of a commodíty traveling through an orífice plate (see Figure 12.9). Toe critica! part of a meter run is the orifice plate. Toe orífice plate is a 'W' thick, flat, circular disk, made of metal, havíng a flat handle (see Figure 12.10). The orífice plate, with a gasket on either side, is sandwiched between two orifice flanges. An exploded view of an installed orífice plate is shown in Figure 12.11. As you can see, a hole is machined through the center of the plate to
23-IA12-2"
1 11
24-PA12-2"
¡¡:
25-W12-3"
1 :
26-S15-3
1
1:
" -IH 11 I 11
1
¡
1
,'ir
11
111 II 1 1'-0" g" 7" 7" 1
UTILITY
No. FIGURE 12. 7
Utility station on piping arrangement drawing.
PIPE DRAFTING AND DESIGN
STATION
1
2"1H
264
12. PIPJ1'G SYSTEMS
'o l
i.n
'o
1
;,..
UTILITY STATION No. 1 FIGURE 12.8 Utilitystation in isometric view.
FIGURE 12.9 Oríficeflangeswith instrumentation. Courtesy of Nisseki Chemical Texas, lnc., Bayport, Texas.
FIGURE 12.10 Oríficeplate.
PIPE DRAFI1NG AND DESIGN
265
METERRUNS
ORIFICE FLANGES
FLANGE FIGURE 12.11
lnstalled orífice plate.
FIGURE 12.12
Meter run pipe lengths.
TAPS
allow comrnodity to pass through. This hole is approxímately 75% of the cliameter of the pipe. Toe size of the hole in the orífice plate, relative to the size of the pipe, is known as the beta factor. Depending on the application, numerous beta factors can be used. However, 0.75 is the one most comrnonly used in meter run calculations. By attaching monitoring equipment to the valve taps, the rate of flow of the commodity can be measured as flow travels along the pipe and through the orífice plate. To receive the most accurate reading possible, turbulence within the pipe must be kept to a minimum. Flow turbulence is created by obstructions in the configuration from items such as fittings and valves. A smooth, consistent flow is created by providing a sufficient amount of straight pipe before and after the orífice flanges. Therefore, the length of the run of pipe
ORIFICE
PLATE
before, or upstream of, the orífice plate and the length of the section of pipe after, or doumstream of, the plate is precisely calculated. These upstream and downstream measurements are established by using precise lengths of pipe that are based on the diameter of the pipe being used. Additional factors also affect how these lengths are calculated. For example, a different beta factor can be used or a multiplane pipe configuration before the orífice plate may be required. However, a general ruleof-thumb formula of 30 pipe diameters upstream and 6 pipe diameters downstream provides adequate distance to create smooth flow in the meter run. A graphical representation of the values used to calculate these lengths is shown in Figure 12.12. To calculate the lengths shown in Figure 12.12, simply multiply the upstream and downstream diameters times
PIPE DRAFTING AND DESIGN
266
12. PIPIKGSYSTEMS
the nominal pipe size. Toe following is an example to calculate the upstream and downstream pipe lengths for a meter run installed in a 6 pipe configuration. 11
Upstreamdistance=30(diameters)x6' = 180' = 15'·0' Downstreamdistance= 6(diameters)x6' = 36' = 3'-0"
Again, the formula above is a rule-of-thumb guide. Specific values for upstream and downstream diameters vary dependíng upon the configuration of the piping system in which the orifice flanges are installed. Review the client's specifications for the project you are working on to verify the correct upstream and downstream diameters.
SEWER ANO UNDERGROUND PIPING SYSTEMS
Though they are not readily visible, extensive piping systems can exist below grade. Sorne piping systems by their very nature must be run underground. Others are placed there as a matter of convenience. Although they both are placed below grade, there is a difference between underground sewer and piping systems. The main difference is that sewer systems are gravity flow and have an origin that is open to atmosphere, whereas underground piping systems are closed systems that have a defined and constant pressure.
Sewer Svstems Underground sewer systems are designed for a number of commodities. They may include sanitary and raw sewage lines, storm and firewater drains, or process waste runoff and oily water sewers. Storm and firewater drain lines are often run separately for those systems that will carry raw sewage and corrosive chemical wastes. Oily water sewers collect oily waste
and residue from compressors, pumps, and other equipment. Each commodity requires special treatment and therefore must be routed to different treatment facilities. Because they are gravity flow, these systems are generally fabricated using no pipe smaller than 4" in diameter.
Underground Piping Systems Many lines, not related to sewer systems, are routed either entirely or partially below the ground, or Grade. Toe commodities in these pipes could be cooling water, firewater, feed supply, hazardous waste materials, and others. Hazardous waste maierials are feed by-products that do not conform to the client's critica! product specifications or parameters and therefore require special treatment prior to disposal. Hazardous waste materials are often generated during a unit's start-up or shutdown. They are typically nonrefinable rernnants of the feed that are unusable, even with further refining. To prevent frequent replacement of piping components in underground systems, commodities flowing through underground pipes may be only slightly corrosive or the pipes themselves may have special corrosion allowances to accommodate the commodities flowing through them. Whichever application exists, the corrosion of exposed metal surfaces below the ground is always a matter of concem. When an exposed metal surface líes in moist or salt-laden soil, galvanic corrosion begíns to occur. Any number of factors may cause a small amount of electrical current to flow through the soil and onto the pipe. When electric current discharges into the soil, metal is removed from the surface of the pipe and the corrosion process begíns. To protect these underground metal surfaces, cathodic protection systems are used. Cathodic protection employs the use of positively charged electrodes being sent down a long, metal rod, to neutralize the corrosive effects of negatively charged particles in the Earth.
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CHAPTER 12 EXERCISES
CHAPTER 12 REVIEW QUIZ 1. What are plant utilities?
7. What is the function of a control valve manifold?
8. List the four types of valves used in a control valve manifold.
2. Name five water systems that can be found in a
piping facility. 9. What is a utility station?
3. Define superheated steam.
10. What is a meter run?
4. What is a steam trap?
S. What is the minimum distance a fiare stack can be installed next to other pieces of equipment?
CHAPTER 12 EXERCISES Exercises: Meter Run Calculations
6. Explain the difference between utility air and instrument air.
Exercise 12.1. Calculate the missing dimensions for the meter run configurati.ons shown. Use the designated size and pound ratings, Show all answers in feet and inch values.
PIPE DRAFTING AND DESIGN
268
12. PIPJ1'G SYSTEMS
EXERCISE 12.1 CALCULATIONS
(])
EXERCISE 12.1
Meter run length cakulations.
PIPE DRAFI1NG AND DESIGN
CHAPTER
13 Piping Isometrics
WHAT IS AN ISOMETRIC? An isometric is a type of three-dimensional drawing known as a pictorial. lsometrics, or isos as they are commonly called, are developed using the three primary dimensions of an object: height, width, and depth. Unlike orthographic drawings that represent the height, width, and depth dimensions in separate views (see Figure 13.1), the isometric combines the three dimensions of the object into a single view to provide a pictorial representation of the object (see Figure 13.2). To include the height, width, and depth dimensions in a single view, an isometric must be drawn on axes that measure 30° from the horizontal plane, as shown in Figure 13.2. Like the front, Top, and Right Side views in Figure 13.1, Piping Plans, Sections, and Elevations offer limited visualization of an object, especially when piping components
like fittings, flanges, or valves are incorporated. However, by combining the height, width, and depth dimensions found on Plan, Section, or Elevation views, a single pietorial view can result in a drawing that provides greater clarity of the piping configuration. A comparison between the orthographic views shown in Figure 13.3 and the isometric in Figure 13.4 demonstrates that an isometric with piping symbols is obviously clearer and easier to understand than standard orthographic views. Toe piping isometric is an important drawing that serves severa! purposes. It is the primary source for material takeoff of each pipe configuration in the facility. Material Take-offis the process by which each individual component that makes up a pipe configuration is tabulated for purchase or procurement. This means all piping components (elbows, flanges, nuts, bolts, washers, gaskets, etc.) must be counted so that purchases of those
TOP VIEW r-WIDTH
HEIGHT
._____A_l FRONT VIEW FIGURE 13.1
Orthographic views.
A R. SIDE VIEW FIGURE 13.2
269
Isometric view.
C, 2012 Ebcvicr
lnc. Ali rights rcserved.
270
13. PIPING ISO:v!ETRICS
t
'
N
TP4
SOUTH ELEVATION FIGURE 13.3
EAST ELEVATION
Piping orthographic views.
;t("
S
FIGURE 13.4
DN
E
Pipíng isometric view.
items can be made. The tabulated results are referred to as the Bill of Materials, or BOM. lsometrics also serve as fabrication drawings. Once drawn and properly dimensioned, isometrics are provided to fabricators who build each piping configuration. Fabricators will use the
completed isometrics to build shop spools. Shap spools are detailed specifically for pipe welders and fitters with precise cut-lengths and weld symbols, which are not typically shown on isos. After configurations are fabricated, X-rayed, painted, and shipped to the construction site, isometric drawings serve as an aid to the construction and erection of the facility by providing workers with the locations of tie-ins, connections, and routings. Most engíneering and construction companies develop a piping isometric of every pipíng configuration to be installed in the facility.Piping isometrics are typically ereated single-line regardless of the pipe's nominal size. Each pipe line is drawn or plotted individually on a sheet of paper with its tabulated BOM. Pipe isometrics are also drawn as a schematic, which means they are not drawn to scale. One common isometric symbol for fittings, flanges, and valves will represent ali sizes of pipe. No attempt is made to represent a pipe's actual síze or pound rating graphically. This information is conveyed through the use of callouts and notes, particularly the line number, placed on the drawing. Although piping isometrics are not drawn to scale, drafters should make every effort to draw them proportionally. Drawing an iso proportionally simply means one should draw a 10'..(J' run of pipe twice as long as a 5' ..(J' length of pipe, when possible. To be successful in drawing isometrics, the pipe drafter must be able to interpret the information conveyed by the drawing symbols of fittings, flanges, or valves represented on piping arrangement, section, and elevation drawings and transfer that information to the isometric. Note in Figures 13.3 and 13.4 that the elbow symbols differ in the orthographic and isometric views. Piping symbols used on plan, section, or elevation drawings dictate whether a pipe turns left, right, up, or down. When the pipe represented on an orthographic drawing makes a change in direction, that change must also be reflected on the isometric drawing. The point at which the pipe changes direction can be referred to as the tuming point (TP). To correctly draw the isometric representation of a pipe shown on a plan, section, or elevation view, the pipe drafter must be knowledgeable in the use of piping symbols used in orthographic views and the corresponding symbols used on isometric views. To make pípíng isometrics look standardized, companies that hand-draw isometrics use drawing paper that has preprinted isometric grid lines that are used as a drawing aid to establish uniform sizes for fitting, flange, and valve symbols. Remember pípíng isometrics are not drawn to any particular scale. No matter what size or pound rating the fittings are, they are all drawn the same size. Figure 13.S shows the size and shape of manually drawn isometric symbols for fittings, flanges, and valves relative to the isometric grid. These symbols are typical of industry applications and should be used as a guide when drawing piping isometrics.
PIPE DRAFTING ANO DESIGN
271
WHAT IS AN !SOMETRJCI
ISOMETRIC ELBOWS 90.LR
GRID FLOW
ARROWS
NOZZLES
90'SR
FLAN GES
VALVES 45'
GATE
TEES STRAIGHT
REDUCING
CHECK
REOUCERS CONTROL CONCENTRIC
PRESSURE SAFETY VALVE ECCENTRIC
FIELD
SUPPORT WELD
CAP DUMMY
SUPPORT FIGURE 13.5 Isometricpiping symbols.
PIPE DRAFilNG AND DESIGN
1 / 4"
272
13. PIPING ISO:v!ETRICS
1.
DRAFTING
SETIINGS:
2.
·~111
ISO GRID = . 125" SNAP = .0625"
3.
:~ .
ROTATE OBJECT FIGURE 13.6 • • • •
.
~
4. .
. · .
BASE PT.
-30" ABOUT
BASE PT.
CREATE BLOCK: BLOCK NAME = GATEVALVE
Creating isometric piping symbols using AutoCAD.
Step l. Drawing setup. Set the SNAP Style to Isometric. Set the vertical spacing to 0.12s•. Set SNAP to 0.062s•. Step 2. Using the isometric grid as a guide draw the desired symbols. Step 3. ROTATE each symbol -30° about a centralized point (Base Point in Step 3 illustration). Step 4. Crea te a BLOCK of each symbol. Use a name that accurately describes the component. Selecta Base Point that will permit convenient attachment to other components in an isometric.
lsometríc symbols drawn with AutoCAD can be developed so that a single orientation of the symbol can be used in any of the isometric axes. lsometric symbols can be drawn, rotated, and BLOCKed for repeated use in any drawing at any isometric angle. Initially symbols for fittings, flanges, or valves are drawn on the north/ south isometric axis, but befare they can be used in the other isometric axes, they must be rotated -30º about a Base Point placed on the center of the symbol. Use the step-by-step procedures provided below and illustrated in Figure 13.6 to create isometric pípíng symbols using AutoCAD commands. Figure 13.7a,b show the size of the symbols relative to the isometric grid in AutoCAD. Companies that use 3D plant modeling software use the software's feature that automatically generates isometrics of the modeled pipes. Isos generated by modeling programs are fully dimensioned, including notes and callouts, and have a completed BOM. lt is common however that revisions be made to those isos to reflect client design requirements and drawing enhancements.
ISOMETRIC ORIENTATION Note in Figures 13.1 and 13.2 how the height, width, and depth dimensions of the L-shaped object in the orthographic views are oriented on the isometric view with A as a point of reference. By using a point of reference, proper orientation of the isometric can occur
by transferring distance and direction from the orthographic view. Similarly, on piping isometrics, establishing a point of reference is imperative. Although the A can be seen in Figures 13.3 and 13.4, it is not an adequate point of reference. Toe complexity of pípíng configurations requires a more descriptive "point of reference" be used to establish orientation between the orthographic and isometric views. In the piping discipline a north arrow is used as a "point of reference." Accurate isometric layout is based on the correlation of the orientation of the north arrow on the Piping Arrangement drawing and the north arrow on the piping isometric. Figure 13.8 illustrates the representation of the north arrow on the arrangement drawing and the north arrow on the isometric. Knowing that the Píping Arrangement drawing is a plan, or top, view drawing, a pipe can be determined to be turning north, south, east, or west when oriented relative to the drawing's North Arrow. So, if a pipe that has been traveling north turns down and then east on the arrangement drawing, it should also be shown to travel north, turn down, and then east on the isometric drawing. Figure 13.9 illustrates the correlation between pipe components shown in a Plan View and those same items in an isometric view. As you may notice, items that can be difficult to visualize on the Plan View drawing become much more evident on the isometric. Most companies prefer to draw piping isometrics with the north arrow pointíng up and to the right, An alternate position is to draw the North Arrow pointing
PIPE DRAFTING ANO DESIGN
273
ISOMETRIC ORIENTATION
(a)
DRAW AS SHOWN BELOW GRID IS .25 ISO-GRID BASE POINT INDICATED AS
<+)
CAD SYM BOLS ELBOWS 90-LR
90-SR
45·
TEES
REDUCERS CONCENTRIC
ECCENTRIC
WELD CAP
FIGURE 13. 7 (a,b) AutoCAD isometric piping symbols,
PIPE DRAFTING AND DESIGN
ROTATE -30" ABOUT INSERTION BASE POINT BEFORE MAKING WBLOCKS
274
13. PIPING ISO:v!ETRICS
(b)
DRAW AS SHOWN BELOW GRID IS .25 ISO-GRID BASE POINT INOICATED AS (
CAD ) SYMBOLS FLOW ARROWS
NOZZLES
FLAN GES VAL VES
GATE
GLOSE
CHECK
CONTROL
PRESSURE SAFETY VALVE
FIELD SUPPORT
DUMMY SUPPORT FIGURE 13. 7
(Continued}
PIPE DRAFTING ANO DESIGN
ROTATE -30º ABOUT INSERTION BASE POINT BEFORE MAKING WBLOCKS
DRAWU,:G PIPING ISOMETRICS
N~J~E
275
w~s
DN
.
FIGURE 13.8
Orthographic and isometric north arrows .
• FIGURE 13.10
FIGURE 13.9
Isometric orientation.
up and to the left. This is done, however, only in exceptional cases to improve drawing clarity. Figure 13.10 uses the configuration from Figure 13.9 to demonstrate how drawing an isometric with the North Arrow pointing up and to the left will affect the isometric representation. The North Arrow rarely, if ever, points down.
DRAWING PIPING ISOMETRICS As an isometric for a particular line is developed, constant reference to the Piping Arrangement, Section, or Elevation drawings is essential. Drawing symbols, callouts, coordinates, and elevations provide detailed information of the pipe's configuration and routing as it travels through the facility. By using this information and the isometric symbols that correspond to the various orthographic drawing symbols, the pipe drafter
Alternate isometric orientation.
can develop an isometric describing the pipe's routing. Remember, the isometric must provide a detailed description of the pípe's routing from beginning to end. However, this does not apply to a pipe in a pipe rack. Piping isometrics are generally drawn to represent the configuration up to and including the first fitting in the pipe rack. Use the procedures that follow to develop a pípíng isometric of line 01-2-C30-10"-IH. As shown in Figure 13.11, line Ol-2-C30-10"-IH is attached to vessel V-101, at nozzle Nl, and reboiler E-101 at nozzle C. The line begíns, relative to the flow direction, at nozzle Nl with a flange and elbow welded together, fitting makeup. The elbow is oriented toward the north, according to the North Arrow. Therefore, as seen in the isometric view in the upper ríght, if line 01-2-C30-10''-IH turns north on the arrangement drawing, it must also turn north on the iso. To determine the distance a pipe travels in the north direction, or any other horizontal plane, one must use two coordinates. Remember, horizontal dimensions are calculated using coordinates and vertical dimensions are calculated using elevations. So, if there were a need to determine the distance a pipe travels in a vertical plane, a drafter would need one of the following: elevation callouts (found on the plan view drawing) or an elevation drawing that graphically depicts the amount of vertical change. Also, recall elevation changes can be shown on the Piping Arrangement drawing in the form of callouts, but the elevation callouts must be adequate enough to determine the length of the pipe traveling in the vertical plane.
PIPE DRAFTING AND DESIGN
;+("
.,,, N
©
S
DN
E
01-2-C30-10"-IH 10·-a·
01-V-101 W.26'-0"
PLAN
-+ 1
01-V-101 01-E-101 ---
01-E-101
EL 1 os· -o\ . ................,.._....._, ..,_,.__._ ~ -~0""-1-2=f30-10" -IH EL.102'-3" 100·-o·
EAST ELEVATION FIGURE 13.11
Line 01-2-C30-10"-IH.
NORTH ELEVATION
DRAWU,:G PIPING ISOMETRICS
After the north run, an elbow turns west and line 01-2-C30-10"-IHtravels below reboiler E-101. Note the elbow is also shown turning west on the iso. When the pipe aligns with the centerline of E-101, another elbow tums the line up and into nozzle C. lsometric drawing symbols for 90° and 45° elbows are typically shown with square comers, as opposed to the round comers
FIGURE callouts.
13.12
FIGURE 13.13
Line 01-2-C30-10"-IH with
dimensions
and
277
found on arrangement drawings. However, it is not unusual for sorne companies and CAD software and 3D modeling packages to draw elbow symbols with round corners. Note also the equipment nozzles are drawn double-line on isos, to distínguish them from flanges and valves. Other important details about line 01-2-C30-10''-IH that must be represented on the iso are shown in Figure 13.12. They indude intersecting coordinates for the center of the equipment, nozzle elevation, nozzle number, nozzle projection, and the name/ number of the piece of mechanical equipment. In addition to ali the information shown, if a nozzle on one end of the configuration happens to be of a different size and pound rating than the rest of the pipe its mating flange is considered to be ouiofspec,and that information must also be shown on the isometric, near that particular nozzle. Toe alignment and orientation of written information (name, coordinates, elevation) about a vessel and/ or nozzle on an isometric are sometimes confusing. Toe four labeling examples in Figure 13.13 indicate that callouts for North and South centerline coordinates are actually written on centerlines running in the east/west direction, while East and West centerline coordinates are labeled on centerlines that run in the north/south direction. To better understand this concept, remember that coordinates measure the distance an object is from the 0'-011, 0'-011 origin, So, if a vessel is 30'-011 east of the 0,0 origin it must have a centerline coordinate índícatíng its geographic direction and lineal distance. However, proper piping isometric labeling techniques require that it be written along the north/ south axis so that it can be read properly. Toe E. 30'0" coordinate indicates a 30'-011 distance in the east direction, although
Isometric orientation and labeling of vessel centerlines.
PIPE DRAFTING AND DESIGN
278
13. PIPING ISO:v!ETRICS
it's written along the north/south axis. As a reminder, all mechanical equipment, structural colurnns, foundations, etc. require two intersecting centerline coordínates to locate their exact position.
drawing with AutoCAD. To achieve the proper obliqu ing and rotation angles required on CAD generated isometrics, create the text styles outlined in the following procedures and demonstrated in Figure 13.16.
ISOMETRIC DIMENSIONS, NOTES, ANO CALLOUTS
ISOMETRIC OFFSETS
lsometric Dimensions Length dimensions, in addition to informational notes and callouts, are used on isometrics to define the pipe's exact routing through the facility. Placement of dimensions on the drawing establishes precise lengths between fittings, valves, equipment connections, etc. Numerous pieces of important information from Piping Arrangement drawings, Sections, Elevations and vendor drawings are used to calculate dimensions on a pipe isometric. These include such items as centerline coordinates, nozzle elevation and projection, and pipe size and pound rating. Toree types of dimensions exist on an isometric, they are center-to-center, centerto-face, and face-to-face. Figure 13.12 provides dimensions for line 01-2-C30-10"-IH usíng information found on the Plan and Elevation views shown in Figure 13.11 and the equipment vendor drawings found in Chapter 10, "Piping Arrangement Drawings, Sections, and Elevations." Placing dimensions on a piping isometric with AutoCAD requires the use of the Aligned and Oblique options within the DIMENSION command. Figure 13.14 provides two options for placíng dimensions on piping isometrics. Dimensions should be aligned with the routed pipe and "obliqued" as shown in Figure 13.15.
Isometric offsets are formed when a pipe turns at any angle other than 90°. Angular offsets can be created by rolling a 90° elbow at any angle or replacing 90° elbows with 45º elbows. Toe result would be pipes that no longer travel north, south, east, west, up, or down. Instead lines would run northwest, northeast, southeast, or southwest. They could also slant upward or downward. Three examples of isometric offsets are shown in Figure 13.17. Dimension lines and callouts are included as a reference. To establish proper visual orientation, the indication of horizontal (H) or vertical (V) angles are included on all isometric offsets. Forty-five degree
Isometric Notes and Callouts
FIGURE 13.14
Dimensioning placement options.
Dimensions alone cannot provide all the information required to properly describe a piping isometric. Notes and callouts placed on the drawing provide significant information that may impact the purchase, fabrication, and erection of the configuration. Appropriately placed notes are used to denote the size and pound rating of fittings, flanges, and valves, as well as insulation type and thickness, locations for pipe guides, anchors, or supports, and offset angles of pipe. Callouts stipulate instrumentation locations and size, specification breaks, piece marks, and other fabrication details. Any information that is pertinent to a particular pipe must be conveyed on the isometric. Whether writing dimensions, notes, or any other information on an iso, all written information should remain on one of the isometric axes and be inclined to the ríght, This task becomes a little more difficult when
FIGURE 13.15
Aligned and Oblique dimensions.
PIPE DRAFTING AND DESIGN
279
ISOMETRIC OFFSETS
ISOMETRIC 0/MENSIONS ANO TEXT CALLOUTS DEVELOP TWO TEXT STYLES FOR ISOMETRIC DIMENSIONS AND CALLOUTS USING THE FOLLOWING VALUES: ,
CREATE íSOTEXT-!" HAVINC AN OBLIOVINC ANCLE OF JO'.
,
CREATE íSOTEXT-2" HAVINC AN OBLIOVINC ANCLE OF -JO'.
NOTE: AS TEXT IS PLACED IN VARIOUS POSITIONS ON THE ISOMETRIC, ADJUST THE ROTATION ANGLE AS INDICATED IN THE FIGURE TO THE LEFT TO CORRESPOND TO THE DESIRED TEXT ORIENTATION.
FIGURE 13.16 Creating isometric dimensionsand text. • Step 1. Use the STYLEcommand to create two different text styles. Use the style names ISOTEXT-1 and ISOTEXT-2 for easy reference. • Step 2. When creating ISOTEXT-1, set the obliquingangle to +30°. For ISOTEXT-2 set the obliquingangle to-30°. • Step 3. Depending on the ISOPLANE being used, set the rotation angle in the TEXT command to the appropriate setting as represented in Figure 13.16.
elbows must always be labeled on an iso for material takeoff purposes. Figure 13.17 represents only three of the many offsets that can be created using 90º and 45º elbows. Example A of Figure 13.17 begins with a line traveling north. A 90º elbow is rolled downward and toward the east at a 45° angle, then another 45° elbow is required to return the angular offset back into a due easterly direction. This example is labeled as a vertical offset because a change in elevation occurs when the 90º elbow is turned downward. Example C is also a vertical offset, but note there is no change in the geographic direction the pipe travels. Here, two 45° elbows are used to angle the pipe upward while continuing in a northerly direction. Both elbows are 45º, thus the inclusion of the abbreviation TYP, meaning "typical" is added to the "45° ELL" callout. Example B demonstrates how
horizontal offsets are created. As with example C, two 45° elbows are used, but rather than turning the elbows upward, they are laid on their side, thus remaining in a horizontal plane. There is no change in elevation.
Dimensioning Offsets With isometric offsets changing a pipe's routing from one plane to another or from one geographic direction to another, coordinates and elevations no Ionger provide all the dimensions necessary to describe a pipe's total length. However, the use of 90º and 45° elbows to form the offsets results in a problem that can be easily solved with simple mathematical formulas. Toe 90º and 45° elbows form right triangles. By usíng the Pythagorean theorem which states that the sum of the squares of the two sides is equal to the
PIPE DRAFTING ANO DESIGN
280
13. PIPING ISO:v!ETRICS
/
N
A FIGURE 13.17
B
e
Isometric offsets.
Multi ..angle Offsets
B A FIGURE 13.18
C=V A2 +82 A=VC2-B2 B=V c2-A2
Pythagorean theorem formulas.
square of the triangle's h~otenuse, this problem can be solved. Simply stated, A + B2 = C2• Figure 13.18 identifies the sides and angles of a ríght triangle and their resulting solution formulas. These formulas can be used to solve the length of an unknown side when the other two sides are known. They work no matter the degree value of angle X. Sorne angles seem to be used repeatedly in pipe drafting. The chart in Figure 13.19 can signíficantly reduce the amount of time spent calculatíng unknown sides of right triangles. Use the appropriate decimal value when X is one of the provided angles. As mentioned previously, 90º elbows can be rolled to form any degree of angular offset. To fabricate such a roll, a pipe fitter should be provided with the lengths of the three sides of the triangle and the degree value of angle X. Solving for an unknown value of X requires sorne additional trigonometric formulas. Use the formulas provided in Figure 13.20 to solve for the unknown value of angle X. Notice that, relative to X, side A is identified as the Side Adjacent (SA), side B is identified as the Side Opposite (SO), and side C is identified as the Hypotenuse (HYP).
Elbows are not the only piping components installed in angular positions. Because of the arangement and orientation of trays inside a vessel, and obstructions such as ladders, platforms, and cages outside the vessel, nozzles are placed in locatíons where they can add or extract commodity from the vessel and not hit an obstruction with painstaking accuracy. As a result, nozzles oriented at angles of 10º, 20º, 35º, etc., are not uncommon. When offset or rolled elbows are added, complex math problems often result. Multi-angle configurations, such as the one in Figure 13.21, require additional calculations to determine dimensions for each of its lengths. We have already seen how unknown lengths can be solved using right-tríangle formulas. The key to solvíng the unknown length dimension in Figure 13.21 is the incorporation of right triangles. Remember, drawing space is limited. Excessive notes, callouts, and dimensions are not practica! on Piping Arrangement drawings. As with traditional isometric dimensions, right-triangle dimensions are aligned so their lengths establish center-to-center measurements, that is, centerof-vessel, to center-of-elbow, to center-of-vessel. So, the length of the unknown dimension can only be solved by using the limited information available in Figure 13.21. Figure 13.22 demonstrates the way to position three right triangles to solve for the "unknown" dimension, marked as "?" in Figure 13.21. Numbering the triangles will aid in the discussion that follows concerning the solution to the lengths of the sides of each triangle. The "unknown" dimension, "?," is equivalent to the hypotenuse of triangle 3. Begin by determining the known values for each of the triangles from the information provided in Figure 13.21. Figure 13.23 shows the known values of triangles 1, 2, and 3 placed in their appropriate locations.
PIPE DRAFTING ANO DESIGN
281
ISOMETRIC OFFSETS
RIGHT TRIANGLE MULTIPLICATION FACTORS
~B
A
WHEN MULTI- WHEN WHEN WHEN WHEN WHEN YOU PLY 'x' IS 'x' IS 'x' IS 'x' IS 'x' IS KNOW SIDE SIDE
TO FINO SIDE
e e
A B B
A A B B
FIGURE 13.19
e A e
Ax Bx Bx Cx Ax Cx
1 5º 30º 45º 60º 75º
1.0353 1.154 7 3.8637 2.0000 3.7320 1.7320 .9659 .8660 .2680 .5773 .2588 .5000
1.4142 2.0000 3.8637 1.4142 1.154 7 1.0353 1.0000 .5773 .2680 .7071 .5000 .2588 1.0000 1.7320 3.7320 .7071 .8660 .9659
Decimal equivalents of common angles.
.e". ~
~
C
B = SIDE OPPOSITE ~O)
A= SIDE(SA)ADJACENT
SA= HYP (eOS X)
SO= HYP (SIN X)
HYP= SA (SEe X)
SA= SO (eOT X)
SO= SA (TAN X)
HYP=
SA SO= eOT X
so SA= TAN X SA= SIN X= FIGURE 13.20
HYP SEe X SO HYP
SO= eOS X=
SA HYP
HYP ese x TAN X= SO SA
Right-triangle formulas.
PIPE DRAFilNG AND DESIGN
so (ese X)
HYP=
so
siNx
SA HYP= eOS X SA eOT X= SO
282
®
13. PIPING ISO:v!ETRICS
14"-150# RFWN NOZZ. PROJ. 4' -9"
N N
USE 1 /8" GASKET
FIGURE 13.22 Locatingright mangles.
FIGURE 13.21 Multi-angleoffsets.
The X angle for triangle 1 is shown to be 20º in Figure 13.21. The 6'-111/8" dimension is the measured length from the center of the vessel to the center of the elbow at Nozzle Nl. This is determined by adding the nozzle projection for nozzle Nl, a gasket, one 14"-150# flange, and a 14" elbow. On triangle 2, the 2' -6" measurement is determined by subtracting the West coordínate of W. 122'-6" from W.125'0''. Toe 5'-7" dimension is established by adding 1h of the OD of the 14" pipe to the 5' --0" dimension. Note there are no known dimensions for triangle 3. However, we must determine the hypotenuse if we are to know the "unknown" dimension. Remember, a mínimum of two values must be known in order to solve the three lengths and the angle of a right triangle. By determining the Side Adjacent (SA) and Side Opposite (SO) of triangle 3, the Pythagorean theorem can be applied to find the Hypotenuse (HYP), the unknown dimension. Using the available formulas, the missing lengths of triangles 1 and 2 must be solved before the sides of triangle 3 can be determined. Notice that by subtracting the SA of triangle 2 from the SA of triangle 1, the SO of triangle 3 can be determined. Also, adding the SO of triangle 1 to the SO of triangle 2 {2' -6") will yield the SA of
2'-6"
FIGURE 13.23 Known values for triangles1, 2, and 3.
triangle 3. The results of these calculations are shown in Figure 13.24. The length of the unknown, "?," dimension is S' -1 Yt/. Angle X of triangle 3 is also an important value to be determined. This angle establishes the rotation angle for the 90° elbows. In the fabrication shop,
PIPE DRAFTING ANO DESIGN
283
ISOMETRIC OFFSETS
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co
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2'-6"
7/ " 2'-4115
PLAN
31 "
1'-6 115 7/ " 4'-10 115 FIGURE 13.24
Solutions for triangles 1, 2, and 3.
the vessel is not available to measure the 5'-0" dimension. Knowing this horizontal angle is the only way the elbows can be accurately welded during the fabrication process in the shop and later installed precisely in the field.
Rolling Offsets Toe cuhnination of multiple isometric offsets is the rolling offset. Toe rolling offset is a compound offset formed by replacing the two 90º elbows, as shown in Figure 13.21, with two 45° elbows. Toe result is an offset that changes elevation and direction simultaneously. Figure 13.25 shows the plan and elevation views of a rolling offset. Because of its complexity, adequate dímensions cannot be placed on the orthographic views that fully describe the rollíng offset. An ísometríc is the best place for representing and dímensíoning the rolling offset, because a simple horizontal or vertical triangle with three dímensions is not adequate enough to fabricate a rolling offset. Incorporating the horizontal and vertical triangles into an ísometric box is the only way to provide all the necessary dímensions and angles needed by welders to fabricate a rolling offset. Figure 13.26 shows construction of the rolling offset box and its accompanying dimensíons and angles. Combining elevational and directional changes compounds the difficulty in representing the rolling offset on an isometric drawing. Visualizing dírectional changes in the plan and elevation views simultaneously requires practice and patience. To aid in this visualization process, sorne helpful notes have been added to the
ELEVATION FIGURE 13.25
Plan and Elevation views of a rolling offset.
plan and elevation views of the rolling offset shown in Figure 13.27. In the plan View, a box has been drawn through the centers of the two 45º elbows that form the rolling offset. Its comers have been labeled northeast (NE), southeast (SE), southwest (SW), and northwest (NW). Toe notes in the elevation view identify upper and lower planes which represent the change in elevation. Remember the Plan view shows north, south, east, west orientations, and the Elevation view depicts vertical changes in elevation. Toe Plan view in Figure 13.27 shows that the pipe enters the box from the southwest comer and travels
PIPE DRAFTING AND DESIGN
284
13. PIPING ISO:v!ETRICS
t
N
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PLAN
VIEW
~UPPER
PLANE
LOWER~ FIGURE 13.26
Rolling offset box.
SOUTH across to the northeast comer where it ends with a flange. Looking at the South Elevation, we can see the pipe begínníng on the upper plane and droppíng down to the lower plane. By combíníng the information from these two views, we know that the pipe begíns in the upper southwest comer and travels down to the lower northeast comer. The resulting isometric representation is shown in Figure 13.28.
ELEVATION
FIGURE 13.2 7 Visualization aids for rollíng offsets.
;t(N
S
DN
E
Dimensioning Rolling Offsets Figure 13.26 identifies the six measurements required to dimension a rolling offset. There are four length dimensions and two angular dimensions. When a rollíng offset is incorporated into a configuration similar to that shown in Figure 13.29, the lengths of the three sides of triangle 3 are applied to the dimensions of the rolling offset box (see Figure 13.26). Note the SA of triangle 3 in Figure 13.29 is equal to the RUN of the rolling offset box, the ROLL of the rollíng offset box is equal to the SO of triangle 3, and angle X of triangle 3 is the same as the horizontal angle (HORº) of the rolling offset box. The RISE is determined by subtracting the lower plane elevation from the upper plane elevation. These two elevations can be found on a section or elevation drawing of the configuration or depicted in the form of notes on the Piping Arrangement drawing. Rollíng offsets are typically fabricated using 45º elbows; therefore, the vertical angle will be 45°. But, 45° to what? Note the dimension labeled TRAVEL in Figure 13.26. It
FIGURE 13.28
Isometric of a rolling offset.
establishes the true length of the pipe from the upper southwest comer to lower northeast comer of the rolling offset box. Naturally, this length is the most difficult to calculate. The values used to determine its length depend on how the pipe enters and exits the rolling
PIPE DRAFTING ANO DESIGN
285
ISOMETRIC OFFSETS
offset box. Figure 13.30 shows the two examples of how a pipe may enter and exit the rolling offset box. These two examples will help us determine what the pipe is 45º to. Note in example A, the pipe enters and exits the rolling offset box in the vertical plane. Example B shows the pipe entering and exiting the box in the horizontal plane. These two methods of entering and exiting the rolling offset box will be used to determine what the TRAVEL is 45° to. When a pipe enters and exits in
SA
the vertical directíon, Example A, a 45° angle is formed between the TRAVEL anda dashed line drawn diagonally across the lower plane of the box (hypotenuse of triangle 3). However, when a pipe enters and exits the rolling offset box in the horizontal direction, Example B, a 45° angle is formed between the TRAVEL and the RUN of the box. Depending on the type, vertical or horizontal, two different 45º right triangles will be formed. Toe TRAVEL of the pipe becomes the hypotenuse for either triangle. Recall that when solving a ríght triangle whose angle is 45°, the SA and SO will always be equal. Therefore, in Example A, the length of the dashed line is equal to the RISE of the box, and in Example B, the dashed line drawn diagonally across the west end of the rolling offset box is equal to the RUN of the box. See Figure 13.31 for a shaded representation of the right triangles formed in Examples A and B. Once the SA and SO lengths of the 45º right triangle are known, the Pythagorean theorem can be used to easily solve the TRAVEL dimension of the pipe. Since 45° is a commonly used angle, Figure 13.19 can be used to make the solution even simpler. Toe chart in Figure 13.32 converts inches and fractions of an inch into decimals. Multiplication and division of fractions are simplified using decimal equivalents. This chart is extremely helpful when performing mathematical calculations on a calculator that is limíted to decimal input only. To use the chart in Figure 13.32, follow the column below the "inch" value down until it is adjacent to the "fraction" value row. Toe number at this intersection is the decimal equivalent of the mixed inch and fraction value, For example, to determine the decimal value of 8 5/8", follow the column below 8 down until it is adjacent to 5/8" (dísplayed in the "Fraction" column). 11
FIGURE 13.29
Rolling offset with right triangle.
~
1
A FIGURE 13.30 Vertical and horizontal pipe entering and exiting the rolling offset box. PIPE DRAFTING AND DESIGN
286
13. PIPING ISO:v!ETRICS
A FIGURE 13.31
Right triangles created with TRAVEL length as hypotenuse.
FR
DECIMALS
"e
1,
·~
ON
1/16" 1/8" 3/16" 1/4"
O"
1"
2"
3"
4"
5"
OF 6"
FOOT
A 7"
8"
9"
10"
11 "
.0000 .0833 .1667
.2500 .3333 .4176 .5000 .5833 .6667 .7500 .8333 .9167
.0052
12" t
,.el
NS
DECIMALS OF AN INCH
----
.0085
.1719
.2552 .3385
.4219 .5052 .5885
.6719
.7552 .8385
.9219
1/16"
.0625
.0104 .0937
.1771
.2604 .3437
.4271 .5104
.5937
.6771
.7604
.8437
.9271
1/8"
.1250
.0156
.0990
.1823
.2656 .3490
.4323 .5156
.5990 .6823
.7656
.8490 .9323
3/16"
.1875
.0208 .1042
.1875
.2708
.3542
.4375 .5208
.6042
.6875
.7708
.8542
.9375
1/4"
.2500
5/16"
.0260
.1093 .1927
.2760
.3594
.4427 .5260 .6094
.6927
.7760
.8594
.9427
5/16"
.3125
3/8"
.0312
.1146
.1979
.2812
.3646
.4479 .5312 .6146
.6979
.7812 .8646
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3/8"
.3750
7/16"
.0365
.1198 .2031
.2865
.3698 .4531 .5365
.6198
.7031
.7865 .8698 .9531
7 /16"
.4-375
.3750 .4583 .5417
.6250
.7083
.7917 .8750
1/2"
.5000
1/2"
.0417 .1250 .2083 .291i
.9583
9/16"
.0468 .1302 .2135
.2969 .3802
.4635 .5469
.6302
.7135 .7969 .8802 .9635
9/16"
.5625
5/8"
.0521 .1354 .2187
.3021
.3854
.4687 .5521
.6354
.7187
.8021
.8854
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5/8"
.6250
11/16"
.0573 .1406 .2240
.3073
.3906 .4740 .5573 .6406
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.8073 .8906
.9740
11/16"
.6875
3/4"
.0625
.1458
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.3958
.4792 .5625
.6458
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.9792
3/4"
.7500
13/16"
.0677
.1510 .2344 .3177
.4010
.4844 .5677 .6510
.7344
.8177 .9010 .9844
13/16"
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7/8"
.8750
15/16"
.9375
.2292
7/8"
.0729 .1562
.2396
15/16"
.0781 .1615
.2448 .3281 .4115
FIGURE 13.32
.3239 .4062
.8958
.4896 .5729 .6564 .7396
.8229 .9062
.4948 .5781
.8281
.6615
.7448
.9896
.9115 .9948
Inch to decimal conversion chart.
Toe number at this intersection is 0.7187. Therefore, 0.7187 is the decimal equivalent of 8 5/8". Two appendices at the end of the book provide solution examples of the mathematical calculations Figure 13.32 employs. Use these to have an understanding of
how to convert inches to decimals and vice-versa when Figure 13.32 is not available. If a decimal number needs to be converted into inches, use the chart in Figure 13.32 in reverse. Simply locate the decimal number and then follow the
PIPE DRAFTING ANO DESIGN
287
ISOMETRIC OFFSETS
eolumn up to locate the whole inch value. Toen follow the row to the left or right to determine the fraction value. If the decimal value you are trying to convert does not match a number in the chart precisely, find the decimal
value nearest to your number and proceed. Toe chart provides numbers in 1/16 increments, which compiles with specifications of most of the projects that require dimensions to be given to the nearest 1/16 of an inch.
PIPE DRAFTING AND DESIGN
11
288
13. PIPING ISO~ETRICS
CHAPTER 13 REVIEW QUIZ 1. What is an isometric?
10. What are placed on isometrics to define the pipe's
exact routing through a facility?
11. How are isometric offsets formed?
2. Which three dimensions found in orthographic views are required when drawing an isometric?
12. To establish proper visual orientation, the
3. What is material take-off?
13. State the Pythagorean theorem.
indication of or isometric offsets.
_ angles are included on ali _
14. What are the names of the three sides of a ríght
4. T F Pipe 14 and above is drawn double-line on an isometric. 11
5. T F Multiple pipes are drawn on a single sheet of isometric grid vellum. 6. T F Ali isometrics are drawn to scale to show exact size and pound rating.
triangle?
15. Name the six dimensions required on a rolling off-
set box.
7. T F Lengths of pipe should be drawn proportionally on an isometric. 8. T F Symbols should be drawn different sizes to reflect a change in pipe size. 9. What is the preferred direction to draw the North Arrow on an isometric?
PIPE DRAFTING ANO DESIGN
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294
13. P!P!NG ISOMETR!CS
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Solve for the missing dimensions on the isometric in the following exercise. Show ali necessary dimensions, coordinates, equipment callouts, line numbers, and related information. :z:
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Draw an isometric for the following exercise. Show all necessary dimensions, coordinates, equipmentcallouts, line numbers, and related information.North Arrow direction on the isometric will be up and to the right,
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CI IAPTER 13 DRAWJ?\G EXERCISES
Solve the conversion problems shown. All feet and inches answers are to be rounded to the nearest Yi6" value. Decimal answers are to be written to the fourth decimal place.
FRACTION TO DECIMAL & DECIMAL TO FRACTION CONVERSIONS
CD 12 -2 1116 =
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PIPE DRAFilNG AND DESIGN
13-9
298
13. P!P!NG ISOMETR!CS
Solve the conversion problems shown. Answers are to be written in degree, minute, and second values. Decimal answers are to be written to the fourth decimal place.
DEGREE TO DECIMAL & DECIMAL TO DEGREE CONVERSIONS
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PIPE DRAFI1NG AND DESIGN
299
CI IAPTER 13 DRAWJ?\G EXERCISES
Solve for the míssing dimensions of the right triangles shown. All dimensions are to be written in Feet and Inches, rounded to the nearest Yi6". Write the angular answers in degree, minute, and second values.
RIGHT
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PIPE DRAFilNG AND DESIGN
300
13. P!P!NG ISOMETR!CS
Draw an isometric for the following exercise. Show all necessary dimensions, coordinates, equipment callouts, line numbers, and related information. North Arrow direction on the isometric will be up and to the right,
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EXERCISE
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CHAPTER 13 DRAWING EXERCISES
Draw an isornetric for the following exercise. Calculate the unknown dirnensions and angle for right triangle of the multi-angle offset. North Arrow direction on the isometric will be up and to the right.
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PIPE DRAFTING AND DESIGN
302
13. P!P!NG ISOMETR!CS
Draw an isometricfor the following exercises. Show all necessary dimensions, coordinates, equipment callouts, line numbers, and related information.North Arrow direction on each isometric will be up and to the right.
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PIPE DRAFI1NG AND DESIGN
303
CHAPTER 13 DRAWING EXERCISES
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RATING FACE 150# RF 150#
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PIPE DRAFTING AND DESIGN
EXERCISE
13-15
304
13. P!P!NG ISOMETR!CS
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Solve for the missing dimensions on each of the rolling offset boxes shown. Ali dimensions are to be written in feet and inches, rounded to the nearest 1/16".
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PIPE DRAFTING ANO DESIGN
CHAPTER
14 Building 3D Piping Models Toe use of three-dimensional pipe modeling software continues to have an impact on the design and engíneering of piping projects. Whether they are offshore production platforms or land-based petrochemical complexes, 3D modeling is the preferred method of designing new piping facilities. Sorne of the available 3D pipe modeling software packages are PDMS1, PDS2, CADWorx2, SmartPLANT 302, AutoPLANT3, and PLANT-404•
ADVANTAGESOF 30 MODELING One advantage a 3D model has over conventional 2D CAD drawíngs is an improved ability to demonstrate clearly the thought processes that occur during the design phase of a piping facility. Chemical plants, refineries, offshore production platforms, and other types of piping facilities are very complex. Vast numbers of foundations and supports, steel columns and beams, pipes and piping components, mechanical equipment, and instrumentation devices must be engineered, designed, fabricated and erected before a project is considered complete. Even seasoned designers occasionally find it difficult to organíze the complexities of the project when working with orthographic drawings alone. Multiple disciplines (civil, structural, electrical, instrumentation and electrical, pípíng) have input into a project's development. By using computergenerated three-dimensional models, designers can view the facility from any direction and quickly visualize and understand the intricacies of its design. The plan and elevation views shown in Figures 14.1 to 14.3 sufficiently represent the components in Unit-01. From these three views an experienced designer should be able to "visualize" the appearance of Unit-01. However, 1 Aveva
Group, ple. Corporation. 3Bentley System, Inc. 4CEA Engineering Software. 2Intergraph
justa single rendered pictorial, as shown in Figure 14.4, provides more analytical opportunities than three "flat" drawings do. See Figures 14.1 to 14.4. Furthermore, to increase comprehension, 3D models make it possible to "zoom" closely into crowded and congested areas of a new facility and have immediate understanding of associated piping components and their routing and configuration. If necessary, any interferíng model elements, pipe, mechanical equipment, foundation, or structural support that líes between the viewer and area of concern can be "clipped" or removed by the modeling software. This makes it possible to see "inside" the facility and study its hidden features. Once a 3D model has been developed a virtual tour or "walkthrough" can be created. Walkthroughs hasten client approval and are used as training videos by plant personnel who are responsible for safely maintaining and operating the facility.Toe improved visualization capabilities alone make modeling a piping facility a worthwhile endeavor. Toe ability to forecast potential design or construction problems during the modeling phase can result in tremendous time and cost savings as opposed to discovering and solving the problem later at the job site.
CHECKING FOR INTERFERENCES Another valuable benefit of 3D computer modeling
is the ability to perform interference or clash detection.
Developing models of complex projects is not sornething new to piping designers. For years, plastic models have been built that can take hundreds of hours to construct and may cost thousands of dollars to produce. One of the main reasons these models are built is to verify the fit of all the components in the facility. Duríng the design phase, it is easy to overlook minor details in something as complex as a piping facility. Only by building a physical model can the designers verify that there are no interferences between components (i.e., a pipe passing through a steel support, a beam hitting
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FIGURE 14.2 Unit-01: North Elevation.
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a piece of equipment, etc.). If a design team can detect problems such as these before construction begíns, savíngs in building costs can be enormous. Each problem area redesígned in the fíeld adds substantially to the cost of completing the project. Interference detection features in modeling software work by checking the physícal posítion of the surfaces of each component in a project against other
component's surfaces in the project, Usually a project is organízed into discipline departments such as Pípíng, Structural, and Equipment. This is easy to do because a 3D model is typícally developed making use of the software's layering capability. Sorne software programs will automatically place piping components (fittings, flanges, valves), steel supports, and mechanical equipment on their respective layers. It can even segregate
PIPE DRAFTING ANO DESIGN
GENERATING DRAWJJs:GS AUTOMATICALLY FROM A MODEL
311
FIGURE 14.4 Unit-01: Pictorial.
ptpmg components according to pound rating (150, 300, etc.), specification, or material and place them on individual layers. One method of interference checking is performed by checking one layer against another to confirm that no two items are occupying the exact same space within the facility. Another method analyzes the database in an attempt to find components identified as "solids" sharing the same space. Figure 14.5 shows interference between a horizontal pipe and a structural support. As the interference detection program is initiated, certain software programs will locate the first clash and change the color of the two elements that are interfering to a different color. The software will relocate the area of the model in question to the center of the display and allow the user to zoom in for a closer look. When multiple interferences are detected, the press of a key instructs the software to proceed to the next problem area, allowing the user to view each area in question. Sorne of the more sophisticated software packages allow the user to "fly" around the problem
area in real time, viewing it from any direction or angle. The ability of computer software to help prevent costly construction errors is another reason why 3D modeling is so valuable.
GENERATING DRAWINGS AUTOMATICALLY FROM A MODEL Once a 3D model has been built, the routing of each piping configuration is clearly defined. Although the procedure is different in each program, designers can then use the modeling software to automatically generate dimensioned Plan, Elevation, and Section drawings of the facility from any desired orientation. If necessary, designers or drafters can then add notes and dimensions to the drawings, prior to sending them to checkers for further approval. Sorne software programs generate plans, sections, or elevations in severa! different drawing formats
PIPE DRAFTING AND DESIGN
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14. BUILDING 30 PIPING MODELS
íncludíng single-line, double-line, and 3D views, with hidden lines removed. Solid modeling is different from wire frame modeling because a solid model can display objects with the hidden surfaces removed. On a wire frame model, ali surfaces are visible. Using this solid modeling capability, 3D software can automatically create projected views of solids with all the hidden lines removed. This capability gives the user a powerful tool for displaying pipíng drawings. Figures 14.6 to 14.9 represent different 3D orientations of the model built from the Units-01, 02, 03, and 04 drawings, presented in Chapters 10 and 16.
GENERATING ISOMETRIC DRAWINGS AUTOMATICALLY In addition to orthographic views, 3D modeling software can generate isometric drawings of pipe configurations automatically. Toe isometrics are created complete with dimensions and a Bill Of Materials. Generally, with just a few manual touchups and additions, they are ready for construction issue (see Figure 14.10). Again, by investing the time to model a project, the engineer, designer, fabricator and client can reap large informational and econornic returns at the conclusion of the project.
COMPUTER;AIDEDENGINEERING OF MODELS Another important task that can be accomplished with 3D models is that of stress analysis. Stress analysis verifies the feasible operation of pipe, steel, and mechanical equipment. Toe piping system and its supports can be analyzed both statically and dynarnically. Stress analysis features include checking for seismic movements, flow-induced vibrations, wind loadíng, and wave loads. By developing a 3D model, and pairing it with a stress analysis program like CAESAR 112, an engineer can ensure the accuracy of the facility's design. FIGURE 14.5 support.
Interference detection between a pipe and structural
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Units-01-04: Northeast pictorial view.
PIPE DRAFTING ANO DESIGN
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Units-01--04: Southeast pictorial view.
FIGURE 14.8 Units-01--04: Southwest pictorial view.
PIPE DRAFilNG AND DESIGN
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14. BUILDING 30 PIPING MODELS
Units-01-04: Northwest pictorial view.
CHOOSING A MODELING SOFTWARE PACKAGE As with any product in the marketplace, each manufacture wants to make their product as attractive and appealing to potential customers as possible. Software is no different. Software developers use the most advanced programming languages available to write routines and incorporate features into their 3D modeling package in order to make it attractive to a potential customer. Sorne 3D modeling programs are written using a specific CAD package as its operating platfonn, while others are written to be "stand-alone." For example, PDS2 is written to use MicroStation as its operaring platform, while Plant Design Management System (PDMS)1 is a stand-alone program. Selecting the right software involves more than choosing the one with the best looking sales brochure. To provide a sample of sorne of the features, a quality 3D pipe modeling software program should include AVEVA:s PDMS1 software is presented.
AVEVNsPDMS PDMS is just one of the modeling programs in the AVEVAPLANT1 Series. Although extensive, a 3D pipe modeling program becomes a more complete desígn
tool when incorporated into a series of products. Along with PDMS, other AVEVA products include P&ID, lnstrumentation, Cable Design, Pipe Stress Interface, and Mechanical Equipment Interface. AVEVAReview, a "walk-through" and animation package, and Laser Model, the point-cloud laser scanning package, makes PDMS one of the most complete facility planning tools.
BUILDING A 3D MODEL USING PDMS PDMS has numerous design applications such as pipe, structural and architecture, equipment, electrical and instrumentation, and HVAC that are used to build a facility model. With either keyboard syntax commands or menu-driven Jorms, PDMS uses its database fonnat to build extensive pipíng models. PDMS, unlike traditional CAD packages, is a database program. This means that one doesn't draft with traditional entities like lines and circles. Rather, one builds the model using three-dimensional components. Figure 14.11 shows the PDMS user interface. PDMS uses a hierarchical system of organizing model components. Starting from a World default level in the Design Explorer, Sites and Zones are established as locations where model components are developed. This method of organízatíon allows various disciplines
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to work on different parts of the facility without affecting each other. Figure 14.12 depicts a sample of the various hierarchical levels used in the development of Units 01-ü4. There are a number of Web sites that provide instruction and educational tutorials on the use of PDMS, including http://www.learnpdms.com and http://www.pdmstutorials.com. Figures 14.13 and 14.14 depict a sample tutorial from http:/ /www.learnpdms.com demonstrating the command sequences necessary to generate a 'Site' and 'Zone' level in the Design Explorer hierarchy. Model elements used to represent common facility components such as paving, foundations, and supports are built using Create Primitives features of PDMS. A Primitive, in PDMS terminology, is an item such as a Box, Cylinder, Sphere, and Snout that, when placed adjacent to other Primitives, is used to 'build' model components. Each Create Primitives form requires various input values that are unique to that particular shape that must be keyed-in before the component is placed in the model. Figures 14.15 to 14.18 represent the sequence of steps used to build a Box primitive which represents the "Paving" in the Unit-O'l model. Of
particular importance to the proper placement of the box is the Position: values. These three values define the exact center of the box primitive. Note, when combined with the X-, Y-, and Z-length Attributes:, the Position: values arrange the Paving so that its lower left, or southeast comer, is in the O' -O", O' -O" location. Progressing to the next step in 3D model building is the creation of all pedestals, foundations, and footings needed to support the mechanical equipment and structural supports required in a facility. Most pedestals and foundations are rectangular or square in shape and would be modeled with a Box primitive. However, sorne, like the octagon-shaped pedestal for vessel 01-V101 in Unit-01, require a different method of modeling. Figures 14.19 to 14.22 present the step-by-step procedures PDMS uses to build 01-V-lOl's eight-sided pedestal foundation. Figure 14.23 shows the completed shape. To provide support for numerous pipes that will be routed throughout a facility, PDMS makes an exhaustive library of structural shapes and sizes available to the modeler. Whether using concrete or American, British, Canadian, or Japanese steel, a modeler can build everything from a multi-level steel structure to a
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simple Miscellaneous Pipe Support with the Beams and Columns application of PDMS. Figures 14.24 to 14.29 represent a few of the procedures and forms necessary to build a column in the PS no. 3 bent of the main pipe rack. Figures 14.30 and 14.31 show the completed columns and beams that comprise the main pipe rack that runs through Unit-01. Once all the required foundations have been modeled, the various pieces of mechanical equipment can be created. In Figures 14.32 to 14.34 sorne of the Primitives forms for creating vessel 01-V-101 are shown. Toree Primitives are needed to model 01-V-101. They are Cylinder (vessel skirt and shell), Dish (2:1 semielliptical heads), and Nozzle (nozzles and manways). The requíred Primitive values are gathered from information provided on the 01-V-101 vendar data drawings provided in Chapter 10. Nozzles are added once the vessel is modeled using the Create Nozzle and Nozzle Specifications form. Size and pound rating information
317
found on the 01-V-101 vendar drawing is used to accurately locate and orient each nozzle on the vessel. Figures 14.35 to 14.37 show the PDMS Create Nozzle forms used to place and size nozzle Nl on 01-V-101. On many pieces of mechanical equipment, vertical vessels in particular, it' s necessary to provide access platforms to nozzles that are not accessible from Grade. PDMS has an extensive array of features that allow for the building, orientation, and placement of platforms and their accompanying ladders and cages on and around vessels. Found in the Structures ASL Modeller (Accessways, Stairs, and Ladders), the Circular Platform form requires a number of user inputs to establish the platform's width, radius, elevation, orientation, and kickplate heíght and thickness. Figures 14.38 and 14.39 represent the forms and input information required to place Platform No. 1 on vessel 01-V-101 in Unit-Ol. Once complete, the vertical ladder and its protective cage are added to Platform No.1. Figures 14.40 to 14.43 show the ladder and cage creation forms. Although additional enhancements are necessary, the initial ladder and cage components are sufficient to represent Platform No. l. If necessary, PDMS will even cut a hole in a platform to allow a pipe to pass through it. Known as a Floor Penetration, PDMS will locate and size a hole in a platform that's needed to allow a pipe to pass through it without a clash detection being generated. Figures 14.44 to 14.46 describe the procedures used by PDMS to ereate a Floor Penetration. Modeling pipe is the prímary function of PDMS. Numerous options and methods exist to connect pipe to a vessel and route it through a facility. Setting a line's specification and pipe size ensure that the configuration and its connections are "acceptable" and in accordance to job specifications. The precision with which PDMS can attach a pipe to a nozzle, route it through a pipe rack, change size, cross supports, roll up, roll down, branch, etc. is astounding. As a confirmation of its accuracy, PDMS employees Data Consistency Checking to verify a pipe's compliance with established cedes and specifications for the job. Figures 14.47 to 14.57 present a few of the Pipeworks forms used to model pipe and check it for consistency errors. Such a large number of 3D pipe modeling programs make it difficult for the piping drafter / designer to be proficient in all of them. In the end an expensive pipe modeling program is just another tool at the designer/ drafter's disposal. Although knowing how to design with a modeling program is essential, eventually, strong fundamental knowledge of the piping discipline will benefit the student more than operational skills of a powerful 30 modeling program. If a mechanic doesn't know how to use his tools, both he and his customer may end up walking.
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Creating a Zone with PDMS. Courtesy
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PIPE DRAFI1NG AND DESIGN
BUILDING A 30 MODEL USING PDMS
1. Before the Prlmitive element which will represent the paving of Unit01 can be created a Design Database Eq11ipmentelement muat be established This element will be the Paving's 'owner' .
FIGURE 14.15 Creaie Equipmeni form. Courlesy of AVE VA Group, ple. and www.learnpdms.eom.
FIGURE 14.16 Create Primilives form. Courtesy of AV EVA Group, ple. and www.learnpdms.com.
PIPE DRAFilNG AND DESIGN
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14. BUILDING 30 PIPING MODELS
PDMS wlll cllsplay a form which Is used to enter the lnformation requlred to aeate the Box element that representa UnitOl's pning.
On the UnltOl arrangement clrawlng. shown on the following slide, notice tha lhe matchlines are labeled u: N. O'-o"' and N. 56'-o"' W. O'-o"' and W. 40'-o"' The paving elevatlon is 100'-o"'. (100'-o"' wil1 be lnterpreted as O'-o"' on lhe model. l.e. The top of the paving should be al O'-o"'.) In order to posltlon the Box prlmitlve accurately you will need to be aware of lhe Box'•p-polnts to establish 1r, orlentatlon.
1. 11w Po,ltlON: val,- (N, W, DI for the 8ox loa~ 111 PO polnt, whkh lt In the euct Cffllff of the box lf the Pavlng't x·length INOlthl lt 56'-0" and the y-lngtb IWettl lt 40'-0", lhe nad ttnlff lt -half of 56'.e, (28',0") and one-half of 40'-0" 120' ,O"). Tlw Do11111 yaJae of fl' lt baHd on the dnltt lo luive the Pavlng elevallon al 0'-0" wllh a ~ (z.lenglh) of 1'-0".
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FIGURE 14.18 Paving primitive. Courtesy of AVE VA Group, ple. and www.learnpdms.com.
PIPE DRAFTING ANO DESIGN
BUILDING A 30 MODEL USING PDMS
FIGURE 14.19 Creaie Extrusion form. Courtesy of AVE VA Group, ple. and unuw.learnpdms.com.
FIGURE 14.20 UsingDefine Vertex form to establishextrusionorigin. Co11rtesy o/ AV EVA Gro11p, ple. and www.learnpdms.eom.
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(a.b) Define Vertex positions with Direction and Distance. Courtesy of AVEVA Group, ple. and www.Iearnpdms.com.
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FIGURE 14.23 CompletedOl-V-101 pedestal.Courtesyof AVEVA Group, ple. and www.learnpdms.com.
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FIGURE 14,27 Create Section form.Courtesy of AVEVA Group, ple. and www.learnpdms.com.
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FIGURE 14.28 Define Sectiun Start form. Courtesy of A VEVA Group, ple. anti unuw.learnpdms.com.
FIGURE 14.29 Define Sectiun End form. Courtesy of AV EVA Group, ple. and www.learnpdms.com.
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FIGURE 14.31 Completed colwnns a.nd beams. Courtesy of AVEVA Group, ple. and www.learnpdms.com.
PIPE DRAFilNG AND DESIGN
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14. BUILDING 30 PIPING MODELS
2. In the form enter the data required to create the primitive which will represent 01-V-lOl's skirt. PDMS will position the cylinder about the Po position of the primitive. Refer to the following slide to determine various primitive's Po location. ··~
FIGURE 14.32
Using Create Cylinder form to model 01-V-lOl's skirt. Courtesy of AVE VA Group, ple. and www.learnpdms.com.
form will Op4!n, enter: 01_V_101_Shell ~-Enter the same coordlnates that were used to poslUon the vessel's sklrt. The Up value wlll locate the cyllnder's Po elevation. NI
FIGURE 14.33
--
--
Using Crea te Cylinder form to model 01-V-101 's shell. Courtesy of AVE VA Group, ple. and www.leampdms.com.
PIPE DRAFTING ANO DESIGN
329
BUILDING A 30 MODEL USING PDMS
Create: Solid Type: Dlsh A 2:1 semi-elliptical
head'sheight is know as the IDO (lnside Oepth of Dish) dimension. The IDO is equal to the vessel diameter x .25 • In this case the dish's height is 4'.() X .25 • 1'-0"'. The Radius value determines theroundness of the dish.
---z..-
, u
Here 3 has been used. FIGURE 14.34
Using Create Dish form to model 01-V-lOl's 2:1 semi-elliptical head. Courtesy of AVEVA Group, ple. and www.learnpdms.com.
2'8 (Thll repNMnll the nozzle projectlon from the cent.rtlne of 01·Y· 101 whlohadded to 21'..0 - lhown llbove.)
3. Set the appropri ate nozzle Attrlbutes, if necessary,before selecting Apply.
FIGURE 14.35
Using Creale Nozzle form to model nozzle Nl on 01-V-101. Courtesy of AVEVA Group, ple. and www.learnpdms.com.
PIPE DRAFilNG AND DESIGN
330
FIGURE 14.36
14. BUILDIJ',;G 30 PIPING MODEI.S
Using Nozzle Specificatum form to model nozzle Nl on 01-V-101. Courtesy of AVEVA Group, ple. and www.learnpdms.com.
Loc:ate the renwning nozzles asing the information foand on the vendor drawings. There are varioas procedares and shorkuts ased to orient and position primitives sach as cylinders, dishes and nozzles. Experiment with them to determine which ones will make you th most effident at model creation. Vessel 01-V-101 should look like the two images shown here when completed. This concludes the tutorial on Creating Equipment with Nozzles using Avna's PDMS.
FIGURE 14.37
Completed nozzles on Ol·V-101. Courtesy
of AV EVA Group, ple. and www.learnpdms.com.
PIPE DRAFI1NG AND DESIGN
331
BUILDING A 30 MODEL USING PDMS
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l. Wilh bigbligbted: Createítm¡jlll:lll1J!l[lt.mlmiJ'[ül;¡~ hasalready Platfonn been created. If lhe ZONE does not exist one must be aeated in the Design Explorer. Circular Round... The following step assumes tbat a
FIGURE 14.38 Creating a circular platform. Courtesy of AVEVA Group, ple. and unourleampdms.com.
2. The platform 11 modeled In the Cnpbical Vlew and added to the Detlgn Explorer hlenrchy. The new SUBSheadlnp contain primltlvee that PDMS UHI to bulld the platform.
FIGURE 14.39 Create Circular Platfarm form. Courtesy of AVEVA Group, ple. and www.learnpdms.com.
PIPE DRAFilNG AND DESIGN
332
14. BUILDIJ',;G 30 PIPING MODEI.S
FIGURE 14.40 Creatinga ladder,Courtesv af AVE
VA Graup, ple. and UTWW.learnpdms.com.
2. The boHom of the Wder il initWly po1ltloned on the ve11el'1 cenlff Une coordlnatea. Next, the • [;3• ~117.1~ com11U1nd 11 uled to preclaely locate the ladder and elimlnate the need to wculate exad North, Wett, and Up coordlnatea.
FIGURE 14.41 Side
Exit Ladder
form.Caurtesy of AVE
VA Graup, ple. and u,ww./earnpdrns.com.
PIPE DRAFI1NG AND DESIGN
BUILDING A 30 MODEL USING PDMS
t. Select the appropriate Sabstradare, &om the Daign Explorer,. thea: Create • Copy •.• form set the desiJed FIGURE 14.42
Completing the cage. Courtesy ofAVE VA Group, ple. and www.learnpdms.com.
l. Depic:ted is lhe ladder wilh fully endoeed cage. 2. Usted in lhe Design Explorer 1re lhe v1riou1 primitiveathlt compriae e1ch aubstructure of lhe ladder.Theae primitivea muat be mlnipul1tedin order to develop I model repreaentltive of intend deaign. Become funillar wilh lhe ,
1nd
Menu commandt to 1cllievebetter modelingeffidency.
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,.. r_
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e-• e-• e .... ,
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4)'411• r•TJltl
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aai•
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FIGURE 14.43
3. The cage'11 bandll will be previewed. Amwer · or , to rewn the copied bandll.
'1
Completed ladder and cage. Courtesy o/ AVEVA Group, ple. and www.learnpdms.com.
PIPE DRAFilNG AND DESIGN
333
334
FIGURE 14.44
14. BUILDIJ',;G 30 PIPING MODEI.S
Creating a platform penetration. Courtesy of AVE VA Group, ple. and www.learnpdms.com.
3. At the bottom of the Design Explorer, in the lower left comer,the command 'ldentify floorplate'appean. 4. Pick the platform floorplate with the left mouse button. S. In the lower left comer the command 'ldentify penetratlngítem' appean. 6. Pick the penetrating pipe with the left mouse button. 7.
FIGURE 14.45 Selecting penetration components. Courtesy of AV EVA Group, ple. and www.learnpdms.com.
PIPE DRAFI1NG AND DESIGN
BUILDING A 30 MODEL USING PDMS
FIGURE 14.46 Displayingthe floor penetration Courtesy of AVEVA Group, ple. and www.learnpdms.com.
FIGURE 14.47 Create Pipe form.Courtesy of AVE VA Group, ple. and www.Iearnpdms.com.
PIPE DRAFilNG AND DESIGN
335
336
14. BUILDIJ',;G 30 PIPING MODEI.S
... T NOr.lOl T-SHC
...
o
formHlect:
FIGURE 14.48 Default Specifications and Pipe Attributes forms.Courlesy of AVEVA Group, ple. and www.learnpdms.com.
,•• r ~ f:i~WORl'
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lH01
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FIGURE 14.49 Creai« Branch form. Courtesy of AVE VA Group, ple. and www.learnpdms.com.
PIPE DRAFI1NG AND DESIGN
OK
1
INo
y
BUILDING A 30 MODEL USING PDMS
of AVE
FIGURE 14.50
Branch at Explicit Position (head) form. Caurtesy
VA Group, ple. and www.learnpdms.com.
FIGURE 14,51
Branch at Explicit Position (taíl) form. Courtesy of AV EVA Group, ple. and www.learnpdms.com.
PIPE DRAFilNG AND DESIGN
337
338
14. BUILDIJ',;G 30 PIPING MODEI.S
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8WO
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V
.,,
V
14'10
ll>
12'•.511<1
Posb:ln_, Wortd
3. In lhe of tbe
form, set lhe
Bore,Connection,Direction and Poeition wrt World: as
shown to lhe lefL When finished:
FIGURE 14.52 Pipe Modificatúm form. Courtesy of AVE VAGroup, ple. and umnuleampdms.com.
S1'
...
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a...,..,'llíf,U.X,~j
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,.,.4" ""'
The'green' arrowshown
aboveconfirmsthat the component will be attached to the corred branch endpoint (}fead orTail).
FIGURE 14.53 Pipe Component Creation form. Courtesy of AVE VA Group, ple. and www.leampdms.com.
PIPE DRAFI1NG AND DESIGN
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339
BUILDING A 30 MODEL USING PDMS
o-·· º°"....
o....,,,..., 1
"'....
r--[ib GiJ ...
FIGURE 14.54 Piping Components form. Cuurtesy ofAVE VA Group, ple. and www.learnpdms.com.
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t. The elbow of brancb 1-c:30-8"'/Bt will appear in the Design Explorer hierardly and in yoar modeL To orient the elbow as lhown on the Unit-ot arrangement clnwing, inthe form: , , · DlrectD 3. The model will confinn the elbow'1 rotation to the conect orientation. Once rotated, the next component can be added. Do not dose the form unW llne 01-1-c:30-8"'is complete. FIGURE 14,55 Placingand orientingan elbow. Courtesy of AV EVA Group, ple. and www.learnpdms.com.
PIPE DRAFilNG AND DESIGN
--
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340
14. BUILDIJ',;G 30 PIPING MODEI.S
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L A Oangecl ple valve ancl its maling componenls ue aclclecl to lhe hierarchy ancl the moclel. u lhown above. The Stanclanl Allembly methocl can be asecl to inaert a Oangecl valve,witb two flanges ancl ils gaskels, into a branch witbout havingto choose each com inclepenclently,one piece at a time. 2. Wben finishecl ...._ the form. FIGURE 14.56
Placing and orienting a valve. Courtesy of AVE VA Group, ple. and umnaleampdms.com.
t. Once line ot+c:30-10"' Is
complete, a 'elata conalstency check'mlllt be ran to verify lhat ali componentsof lhe pipe conftgantlon meet appllcable Job lpedflcatlons.
2. Wben conftrmecl, tbe IIMINp •_•NO DATA INCDN!IISTl!NCDº_ • will be cllsplayeclIn tbe O.t•
C0111i1tnq Cll«k form.
FIGURE 14.57
Data consistency check. Courtesy of AVEVA Group, ple. and www.learnpdms.com.
PIPE DRAFI1NG AND DESIGN
º'"
CHAPTER
15 Project Coordination
Toe complete design of a petrochemical facility involves engineering disciplines other than Piping. Toe effective coordination of ancillary disciplines such as Civil, Structural, Architectural, Electrical, and Instrumentation are necessary throughout the engineering, design, and construction phases of a facility. Although pipe might be considered the most critica! component of the design, other disciplines can make that claim as well. Without the Structural group there would be no steel to support the pipe. Without the Electrical group there would be no power supplied to pump motors or electricity for illumination. Without the Instrumentation group there would be no means of monitoring or controlling the pressure and temperature levels of the commodity flowing through the pipe and equipment. Each discipline has a unique impact on the design of a facility in its own specific way. Toe confluence of so many disciplines in such a rather confined space means that in order for the engineering, design, construction, and ultimately, operation of a facility to be considered successful, the interaction of all disciplines must be coordinated in a precise and timely manner. For example, the main pipe rack and each miscellaneous pipe support must not only be designed with enough structural strength and space capacity to hold the required pipe, fittings, flanges, valves, etc. being routed through it, but it must also be designed for the inclusion of all electrical and instrumentation trays and conduit. Toen, the civil group must engineer and design the concrete footings and foundations large enough to support not only all the items mentioned previously, but also the structural steel columns and beams as well. Additionally, these massive, underground concrete structures must be positioned and oriented so that the below-grade piping and drainage systerns can be routed around them with the most direct and economical configuration. Toe drawings in this chapter represent those that would be furnished to the Pipíng group by the Civil, Structural, Instrumentation, and Electrical groups to
help develop the Piping Arrangement drawing. For example, the civil drawings depict the size and shape of the concrete foundations that are to be built for the various píeces of mechanical equipment. Likewise, the structural drawings will allow for the representation of the main pipe rack, pipe supports, platforms, ladders, and cages on the Piping Arrangement drawing. In addition to drawings developed in-house by the various disciplines, the suppliers of the numerous pieces of mechanical equipment such as pumps, exchangers, and vessels will supply drawings that will allow all equípment to be represented on the Piping Arrangement drawing. Ultimately, coordination between l&E (Instrumentation and Electrical) and the Pípíng group becomes critica! because these groups often must have equal access to the same pieces of equipment. Therefore, the drawings they provide help determine where underground conduit and cabling may lle. Other than the Lighting and Power Supply drawing and the Grounding Plan, which are included in this chapter, all of the discipline-specific drawings needed to develop Unit-01 are present in Chapter 10. All of the drawings needed to develop Unit-02, Unit-03, and Unit-04 follow, and are grouped by discipline. Included with the discipline drawings are the Process and instrument Diagrarns (P&IDs), Foundation Location Plans, Equipment Location Plans and Section drawings, all of which are used asan aid in the development of the Piping Arrangement drawing or a 3D model. Since most companies now use sorne version of a pipe modeling software, four pictorial representations of the three-dimensional model of Units 01-04 are included at the end of the chapter. Use them as a visual reference to better understand the location and size of mechanical equipment, the orientation of ladders and platforms, the routing of pipe, and placement of pipe supports. Toe numerous dimensioning charts, drawing standards, and reference tables located throughout the text will also be used as reference tools.
341
C, 2012 Ehcvic-r lnc. Ali rlghts rcserved.
02-E-201
02-V-203
PRODUCT CONDENSER
FRACTIONATION COLUMN 4'-9" OD X 18'-9" T/T DES. 375# O 750'F VENT TO ATMOS.
4"x6"
02-39-A 15-6"
02-28-A15-6"
FEED
02-34-Al 5-12"
COOUNG WATER SEE UTIUTY F'LOW DIAGRAM
02-E-201 02-29-A15-6"
6" 02-38-Al 5-6" 02-37-Al 5-4" -IH
02-P-202A
02-35-A 15-6" -IH
02-P-202
A&B
REFLUX PUMPS 12 HP@ 4200 RPMs
FIGURE 15.1
Unit-02: Process and Instrument Diagram.
6"
03-V-303
03-H-304
FLARE STACK
T/T
03-33-A 15-4"
PRODUCT STORAGE
03-FS-305
HEATER
SEPERATOR 36"0.D. X 19' -0"
03-32-A15-6"
03-V-303 40#
e
118'F
2"
Yows
FACILITY LOADING/ UNLOADING
03-18-A15-8"
03-FS-305
03-20-A15-10"-IH
HOT OIL SUPPLY SEE UTlUTY
~----1----~---l 03-31-A15-12"-IH FUEL GAS
03-30-A 15-6"
~--------1 10"
HOT OIL RET\JRN SEE UTILITY
FLOW DIAGRAM
10"
03-19-A15-10"-IH
355·
03-H-304
03-P-301A
& 3018
HOT OIL PUMPS
FIGURE 15.2 Unit-03: Process and Instrument Oiagram.
FLOW OVIGRAM
04-E-404
04-V-401
FRACTIONATOR REBOILER
FRACTIONATOR
04-CT-406
04-E-402A&B
COOUNG TOWER
PROOUCT CONOENSORS
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1
04-49-A1~a·
04-42-CJO-e•
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04-E-4028 04-P-4058 04-22-A.15-8.
04-P-405A & 04-P-4058 COOUNG WATER SUPPLY PUMPS
FIGURE 15.3 Unit-04:Process and Instrument Diagram.
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Unit-02· . Piipmg . Arrangement Drawmg. .
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TOC ELEV 101'-0'
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UNIT FIGURE 15.6
Unit-02: South Elevation.
02
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349
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03-H-304
03-JO-A15-6"
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03-P-3018 TOC ELEV. 101'-0" HP PA't1NC D.[V.
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UNIT FIGURE 15.8
03
EAST ELEVATION
Unit-03: East Elevation.
PIPE DRAFilNG AND DESIGN
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PIPE DRAFilNG AND DESIGN
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MATCH UNE 0'-0"
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UNIT 04 AREA LIMIT E. 40' -O"
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UNIT 04 AREA LIMIT E. 40' -0"
PS-5
NOZZLES
"T 1" & "T 2' and "S 1"
NOZZLE
& "S2•
Fl_u i;~-r 11"
.L-B1~r
1;2·t2"
NOZZLE
DETAILS
MK
SERVICE
T1
C.W. OUTLET
T2
C.W. INLET PRODUCT IN
NO.
s, 52
PRODUCT OUT
V
TW/VENT
SCHEDULE
SIZE
6" 6" 6" 6" 4
,·
RATING FACE
PROJ.
150/1 RF 2·-1 • 150/1 2'-1" RF 150/1 RF 2·-1 • 2·-1 • 150/1 RF 6000/1 CPLG W/PLUG
3 1/2"
Q]
PLAN 22'-6"
DETAil
"A" 19'-9"
.----f-1
N:i_ _
-------,f----
-
--
.
o 1
;..,
_.'!!Q;;:¡;;i;er,-----=-:CL
13'-0"
SOUTH ELEVATION
PRODUCT CONDENSER FIGURE 15.17
Unit-02:Product Condenser02:E-201.
• , 1. 8"
EAST ELEVATION
UNIT 02: E-201
NQto· NOT IP 591 E
, .ry
NOZZLE
NOZZLE SCHEDULE
"B"
10"
J_H
NOZZLE DETAILS ~~=~~-~
MK
SERVICE
A
SUCTION
NO.
SIZE 6"
RATING FACE 150#
RF
B
DISCHARGE
4•
300#
RF
4·
6'-1"
A
_______
-:}[ ..,!]
PLAN 2'-0"
1'-11/2" 2"
HP PAVING
1 oo' -o"
ELEVATION
END VIEW Notn· NOT
PRODUCT FIGURE 15.18
PUMPS
Unit-02:Product Pumps 02:P-202A & P-202B.
UNIT
02:
P-202A
AND
P-2028
m
SAN f
NOZZLE SCHEDULE
MK
SERV1CE
NI PHONIUM SUPPLY
NOTES: 1.
THE ELEVATIONS SHOWN ON THE EQUIPMENT DRAWING DO NOT INCLUDE 1 '-0" CONCRETE FOUNDATION.
2.
2" THICK BASERING, 5' -9" O.O.
RATING FACE
SIZE
1
6"
150#
RF
3' -3"
N2
LG. CONN.
1
RF
3'-0"
LG. CONN.
1
2· 2·
150#
N3
150#
RF
3'-0"
N4
FEED INLET
1
12·
150#
RF
3'-3"
N5 PHONIUM RETURN
1
s·
150#
RF
3'-3"
NS PRODUCT STORAGE
1
14"
150#
RF
3'-3"
150#
RF
3'-3" 1 '-9"
s·
N7
REflUX
N8
VENT
1
2·
150#
RF
N9
P.S.V.
1
4•
150#
RF
1 '-9"
MI
MANWAY
1
18"
150#
RF
2'-10"
8'-6" 18' -9" TANGENT TO TANGENT ~----------------------+~----------!
t-
s
~o
~
~
w
z
N9
o,
1
L
r
1
24'-o"
z
~~--~ N7
I~~
1--+1-+--o-+---+-~
ot
1'-7"
=
14'-3"
(10 TRAYS)
1~b'
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-r-1 ~ d - 1 _I_
z
u
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t-
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s ie ~
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rr
TI
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o
_1__ 1 _1__ 1 -r- 1 _1__ 1 1 1 1 1 1 1 1 1 1 _L_ 1 _L_ 1 _I __ 1 _I __ 1 _L_ 1 1 1
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N8
r l:
9 SPACES
M1
PROJ.
NO.
IO
\ )
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--
w
~
~
1
\
+ ) -2·-o·
I Ngte· NOT m SCIJ E
PHONIUM FIGURE 15.19
COLUMN
Unit-02: Phonium Column 02:V-203sheet 1 of 2.
UNIT 02:
V-203
1 of 2
NOZZLE MK
45·
N
e:::==-
NOZZLES
"N1 ","N5","N7"
"1_1·
11"
1
11·
"N6"
1'-9"
·1_1
,'g1- 10
NOZZLE "N8"
1 e
6"
3/41_111
3,1¡ .JL10112·
l .1·-2:I-,
SIZE
RATING
FACE
PROJ.
1
6"
150#
RF
3'-3"
f'R5%"
40
N2
L.G. CONN.
2"
150#
RF
3'-0"
N3
L.G. CONN.
2"
150#
RF
3'-0"
N4
FEED INLET
12·
150#
RF
3'-3"
NS PHONIUM RETURN
6"
150#
RF
3'-3"
N6 PRODUCT STORAGE
14"
150#
RF
3'-3"
N7
RE FLUX
6"
150#
RF
3'-3"
N8
VENT
2·
150#
RF
1'-9"
N9
P.S.V.
4•
150#
RF
1'-9"
M1
MANWAY
18"
150(1
RF
2'-10"
NOZZLES
"N2"&"N3"
NOZZLE "N4"
1_1"
·1_1
1-q NOZZLE
SCHEDULE
NO.
Nl PHONIUM SUPPL Y
N6
N4
SERVICE
n.
1/2"
1¡ .
(1YP.9)
1 4
NOZZLE "N9"
15 • g" y16lÍÍl
f'R5%"
4-0
J
I
1 '-7"
Q
"lj_ 101/2" 1
l ro:I'
NOZZLE "M1"
11·
19~J
1
2'-1" [i_J
·1_1 ' s1!2 •
~--,
NOZZLE DETAILS Note· NOT TO SCALE
PHONIUM FIGURE 15.20
COLUMN
Unit-02: Phonium Column 02:V-203sheet 2 of2.
UNIT 02: V-203
2 of 2
255º
270º
\
4"
3'-0"
::g '"O
y,
.,,;,:,
180º
IT1
o ~ ~
.Q ::
z
~
C)
>
ª
N
1
o
..._¡--
IB C)
ñ
N
§ ;,:,
o~
º
z>
O)
:j
o z
1
"'-:-
z
<,
R1 '-1"
90º PLATFORM
No.1 Note· NOJ JO SCALE
PHONIUM FIGURE 15.21
COLUMN
UNIT 02: V-203
Unit-02: Phonium Column 02:V-203platform dimensions.
PLATFORM DIMENSIONS
NOZZLE
LI
1'-7"
TLJ
NOZZLE SCHEDULE
"A"
I
MK
SERVICE
A
SUCTION
B
DISCHARGE
NO.
SIZE
12"
1 o•
RATING FACE 150#
RF
150#
RF
14
11
l 12·1
NOZZLE DETAILS
11 "
Jr-r l'
!!::
_
,..
6'-10"
-1
g"
B
PLAN 1/ "
2'-7"
1 O! 2
~
Ir
A
1 '-8"
+-----iA 1'-91/2" 2"
HP PAVING 100'-0"
ELEVATION
REBOILER PUMPS FIGURE 15.22
Unit--03: Reboiler Pumps 03:P-301A & P-301B.
END VIEW
UNIT
03:
P-301A
ANO
Note· NQT m $CN..E
P-3018
~
- e- -+ -
í·l 1 ! 1
1
-lt+-1' 1
L!J
N=1 l I ,.1
-++1-I j I L·J
NOZZLE ITEM Sil[ RATING
?
SCHEDULE
FACING
DUlY
PROJ.
N1
4•
150#
RF
FEED
1'-10'
N2
6"
150#
RF
VAPOR OUT
1'-10·
NJ
2·
150#
RF
LC-LG CONN.
1'-10'
N4
2·
150#
RF
LC-LG CONN.
1'-10'
N5
2·
150#
RF
ORAIN
1'-10'
M1
18"
150#
RF
w.NHOLE
2·-2·
PLAN 19·-o· 4'-2"
3'-o·
4'-0"
6'-9"
(f) o -
--
-
--
-
~
o
ELEV. 105' -9" - -- -_1
·1
8"
-f,-t--
-
-
o1
r')
"' N 5 12·-o·
EAST
ELEVATION
J'-6"
NORTH
ELEVATION Note: NOT TO SCALE
LIQUIFIED
PHONIUM
SEPARATOR
FIGURE 15.23 Unit-03: Liquefied Phonium Separator 03:'V-303.
UNIT 03: V-303
NOZZLE
SCHEDULE
ITEM
SIZE
RATING
FACING
OUTY
PROJECTION
Nt
6"
15DH
RF
FUEL OIL FEED
6"
N2
10·
1506
RF
N3
12·
1506
RF
....
10" 10"
11 '-0"
1· /
HEATING OIL SUPPLY HEATING OIL RETURN
/~--------
;;
· 1
3'-0" TYP
o 1
:
io 1
I·
4·-o"
•
I PLAN Note: NOT JO SCALE
HEATER FIGURE 15.24
Unit-03: Heater 03:H-304sheet 1 of 2.
UNIT 03: H-304
1 of 2
i 4'-o" I 1
9l8' -o" 9l1 o· -o"
T.O.C. EL 101'-0" H.P. PAVING EL 1 oc' -o'
SOUTH ELEVATION
1
1
1
1
1
1 1
EAST ELEVATION Note· NOT TO SCALE
HEATER FIGURE 15.25
Unit-03: Heater 03:H-304 sheet 2 of 2.
UNIT 03: H-304
2 of 2
367
MECHANICAL EQUIPMENT: VEI\OOR DRAWINGS
EL. 180' -O" EL. 178'-0"
155·
-o"
EL. 153' -0"
{¿
151'-~ EL. 150' -O"
PLATF. No.2 ELEV. 150' -O"
PLATF. No.1 ELEV. 120' -0" 108' -0"
TOC ELEV.101'-0"
HP PAVING ELEV. 1 00' -0"
ELEVATION
FLARE STACK FIGURE 15.26
UNIT 03:
Urut-03: Fiare Stack 03:FS-305.
PIPE DRAFilNG AND DESIGN
FS-305
:l:! "O m
o ~
=l
;;; -e
'§º
180º
~
tí
so>
;<>
º z ~ ~
m
l'[l C)
z
90º PLATFORM No.1 Note· NOT JO SCALE
FLARE STACK UNIT 03: FS-305 FIGURE 15.27 Unit--03: Fiare Stack 03:FS.305Platforrn No. 1 dimensions.
PLATFORM No.1 DIMENSIONS
NOZZLE SCHEDULE ITEM
SIZE
RATING
3"
150#
8"
150#
FACING
RF
PROJECTION
1 '-6"
i1 '-0"
90' PLATFORM No.2
FLARE STACK UNIT 03: FS-305 FIGURE 15.28
Unit--03: Fiare Stack 03:FS--305 Platform No. 2 dimensions.
PLATFORM
Note· NOJ JO SCALE
No.2
DIMENSIONS
~ o
-...]
NOZZLE SCHEDULE
N
e:-:-=-
MK
SERVICE
N1
BOTTOM OUT
1'3"
ORIENTATION
SIZE
RATING FACE
PROJ.
12·
300#
RF
2'-8"
N2 REBOILER RETURN
10·
300#
RF
2'-8"
N3
FEED INLET
8"
300#
RF
2'-8"
N4
REFLUX
4•
300#
RF
2'-6"
N5 OVHD.VAPOR OUT
10·
300#
RF
2'-8"
N6
P.S.V.
4•
300#
RF
1'-3"
N7
VENT
1
2·
300#
RF
1'-3"
L.G.CONN.
2
3/4"
3000#
CPLG
MANWAY
2
18"
300#
RF
NOTE: 1.
NOZZLE
NO.
2·-10·
THE ELEVATIONS SHOWN ON THE EQUIPMENT DRAWING DO NOT INCLUDE 1 '-0" CONCRETE FOUNDATION.
J6'-o• TANGENT TO TANGENT
5'-o"
12 SPACES ot 2'-0" • 24'-0" (13 TRAYS )
1·-10 1 16"
Ng4;1·
COLUMN FIGURE 15.29
UNIT 04:
Unit-04: SosilliumColumn 04:V-401 sheet 1 of 2.
V-401
HOT TO SCSí
1 of 2
NOZZLE SCHEDULE
270' MK N1
225'
:
135'
ca"" 111 o
330'
SERVICE BOTTOM OUT
~ o
IB C)
12·
RATING FACE 300#
RF
2'-8"
PROJ.
1
10·
300#
RF
2'-8"
FEED INLET
1
8"
300#
RF
2'-8"
N4
REFLUX
1
4•
300#
RF
2'-6"
NS OVHD.VAPOR OUT
1
10·
300#
RF
2'-8"
N6
P.S.V.
1
4•
300#
RF
1'-3"
N7
VENT
1
2·
300#
RF
1 '-3"
~,&2
L.G.CONN.
2
3/4"
3000#
CPLG
Ml&l
MANWAY
2
18"
300#
RF
:\_M r
2'-10"
NOZZLES "N2"&"N5"
90'
21
~
SIZE
1
N3
N2 REBOILER RETURN
PLATFORM No.1
s'
NO.
[~}-'_j_
270'
8"
~
225'
z
NOZZLE "N3"
NOZZLES "N4"&"N6"
NOZZLE
"N7"
iA~·
180'
7¡a·f~
2:LJ_
90'
NOZZLE DETAILS
PLATFORM No.2
COLUMN
8"
Nota· NOJ JO $CALE
UNIT 04: V-401
FIGURE 15.30 Unit--04: Sosillium Column 04:V-401 sheet 2 of 2.
2 of 2
270º o 1
t0
18ü°
E.18'-ü"
135º 90"
PLATFORM
No.
1
PLATFORM ELEV. 114' -9" Note· NOT JO $CALE
UNIT 04: V-401 FIGURE 15.31
PLATFORM No.1
Unit-04: Sosillium Column 04:V-401 Platform No. 1 dimensions.
DIMENSIONS
270º 225º
18
Oº
~ E. 1 8' -0"
90º PLATFORM PLATFORM ELEV.
No.
2
137' -6" Note· NOT JO $CALE
UNIT 04: V-401 FIGURE 15.32
PLATFORM
Unit-04: Sosillium Column 04:V-401 Platform No. 2 dimensions.
No.2
DIMENSIONS
NOZZLES
"A"&"B"
r~w-r
NOZZLE
11 EJ I r
8"(1YP. 4)
~
1
1 5/8"J
MK
SERVICE
1~·11
A
e
C.W.OUTLET C.W.INLET LIQUID OUT
D
VAPOR IN
1
V
TW/VENT
8
3"(1YP. 4)
~1
~'
B
7/8"
NOZZLE DETAILS
:l:! "O m
o ~
1
1
1
1
-f:
N
PLAN
so>
25'-3"
tí
1 1
8"
150#
a·
300#
10" 1"
300# 6000#
''+1
SEE DETAil "A"
16'-10"
RF RF
1'-8" 1'-8"
RF
1'-8"
CPLG W/PLUG
2"
Q] DETAil
m
PROJ. 1'-8"
e::----3 1/2"t 1 1/2"
1$
E. 28'-0" E. 36'-9"
=l
NOZZLE SCHEDULE NO. SIZE RATING FACE 1 RF 8" 150#
NOZZLE "D"
15"
1113.S"l_j_
1 1/8"
"C"
"A"
3'-6"
l'[l C)
z ci
p
...
"' 17'-0"
EAST ELEVATION
NORTH ELEVATION Note· NOT TO SCAt E
PRODUCT
CONDENSER
FIGURE 15.33 Unit-04: Product Condenser 04:E-402A & B.
UNIT 04: E-402 A&B
;;; -e
'§º ~
;<>
º z ~ ~
NOZZLE "A"&"B"
•o• _1_11'-8 1/2"1
NOZZLE "C"
NOZZLE
1'-5 1/t
,tl~-t . 11"
~11 T~ª·
~i
,.:¡-'
lrn·I~
NOZZLE SCHEDULE
Fl~-
MK
P-i(TYP) NOZZLE "E"
11º" 1
+i +a· 4:w-i 11/4º
NOZZLES "F"&"G"
.n-ft11 1¡s·I1rf
2"
2_:wj
6"
3 1;2·-ii11 1/2"ln=2"
SERVICE
NO.
SIZE
RATING
FACE
A
HEAT MEO OUT
1
6"
150#
RF
1'-8"
B
HEAT MEO IN
1
6"
150#
RF
1'-8"
e
VAPOR OUT
1
10"
300#
RF
2·-2·
D
LIQUID IN
1
12"
300#
RF
2'-2"
E
PRODUCT OUT
1
4"
300#
RF
2'-2"
F
LG CONN.
1
2"
300#
RF
2'-0"
G
LG CONN.
1
2"
300tf
RF
2'-0"
V
TW/VENT
8
1"
6000#
CPLG W/PLUG
E. 8'-0"
ijj
PLAN 26'-o"
G
DETAil "A"
o o
-+--+---,~O
~
'o
EL.106'-0
3 4•
I
;,,
1s·-o· EAST ELEVATION
PRODUCT FIGURE 15.34
REBOILER
Unit-04: Product Reboiler 04:E-404.
UNIT
04:
PROJ.
E-404
NOZZLE "B"
NOZZLE "A"
_1_H
2
L
,1
1
1
1aTLJ
-+-4-
1·.Jrr 11·
1·-11/ •
NOZZLE 11
Y2"
DETAILS
NOZZLE SCHEDULE MK
SERVICE
A
SUCTION OISCHARGE
B
NO.
SIZE 8" 6"
RATING FACE 150# 150#
~
2'-0"
-[[
1 '-6" 2"
HP PAVING
ELEVATION
1 oc' -0"
END VIEW Note· NOJ TO $CALE
COOLING WATER PUMPS FIGURE 15.35
Unit-04: Cooling Water Pumps 04:P-405A and P-4058.
UNIT
04: P-405A
AND
P-4058
RF RF
r-----------------1 1r---------------,1
-
1 1 1 1 1 1
1
....__ --'-1
1 1 I') 1 1 in 1 1 1
~ ,.._
-J..+li. 1 ¡-u l l l l l
1
'
----T""-
1 I I I I
l l l l I lJ1
1
L.....
NOZZLE SCHEDULE
1
______
1 (!)
N
SIZE
RATING
FACE
PROJECTION
INLET
8"
RF
6"
OUTLET
1 O"
150# 150#
RF
6"
,__-NOTES:
I I I I I 1
1. M - FAN MOTOR LOCATION 2. COOUNG TOWER RESTS WITHIN 15'-9" X 12'-Q" X 4'-0" CONCRETE BASIN WALL.
A
.J_J
---¡-4·=-3=--r- Ls· PLAN
CONCRETE
BASIN WALL
11'-3"
1
:,,
NOZZLE
1
1
1
1
1
•
1
• o1
~~-
ir,
-~--i
-~l.Q"-
~ ~ (1)
1
., r,-
11 11
1 1
---:' '.":'"""."""'.""A"'""
1
11
-
--
,.,,_---:'
~
-
11
11
EAST ELEVATION
COOLING FIGURE 15.36
_.._ -
-,,--
-~--,
1
I I
1
H1 HJ 1
TOWER
Unit-04: Cooling Tower 04:CT-406.
-~rr 11 11
------------:..... 1 1 4~11
NORTH
UNIT
1V11
ELEVATION
04:
,SUPPORT
ii
LEGS
NOTE: NOT TO SCALE
CT -406
1.,,1 .,_J (X)
.n. .. 4'-6"
1 •
'.f[ f"}
•
•
4
:
:
:.
,
02[201
tw. ,a·-o·---
•.
~
. ..
••
~ ......
.
o
>t""'
... e..
..¿)4
.. ~
1 ""
1
trj 13'-0"
1
~
;¡' t
t:a ~
~
z ~ ~
o ~
!!L1rJ IL _:_: ~I!! !!!
--T--'-r-,-~ .;
.
-..=r.: . . -----~-----------
TOC ELEV. 103'-6"
n 10·
~·'.-·~
1
in
~
Q :;fJ
~ 1'-3" 1'-3" 2'-6"
:;fJ
..
Note· NOT TO SCALE
PRODUCT CONDENSER
EAST ELEVATION
UNIT 02: E-201
FIGURE 15.3 7 Unit-02: 02:E-201. Product Condenser Pedestal and Foundation.
~
z >
·~-~~~.-~·iE:,.•:--
·
e,
o
HP PAVING 100'-0"
-·.;-"""·~-~ ... 4 ~-,··E.2·.1' ~--~~· .~,
·..
~
~ "'é
NORTH ELEVATION
PEDESTAL ANO FOUNDATION
~ trj (fJ
~
e(fJ
y,
.,,;,:,
.Q
ñ
§ ;,:,
º
z> :j
o z
12'-2" 6°-1·
6'-1"
.•
6'-3"
·• . t
P-202 8
W. J0'-6" ~
P-202A
W. 2J'-6"
..
e,
.e
·•.
'
\:, 1
;.,
-e,
.
.
. . .. . . • .. . . . ,, .•
;,.,
11 •.
:
<1
b
.
1
b 1
;,.,
\ -..> /
¡::::::::.=-=-:.=-=-=.-=-:'!:-e==-=--=-:=, TOC ELEV.
<1
o1
·r,
e
101'-0"
HP PAVING 100' -0"
1
EAST ELEVATION
NORTH ELEVATION Hett·
PRODUCT
PUMPS
UNIT 02: P-202A
FIGURE 15.38 Urút-02: 02:P-202A & P-202B. Product Pump Foundations.
AND
P-2028
NOT ID flCN C
FOUNDATION
380
15. PROJECT CXX)RDINATION
6'-0" 1'-9"
2'-5(" , ·-9"
,·-2¡¡
1'-21i
..
1 ...
-·
A
.,,.
"
·.;..
"
.: ,q
A
..
~1
..,
1..,
,;
·~ '.
12-1• DI\. ANCHOR BOLlS EQUAU.Y SPACED ON A '5'-3" BOLT ORCU:
'1B'1 lo
1f1 lo
~
... 1
TOC EL 101'-0"
----1111 .
.
..
,.
1111'·
11: kj - I · 11 l. 11"·1
::
-.~:
::
1
1111·1111,1~ 1111 :11
'"
~
1
~~<:J
•
r
.,
16'-Jd¡"
SECTION A-A
COLUMN UNIT 02: V-203 FIGURE 15.39
H.P. PAVING 100'-0"
11 .1
UU.iü>IU . -:
:·:
-.-.•-.-.-.----------
PEDESTAL
Unit-02: 02:V-203. Colu.m.n Pedestal and Fou.ndation.
PIPE DRAFI1NG AND DESIGN
Noto· NOT JO
ANO
SCA1,E
FOUNDATION
14'-0" 7'-0"
4
.... 1
·.
;,, 'N
1
..
.... 1
;,, . 4
o·
'4
.
~- '°· I
-+----_.,-. -:-· ·~/~~ .,,j z 1·-0·
;,,
•4.
,__
.
· _4_·:
._.._·-+---
P-JQ!_ A P301 B
'. ·44,
'c,11,,J
.,
.,
. 4·.
E. 26'-0" E. 35'0"
\~~.'Ll__J: .: . ~~! . . . . . -
•
. 4.
....1
·"
< . ·. ~ _. 4
~ ..
---
j-.
1·
.
4· 4
7'-0"
.
·4
4
.
(.)
PLAN
5
:.!:
'------, TOC ELEV. 101'-0"
.; 4
4.·
., .. 4
., ·4
.... .,
4 4
.,
4
HP PAVING 100'-0"
4
:
"'
·4
... A ,
;,
/\
·.
• •
EAST ELEVATION
!tE·.•.,· · ... -
\o
·'
.
' ..
.. .
~
4
1
. .... t, 4 4
« •,
'4•
------~
..
,..
.
NORTH ELEVATION Note· NOT TO $CALE
REBOILER PUMPS UNIT FIGURE 15.40
03:P-301
Unit-03: 03:P-301A & B. Reboiler Pumps Pedestal and Foundation.
A& B
PEDESTAL ANO FOUNDATION
12·-o·
.
o Ul
o 1 -;.¡.
=r
.
··4. . ·· ••·. . .. .°
·"
...
•
.>· . : ••••
•
i,:;1·
1
. ·..•..·. •.
1
1
1
.L·
1
•
...
• .., ••
.. <11
••
J: ..:' . :
.
• ~· .=.:I=,.:::!
•
ft.
03V303 E. 30'-6"
• ...
•o
o
,1 1
~I
1
\
~
1
\l_
_J :----g
---roe
_J
ELEV. -103'-9"
L
1
/
i,/ .•· .·
..
1'-0
1'-5"
,'
~ 1
io
4 ,'
. '·
Note: NOT TO SCALE
LIQUIFIED FIGURE 15.41
..
." 44
.
1 /2° EXPASN. JNT.
HP PAVING 1 00' -0"
.
W.lL (TYP)
EAST ELEVATION
PHONIUM SEPARATOR
1'-5"
2'-10"
NORTH ELEVATION
UNIT 03: V-303 PEDESTAL
Unit-03: 03:V-303.Liquefied Phoniurn Separator Pedestal and Foundation.
ANo
FOUNDATION
383
MECHA1'1CAL EQU!PME1'T: FOOTINGS, FOUNDATI01'S, ANO PEDESTALS
z
~ o z
ª
~·. ,, " ~··.' ~~-~·· .
"
A
A
--~
,s·Y
.Jº.~15·
12-1" W.. ANCHOR BOLTS EQUAU.Y SPACED ON A
f8' -3" BOLT CIRCLE
PLAN ~10·-o·
TOC EL. 101'-0"
.
·
"11 11 . '11 •· 11 11 _.- 1 "11 . 11 11 _,, fJ 11 · 11 -11 11 - 11 11 . ·11 · 11 1 ~·" 11 • 11
~-.
t·
.,,.~ ·u.
11 11 11 11 11 11 11
PAVING 100' -0"
u
..
. ~I ·..
.1
~14'-0"
SECTION
A-A Note:
HEATER FIGURE 15.42
UNIT 03: H-304
PEDESTAL
Unit-03: 03:H-304. Heater Pedestal and Foundation.
PIPE DRAFilNG AND DESIGN
AND
NOT TO SCALE
FOUNDATION
384
15. PROJECT CXX)RDINATION
5'-4"
1'-~· 2'- •
1·-1¡·
1'-&i 1·-1¡· •
-"'1
. •.. .. ..
si'
•
.
A
·,
4.,,·:
.
::."':o
{FOl-'10,t,~N
1
• co
--:":'-o
io
."'"' "'""' 1
·~_'!'. :.... 12-1 • OIA. »1C1<0R l!Ollli EQlW.LY SPACm ON A _.. -s· l!OLT CIRCLE
1
. -"'
_...;: 1
"'
TOC EL 101 '-0"
H.P. PAVING 100'-0"
1
1
,n,....,nWm,...,,..,.,...,,.I
..... ..,.. 1. FLARE STACK FIGURE 15.43
: ,
• •
.
·""=
. . ...; -.1·.,· ' . _. . ..
"
.. ~ ..
......
..•
."' 1
·~-·
.....
.1 SECTION A-A
UNIT 03: FS-305
Note: NOT TO SCALE
PEDESTAL AND FOUNDATION
Unit--03: 03:Fs.305. Fiare Stack Pedestal and Foundation.
PIPE DRAFI1NG AND DESIGN
385
MECHA1'1CAL EQU!PME1'T: FOOTINGS, FOUNDATI01'S, ANO PEDESTALS
5'-4"
1·-~· 2·-ia· 1·-~ ·-11 ·-11 . ".
... . . ... el • :-
..
~ 1
~-
A
. ~ .•
"
...x í •
~I
..
,q·
~
A
~~ ~f ~ o, 1
..
~
io
1
;,,
1
"' ... x
12-1" DIA. NOIOR OOllS ElllW.LY SP~ED ON A "4'-e" OOlT
CRCtE
í
•
TOC EL. 101'-0"
.
co 1
"' 13'-11
SECTION
A-A
COLUMN UNIT 04: V-401 FIGURE 15.44
.1
1/2"
PEDESTAL
Unit-04: 04:V-401. Column Pedestal and Foundation.
PIPE DRAFilNG AND DESIGN
Noto· NOT TO SCALE
ANO
FOUNDATION
{
4'-6"
1·
..
" . "
..
.. 1 " 04E402
E. 28'-0" &
t
"
•(3 ..
1 ...
..
..
A& B
~
..
E. J6'-9"
..
""
15'-0"
1
"°'
1
•
1
~I
~I
v¡I
v¡I
~
PLAN
~
;;; -e
'§º ~
I!!!!
~::~-«)
~~~1]: _
~
'
__ - --~~~--TO_C_E_LEV_._10_3_'-_4" __
HP PAVING 100' -o·
1
in
~' ' '
,{
;<>
º
z ~ ~
'
2·-0·
1 /2" EXPASN. JNT.
MATL (lYP)
c•;.,r:.~.-··,"',.
Note· NOJ JO SCALE
EAST ELEVATION
PRODUCT CONDENSER UNIT 04: E-402 A&B PEDESTAL FIGURE 15.45
Unit-04: 04:E-402A & B. Product Condenser Pedestal and Foundation.
NORTH ELEVATION
AND
FOUNDATION
,s·-o·
.
d
V)
.;
.' r 1 1 1
1 1
4
04-E-404
"'4
~
1
-:.,.
E:. 8'0"
:¡ 011
n •
TOC ELEV.
,o·
•4
.,,, 1
.
1
~
<
---~m • <
.:
.: ·.•. .
.
11
104'-0 3/4"
HP PAVING 100'
-~
.
:
3'-0"
1 /2' EXPASN. JNT. MATL (TYP)
-o·
. 4
"
.. '
EAST ELEVATION
NORTH
ELEVATION Note· NOT TO SCALE
PRODUCT REBOILER FIGURE 15.46
UNIT 04:E-404
Unit-04: 04:E-404. Product Reboiler Pedestal and Foundation.
PEDESTAL
ANO
FOUNDATION
~
00 00
11 '-10" 5'-11"
..
5'-11"
5'-11·
.. •.
.
b
•
..
o1
. ·b..
tP405~
f:. 14'9"
.~~...
. .
..
i !~~1 \__lo
,I ~
P405 BUJE:. 21'J"
1
1
.
e,. b
• •..
•
~
·.~
•
o
o
.b.
.,...---¡.', -.b.
. ... -
¡,.,
b:
_.._ ~
.b.
'.
-~1·-0·
~o
~ ·.
':
., t.~·
o ~
. t.·
11~~--1---------'---'--L-
~1f:
PLAN
---~-4
..
.
ll~---~_>_ . _. . _. _·
«: .
. f ü. , . _.~~-~===Ir TOC ELEV. 101'-0"
.... "·
HP PAVING 1 oo' -o·
. ~ :
C>
1
N
.
~
4-~-·_"~_··._.
1
:--
EAST ELEVATION
.
. ....-..-:·.,.
.
. ..
.
•
e '.
•
..• •
.
.
NORTH
·-
.•
<1:
.
.... .
.1
. .. •
4_. .
ELEVATION Noto· NOI TO $CAlE
COOLING WATER PUMPS UNIT 04: P-405A FIGURE 15.4 7 Unit-04:04:P-40SA& P-405B.Cooling Water Pumps Foundation.
AND
P-4058
FOUNDATION
..·· ~ : .....
···..,~, i <: ..•. : .,•• ,:··.···.: ··~· .• ,.. ~ ....... .' :.·· :·:··
ro
..~ ...··:-.
. ... . . .
.
. . ... ~ ·
...
-~.·, ··~ ,: ".
. .
o o 1
1
N -t
·:.,. ...
'•/·
.;.:·...·
·:.: ... : .. ....
_,: -..~~
·:,
.... .. ,:.... .. ~
,('.'
ro
13,_6•6 ---------1-5• 1
.....
·.
__, I
•
• PLAN
n- --n- - - ~- 11
11
11
1 1
1-J -+-----~-~ 6"
n- :
-~LJ!LET 11
5" CONCRETE BASIN WALL
o1
11
SUPPORT LEGS
11 11
ff
- - -¡;-~OUTLET+ 11-11 11
11
11
11
r-,
SECTION
A-A
SECTION
8-8 NOTE: NOT TO SCAI..E
COOLING FIGURE 15.48
TOWER
BASIN
& FOUNDATION
Unit--04: 04:CT-406. Cooling Tower Basin and Foundation.
UNIT
04: CT -406
z::si ~
1' •
~ ~
~
OETAIL 2. IA
uwr 112m Sll'POIU:-. ~11CW"" OETMS
~
COUIN. '8'
W.3J-0
I
~
12"
ti. I,2 ,;a··
~
t
~
W12x65
00
DETAIL 2.18
DETAIL 2.1A
STRUCTURAL SHAPE S/ZES
Q e-
i~eo tr.l 00
DETAIL 2.18
~'¡;j TOS
a:
110·-o·
...... ~ t""tr.l
;;; "O
'§º ~
;<>
z e º~
W12Jc6.5
00 00
::g
o
Wl2Jc65 (M".)
COUIN. 'A'
w.s·c·
~
:{J
DETAIL 2. IC
~
roe a tovo:
> z
H.P. PAVING 100'-0"
NORTH ELEVATION
DETAIL 2.1C
Note· NQT TO SCALE
UNIT 02: PIPE SUPPORT FIGURE 15.49 Unit-02:Pipe Support Plan, Elevations,and Details.
PLAN, ELEVATION
ANO
DETAILS
SJ, tr.l etr.l
~
:::3 ~
00
> z
t:,
~
~I
~I
@º"" 02 IIPS-J.I &
.J.2
DITAIL 2A
TOS
ros ELJ 12·-o·
EL 114'--0"
DITAIL JA
ros a. no·-o· WIOxJ9
(rlP.}
DITAIL 28 , • THCI(
PV.n:.
". SQ.
(rlP.}
DITAIL JB
roe a.rer-e: H.P. PAVINC
NORTH ELEVATION
NORTH ELEVAVQN
EAST ELEVAVQN
,oo·o·
NORTH E;LEVATION Note· NOT TO SQ\LE
UN/TS 02 & 03: MISCELLANEOUS PIPE SUPPORTS 3-6 FIGURE 15.50
Units 02 and 03: Miscellaneous Pipe Supports 3-6.
8"
-1 Q
I
W8x31
8"
1
8"
1 I tL
W10x39
10,,
1
DITAIL JA
DITAIL 2A
STRUCTURAL SHAPE SIZES
roe
roe
EL 101·-o·
H.P. PAVING 100' -o·
OITAIL 28
EL 101·-o·
H.P. PAVING 100'-0"
OITAIL 38 Note· NOT TO SCALE
UNITS 02 & 03: CONNECTION DETAILS 2A-3B FIGURE 15.51
Units 02 and 03: Connection Details 2A-3B.
¡!.;:t'
- s: so.
,_
.
vr
o
~ MPS-8_
UNff
.
1
;..,
WBxJ1 (TYP.)
2·-9•
CH: COIIHfC'OOHDf:rAILS '4 - O
.
..
,,,.
o.1 "'l
so. a·
DETAIL 4A
•
J ~
1
"'
..;
81
TOS El.. 112'
-o·
DETAIL 4C
DETAIL 40 1/HfT
CH: CtJNNf.COON Df:rNI.S '4 - O TOS f'.L.110'-0" (TYP.4)
W10xJ9 (TYP.)
DETAIL 48
roe
E:L.101·-o·
1 • THCK PLATE:, 11 " SQ. (TYP.)
H.P. PAVING 100'-0"
fAST ELEVATION
NORTH ELEVATION
NORTH ELEVA TION
NORTH ELEVAVON
NORTH ELEVATION Note· NQT TQ SCALE
UNIT 04: MISCELLANEOUS FIGURE 15.52
Unit-04: Miscellaneous Pipe Supports 7-10.
PIPE SUPPORTS
7-10
11• SQ.
2·
1'-6"
2·
-;-;-t1
!
l'-6"
1
TOS EL 110'-0"
W8xJI
u;, ~i1-·x 1'8" LC.
1• THCK PLAIE
5/16°
5/16"
DETAIL 4A
DETAIL 4C
8"
TOC EL 101'-0"
W8x31 -i
H.P. PA\lfNG 100'-0"
y o, " 1 ..,
W8xJ1
º1~
W10x39
I
Q
8"
1
I u70,,
-j
8"
1
OETAIL 48
DETAIL 40
STRUCTURAL SHAPE SIZES Note: NOT TO SCALE
UNIT 04: FIGURE 15.53
Unit-04:Connection Details 4A-D.
CONNECT/ON DETAILS 4A-0
...,
o
-
~ \Jl
U\
~ e
2.
'7
~
t!J
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,~
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s
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1
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;
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UNIT-03
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- --
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PS-L,. -
UNIT -03
_J
---
MATCHLINE
o' -0"
'§º ~
;<>
º~
i'et::.5 z
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30 MODEL VIEWS: UNITS 01--04
30 MODEL VIEWS: UNITS 01-04
FIGURE 15.62
Northeast view of Units 01, 02, 03 and 04.
PIPE DRAFTING ANO DESIGN
403
404
FIGURE 15.63
15. PROJECT CXX)RDINATION
Southeast view of Units 01, 02, 03 and 04.
PIPE DRAFI1NG AND DESIGN
30 MODEL VIEWS: UNITS 01--04
FIGURE 15.64
Southwest view of Units 01, 02, 03 and 04.
PIPE DRAFTING AND DESIGN
405
406
FIGURE 15.65
15. PROJECT CXX)RDINATION
Northwest view of Units 01, 02, 03 and 04.
PIPE DRAFI1NG AND DESIGN
AppendixA Dimensional Data-p.
408
AppendixB Alphabet of Lines-p.
448
Appendix C Review of Math-p.
449
AppendixD Use of the Calculator-p. Appendix E Architect's Scale-p. 453
450
Appendix A: Dimensional Data
WELDED FITTINGS-FLANGES NOM. PIPE SIZE (in)
O.O. Of PIPE
F 1
WT
E T
V 90l.R. ELL A
45.L.R. ELL O N G fil HALF TEE s 8- REDUCER L I
4)
B
e
H
A STO.
B
90' &
45·
T K T E
+nt
N U G p
~
1
F
R
3i 4-12
FA
w~ NE
R
1
F
TA
J ~ E
s
1
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1
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o
l~I~
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1
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1 -
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NOTE:
_
/T_J L
l
6"
8"
1 o" 12"
6 9 12 15 212 3J4 5 12J4 17
8i 6
9
82 12.J4
18
14"
16"
18"
14
16
18
21 g.J 11 13
24 27 10 11-l 12 13~ 14 15
21
24
4
12 17
9 12~
5
5J4 6 .i8
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11
12~ 14i
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1 o-14 12 13J4
16 19
3Z8 4~
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7
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1 1 13~
16
15 16
3 15 16
3i 1
4
4
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9
11
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16
3t 3j 1136 1.l4 3 .J. 16 16
4t 1~
4t 1,76
16
16
6
o
6
21 2-i
27 11t
5-12 7-14
2~ .J
T G
4"
5-12
L T
L
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- 1=-r
4i 2
3 1J8
D
TEE&WN FLG 45º&WN FLG
3"
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trJf 90º&WN FLG
1" 22
2 .J.8 2Z8 3i 41.2 5.2.8 s.2.8 1 o.J.4 12.J4 3 3-¡3 4i 6 9 12 15 18 1 J8 1 J4 2 2~ 3Í 5 6t 712 212 3 3j 418 5 .§.8 7 8~ 10 3 31.2 31.2 4 7 8 6
4J
E F M IA
2"
150# RFWN
22~ 26
19
16
29 32~ 17 1914 15
19
21 2312 25 5 5 5~
4~ 7 9 1i 115 1t 1i 115 1 f6 4 8 1 / 16" RAISED FACE INCLUDED ON 'L' & T DIMENSIONS i
2-i
7 3
1
1i
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16
3
16
ALL DIMENSIONS
3
1~ 3 16
3
.J.
.J.
ARE IN INCHES 408
19
4j
21 2312 25
si
5t st 112 1 .§.8 1.U 16 1 16Ll 1 1 1 .J. 16 8 8 8
150#
409
APPENDIX A: DIMENSIONAL DATA
VALVES
150#
NOMINAL PIPE SIZES (in) O.O. of PIPE G
A
T
E
G L
V o A EB
[z~---tr _
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----'=:-
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1
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6~8 8~8 10i 8 1ot 111 13 20i 35-l- 44 52~ 14 16 18 9 16 19t 9i 24~ 26 16~ 9 12 16 11-i 17Í 21¡ 26~ 28,76 29,76 38 39-l 46-l 13-A- 13i 16 16 21i 3t
4t 9 25Í 10 11 i 19~4 10 13¡
9~ 1 1 .12 14 6 7 9
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G L
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1
? PIPE SIZE
[~? [~
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1-L-J __[H
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71 2 8 21 9 21
9 10 st 10 12 1 H 13i 16~ 19i 9 10 8 L 10t 12t 14! 8
o H
o L H
14 15 16 17 60~ 70f 79i 89 18 22 24 27
19~
10:t 12i 13-i
18
20~
150# RF
H 15i 20i 25t
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16 18
* * * * * * * * * * * * * * * * * * * * * 24i 27~ 35 39
NOTE: All DIMENSIONS ARE IN INCHES • REFER to VENDOR CATALOG
G A T
12j 14
11 35t 14 16~ 24~ 12
12 13~ 14~ 15~ 16~ 17~ 43 52i 60i 70t 79Í 89 14 18 18 22 24 27 20 26 16 18-l 21Í 27
27Í 28t5 29,76 38 39.¡. 13i 13-! 13-! 16 8~
10
5
6
16
12 14t 20 7
* * * * * * * *
9
NOTE: ALL DIMENSIONS ARE IN INCHES • REFER to VENDOR CATALOG
PIPE DRAFilNG AND DESIGN
* * * * * * * * * * * * * * * 46f * * * 21-! * * * 25 28 35-l 39-l
1ot 12t 13t 18 20~
150#RTJ
* * * * * * * *
410
APPENDIX A: DIMENSIONAL DATA
WELDED FITTINGSFLANGES , ..
NOM. PIPE SIZE (in) F 1
O.O. Of PIPE
u 90l.R.
ELL tP 45l.R. ELL D N fil HALF TEE G s D- REDUCER
W T E T L I
,
STO.
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6t 7! 2t 3 2
18
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TEE&WN FLG 45"&WN FLG
o
16
21 24 27 8t 10 11{ 1 1 12 13t 13 14 15
9 3 3t 4-± 6 1.J.8 1 .J.4 2 2t 3.J.4 4j st 6t 12t 9 3-k 3¡ 4i 6 4{ 5 -2.8 6i Bf 12{
4-lf 4t
14" 16" 18"
12 5 7
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NOTE:
3"
6t
1
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22
5t
1
1 1
2"
90º&WN FLG
1 ? I&
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Lb F M IA
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90" &
A
300# RFWN
8.}
st
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2i
T
T
ALL DIMENSIONS
T
ARE IN INCHES
PIPE DRAFI1NG AND DESIGN
300#
411
APPENDIX A: DIMENSIONAL DATA
VALVES
300#
NOMINAL PIPE SIZES (in) O.O. of PIPE G
A
T
L~~1 /
E
i-
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...
l
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2
3 4
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4f 12 28{10 14 24f 14 14-}
6
8 10 12 14 1 6 18
6i 8! h Ot 1s¡ 16f 18 38i 47 56f 14 16 20 17f 22 29i 36f 18 24 18i 22¡ 27Í
12j 14 19i 30 64-l- 74i 20 27
16 33 80-a27
18 36 91 30
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V 6 A a \1
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8 9 10 L 11 ti 13i 14i H 17t 20t 241 9 10 14 L 11 i 13i 15i H 27¡ 28~ ~9~ 13i 13i 13i L 11 l 13i 14i H 6j 8f 9Í
o
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14 16 20 20 27 18-t 22! 291 36J 18 24 19t 23 28f 38 39t 46t ·15 16 21i 18i 21i 25i 28i 11 i 14 15 16Í
NOTE: ALL DIMENSIONS ARE IN INCHES • REFER to VENDOR CATALOG
PIPE DRAFilNG AND DESIGN
27
* * * * * * * * * * * * * * * * * * * * * * * * * 300#RTJ
30
*
* * * * * * *
412
APPENDIX A: DIMENSIONAL DATA
WELDED FITTINGS-FLANGES 2" 221" 3"
NOM. PIPE SIZE (in)
O.O. Of PIPE
F
1 W T E T
t? 90l.R. ELL
ON
é HALF TEE
4} 45l.R. ELL
A B
s f3- REDUCER
H
L I
G
,
STO. 90'
o-
e
A
f
A
& 45"
B ~
~
E
L:::j F M IA
e B
e o
E
2i 2i 3 3t 1! 1t 2-t 3 3 3-l
3t
600# RFWN
4"
6"
3f 4t 4! 6 2 2t 3Í 4-t 3f 4
6j
8" 1 o" 12" 14" 1 6" 18"
8-º-8 1 Oj 9 12 15 3t 5 6f 5! 7 8 -t 7 5 -t 6
9 12 1.J.8 1 .J.4 2 2.12 3.J.4 5 4j st 6 f 8f 12-i 17 3i 3¡ 458 6 9 12 4t 5j 6Í 8 21 12t 17 3
4t
6
15 6t 21t 15 21-l-
12-i 14 16 18 21 24 7f 8{ 10 10 11 12 8 13 14 18 71 2st 18 25-t
21
24 81 10 29-i 34 21lt 2411 2~ l3411
18 27 11t 13f 15 27 11-l38-} 2711 38,Í
90-&WN FLG 6-t 7-k 8 1 ot 13Í 17! 21.} 24! 27t 31t 34t T K 6j 51.8 8Í 1 o-t 12-t 14t 16Í 17t 19.} 22-t si T E ~ TEE&WN FLG 1 N U G p sat 45º&WN FLG 4t Si st 6t 8! 10-t 12-t 13-fr 15f 171 18-i ~
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s F
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1
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t-;'cf'\lG o 1 -
1
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NOTE:
_ I~
1=--r
/r-' r
L
T
G
61
7! 8t 10t 14 16-t 20 22 23-i 27 29f 3t 3! 3f 4t 4! s-t 6t 6! 6t 7-r 7t 1t 1! 1-t 1 t 2-t 2ts 2 -i- 2t 3 3f 3-t 1 / 4" RAISED FACE INCLUDED ON 'L' & 'T' DIMENSIONS 6! 7-t 81 10t 14 3(6 3ts 3& 4(5 41-i 1+ 1i 1t 2 2i 3 3 3 fg fs 16 16 16
ALL DIMENSIONS
1 6f 20 22 23t 27 29-l5(6 6fs 6ii 5-ij 7(6 7~ 211f6 3 3t 3f 3f 3-t fg fs ls fs f6 fs
ARE IN INCHES
PIPE DRAFI1NG AND DESIGN
600#
APPENDIX A: DIMENSIONAL
413
DATA
VALVES
600#
NOMINAL PIPE SIZES (in) O.O. of PIPE 1 1 G ---A r ; - o1
--
T
E
H
G
r
L
V e E No
s
----~tr?
1
L
V o A BE
T
R
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H
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3 4
6
2¡
3~
6j 8j
11~ 14
H
18t 8 11 t 19 10 11 t
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H
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H
l25i 10 14 23! 12 13-l
4~ 17 32 14 17 27t 18 15t
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35
24 20
13i 13i 13i
16
11-!
22
14
17
9 1ot 13-!
7
to VENDOR CATALOG
REfER
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r;
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1-- PIPE stZE
L
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14i l25t 10 14-k 23-! 12 13i
17i 32 14 17i 27-! 18 15i
13-k 13i 13i
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11
H
16
18
35
39 43 r:nt 83j 93i 30 30 36
* * * * * * * * * * * * 24 t29j * * 39,l 46-l* * 16 21i * * 26 31 33 * 15-t 18Í 21-! *
* * * * * * * *
* * * * * * * *
600# RF
NOTE: ALL DIMENSIONS ARE IN INCHES
*
o.l4 12-i 14
22 26 31 33 f42i s2t 62t 70 20 24 27 27 22
Q7Í 28fs 29(6 38
L H
t-L-1 ~H
H
L
8 10 12 14 1 6 18
2
7
22i 26-a- 31-a- 33i 35-k 39-A 43i f4-2 Í s2t 62t 70 77i 83i 93'.f 20 24 27 27 30 30 36 22i 35 24 20i 24i Q9j 16
14-a- 17-a- 22i 9 1ot 13t
NOTE: ALL DIMENSIONS ARE IN INCHES • REFER to VENDOR CATALOG
PIPE DRAFilNG AND DESIGN
* * * * * * * * * * * * * * 39-l- 46-l* * 16 21i * * 26i 31i ~3i * 15-! 18j 21~ *
* * * * * * * *
600# RT J
* * * * * * * *
414
APPENDIX A: DIMENSIONAL DATA
SCREWED FITTINGS NOMINAL
PIPE SIZES (in) 3000 # A 90ºELL
~
Afi]
6000 # 3000 # TEE
6000 # 3000 #
A A A B B
45ºELL 6000 #
~
cc=i
e
3000 #
-E:3
@J
COUPLING 6000 #
e o
3000 #
UNION
6000 # D NORMAL THREAD 3000 # ENGAGEMENT 6000 #
rt3¡? r~ H
1111
~
T
PIPE SIZE
S-J
1
1
G A E
G L
o
B E
L
H
o L
H
o
1" ?
4
3"
1"
1.1 2
13 4
13 4 5 1.1 116 2
2
5
116 1.1 2
1.1 2 1
13 4
A G E
_J
~ e=:>
s
2"
1" 22 3"
2.J
8
2.1 2
Yg
31
2.J 2..1 8 2
31
3Í
415
2..1 3i 2
3l.
2
2
2i
8
5 1li 1li 123 1 1...l. 1f6 8 32 16 32 215 2~ 23 2-º- 3.1 3.J 1l 8 2 8 8 8 8 3i
1l
8
4
3
4
3 1 3 2 2.J 2.1 3.J 33 4 8 2 8 4 415 5 7 1 1...l. 1f6 116 111 8 16 2 215 2~
2
2.J 8
2...l. 2165 2..1 8 2
31 8
4..l 4
3i 4..1 4 213 3-1 3...l. 315 41 16 8 2 16 2 2-2· 3.1 33 8
8
8
3 5115 2Z8 3.J8 358 3Z8 4153 4-28 515 16 1
2 1
2
9
16 9
16
11 16 11 16
3196 4 .1 2 4i
si2 si4 4
3i
9,\
si si
4'º8 6-;t
s.1. 8
8t5
1~
4
4~
5..Q_
4
4
s t=i 14 14 V4
w
1-41" 121"
11 16
16
11 16 11 16
5
5.1
11
2
.J 4
.J
16
15
1
7
* * * * * *
* * * * * *
8 11,76 14,t 2
7
8
7
7j
9
1
, ,i2
12,~ , 4.l.2
8
8
8
V4
V4
14
TO TO TO TO TO TO
3/É
V2
23A 3
PIPE DRAFI1NG AND DESIGN
1
4
1O7
6
15 16
V4 114 TO TO
3t4
1 114 1 V2 2V4 21h
31h
4
4V2 6V2 7
8
415
APPENDIX A: DIMENSIONAL DATA
SOCKET WELD FITTINGS NOMINAL _L_H:b
Ái
o-' ~ D
SIZES (in) 3000 # A 90ºELL 6000 # A 3000 # A TEE 6000 # A 3000 # B 45ºELL 6000 # B 3000 #
PIPE
J-tf ,~~
o,~ '• .--
B
m:~D u
"1
o~] SOCKET 1
Lz
COUPLING
6000 # 3000 # UNION 6000 # 3000 # DEPTH 6000 #
---
L'
G
o
A T E
H~~
[)~ H •1 1
.
s,
==
1
-r o
~>---
1
G L
o B
E
e e E
E o o L
H
o L
H
o
s t:::i
w A G
E
____J
1--
:::::::> e:::,
s
3" 4
1" 2
1"
14
1-21 "
115
1~
1i
2
2i
d
1í
2
2i
2d
5
1i 5
115 1
5
1¿
115 1~ 5
115 1 7
8 1
d
1¡
1
1i
1
¡
2
2i
1" 3" 2" 22
2i
3
3j
3t
3i
3
3j
2 2d 3-¡. 3j 7 5 1 1f6 115 1 ll 16 215 2d
1i
5 1 123 115 1.11 32 1ll 16 32 215 2~
1
1í
1~
d 1d
27
33
1~
1"
1i
2
2~
2~ 2í
2d
2 2~ 1i 1~ 2i 5 2j_ 213 3..l 3..l 315 4j_ 2..l 8 215 2 16 2 8 2 16 8
1
2 11
16
8
9
35 8
5
16
8
3
7
4
8
3196 412
4Í
5--1.. 3--1..4 2
4 3~
5.Z. 8 4 ~
318 4163 11 16 15 16 5
2314
11.
11
11
1.2
* 1 * * 9 *
* * * * *
1
8 , 1.
512
7
s1 5¡
4-º-8 6-l-
e 116 1Ü*8 4.J
52.
~
1/4
4
7
3 516 51º 16
8
8
2
91\ 1 o.z. 8 11,76 14, 5..l 7 8 2
4
7
7i
11--1.. 14..l2 2 12,36
-X-
8
8
-,(-
~
1/4
8
1/4 1/4
TO TO TO TO
3/s
3
4
4-º-8
8
8
-X-
1Ai
TO TO TO TO 1 3/4 11/4 11/2 21/4 21h 1/2 3 31h 4 41/2 61/2 7 8
PIPE DRAFilNG AND DESIGN
416
APPENDIX A: DIMENSIONAL DATA
WELDED FITTINGS-FLANGES
NOM. PIPE SIZE (mm) 1
if790l.R. ELL L I ~ 45l.R. ELL O N G fil HALF TEE s -E3- REDUCER
WT E T
1-
,
STO. 90' &
f
A
45·
e
E
B ~
'
L ::::::i
F M IA
~
T K
T E ~ 1
N U
G p
76.2
101.6 152.4 203.2 254
304.8 355.6 406.4 457.2
60.3
73.0 88.9
114.3 152.4 203.2 254
304.8 355.6 406.4 457.2
76.2
95.3 114.3
152.4 228.6 304.8 381.0 457.2 533.4 609.6 685.8
34.9
44.5
50.8
63.5
63.5
76.2
85.7 104.8
H
76.2
88.9
88.9 101.6 139.7 152.4 177.8 203.2 330.2 355.6 381.0
A
76.2
95.2 114.3 152.4 228.6 304.8 381.0 457.2 533.4 609.6 685.4
B
34.9
44.5
e
111.1
139.7 165.1 215.9 323.9 431.8 539.8 647.7 755.7 863.6 971.6
D
79.4
98.4
E
114.3 142.9 168.3 215.9 323.9 431.8 539.8 647.7 757.2 865.2 973.1
~
B
e
1
1
o
L
T
254
279.4 304.8 342.9
95.3 127.0 158.8 190.5 222.3 254.0 285.8
117.5 152.4 228.6 304.8 304.8 457.2 535.0 611.2 687.4
TA
L
J ~
~~~~
s
l
T=r L
368.3 406.4 431.8 482.6
98.4 114.3 120.7 139.7 184.2 228.6 260.4 304.8 349.3 381.0 482.6
152.4 177.8 190.5 228.6 279.4 342.9 406.4 482.6 533.4 596.9
635
63.5
69.9
69.9
76.2
88.9 101.6 101.6 114.3
127
127
139.7
19.l
22.2
23.8
23.8
25.4
34.9
36.5
39.7
28.6
30.2
31.8
1.6 (mm) RAISED FACE INCLUDED ON 'L' & 'T' DIMENSIONS
o
F
L
E
63.5
142.9 177.8 215.9
127.0 146.1 155.6 181.0 231.8 279.4 317.5
1
R
50.8
95.3 127.0 158.8 190.5 222.3 254.0 285.8
TEE&WN FLG 45º&WN FLG
L
1
A
139.7 165.1 184.2 228.6 317.5 406.4 482.6 571.5 660.4 736.6 825.5
F
FA
63.5
90"&WN FLG
l?I~ w~ NE \ i; 'r s R
50.8
O.D. Of PIPE
F
150# RFWN
T
G
152.4 177.8 190.5 228.6 279.4 342.9 406.4 482.6 533.4 596.9 635.0 69.9
76.2
76.2
82.6
95.3
108
108
120.7
133.4 133.4 146.1
25.4
28.6
30.2
30.2
31.8
34.9
36.5
38.1
41.3
42.9
46
4.8
4.8
4.8
4.8
4.8
4.8
4.8
4.8
3.2
3.2
3.2
NOTE: ALL DIMENSIONS ARE IN MILLIMETERS
PIPE DRAFI1NG AND DESIGN
150#
417
APPENDIX A: DIMENSIONAL DATA
VALVES
NOMINAL PIPE SIZES (mm) O.O. of PIPE
~-*=~?
1
G L A .L T
E
G
L
V o
A L
B
E
.__
H
L.- PIPE SIZE
\-
1--H--l
V e
E o
s R~ I¿ o
~~i~~ ¿ /
/'
1
i---H-
L
e
t-L-J __[H
H
N-,
E
e K
L
H
o L H
-----_-h?
1
150# 50.8
76.2
101.6 152.4 203.2
60.3
88.9 114.3 168.3 219.1 273.1 323.9 355.6 406.4 457.2
254
177.8 203.2 228.6 266.7 292.1 330.2 355.6
G
A T
1
203.2 228.6
254
* * * o 203.2 228.6 254 304.8 406.4 ** ** ** L 254 298.5 352.4 450.9 542.9 673.1 * * H 708.0 722.3 747.7 965.2 997 1174.8 o 333.4 333.4 333.4 406.4 406.4 536.6 ** ** L 203.2 241.3 292.1 355.6 495.3 622.3 698.5 889 H
t )
E
G L
V o
A BE
-H-
s
T
R
o
\-
------tt,- ?
L .L
----·i~
H
1
?
H-
L
N~H
e
H
E
e
K
NOTE: ALL OIMENSIONS
*
.._. PIPE SIZE
1
L V e
E oN
¿¡
REFER
406.4 431.8
355.6 406.4 457.2 457.2 558.8 609.6 685.8
203.2 241.3 292.1 406.4 495.3
349.3 419.1 501.7 622.3 660.4
.
127
152.4 177.8 228.6 260.4
308
* * * * * * 990
349.3 457.2 520.7
*
* * *
*
* *
*
150# RF
to VENDOR CATALOG
----·lrt,
381
400.1 527.1 654.1 895.4 1092.2 1333.5 1536.7 1784.4 2025.7 2260.6
NOTE: ALL OIMENSIONS ARE IN MIWMETERS • REfER
304.8 355.6 406.4 457.2
L
190.5 215.9 241.3 279.4 304.8 342.9 368.3 393.7 419.1 444.5
H
400.1 527.1 654.1 895.4 1092.2 1333.5 1536.7 1784.4 2025.7 2260.6
o
203.2 228.6
H
349.3 419.1 501.7 622.3 660.4
H
127
1
254
355.6 406.4 457.2 457.2 558.8 609.6 685.8
* * * * * * * () 203.2 228.6 254 304.8 406.4 * * * * * L 266.7 311.2 365.1 463.6 555.6 685.8 * * * H 708.0 722.3 747.7 965.2 997 1174.8 o 333.4 333.4 333.4 406.4 406.4 536.6 ** ** ** L 215.9 254 304.8 368.3 508 635 711.2 901.7 1003.3 215.9
254
304.8 419.1
508
152.4 177.8 228.6 260.4
ARE IN MIWMETERS
to VENOOR CATALOG
PIPE DRAFilNG AND DESIGN
308
349.3 457.2 520.7
150#RTJ
* * * * * * * *
418
APPENDIX A: DIMENSIONAL DATA
WELDED FITTINGS-FLANGES
NOM. PIPE SIZE (mm) 1
WT V90l.R. ET
ELL L I ~ 45l.R. ELL O N G fil HALF TEE s -8- REDUCER ,
STD. 90' &
IA
TK T E 1
N U G p
F
D-
l E
A r..
45·
FM
e~
TA J ~ E
s
60.3
73.0
88.9
114.3
304.8 355.6 406.4 457.2
76.2
95.3
114.3
152.4 228.6 304.8 381.0 457.2 533.4 609.6 685.8
34.9
44.5
50.8
63.5
63.5
76.2
85.7 104.8 142.9 177.8 215.9
H
76.2
88.9
88.9 101.6 139.7 152.4 177.8 203.2 330.2 355.6 381.0
A
76.2
95.2
114.3 152.4 228.6 304.8 381.0 457.2 533.4 609.6 685.4
B
34.9
44.5
50.8
111.1
139.7 165.1 215.9 323.9 431.8 539.8 647.7 755.7 863.6 971.6
79.4
98.4
A
B
e
e o
TEE&WN FLG sal- 45°&WN FLG
o
~IL1
F
304.8 355.6 406.4 457.2
~
NE
RL
101.6 152.4 203.2 254
tt3l 90º&WN FLG
lºI~
s
63.5 76.2
L T
\
- 1=-r
¡r:r
95.3 127.0 158.8 190.5 254
222.3 254.0 285.8 279.4 304.8 342.9
95.3 127.0 158.8 190.5 222.3 254.0 285.8
117.5 152.4 228.6 304.8 304.8 457.2 535.0 611.2 687.4
r
146.1
171.5 193.7 238.1 0000 415.9 498.5 587.4 676.3 755.7 844.6
139.7 152.4 165.1 190.5 238.1 288.9 333.4 384.2 422.3 450.9 501.7 104.8 120.7 142.9 149.2 193.7 238.1 276.2 320.7 365.1
165.1 190.5 209.6
254
317.5
381
400.1 444.5
444.5 520.7 584.2 647.7 711.2
69.9
76.2
79,4
85.7
98.4 111.1 117.5 130.2 142.9 146.1 158.1
22.2
25.4
28.6
31.8
36.5
41.3
47.6
50.8
54
57.2
60.3
1.6 (mm) RAISED FACE INCLUDED ON 'L' & 'T' DIMENSIONS
o 17-~\lG 1 _ _ 1.:J.. L 1 -
63.5
152.4 203.2 254
E 114.3 142.9 168.3 215.9 323.9 431.8 539.8 647.7 757.2 865.2 973.1
Ld
RL FA
w~
50.8
O.O. Of PIPE
F
300# RFWN
T
G
165.1
190.5 209.6
254
317.5
381
444.5 520.7 584.2 647.7 711.2
77.8
84.1
87.3
93.7 106.4
119.1 125.4 138.1 150.8
154
166.7
28.6
31.8
34.9
38.1
42.9
47.6
54
57.2
60.3
63.5
66.7
6.4
6.4
6.4
6.4
6.4
6.4
6.4
6.4
6.4
6.4
6.4
NOTE: ALL DIMENSIONS ARE IN MILLIMETERS
PIPE DRAFI1NG AND DESIGN
300#
419
APPENDIX A: DIMENSIONAL DATA
VALVES
300#
NOMINAL PIPE SIZES (mm) O.O. of PIPE G A
T
G
V A
Lz~tt~? __
E
6B
L E V e Eo
s R~
o L
H ____!:: .- PIPE S1ZE
6¡
H-
e
¡-L-¡ __[H
e
N----i-
K
254
60.3
88.9
273.1 323.9 355.6 406.4 457.2
114.3 168.3 219.1
304.8 355.6 406.4 457.2
0000 0000 0000 0000 0000 0000 0000 0000 0000 0000
H
469.9 590.6 717.6 968.4 1193.8 1435.1 1632 1898.7 2035.2 2311.4
u
203.2 228.6
254
355.6 406.4
508
508
685.8 685.8
762
* * * * * H o 228.6 254 355.6 457 609.6 ** ** ** ** ** L 0000 0000 0000 0000 0000 0000 * * * * H 708 722.3 747.7 965.2 997 1174.8 o 333.4 333.4 333.4 406.4 406.4 536.6 ** ** ** ** L 0000 0000 0000 0000 0000 0000 0000 * * * H 171.5 215.9 247.7 298.5 355.6 381 425.5 * * * 300# RF 0000 0000 0000 0000 0000
450.9 520.7 628.7 755.7 927.1
~f
H E
76.2 101.6 152.4 203.2
L L
[~?
50.8
NOTE: Ali DIMENSIONS ARE IN MIWMETERS • REFER
G A T E G L
V o
A L
B
E
V e
E o
s ~R
o
1
\- ;
1
\-
to VENDOR CATALOG
----
11:=-
o1 1
L
231.8 298.5 320.7 419.1
H
469.9 590.6 717.6 968.4 1193.8 1435.1 1632 1898.7 2035.2 2311.4
-H----= -PIPE stZE o
-----_1r? H
Lz~f?
L H
o L
H
-H-
e
o
¡-L-¡ __[H
e
----i-
L H
L
H E K
203.2 228.6
254
435
355.6 406.4 508
685.8 685.8
762
* * * * * * * * 609.6 * * * * 584.2 723.9 * * * 997 1174.8 * * * 406.4 536.6 * * * 549.3 638.2 727.1 * * 355.6 381 425.5 * *· 300# RT J
* * * * * * * *
282.6 333.4 371.5 460.4 574.7 450.9 520.7 628.7 755.7 927.1 228.6
355.6
457
282.6 333.4 384.2
489
708
254
473.1 51.7.5 777.9 854.1 930.3
722.3 747.7 965.2
333.4 333.4 333.4 406.4 282.6 333.4 371.5 460.4 171.5 215.9 247.7 298.5
NOTE: Ali DIMENSIONS ARE IN MILLIMETERS • REfER to VENDOR CATALOG
PIPE DRAFilNG AND DESIGN
508
420
APPENDIX A: DIMENSIONAL DATA
WELDED FITTINGS-FLANGES NOM. PIPE SIZE (mm) F 1
WT E T L I O N
50.8
63.5 76.2
101.6 152.4 203.2 254
304.8 355.6 406.4 457.2
60.3
73.0 88.9
114.3 152.4 203.2 254
304.8 355.6 406.4 457.2
76.2
95.3
114.3 152.4 228.6 304.8 381.0 457.2 533.4 609.6 685.8
34.9
44.5
50.8
63.5
76.2
85.7 104.8 142.9 177.8 215.9
H
76.2
88.9
88.9 101.6 139.7 152.4 177.8 203.2 330.2 355.6 381.0
A
76.2
95.2 114.3 152.4 228.6 304.8 381.0 457.2 533.4 609.6 685.4
B
34.9
44.5
O.O. Of PIPE t? 90l.R. ELL A fl 45l.R. ELL B
e
fil HALF TEE s 8- REDUCER
G
.J. STO. 90&
•
1
E
A
45·
e
B ~
r-
IA
T K T E \ N U G
p F
R L
FA
w~ NE
s
R
TA
E
s
63.5
95.3 127.0 158.8 190.5 254
95.3 127.0 158.8 190.5
222.3 254.0 285.8 279.4 304.8 342.9
222.3 254.0 285.8
111.1 139.7 165.1 215.9 323.9 431.8 539.8 647.7 755.7 863.6 971.6
o
79.4
E
114.3 142.9 168.3 215.9 323.9 431.8 539.8 647.7 757.2 865.2 973.1
98.4
117.5
152.4 228.6 304.8 304.8 457.2 535.0 611.2
687.4
V SI
90-&WN FLG TEE&WN FLG
155.6 181.0 203.2 260.4 352.4 444.5 539.8 619.1 704.9 793.8 876.3
~
45"&WN FLG
114.3
WTL'
lºI~
F L
J ~
50.8
63.5
e
L ::::J
FM
600# RFWN
o
L
T
o
L
~~~~
r=t"° L _J_
T
G
142.9 168.3 174.6 212.7 266.7 317.5 374.7 415.9 450.9
489
571.5
130.2 139.7 171.5 219.1 266.7 317.5 352.4 393.7 438.2 476.3
165.1 190.5 209.6 273.1 355.6 419.1 79.4
85.7
88.9
108
31.8
34.9
38.1
44.5
508
558.8 603.3 685.8
743
123.8 139.7 158.8 161.9 174.6 184.2 190.5 54
61.9
69.9
73
76.2
82.6
88.9
6.4 (mm) RAISED FACE INCLUDED ON 'L' & T DIMENSIONS 165.1 190.5 209.6 273.1 355.6 419.1
508
558.8 603.3 685.8
743
173 185.7 192.1
81
87.3
90.5 109.5 125.4 141.3
160.3 163.5
38.1
41.3
44.5
50.8
60.3
68.3
76.2
79.4
82.6
88.9
95.3
4.8
4.8
4.8
4.8
4.8
4.8
4.8
4.8
4.8
4.8
4.8
NOTE: ALL DIMENSIONS
ARE IN MILLIMETERS
PIPE DRAFI1NG AND DESIGN
600#
421
APPENDIX A: DIMENSIONAL DATA
600#
VALVES NOMINAL PIPE SIZES (mm) O.D. of PIPE G A
T E
[z~~?
G L
V o A BE L
[~?
E oN
~~i~-
L H
T R
o
Lr
L
e
H
E
/
_,1
o
rl-J __[H
L H
--r
e
60.3
88.9 114.3 168.3 219.1 273.1 323.9 355.6 406.4 457.2
203.2 254
355.6
508
482.6 596.9 698.5 254
708
889
304.8 457.2 609.6 508
722.3 747.7 965.2
333.4 333.4 333.4 406.4 292.1 355.6 431.8 558.8
f;~~
T
_
E
G
L 1
V o
8
A E L V e
E o
s R~
o
L
e
H
E
e
K
r
914.4
* * * * * * * * * * * * * * * * * * * * * * * *
600#RF
1
H
463.6 654.1 812.8 1085.9 1327.2 1581.2 1778 1962.2 2127.3 2381.3
H
__[H
* * * * * * * * * 609.6 752.5 * 997 1174.8 * 406.4 536.6 * 660.4 787.4 863.6
762
295.3 358.8
-----Jr? rL
1092.2
L
H __.:::::: .... Pf>E SIZE
~
990
1
..... o
lf:~-
889
609.6 685.8 685.8 762
177.8 228.6 260.4 342.9 387.4 476.3 546.1
NOTE: ALl DIMENSIONS ARE IN MIWMETERS • REFER to VENDOR CATALOG
G A
304.8 355.6 406.4 457.2
463.6 654.1 812.8 1085.9 1327.2 1581.2 1778 1962.2 2127.3 2381.3
285.8 336.6 393.7
1--H-
K
101.6 152.4 203.2 254
292.1 355.6 431.8 558.8
o
b1
76.2
292.1 355.6 431.8 558.8 660.4 787.4 838.2
o L H
V e
s
H __.!:::- PIPE SIZE
_
L H
50.8
o
o l
H
o L H
L H
203.2
254 355.6
295.3
358
254
304.8
708
722.3
333.4 333.4 295.3 358 177.8 228.6
NOTE: ALL DIMENSIONS ARE IN MILLJMETERS • REFER to VENDOR CATALOG
562 663.6 790.6 841.4 892.2 993.8 1095.4 508
609.6 685.8 685.8
762
762
* * * * * * * * * * 457.2 609.6 * * * * * 396.9 511.2 612.8 755.7 * * * 747.7 965.2 997 1174.8 * * * 333.4 406.4 406.4 536.6 * * * 435 562 663.6 790.6 841.4 * * 260.4 342.9 387.4 476.3 546.1 * * 435
482.6 596.9 698.5 288.9 339.7
o
435
562
889
PIPE DRAFilNG AND DESIGN
600#RTJ
914.4
* * * * * * * *
422
APPENDIX A: DIMENSIONAL DATA
FITTINGS
SCREWED NOMINAL
PIPE SIZES
(mm)
3000 #
p ~
~
(
'
8
l
1
'
cc=i
EJ 1
I
11111~
I
1
1
o
11111~ 1
NORMAL THREAD
ENGAGEMENT
90ºELL 6000 # 3000 # TEE 6000 # 3000 # 45ºELL 6000 # 3000 # COUPLING 6000 # 3000 # UNION 6000 #
1
1111
~
e e o
D
3000 # 6000 #
~g!E~E [~? s, 1
A A A A B B
G A T E G
L
o
B E
s
w A G
E
L H
o L H
o t::;:::¡ __J
1--
:=::::,
e::,
s
12.7
19.1
25.4 31.8
38.1 50.8 63.5 76.2
33.3
38.1
44.5 50.8 60.3 63.5 85.7 95.3
38.1
44.5 50.8 60.3 63.5 85.7 95.3 106.4
33.3
38.1 44.5 50.8 60.3 63.5 85.7 95.3
38.1
44.5 50.8 60.3
63.5 85.7 95.3 106.4
25.4 28.6 33.3 36.5 42.9 50.8 52.4 63.5 28.6 33.3 34.9 42.9 44.5 52.4 63.5
79.4
47.6 50.8 60.3 66.7 79.4 85.7
92.1
108
47.6 50.8 60.3
92.1
108
66.7 79.4 85.7
54
58.7
63.5 71.4
73
85.7
92.1
12.7
14.3 17.5 17.5 17.5
12.7 14.3
79.4 88.9
100 114.3
98.4 106.4 117.5 131.8 150.8
17.5 17.5 17.5
19.1 23.8 25.4 19.1
90.5 114.3 120.7 127 139.7 177.8 165.1 209.6 242.9 276.2 290.5 357.2 101.6 139.7 146.1 165.1 177.8 203.2 92.1 117.5 158.8 177.8 196.9 228.6 174.6 214.3 263.5 292.1 309.6 368.3 101.6 120.7 146.1 203.2 203.2 203.2 6.4
6.4
6.4
6.4
6.4
6.4
9.5
12.7
19.1 25.4 31.8 38.1
23.8 25.4
* * * * * * 6.4
* * * * * * 6.4
TO TO TO TO TO TO TO TO 95.3 76.2
PIPE DRAFI1NG AND DESIGN
57.2 63.5
88.9 101.6 114.3 165.1 177.8 203.2
APPENDIX A: DIMENSIONAL
423
DATA
SOCKET WELD FITTINGS NOMINAL
PIPE
LJt±J;¡
SIZES
f
90ºELL 6000 # 3000 # TEE 6000 # 3000 # B 45ºELL 6000 # B 3000 # COUPLING 6000 # 3000 # E UNION 6000 # E 3000 # D 6000 # D
o ~
º• ~ ti
1
1
'
B
"1
e e
1
fü:illfº
o~]
SOCKET
DEPTH
L>t:§ im ,1
[~9 s--¡
1
1
1
:::
A A A A
3000 #
t
oJ ~
(mm)
1
G
A
T E G
L
o
B
E
s
w A G E
L H
o L
H
ob ___J
1--
:=::::> e:::>
s
12.7
19.1 25.4 31.8 38.1
50.8 63.5
76.2
44.5 50.8 60.3 76.2
85.7
33.3 38.1 44.5 50.8 60.3 63.5 82.6
95.3
28.6 33.3 38.1
85.7
28.6 33.3 38.1
33.3 38.1
44.5 50.8 60.3 76.2
44.5 50.8 60.3 63.5 82.6 95.3
22.2 25.4 28.6
33.3 36.5 42.9 52.4 63.5
25.4 28.6 33.3 34.9 42.9 44.5 52.4 63.5 34.9
38.1
44.5 47.6 50.8
34.9 38.1 44.5
63.5 63.5 69.9
47.6' 50.8 63.5
63.5 69.9
54
58.7 63.5 71.4 79.4 88.9
100 114.3
73
85.7 92.1 98.4 106.4 117.5 131.8 150.8
12.7 14.3 17.5
15.9 17.5
19.1 22.2
19.1
22.2
23.8 25.4 28.6
28.6
38.1 41.3
6.4
6.4
6.4
6.4
6.4
6.4
* * * * * * 6.4
9.5
12.7
19.1
25.4 31.8
38.1
57.2
90.5 114.3 120.7 127 139.7 177.8 165.1 209.6 242.9 276.2 290.5 357.2 101.6 139.7 146.1 165.1 177.8 203.2 92.1 117.5 158.8 177.8 196.9 228.6 174.6 214.3 263.5 292.1 309.6 368.3 101.6 120.7 146.1 203.2 203.2 203.2
34.9
* * * * * *
6.4
63.5
TO TO TO TO TO TO TO TO 95.3 76.2
PIPE DRAFilNG AND DESIGN
88.9 101.6 114.3 165.1 177.8 203.2
424
APPENDIX A: DIMENSIONAL DATA
Commercial Wrought Steel Pipe Data Outside Schedule WuJI ThickOiamNo. ness e ter See (t) (D) Note 1 lnchc, lnchc, lncbcs 40s .068 0.405 1/s 80x 1 .095 1 40s .088 0.540 .119 80x 1 1 40s .091 3Ai 1 0.675 80x 1 .126 40s .109 .147 80x 1/2 0.840 160 .187 .294 ••• xx 1 40s .113 80x .154 1.050 JA .218 160 ... xx .308 1 1 .133 40s 80x .179 1.315 l .250 160 ... xx .358 .140 40s 80x .191 1.660 .250 160 11A ... xx .382 .145 .200 80x 40s 1.900 .281 .400 1 .154 40s 80x .218 2.375 2 .343 .436 .203 .276 80x 40s .375 2% 1 2.875 .552 1 .216 .300 80x 40s 3.500 3 .438 .600 '.~xx 1 .226 40s 4.000 31/z 80x 1 .318 1 .237 40s .337 80x 4 120 .438 4.500 160 .531 .674 ... xx 40s .258 .375 80x 5 5.5()J 120 .500 160 .625 ... xx .750 .280 40s 80x .432 .562 6 &.1>25 120 160 .718 .864 ... xx .250 20 .277 30 .322 40s .406 60 .500 80x 8.625 R 100 .593 .718 120 140 .812 ..• XX .875 160 .906
Nominul Pipe Siee
v.
1
\
\
I
1112\
1
1
1
I '.~~XX I '.~~XX I -,
I
I
Moment Wci,ht of lnertia Pipe (1) Pnund, 1 Note See 2 Squa re ~u ore lnches to 4,h Powcr ~t lncbes lnehes Fecr .0568 .00040 .244 .269 .001061 .00122 .314 .215 .0364 .00025 .1041 .00072 .00331 .424 .3641 .302 .1574 .0716 .00050 .00377 .535 1 .1910 .00133 .00729 .567 .493 1 .16701 .423 .2173 .1405 .00098 .00862 .738 1 .622 .3040 .01709 .850 .2503 .00211 1 .001()3 .546 .3200 .2340 .02008 1.087 .00118 .02211 1.300 .466 .3836 .1706 .02424 .252 .5043 .050 .00035 1.714 1.130 .824 .3326 .5330 .00371 .03704 .742 .4335 .4330 .00300 .04479 1.473 1.940 .614 .5698 .2961 .00206 .05269 .05792 l.440 .148 .00103 .434 .7180 1.678 1.049 .4939 .8640 \ . 00600 .087341 .7190 .00499 .1056 2.171 .957 .6388 2.840 .5217 .00362 .1251 .815 .8365 .1405 3.659 1.0760 .282 .00196 .599 .1947 .6685 1.380 1.495 \ .01040 2.2721 1.283 .00891 .2418 2.996 1.278 .8815 .2839 3.764 1.1070 l. 057 .00734 1.160 .3411 5.214 .630 .00438 .896 1.534 .01414 .3099 2.717 2.036 1.610 1 1.068 .79951 1.767 3.631 .01225 .3912 1.500 .0097() .4824 4.862 1.429 1.406 1.338 6.408 .5678 .950 .00660 1 1.100 1.885 J.()52 .02330 .6657 2.067 1.075 3.355 5.022 .OZ050 .8679 1.939 1.477 2.953 1.162 7.440 2.190 2.241 .01556 1.689 1.311 9.029 1.503 2.656 1 1.774 1 .01232 5.79 4.788 .03322 1.530 1.704 2.4691 1.924 7.66 l.254 4.238 .02942 2.323 10.01 .02463 2.353 2.125 2.945 3.546 13.70 2.871 4.028 2.464 .01710 1.771 7.58 7.393 .05130 3.017 2.228 3.0681 3.894 10.25 3.016 6.605 .04587 2.900 14.32 5.408 .03755 5.032 2.624 4.205 5.993 18.58 .OZ885 2.300 S.466 \ 4.155 9.11 .06870 4.788 2.680 9.886 3.5481 6.280 1 12.51 3.678 1 8.888 1 .06170 1 3.364 7.233 10.79 3.174 12.73 .08840 4.026 14.98 4.407 11.50 .07986 9.610 3.826 11.65 19.00 J.624 5.595 \O.JI .0716 22.Sl .0645 13.27 6.621 9.28 3.438 27.54 15.28 8.101 7.80 .0542 3.152 14.62 20.01 .1390 15.16 5.047 4.300 20.67 20.78 6.112 18.19 .1263 4.813 27.10 .1136 25.73 4.563 7.953 16.35 32.96 14.61 .1015 30.03 4.313 9.696 38.55 .0901 33.63 12.97 4.063 11.340 .2006 28.14 18.97 5.581 28.89 6.065 28.57 .1810 40.49 5.761 8.405 26.07 36.40 49.bl 10.70 23.77 .1650 5.501 58.97 45.30 .1469 13.32 21.15 5.189 53.16 .1308 66.33 4.897 15.64 18.84 22.36 .3601 57.72 8.125 6.57 51.85 24.70 63.35 51.16 .3553 8.071 7.26 28.55 .3474 72.49 7.981 8.40 50.03 88.73 35.64 47.94 .3329 7.813 10.48 43.39 .3171 105.7 7.625 12.76 45.66 121.3 50.87 43.46 .3018 7.439 14.96 140.5 60.63 17.84 40.59 .2819 7.189 67.76 .2673 153.7 7.001 19.93 38.50 162.0 72.42 37.12 .2578 6.875 21.30 74.69 .2532 165.9 6.813 21.97 36.46 lnside Oiame ter (d)
Aree of Metal (a) Squarc lnche~ .0720 .Cl'l25
Transverse Interna! Area
.12501
1
1
1
Note 1: The tetters s, x , and xx in the column of Schedule Numhcrs indicare Standard, Extra Strong, and Doublc
l:xlra Slron¡: l'ipc. resnecnveb.
Externa) Scction Surface Modulus Weter Pound~ Sq, í't. pcr Ioor pcr Íuol oí pipe olp,~ .025 .106 .00523 .oie .106 1 .00602 .141 .01227 ·'.045 .031 .141 .01395 .083 .178 .02160 .178 .061 .02554 .132 .220 .04069 .04780 .102 .220 .074 .220 .05267 .05772 .022 .220 .231 .275 .07055 .08531 .188 .275 .128 .275 .10036 .0{)4 .11032 .275 .344 .1328 .375 .344 .1606 .312 .230 .344 .1903 .213() .344 .122 .435 .2346 .649 .2913 .555 .435 1 · .3421 .458 .435 .435 .4110 .273 .882 .497 .3262 .4118 .765 .497 .497 .5078 .6011 .42, .497 1 .5977 .622 .5606 1.45 .7309 1.28 .622 .979 .622 .97 1.104 .77 1 .622 1.064 2.07 .753 .753 1.339 1.87 .753 1.638 1.54 .753 1 1.997 1 1.07 .916 1.724 3.20 ,916 2.225 2.86 .91(, 2.876 2.35 3.424 1.80 .916 1.047 2.394 4.29 1.047 1 3.140 1 3.84 1.178 3.214 5.50 1.178 4.271 4.98 4.47 1.178 5.178 5.898 4.02 1.178 6.791 3.38 1.178 5.451 8.67 1.456 7.431 1.456 7.88 1.456 9.250 7.09 10.796 6.33 1.456 1.456 12.090 5.61 8.50 12.51 1.734 12.22 1.734 11.29 14.98 1.734 10.30 17.81 9.16 1.734 20.0l 8.lt\ 1.734 13.39 22.47 2.258 14.&9 22.17 2.258 2.258 16.81 21.70 20.58 20.77 2.258 14.51 19.78 2.258 2.25!! 28.14 18.83 32.58 2.258 17.59 2.258 35.65 16.68 37.51, 16.10 2.258 38.411 15.80 2.258 wcifht
(2~)
1
\
l
Note 2: The valúes shown in squure feet for thc Transverso Interna! Area ulso represen! Jhc volumc in cubi« fccl per Ioot of pip,: lc11y;tl1.
Courtesy of Crane Co.
PIPE DRAFI1NG AND DESIGN
425
APPENDIX A: DIMENSIONAL DATA
Nominal Pipe Si:te lnches
10
Schedule WaH Inside No. Thick- Díamnen e ter (d) (D) See (t) Note 1 lnches loches lnches 20 .250 10.250 JO .307 10.136 408 .365 10.020 .500 9.750 60" 10.750 80 .593 9.564 100 .718 9.314 120 .843 9.064 140 1.000 8.750 8.500 160 1.125 20 .250 12.250 JO .330 12.090 .375 12.000 40 .406 11.938 .. x .500 11.750 .562 11.626 12.75 60 11.376 80 .687 11.064 100 .843 10.750 120 1.000 1.125 10.500 140 10.126 160 1.312 10 .250 13.500 20 .312 13.376 13.250 30s .375 40 .438 13.124 13.000 .. x .500 14.00 60 .593 12.814 .750 12.500 80 12.126 100 .937 1.093 11.814 120 1.250 11.500 140 1.406 11.188 160 10 .250 15.500 20 .312 15.376 30s .375 15.250 40x .500 15.000 14.688 60 .b56 16.00 14.314 80 .843 13.938 100 1.031 120 1.218 13.564 140 1.438 13.124 160 1.593 12.814 .250 17.500 10 17.376 20 .312 17.250 .. s .375 .438 17.124 30 .. x .500 17.000 .562 16.876 40 18.00 .750 16.500 60 16.126 .937 80 1.156 15.688 100 15.250 120 1.375 14.876 140 1.562 t.781 14.438 160 .250 19.500 10 .375 19.250 20s .500 19.000 30x 18.814 40 .593 .812 18.376 60 20.00 17.938 80 1.031 17.438 100 1.281 17.000 120 t.500 140 1.750 16.500 16.064 1&0 1.968 10 .250 23.500 20s .375 23.250 .. x .500 23.000 30 .562 22.876 22.626 40 .687 22.064 24.00 60 .968 80 1.218 11.564 100 20.938 1.531 1.812 20.376 120 2.062 19.876 140 160 2.343 19.314
Outaide
Díameter
...
12
14
16
18
20
24
Area oí Metal (a) Square lnches 8.24 10.07 11.90 16.10 18.92 22.63 26.24 30.63 34.02 9.82 12.87 14.58 15.77 19.24 21.52 26.03 Jl.53 36.91 41.08 47.14 10.80 13.42 16.05 18.66 21.21 24.98 Jl.22 38.45 44.32 50.07 55.63 12.37 15.38 18.41 24.35 31.62 40.14 48.48 56.56 65.78 72.10 13.94 17.34 20.76 24.17 27.49 30.79 40.64 50.23 61.17 71.81 80.66 90.75 15.51 23.12 30.63 36.15 48.95 61.44 75.33 87.18 100.33 111.49 18.65 27.83 36.91 41.39 50.31 70.04 87.17 108.07 12&.31 142.11 159.41
Transverse lnternal Areo See Squure lnches 82.52 80.69 78.86 74.66 71.84 68.13 64.53 60.13 56.75 117.86 114.80 113.10 111.93 108.43 106.16 101.64 96.14 90.76 86.59 80.53 143.14 140.52 137.88 135.28 132.73 128.96 122.72 115.49 109.62 103.87 98.31 188.69 185.69 182.65 176.72 169.44 160.92 152.58 144.50 135.28 128.96 240.53 237.lJ 233.71 230.30 226.98 223.68 213.83 204.24 193.30 182.66 173.80 163.72 298.65 290.04 283.53 278.00 265.21 252.72
238.83 226.98 213.82 202.f>7 433.74 424.56 415.48 411.00 402.07 382.35 3&5.22 344.32 326.08 310.28 292.98
Moment We~fht We~fht oí lnertia Pipe Water (l) Note 2 Pounds Pounds per ÍOOl 5rc:arc loches to oí pipe eet 41hPower 1 IJ.7 35.76 .5731 28.04 137.4 34.96 .~J 34.24 160.7 34.20 .5475 40.48 212.0 54.74 32.35 .5185 .4989 244.8 31.13 64.33 .4732 286.1 76.93 29.53 .4481 324.2 89.20 27.96 .4176 367.8 104.13 26.06 .3941 399.J 115.65 24.59 51.07 .8185 191.8 33.38 43.77 49.74 .7972 248.4 279.3 49.56 49.00 .7854 .7773 300.J 53.53 48.50 65.42 46.92 .7528 361.5 46.00 .7372 400.4 73.16 44.04 .7058 475.1 88.51 41.66 .6677 561.6 107.20 39.33 .6303 641.6 125.49 37.52 .6013 700.5 133.68 34.89 .5592 781.1 160.27 .9940 255.J 36.71 62.03 45.68 60.89 .9758 314.4 54.57 59.75 .9575 372.8 63.37 58.64 .9394 429.1 72.09 57.46 .9217 483.8 562.3 84.91 55.86 .8956 687.3 106.13 53.18 .8522 824.4 130.73 50.04 .8020 929.6 150.67 47.45 .7612 45.01 .7213 1027.0 170.22 189.12 42.60 .6827 1117.0 42.05 81.74 1.3103 383.7 52.36 80.50 l.2895 473.2 62.58 79.12 1.2684 562.1 82.77 76.58 1.2272 731.9 73.42 1.1766 932.4 107.50 69.73 1.1175 1155.8 136.46 66.12 1.0596 1364.5 164.83 62.62 1.0035 1555.8 192.29 .9394 1760.3 223.64 58.64 .8956 1893.5 245.11 55.83 47.39 104.21 1.6703 549.1 59.03 102.77 1.6467 &78.2 806.7 70.59 101.18 1.6230 82.06 99.84 1.5990 930.3 1.5763 1053.2 92.45 98.27 t.5533 1171.5 104.75 96.93 92.57 1.4849 1514.7 138.17 1.4183 1833.0 170.75 88.50 83.7& 1.3423 2180.0 207.96 79.07 1.2684 2498.1 244.14 75.32 1.2070 2749.0 274.23 1.1369 3020.0 308.51 70.88 52.73 129.42 2.0740 75&.4 78.60 125.67 2.0142 1113.0 122.87 1.9690 1457.0 104.13 120.46 1703.0 122.91 1.9305 114.92 1.8417 2257.0 166.40 1.7550 2772.0 208.87 109.51 103.39 1.6585 3315.2 256.10 I.5762 3754.0 296.37 98.35 1.4849 4216.0 341.10 92.66 87.74 1.4074 4585.5 379.01 &3.41 187.95 3.0121 1315.4 94.62 183.95 2.9483 1942.0 2549.5 125.49 179.87 2.8853 178.09 2.8542 2843.0 140.80 174.23 2.7921 3421.3 171.17 165.52 2.6552 4652.8 238.11 2.5362 5672.0 296.3& 158.26 2.3911 6849.9 367.40 149.06 1.2645 7825.0 429.39 141.17 134.45 2.1547 8625.0 1 483.13 2.0346 9455.9 541.94 126.84
Courtesy of Crane Co.
PIPE DRAFilNG AND DESIGN
t:
Exterrral Section
Surface Modulus Sq. Ft.
per ÍOOl of pie_<:
2.814 2.814 2.814 2.814 2.814 2.814 2.814 2.814 2.814 3.338 3.338 3.338 3.338 3.338 3.338 3.338 3.338 3.338 3.338 3.338 3.665 3.665 3.665 J.665 3.665 3.665 3.665 3.665 3.665 3.665 3.665 4.189 4.189 4.189 4.189 4.189 4.189 4.189 4.189 4.189 4.189 4.712 4.712 4.712 4.712 4.712 4.712 4.712 4.712 4.712 4.712 4.712 4.712 5.23& 5.236 5.236 5.236 5.236 5.236 5.236 5.236 5.23& 5.236 &.283 6.283 &.283 &.283 6.283 6.283 6.283 6.283 6.283 6.283 6.283
(2~) 21.15 25.57 29.90 39.43 45.54 53.22 60.32 68.43 74.29 30.2 39.0 43.8 47.1 56.7 62.8 74.6 88.1 100.7 109.9 122.6 36.6 45.0 53.2 61.3 69.1 80.3 98.2 117.8 132.8 146.8 159.6 48.0 59.2 70.3 91.5 116.6 144.5 170.5 194.5 220.0 236.7 61.1 75.5 89.6 103.4 117.0 130.1 168.3 203.8 242.3 277.6 305.5 335.& 75.6 111.3 145.7 170.4 225.7 277.1 331.5 375.5 4ll.7 458.5 109.6 161.9 212.5 237.0 285.1 387.7 472.8 570.8 652.l 718.9 787.9
426
APPENDIX A: DIMENSIONAL DATA
DIMENSIONS 1
@@t .11
-
........
840 1 050 1315 1660 1900 2375 2875
.•
a
a a
3500 4000 4500 5563 6.625 8625 10750 12750 14000 16.000 18000 20000 24.000 30000 36000 42000 48.000
4
••
..
10 14 11 11
lM
..
"' 111
-
Ou1let
~
V,
~
11, lb IV,
V,
114 1
~
V,
1\1, 114 1
~
2 1\1, 114 1
~
... •
e 11' 11'
V,
1
,..
•mi.llllD.
B
,
'• '•
-1
,~.
2 2'> 3 3,, 4 5 6 8 10 12 14 16 18 20 24 30 36 42 48
. ..
..
11,
, ..
11>
2'• 3 3'• 41'; 5'· 6 7',
1'1
2 2'• 2•, 3,.. 3', 5 6•, 7'> 8.. 10 11'• 12\.> 15 18\'; 22i. 26 29;¡,
9 12 15 18 21 24 27 30 36 45 S4
63 72
2V, 2 IV, 114 1 3 2V, 2 1\1, 114
IV. lli, 11'. IV. 21, 2'· 21, 21, 21, 21, 21, 2•, 2•, 2•, 3 3
3 3 3
3~
314
314 3JI. )JI,
M Oi
,.,
11,
,~
lli,
H .. 11>
2 2
114.
2 2 2
2'• 2'· 2'• 2'•
21> 21'; 2'> 21>
211 2'• 2
3 3 3 3
, ..
2'· 211 21> 2'•
3b 31, 3'>
-
.
~
4
• •
3,,
3,, 3
3,, 3,,
2A,
3,,
2'·
31,
•
· ~.
2'• 3,,
st,.
e
,v.
4 3v, 3 2V, 2 1V,
41' 414 41' 41' 41' 411
5 4 3\1, 3 2\1, 2
416 416 416 416 416 416
6 5 4 3v, 3 2V.
5'4 5)4 511 5% 5)1 5~ 7
7 7 7 7
9:...
12-...i 15, 18-..
28 32 36 40 48 60
3" 3,, 3.. 3.. 3'•
a
51, 6'• 7'•
21 24 27 30 26 45
--
-
w- -
M
3)1 31, 3'• 311 4 3~ 3l', 31> 3ll. 4i ,,,
•..
4ll, 4\'o 5ll. 5 ... 5 O, 4',
64
6ll 6M, 6
H
4 4 4 4
~
10 8 10
4
4 4
11
4
•
5 5 5 5 5 5,, 51, 51> 51,
14
11
s•~
5 4
ª"
21 23 211.-,
-
-
-
-
-
M
7'\o 8•, 10, 121• 15
8 7'11. 71, 71<
7 7 7 7
8 8 8 8
14 12 10
IO'Xo 10\'o 9',
6
11 11 11 11 11
9.,..
13 13 13 13
16 14 12 10 8 8
12 12 12 12 12 12
12 11.,.. 11~ 10 .. 101'.
14 14 14 14 14
131-, 13', 131:t 131, 13•1 131,
13 13 12Y. 12\'o 11" ..
15 15 15 15 15
,,
•
• See M d,menSIOl1s lor branch he,ght ot 42" or 48" full branch tee Ali d,mensoons ara ,n 1nches See ANSI B t 6 9 to, cap lengths when wall thicknesses are greater than x-stg
PIPE DRAFI1NG AND DESIGN
1,
•
.. • •
..
•
.. .
,,
1;
·•,~
= ...
10 ti 14 11 11
,,
\;
-
91, 9 8'X, 8•,
12 10
,,
181,:
H
4
11• 1)
,s, ..
10 10 10 10 10
a
''~.
&r,.
IO
1•
'•
5 51,
ICC•-
Outlet
20 18 16& 14 12 10 8 24 20 18 16& 14 12 10
30
24 20 18 16& 1, 36 30 24 20 16 16 42 36& 30 24 & 20 48 42 36 30 24
e
"..
.,. •• •• ••• 1
';;, '!,,
4',
12 10 8 6 5
,a
11
8', 51, 51, 91,
6
16
6 6 6 6
e
Outlet
'•
v,,
6 6 6 6 6 8 8 8 10 10 12 12 12 12 12
-
CCINlmffllC
'•'•
1'h. 2 2•, 2~,. 3'4
-
...
Co
,-..
4 4
2 2'> 2'> 3 3,, 4 5 6 61, 7 8 9 10'1 101> 12 12 13;,
4 ..
6'• 7,, 8•, 1011, 1211. 16110 201'o 241'o
3\1, 3 2\1, 2
8 5 4 3v,
3"," 3"•,.,.
4)¡,
G
4
IT
-
¡..p .. -
00 ol Lao
3 3
11, 11, 11, 11,
_.L........
11
STUB ENOS
ANSI Sld
,,,
1~ 2', .. 2"',.
'
_, • ,-
CAP
F
1 1
2);,
(
1
D
E
1~
...... .... Outlet
V
K
,,.,..
, ..
1
~
CAPS•
o
A
......... f-}lÍ' i.c.c:~ 1
1
@ .......,,,.
A
WeldELL P,pe 00
11' 111
:E"
~
1
'
A
t..-.... ~.m,,u¡
"..
• ••• •
1
A
~J!A
'
11
• •• •
fC M
H
141., 14 13'1!. 13 ...
20 20 20 20 20
17 16•1 16 15.,.. 15'11
20 20 20 20 20
21 20 191) 19
2, 24 2, 2,
26•,
25 24 23 22•, 22
2• 2, 2• 2, 2•
30 30 30 35 35 35 35 35
28 28 26 33 32 31 30 29
15 15 15 15 15 15 17 17 17 17 17 17 22 22 22 22 22 26•• 26•, 26•, 261> 26'>
12ª• ..
2, 2• 28 28 28 28
Courtesy of Taylor Forge
427
APPENDIX A: DIMENSIONAL DATA
FLANGES WELDING NECK
DIMENSIONS
SLIP-ON
BLIND
'---X --- 1
(l l ...._....1'"" _...
THREADED
LAP JOINT
. •.
11~·
_-1-====-s---=_-..¡_._ .....,rttw SOCKET -WELD '
150-LB. No•.
°""
s,.. o,-. o Pipe
•lde
'h '14 1
3'h 3Va 4Y,
tY, 1 'h 2
4% 5 6
21/z 3 31/z
7 7'h 8\.'z
4' 5 6
Thltn. (mln.)
e
3<,
'h
'<, ~
'}(,
'14 Va
')(,
')(,
9 10 11
1
6 10 12
13'h 16 19
14 16' 18 20 22 24
'J<, 'J<,
-
0.D, ol RelNd Foce
Hvb
o, .....
:~~
Sllp-on
Thrd. Sock. w. Y,
U!' Wldg.2 SIII>Jolnt Ne etc Sock. W
up Jolnl
Y,
8,
8,
81
"" ""
0.62 0.82 1.05
0.88 1.09 1.36
0.90 1.11 1.38
v,
Va
1
1
1.38 1.61 2.07
1.70 1.95 2.44
1.72 1.97 2.46
2'14 2'14 2'3{,
1 Ye 13{, 1Y,
1 Ye 13{, 1Y,
2.47 3.07 3.55
2.94 3.57 4.07
2.97 3.60 4.10
1)(, 1K, 1'{,
1)(,
1K,
1J(,
4.03 5.05 6.07
4.57 5.66 6.72
4.60 5.69 6.75
8.72
R
X
Yt
1% 1'}(, 2
13{, 1'h 1')(,
1Va 2}<,
2'h 2V, 3%
23<,
2Y,
2J(, 3)(,
21/z
4Ye 5 51/z
3J(, 4V.. 4'3{, SJ(,
GK,
eo,.o
lenglh lhru Hvb
23<,
'J<,
'J<,
w.
'J<,
2K,
App,01. Welght (Lb1.) Drllllng Deplh ol Sllp,On Bolt No. 01,m. Wld9 l•p Sock11 Thrd. Bllnd Clrcte Neck Jolnl Hole1 Hofe1 Ot1m. Sock. W. D
2 2 3
1 2 2
1 2 2
1 2 2
4 4 4
3 4 6
3 3 5
3 3 5
3 4 5
4 4 4
8 10 12
7 8 11
7 8 11
7 9 13
'X,
1J<,
15 19 24
13 15 19
13 15 19
%
K, 'h
!<, %
')(, '14
13{. Va
')(,
~ % %
.,.
"
2~ 2:Y• 31,í 3Y2 31¡,
:Y,
O',
4 4 6
'14 '14 '14
51h 6 7
17 20 26
8 8 8
'14 Va Va
8'h 9V.
1v,
7)(, 8'h
6K, 71<,
3 31/z 3\.'z
1 Ye 1)(, tY,
10% 12'14 15
9'.)(, 12 14~
4 4 4\.'z
1 '14 1'}(, 23{,
1 :Y, 1 '}(, 2}(,
7.98 10.02 12.00
ro.se
12.88
8.75 10.92 12.92
1Y, 1)(, 1l{,
39 52 80
30 43 64
30 43 64
45 70 110
8 12 12
1 1
14Y, 17
21 23'h 25
1~ 13(, 11(,
16Y, 18\.'z 21
15'14 18 19Va
5 5 S'h
2Y, 2V. 2'J<,
3Ye 3K, 39(,
13.25 15.25 17.25
14.14 16.16 18.18
14.18 16.19 18.20
1% 1 '14 1')(,
110, 140 150
90 98 130
105 140 180
140 180 220
12 16 16
1111 1111 tY,
18:Y• 21Y, 22'14
27'h 29'h 32
1 'J<. 1 '}(, 1Va
23 25V, 27Y,
22 24V, 26Ye
5% 5Va 6
2Va 3V. 3V..
4)(, 4V, 4~
19.25 21.25 23.25
20.20 22.22 24.25
20.25 22.25 24.25
2V. 2% 2'h
180 225 260
165 185 220
195 245 275
285 355 430
20 20 20
w,
tY,
25 27V, 291/:z
v,
1%
11 :Y,
ANSI B 16.5 eevers only sizes lhrovgh 24". lorger sizes os lisled below hove the some flange and drilllng dlmensions as Clan 125 Casi lron flanges, ASA 816.1. 26 28 30
32 34 36 42
34Y, 36\.'z 38'14
2 2}<, 2Ye
29V, 31Y, 33:Y..
281/z 30:Y, 32:Y..
5 5)(, 5Ye
3~ 3K, 3'h
4H'• 43:Y.. 46
2Y, 2)<, 2~ 2"
35'!4 37'14 40Y, 47
35 37 39Y, 46
5Y, 5.1(, 5~ 5"
3% 3')(, 3'14 4
53
-
-
--
~~ :: ..,
u .. ., .e
~2
i~ ,,.. ~D
26.25 28.25 30.25 32.25 34.25 36.25 42.25
-
Courtesy of Taylor Forge
PIPE DRAFilNG AND DESIGN
-
-
-
-
-
315 360
250 285 315
435 465 520 750
395 420 480 680
300
-
-
525 620 720
24 28 28
1% 1% 1%
31'14 34 36
870 990 1125 1625
28 32 32 36
1% 1" 1% 1"
381/:, 40V. 42:Y, 49'h
428
APPENDIX A: DIMENSIONAL DATA
FLANGES WELDING NECK
p¡p. a1..
°"..
•lelo 01.....
D
n.kri~ (RIIA.)
e
"'~'J<.
=
...
1'141 1')!', 2
1Y.i 1V. 2Y, 2,,., 2V. 3)(.
2",
, "
RalNd
X
BLIND
SLIP-ON
H~b 01.....
...
o.o.
DIMENSIONS
Yo 2)(. 2Y• 2}(,
300-lb
--lh .. NHlltlt Tiud. ª"''"°" '-"" Jol
Y,
Y,
-
Wide.'
••
..... o
lli,,.o,t '\odl.W.
••
.:.::. º'
Deplh
•• 0.90
v.
v.
1
H<,
1 1)(,
0.62 0.82 1.05
0.88 1.09 1.36
2'.l<, 2V.
1)(, 1K, 1J(,
1.1(. 11(. 1K,
1.38 1.61 2.07
1.70 1.95 2.-44
1.72 1.97 2.46
3'J(, 4'M, 5Y•
3 3Y. 3K,
1,,., 1')(, 1V.
1,,., 1'.l<, 1V.
2.47 3.07 3.55
2.94 3.57 4.07
6J<,
7)(. 8,,.,
5V. 7 8Y,
3'M, 3V. 37,io
119 2 2}(,
1 2 2}(,
4.03 5.05 6.07
1~ 1V. 2
10~ 12:V. 15
1ov. 12'MI 14'!4
4'MI 4~ 5Y,
2K,
2K,
2'MI 2V.
23 25Yl 28
2Y. 2v. 2'MI
18Y• 18Yl 21
16:V. 19 21
5~ 5V. 6Y,
20
30,,.,
22
33
24
36
2,,., 2~ 2-lli
23 25Y• 27Y•
23Y, 25Y• 27~
Y,
v. 1
3:V. 4~ 4V.
1Y• 1,,., 2
5Y• 6Y, 6,,.,
v.
2,,., 219 3~
2,,., 3 3,,.,
7,,., 8Y• 9
1 1Y, 1J(,
4Y, 5 5,,.,
4 5 6
10 11 12,,.,
1v. 1'MI 1Ji',
8 10 12
15 17,,., 20,,.,
14 16 18
-
v. w.
MSS SP44 Clou 300 ... 26 28
22
39
27 35 50
67 91 140
58
58
81 115
91 140
180 250 320
165 190 250
400
6'MI 6Yl 6%
3-lli 4 4K,
5,,., 5-lli 6
19.25 21.25 23.25
20.20
20.25 22.25 24.25
1v.
-
7V.
-
-
---
4.l(,
10~ 12~ 14:V.
4~ 4V. 5'MI
2')(, 2V. 3Y.
21)(, 4 4Y,
16Y, 18Y.i 21
16'14 19 21
5V. 8 6Yl
3J<.
31)(, 3V.
4~ 5 5'MI
23 25Y, 27Y,
23Y. 2sv. 27~
6~ 6V. 6V.
4 4Y, 4Yl
5:V. 6 6Y,
7
4
6
n<. 8,,.,
8Y.
8 10 12
15 17Y, 20Y,
1V. 2Y. 2Y,
10~ 12-lli 15
14 18 18
23 25Y.i 28
2'M, 2Y.i 2~
20
30,,.,
22
33
2'111 2V. 3
MSS-SP,U Clou 400 ... 38Y• 40'14 43
3,,., 3'111 4
29Y. 31Y.i 33'14
28~ SO'K, 32'J(,
7~ 8Yl 8'MI
45Y, 47Yl so
4Y, 4'M, 4Y,
36
35 37J(, 39'MI
9Y, 9Yl 9V.
-
--
,:r'é}
-e a
'D ..
c.
~~ ·-.
a-s
:J'CD
CD
n ::
22.22 24.25
---
-t
o
.. ,,,.. .. --..... a
o
a
-
'<
e
~
....
n
..~
:J'
-
-
-
-
-
4H0T"E:
11;,_.
4.57 5.66 6.72
4.60 5.69 6.75
8.72 10.88 12.88
8.75 10.92 12.92
14.14 16.18 18.18
14.18 16.19 18.20
20.20 22.22 24.25
20.25 22.25 24.25
-
-
-
-
-
-
--
-
- -- --
-
400-lb
2 2Y. 2Y,
3,,.,
1'MI 1,,., 1~
40Y,
22 26
14.18 16.19 18.20
10 11 12Y,
36
25 32 42
14.14 16.16 18.18
2 2Y. 2Y,
38
8 8 8
13.25 15.25 17.25
8Y•
34
12 16 21
4'MI 4-\li 5Y.
8:V. 9Y. 9Yl 10V.
32
10 13 17
3 3Y• 3,,.,
341)(. 36V. 39 45!(.
30
10 13 17
3V. 4
36
26 28
12 15 18
8.75 10.92 12.92
3V. 4 4Y, 4~
36
4 4 8
8.72 10.88 12.88
45Y• 47,,., so 57
24
4 6 8
7.98 10.02 12.00
30
5'111
4 6 7
-
32 34 36 42
SJ<,
4 6 7
4.60 5.69 6.75
28'MI 30Y.i 32)(,
4
5 7 9
4.57 5.66 6.72
-
-
-
_.••
No. Holo,
4 4 4
'K.
v.
465
580 670 810
930
.. -..
o
3
::,
e
n
..~
e
e,
-
..
-- -' ::,
o o
a
....
i::·-·
~
v. v. v. v. v.
8oll Cite ..
DI-.
2~ 3Y• 3,,., 3V. 4,,., 5
8 8 12
v. v. v. v. v. v.
7V. 9~ 10'MI
81 124 185
12 16 16
1 1Y. 1~
13 15"4 17'!4
190 250 295
250 295 395
20 20 24
1Y• 20Y• 1'MI 24:V. 1~
315 370 475
1370 435 550
505 790
24 24 24
1'141 1~ 1~
570 720 810
-
1050 1275 1500
28 28 28
1V. 34,,., 1'111 37 1V. 391,4
1775 2025 2275 13165
28 28 32 36
2 41,,., 43Y, 2 2Y, 46 2Y. 52'14
1025 890 1200 1075 1300 1200 1740. h610
28 39
-
-
640
5V. 6'MI 7Y,
22,,.,
27 29Y• 32
ASTM Al05·11
ew ••• ............. wt .. lOO .........
z
Ortlllne
.,i.., 2 3 3
2.97 3.60 4.10
v.
'-"" Jolftl 2 3 3
"'~')(,
1.11 1.38
~SI~
2 3 3
Y,
29Y.i 31,,., 33:V.
5
'MI
=· 2 3 4
3Y. 3'MI 3'MI
40Y, 47
D
J<.
38~ 40:V. 43
38
Sock.
.a.. rox. Wet.ar.t,. ......
(... Mll.1 ......
7V.
«
25 29 42
33 44 61
8 8 12
1 1 1
9Y• 10~
89 125 175
87 91 130
84 110 150
100 155 225
12 16 16
1Y. 1Y• 1'MI
13 15"4 17V.
230 295 350
180 235 285
205 280 315
290 370 455
20 20 24
1'MI 1Y, 1,,.,
20~ 22Y.i 24'14
425 sos 620
345 405 510
1385 455 570
587 720 890
24 24 24
1~ 27 1V. 29Y, 1 v. 32
750 880 1000
650
--
28 28
2 2Y,
1150 1300 1475
1025 1150 1325
28 28 32
2Y, 2Y, 2Y.
35 43 57
26 31
780
900
-
--
1125 1425 1675 1975
2250 2525
ASTM AIOS . II 28 1V. 34,,.,
-37 39Y• 41Y, 43Y, 46
Courtesy of Taylor Forge
PIPE DRAFI1NG AND DESIGN
429
APPENDIX A: DIMENSIONAL DATA
FLANGES THREADED - X---
DIMENSIONS
LAP JOINT
-<
SOCKET-WELD
1--X~
··--- r
--~.y;
¡--i--~--::--!'----1~--i
~,...
.....
Out·
:~~
llub Olem.
R
X
1~ 1')(, 2
1 1V. 2.,.
2}(, 214
2K,
1 1)(,
2'h 2Yo 3%
2•1, 2o/.< 3)(,
2% 2:v. 2'/o
1.,. 114 1J<,
1.,. 1 v.
4.,. 5 5'h
3')(, 4r,I, 514
3.,. 314 3~
1'11, 11)(, 1 ')(,
1% 11)(, 1 ')(,
1 'h lo/.< 1Yo
6j(, 7)(,
6
4'h
8:Y.,
4r,I,
2.,. 2:i. 2%
2V.
8'h
TK,
4
6
10:Y., 13 14
2:i. 2%
8 10 12
161', 20 22
23<,
10:Y., 13'h 15:Y.,
5V,
2%
10'11, 12:Y., 15
3 3~ 3'11,
3 4"4r,I,
14 16 18
23'!4 27 2914
2'14 3 3V.
16Y• 18Y:i 21
17 19Y:i 21 V.
6'h 7V,
3')(, 41(, 4%
5 5V.
20 22 24
32 3414 37
3'h 3'\I, 4
23 25Y• 27Y,
24
7Yz 7:Y., 6
5 5Y• 5'h
6Yz
Slu
-
Ol•m.
1
3'\I• 4% 4Yo
1v. 1Yz 2
5Y• 6.,. 6'h
2'h
7Yz
3 3'h
8Y•
4
5
ThltA.
(,nin.)
o
Y, o/.<
9
e J<,
~
')(, 'j(,
Yo
1
·~
2'h
v.
26Y, 28Y•
MSS-SP44 Closs 600.. • 26 40 4Y, 29'h 291(,
6 6.,. 7
Yo
2.94 3.57 4.07
2.97 3.60 4.10
4.57 5.66 6.72
4.60 5.69 6.75
8.72 10.88 12.88
8.75 10.92 12.92
14.14 16.16 18.18
14.18 16.19 18.20
-
20.25 22.25 24.25
-
7Y,
~"'
20.20 22.22 24.25
--
....
-
6Yo
31% 33')(,
32 34 36
47 49 51:Y.,
4'11, 4:V. 4Yo
36 38 40Y•
36.,. 38)(, 40%
1ov. 10\\ 11.,.
l
9Yz 11Y:i 13:Y., 15
1 Yz 1'\I, 2
23<,
5 6)(, 7)(, 81,',
5 6Y• 71,',
4 41', 6 5Y:i
10 12
18Yz 21 Y, 24
2Y1 2o/.< 3V.
10% 12:V. 15
11'!4 14Y, 16Y:i
71/o
4 4Y• 4%
14 16 18
25Y• 27:Y., 31
3~ 3Y.t 4
16Y• 181', 21
17'!4 20 22Y•
8~ 8Y.t 9
5.,. 5V. 6
6.,. 6Y:i 7Y:1
20 22 24
33:V.
4Y•
23
24Yz
9~
6Y•
8V•
41
6Y.t
MSS 28 28 30 ....___ 32 34 36
-
-
- 51'44 Clou
-
5Y, 5% 5V.
29'h 31Y, 33~
30Yt 32:V. 35
11Y• 11 12v.
51~ 65 57Yz
6V•
36 38 40Y•
37Y• 39~ 41Yo
13 13'\I• 14Y•
6Yz 6o/.<
-
29Yz
42o/.< 46 46Y,
:v.
-
-
-
-
-11 Yz 8
900 .. •
27Y•
-
-
-
--
-
--
-i
o
-
..
<7
~
..
,::, 1- ..
n
-
-· - -· CD
,__
a.
_,_.
-e
6
31Yz 33o/.<
--
o
~
1.72 1.97 2.46
1 V. 1v. 1J<,
4~ 41',
e~ 1v.
••
1.70 1.95 2.44
__ ,_ 1 1){,
42Y• 441',
e
º'
0.90 1.11 1.38
28 30
9Y•
..
••
Depth L ...
Jolnt Sockel
0.88 1.09 1 36 ,____
-
2.,. 2:V. 31/o 3'1'o
BoreO Wldg, Sllp·Oft Heck hc:ket w
Yo
8:Y., 9Y, 9:y.,
4 5 6
'l·T· ., 11,r
600-lb Unath thrv Hub SUp-Ot1 Lep Thrd. Jolr,t Soc.k. W Y, v, Y,
O.O.of A•l••d Foce
NOM.
t
2.,. 2:V. 3.,. 3'1'o
--
41', 5 5~
-
lOY:i
-
,::,
=r
CD
~
--
9QQ ..fb.
--
....
-e
~"'
----- _ ...... - ~ n
=r
-
-
2% 3Y• 3Yz '--3Yo 4\/2 l/1 5 '\/•
5 7 9
5 7 9
18 23 28
13 16 21
12 15 20
15 20 29
8 8 8
42 66 81
37 63 80
36 61 78
41 66 86
6 8 12
1 1.,. l'AI
10\/2 11Yz
120 190 225
115 170 200
110 170 200
140 230 295
12 16 20
1v. 1~ 1:i.
13:Y., 17 1914
280 390 475
230 330 400
250 365 435
355 495 630
20 20 20
1 Yz 1% 1
:v.
20:Y., 23:Y. 25:Y.,
590 720 830
510 590 730
570 670 610
610 1000 1250
24 24 24
1:Y., 1Yo 2
261/z 30% 33
1025 1175 1300
950 1075 1175
-
1525 1750 2000
28 28 28
2 2.,. 21Ao
40V•
1500 1650 1750
1375 1500 1600
-
2300 2575 2950
28 28 26
2~ 2~ 2%
421', 44Y, 47
,,,
-
-
-
5 8 10
:v. :v.
·-4 -""•
4 8
'lo l/1 1
5Yo 6%
1v. 6'h
ASTM A 105-11
,;·• ltWU "'" •• fdilftttMI wl1h 1IIOO lb. lllnfN
--
º'ª"'·
'ti,
2 3 ,__4
t...
36 38
M:.:101191t.
8 6 8 12
1 1Y• 1 'l'o 1v.
71', 9Y• 11 121',
175 260 326
170 245 325
190 275 370
200 290 416
12 20
1 Yz 1Yt 1Yt
15Y1 161', 21
14.18 16.19 18.20
400 495 680
400 425 600
415 465 850
520 600 850
20 20 20
1% 1~ 2
22 24Y• 27
20.20
20.25
830
730
810
1076
20
2.,.
29Yz
24.25
24.25
1500
1400
1550
2025
- 20 2'1'o
1575 1850 2150
1525 1800 2075
2200 2575 3025
20 20 20
2Yo 3.,. 3.,.
37Yz 40V. 42~
2575 3025 3450
2500 2950 3350
3650 4275 4900
20 20 20
3'1'o 3~ 3~
451', 48V• 50'\I•
<7
CD
-
4 4 4
lloll
ctee ..
2 3 4
6 8 12
2 3 4
No. Olem. Hole1 Hol••
29 54 87 116
,::,
n
-
__
Bllnd
25 61 81 105
o,
---
-
2 4 4
Soctt:.w.
Lop Jolnt
26 63 63 110
14.14 16.16 16.16
.. -
-
:~~t
S!¡C;3_n
31 53 66 110
8.75 10.92 12.92
,::,
-
-
-
8.72 10.88 12.88
....
<7
:y.,
'J<,
-
3.60 4.60 5.69 6.75
o
'ti,
')(,
-
-
tHOTI::
'l2
'<,
-
-
3.57 4.57 5.66 G.72
-i
J<,
OrUlln
Anoto•. Welaht llbl.,
-
-
-- --- --- - - - - - --- -- - - - - - - - -
Courtesy of Taylor Forge
PIPE DRAFilNG AND DESIGN
-
--
-
-
-
18
-
35Y:i ASTM A 1 e t.:i-11
430
APPENDIX A: DIMENSIONAL DATA
FLAN GES WELDING NECK
DIMENSIONS
SLIP-ON
LAP JOINT
~:~1mü
~X-¡
_r_·-0-~
1500-lb.
º"'" tlde "°"'· Pipo SI.u
º'ª"'· o
V,
4~
o/•
5V.
1
5V.
1Y.. 1 V, 2
lMt". (ffllo.)
6Y. 7 8Y.t
e.e.
º'
H•b 018ffl.
:!~t·
R
X
Y,
1Y.t 1o/4 2)(,
2~ 2~ 2V.
RalNd F.. e
e
v.
1~ 1')(, 2
1 1V.
UnOlh .. nt Hub Sllp.On Lop Thrd, t Jolnt Soc.k. W.
Y,
Y,
1v. 1~ 1'\'o
1V. 1Y, 1 V,
2Yz 2V. 3%
2V, 2:V. 4V.
2V. 3Y, 4
1'\'o 1* 2Y..
1119 1* 2Y..
1'ii
4V. 5
41~ 5Y..
4~ 4'ii
2Yz 2V.
2Y, 2V.
6)(,
6~
1*
41~ 6V.
3)(, 4V. 4')(,
3)(, 4V. 4% 5'ii 7 8'ii
2Y.t 3 3Y.t
9,Y. lOY.t
1'~
4 5 6
12Y, 14* 15Y.t
2V. 2V. 3Y,
8Y,
9
6*
8 10 12
19 23 26Y.z
3'í'o 4Y, 4V.
10'í'o 12:V. 15
11\'.z 14\'.z 17*
8~ 10 11 V.
5119 6Y..
14 16 18
29\'.z 32\'.z 36
5Y, So/, 6~
16Y, 18Y.t 21
19Y. 21* 23\'.z
11:V. 12Y.. 12V.
-
23
25Y,
20 22 24
-
38:V.
-
46
1Y• 1~ 1%
-
7
-
-
n<,
-
14
-
-
-
-
8
27Y,
30
16
-
7V.
-
9Y.z lOV. 10V.
-
-
11\'.z
-
-
-
13
-=~~t· B,
-l
o
..
c:r
.. ..
V
o
--·-..
o. c:r -c
o
..e
o
.. ~ 3
Bor•O Sllp..on
Lop
O.pltl ol
Sock. w. Joltll Sockel B,
...
0.88 1.09 1.36
0.90 1.11 1.38
1.70 1.95 2.44
1.72 1.97 2.46
2.94 3.57
2.97 3.60
4.57 5.66 6.72
4.60 5.69 6.75
6.72 10.88 12.88
8.75 10.92 12.92
-
-
-
-
14.18 16.19 18.20 20.25
-
24.25
o
Appro,. WgL (U.t.)
:~~·
~
Sllp·OJ Thrd, Sock. W
Lop
Jolnl
DrllllnO
•
Boll No. 01....... Clrcle Bllod HolH HolH Ol•m.
v. v.
5 6 9
4 5 8
4 5 8
4 6 8
4 4 4
1
3Y, 3Yz 4
'Yo
10 13 25
9 12 25
9 12 25
9 13 25
4 4 8
1 1V. 1
4~ 4V. 6Yz
-
*
36 46
36 48
35 47
35 48
-
8 8
-
1\.'o 1v.
7V, 8
-
73 130 165
73 130 165
75 140 170
73 140 160
8 8 12
1'\'o 1 Y,
9Yz 11 Yz 12V.
275 455 690
260 435 580
265 485 630
300 510 690
12 12 16
1:V. 2 2\.'o
15Yz 19 22\'.z
-
890 975 1150 1300 1475 1750
16 16 16
2~ 2'í'o 2V.
25 2H', 30Y2
-
1775
3V.
32:V,
3,;¡,
39
K,
V,
)(,
')(, -
-
-
-
-
-
-
-
940 1250 1625 2050
-
3325
-
-
-
-
-
2225
-
16
-
2825 3625
16
7
-
Hw
-
-
-
2500-lb. Y, 1
*
1Y, 1Y.z 2 2Y.z 3 3Y.z
4 5 6 8 10 12
5Y·
H(,
6Y,
1Y.. 1~
1~ 1•)(, 2
11)(. 2 2Y,
2V. 3V. 3Y.z
1J(, 1 ')(, 1V.
1)(, 1')(, 1V.
7Y, 8 9Y.
1Y, 1:V. 2
2Yl 2V. 3'ii
2V. 3V. 3:V.
3~
2)(, 2~ 2*
2)(, 2~ 2~
3V. 3'\'o
3Yo 3'ii
sv.
10\'.z 12
2Y, 2'ii
4V. 5
4V, 5Y•
-
-
-
-
14 16\'.z 19
3 3'í'o 4Y..
6)(, 7)(, 8Y.z
6Y.z 8
21:V. 26Y.t
5 6Y.t 7Y,
10'ii 12:V. 15
12 14o/,
30
9Y,
17~
4~ 5 5'ii 6'ii
-
7V. 9 10* 12V. 16\,', 18Y,
-
4Y, 5Yo 6 7 9 10
-
4Y•
5V. 6 7 9 10
-l
o
....
c:r
.. -·..
..,
-n
-·
o. sr
-e o e
"¡;
.. 3
~
I Ouncns;ons aro- in tnehos. Pncos on Af)t)kauon.
borewol be hwnished unleu 01-.e
2 S•-d
1pec,ried 3 Sockot Wcfd hgs aro not mtd.1n 1501 rypo ov« 24 .., W'l lOOI and 600# ovcr 3'". In 15001 ~
2
•."' 4001 aOd 2500• "" any su.e.
• Spccotoc.,1oons-A11Toyto, Fo,go n,,,,gos c:ontorm 10 ANSI Std. 816.5 o, MSS $P44 u llPl)lrcal)1e ond 10 ASTM$poc. A181 (lor 1501 end 3001 0311gOS) o, A105 (fo, 4001 ond hro"1Cf '1.lngcs. 5 Wotd,ng boY<>I Sl:indatds Olld lolefoncos 6 Prossuro-Tenll)Omlute ,.it.ngs 1. Th
0.88 1.09 1.36
0.90 1.11 1.38
1.70 1.95 2.44
1.72 1,97 2.46 2.97 3.60
2.94 3.57
-
-
4.57 5.66 6.72
4.60 5.69 6.75
8.72 10.88 12.88
8.75 10.92 12.92
1~
~
7 8 12
7 8 11
7 8 11
11
4 4 4
1
3V. 3:V, 4Y,
3
17
:,
e
..-
25 42
16 22 38
16 22 37
17 23 39
4 4 8
lV. lY, 1V.
5:V. 6:V,
o e
52 94
55 83
53 80
56 86
8
1Y, 1~
1*
120 205 315
135 225 345
8 8 8
1119 1V. 2V.
10~ 12:v. 14V.
470 530 900 1025 1100 1300
12 12 12
2V. 2'Yo 2V.
17V. 21Y, 24~
z
..
;¡;
-
-
;-
145 245 380
125 210 325
580 1075 1525
485 930 1100
o. N
"'o -~ ':'
8
- -
8
-
v.
5V.
9
-
-
8. U1f110 doMlCIOf llongos. c. Minimurn borN •Faclng.s: 1501 and 300• flnnQOI (excopl t...ap Jo,4nt} fvrn,shed wlth 1 •:A,• raJHd f3ee, wt.:h lo lncluded In the lhlcl
llon1
°'
"Rof..-10 Toyl0< Fo,go Pipeline Catnlog 72310< complolo llsllng, ol MSS·SP4• 1nd API 605 llangoo. • O.mensk>n and bhf\d flango •• aome aa companion nange. howover. th1t 1, nol true tcw M~S bltod flange,9, clau 300 or ho1>v10,, 26'" 3nd la~e<. whteh Mvc o groalOf thk;knns.
Courtesy of Taylor Forge
PIPE DRAFI1NG AND DESIGN
APPENDIX A: DIMENSIONAL
DIAPHRAGM
AND
431
DATA
PISTON
ACTUATORS
DIAPHRAGM ACTUATORS
2
5
0
®
1 Díaphragm Case 2 Diaphragm 3 Dfaphragm Plate
4 Actuator Spring
5 Actuator Stem
6 Spring Seat
7 Spring Adjustor 8 Stem coonector 9 Yoke
Type 657 direct acting diaphragm actuator. Courtesy of Fisher Controls
PIPE DRAFilNG AND DESIGN
1 O Travel lndícator 11 Travel I ndicator Scale
432
APPENDIX A: DIMENSIONAL DATA
YALVE
IODIES
VALVE TRIM ~-------PACllNG FUNGE NUT-------FEU WIPER RIN& -------..J..t.i'H11 PACllNG FOUOWEI ---------+-+-lial
PACIIIN6 BOX RIN6
PACKING FUNGE STUD
~-------PACKING FUNGE _;...,-------
YOKE LOCKNUT
1;1+~~-------
PACKING
11-4---------
VALVE PLUG STEM
m--4---------
TEFLON WIPER RIN& BONNET
---------l....-<'4,.l
14--=------
VALVE PLUG
Design "A" double port body.
VALVE TRIM The term "trim" refers to the interna! parts of a valve body assembly which come in contact with the controlled fluid. Type 316 stainless steel is Fisher's standard trim material. It ís satisfactory for rnost applications and is generally recommended for fluid temperatures up to
750ºF and pressure drops up to 150 psi. For very high pressure drops or high temperature conditions, a hard surfacing alloy such as Stellite can be used on the wearing parts of the valve plug, seat rings, guide bushings and guide posts. Other alloys such as Monel, Hastelloy "B". Durimet 20 or 440C stainless steel may be selected to combat individual corrosion and erosion problems. Courtesy of Flsher Controls
PIPE DRAFI1NG AND DESIGN
APPENDIX A: DIMENSIONAL
CONTROL
VALYE
433
DATA
SELECTION
CONTROL VALVES WITH DESIGN "A" BODIES
-_,
J
Figure 3-1. Type 657-A control valve with double port. top and bottom guided V-pup valve plug.
Figure 3-2. Type 667-A control valve with single port. top and port guided Micro-Flute valve plug.
Figure 3-4. Double port Oes,gn "A" body wi1h top and bottom throttle Plug valve plug
:.,
Figure 3-3. Type 470-A control valve with single port. top and bottom guided Throttle Plug valve plug.
Figure 3-6. Double port Des,gn "AR" body w,th reverse acting V-Pup valve plug.
Figure 3-5. Double port Oeslgn "A" body wilh port guided V-Port valve plug.
Courtesy of Flsher Controls
PIPE DRAFilNG AND DESIGN
434
APPENDIX A: DIMENSIONAL DATA
ACTUATORS Type Type Type Type Type
657 667 470 472 473 Type 513
3 3 4 4 5 5
BODIES
Dcsign ''HS'"
Design '"Aºº Single Pon
Dcsign Dcsign Design De ign De ign Design
Dcsign ''BFC" Design "D" Design ·'DAº' Design "DBºº & ''DBQ" Dcsign "DBAº' & "DBAQº' Dcsign "E'º Dcsign ··EA'' Design '·Gs··
6 and 7 8 and 9 1O 1 O and 1 1 11 12 12
··A·· Double Pon ººAA ··AC'º "B" º'BAºº ··BF'
12 12 13 13 13 14 15 15
............•...................
16
Dcsign "K" & "KBº' Dcsign "Y" (lron) .............•............... Design "Y'º (Stecl) De ign ··yr (lron) Dcsign ··yy··(Steel) Dcsign ··z·· Design ·'ZLA''
17 17 18 18 19 19 19
PROCEDURE dimensions of a control valve. add the '"Dºº and "G"º body dimensions to the ··E·· dimen ion of the actuator. Dimensions for val ve Jodic, with a 5~ boss head are so indicated and these dirnensions should be combincd with onc of thc following actuators: Sizc 80 and 87. Types 657 and 667: Sizes 80. 86. 100 and 130. Type 470: Sizes 80 and 100. Types 472 and 473. Similarly. dimensions for , alve bodie that can be furnished with a 11A" boss head are so indicated and these dimensions should be combined ,, ith the dimensions of the Type 513 or the Type 470. Size 23. actuators. To obtain
the ovcrall
Example: Given: 6~ Type 657-A. 150 lb. RF tlangcd. double pon stcel body with top and bonom guided valve plug. From the table below, note that a Size 50 or 60 Type 657 actuator is normally supplied with a 6" val ve. Dimension '"E'' from Page 3 is 28- 11ir:1• Frorn Page 8. we see 1hat "G" is 13-Ya/ and "D'' is 14-15ft•"· Thus. E+ G + D = 287/Í/ + 13-Yi/ + 14-15/16" = 56-11/16"· NOTE: When using a valve plug requiring a top guide but not a bouom guide. such as Micro-Forrn valve plug. use dimension "D'' under top and bottom guided and dimensión "G" undcr skirt guided.
STANDARD CONSTRUCTIONS UIUES 657 AND 667 DIA,HRAGM ACTUATORS
ActuaÍot Size
30
34
40
45
50
60
70
80
87
Effeclive Area, Sq. In.
46
69
69
105
105
156
220
283
220
Slem S11e, In.
3/8
3/8
1/2
1/2
3/4
3/4
3/4
1, 1-1/4
l
2-1/8
2 1/8
2-13/16
2-13/16
3-9/16
3-9/16
3-9/16
5
5
2-4
2 4
5-8
5 8
10 16
10 · 16
10-16
Yoke Boss S11e, In. Body Size, In
1/2 · 1·1/2 1/2 11/2
SERIES 470 ,isTON ACTUATOltS
Actuator Size Cylinder Dia., In. Stem Size, In. Yoke Boss Size, In. Body Size, In.
23
30
40
43
60
63
64
80
86
100
130
4-3/4
4-3/4
6-1/8
4-3/4
8-1/2
4-3/4
6-1/8
10-3/4
8-1/2
13
17
3/8
3/8
1/2
1/2
3/4
3/4
3/4
1
l
1-1/4
1-1/4
1-1/4
2-1/8
2-13/16
2-13/16
J.9/16
3-9/16
3-9/16
5
5
5
5
112-2·
1/2-1-1/2
2-4
2-4
5-8
5-8
5-8
10-16
10-16
10-16
10-16
·ocs,gn "Gs;· "B," and "BA" bodíes only.
Courtesy of Fisher Controls
PIPE DRAFI1NG AND DESIGN
435
APPENDIX A: DIMENSIONAL DATA
ACTUA TOR DIMENSIONS TYPE 657 DIAPHRAGM ACTUATOR
TYPE 667 DIAPHRAGM ACTUATOR
1
CD
E
[E
1
-
SIZE
E
"'t9're
~
e
J, 6lr,
30 34 40 45 50 60 70
21~••
,,.,.
a•,.
2~'\,
16
2ef~
16
ª"• 8 ••
87
36"'
28~
11\.. ll't.
18,
33~- 21", z11,_
NPT
SIZE
,.-,. .,,., ."·-,e
30 34 40 45 50 60 70
He 4lr.
1'4-18
6',1,, 6 ,,..
114-II
ª"•
7"1',,
"4-18
7'\i
"4-18
14
12'1-.
~2-14
14
te:\ ..
",,-14
ª"•
87
e 4l'J. .,... .. .,.-1, 22,. ,,.,. e''"·Y, ,.,. ,,.. -,. ª"'· E
181~"
J,
H,
e"4
..,.. •,.. -,.
11~.
TYPE 657 - SIZE 80
NPT
4'Y,
231',, 30''4 30f, 30\ 36~ 3')f/z
131,, 16
16
ª"·
,,ei,. e'I-, 211,.
21"•
6~ 6'11,
"• -11
...,.. l¡z-t• ,,,_,. •• 114 -··
14
111, ..
SIZE 17 HAS A r
SIZE 17 HAS A 5• 1055
Ir
E
E
1055
TYPE 667 • SIZE 80
YOH 10551
15" YOKI 10551
2501
Courtesy of Fisher Controls
PIPE DRAFilNG AND DESIGN
436
APPENDIX A: DIMENSIONAL DATA
DESIGN "A" DOUBLE PORT IRON BODIES PLAIN IONNET
-
SIZE
o
o
1
6
l'I.
_J
'
1'1,
IV:,
2 2~ 3
G
A
..
,,,,." 1,1,..,, "''
5 6 8
11'!.
º" 7
,,,.
'ª"' 22\
.
1!1,
21\ 2,•,. 27~.
AIIIAtVtAf 10• S
PORT GUIOEO 3 ~. 5\1
.
.
111
1,
...... &
TOP ANO BOTTOM GUIOEO
o
GUIOE:O 6 6 7
1~•
e'r,, e~..
'''" e•,,
10,,,
''"'• ,,,,,. 1 ,1,~ ,.,.,.,. ª"" ,tt, ,,.,. ... t, ••''loo. ''.
9'1-.
13~
12'1\, 13 \
, .,,..
,,
101,,
151/4
SClltD StJth[D UiOS H•fLAT J'AC.(, lllf•5¡MS.[0 fACí 'LAHGl SP((.1ftC,ArtON lttfCR(Ct;.1?-S Ll·USAS BJII 2~ LI • USAS 116~ US[O
G rae
•'r.. .,,, 51,,,,, He ,,,~.. .,,,,5>,, ..,• ~,,.. 1't, .. v. ,,,, ,i, ª"' ~·.y.,
,.,,,.
,,,ª"°-..
..
10 POllT GUIOEO
250 125 250 Rr SCRO rr Rr 7'14 1•,. 2·~.. 3'ro 3Y1 1i. 2·~. •'11. e>r. 3'1-. 10\o, 3\ ,oJ,, 11"2 5-,., $~1, ;. 12111 53ta 5'1-.
,~. 'º
4
G
GID
B
SCRO 125 FF
,e1~1,
151\. 20~..
9(W[
DESIGN "A" DOUBLE PORT STEEL BODIES PLAIN IONNET
EXTENSION IONNET
o 1
1
o'
.1
8-
G G
. -A---~
8
'----A l'ORT GUIOEO
~ZE 1
"'·
11/2
2 2'h 3 4
5 6 8
'º
----
TOP ANO BOTTOM GUIOEO
A
'" ..,.. . 1'4 1'r, ,, '"· ., ' ..... ,,,. ,.,. ,i. .. 1"4
SCRO •:
1$0
AlJ
300
300 RIJ
400 AF
6
rY,
,,1,
9~
...,,. '°"' ••'11. ,,¡.. ,1, "'.•.,. 22,""· ,,,,. 'º
10~.
11"1,
121,.
13~.
11\, 21'!-o 21•, 261.
'º"' 111¡,
11'1, 12'-'o
...
.·~~.· ... ',.. ,.,. .,,. ., , . ..,,. ,,,. ,,,,......~. ,.,. , .,, .r. .
TOP ANO BOTTOM GUIOEO
G
B
400 RTJ
600 Ar
'
814
'
'r
600 RTJ
,.,.. 9
5CRO
2'',¡, 2•11.
1
•
.,~
1$0
,.,_ RF
91\
121,.
..
29"'•
4181t('t'IA,,()H.S v,(0 A.eov( .sc;,tCJ• SCJtl:W(O (NOS, ttr•twt(D JACf.:, IUJ • '--1.1110 ..-I.AJ'IIO< SPt:CArlCNl()k MrUUIC(,IM>·JOO ,IOC) I001,.I USAt ... , • ~'41.ofr,jAU.'f IH( SA.... AS 100 1,.I •• • 01t•(NSOff4\.t..YIH( ,,.,.., AS to0 LI "'"
ATJ
1$0
300 Rí
.:,~.
3Y..
300 ATJ
400 Rí
l'\t •'lit •'lit
ll'tc,
12>r. 1314 13>,,, 15'!,,, 15';, i,'I<. 1111, 11'1, 11'1a 1,.,. 11'11. 20 201\o 23 u'li, 23'1-, 24 24'-'o 2,i_ 2,~. 21'ta 29 29''a 121,, 1)111 141... 15!,. 1,•,.
PORT GUIOEO
5'1a
,.i... 7 7~
,;,
11•1, , YH.
,·~•. •. ''"' ,. , ,l., ,·~ '~ 5'1,,, 5"ta
,;,
5l\.
,,,.
.,~.~. .~. .... .. 70,.
1,,.
7~
'º''••
IO'ta 11>,, ll'iJ.,. 1211,
400 R1J
', T
' ,•
,·'lit 1''11. 1\
,.
600 Ar
600 ATJ
•'" •''ll.
•'.
.~. ,ir. 7
G
•'!-,.
,.---,
.
• 't•
5"1',o
1'1<,
• 11.,
..,...,.. ·~,,,, '""• ,·~. ,~.
. v. ...,. 5~. 5"4
o
PORT
GUID
54.,.
1>,,
o
TIIB GUIOEO 6
PIPE DRAFI1NG AND DESIGN
e~..
'"·· . . ,.,. ,ª"•.. ~ ~.. íof. • '1•
''1,
6 7
~
,~. 7',,,..._ e'!\, ,.,,,. a'1'r;,1~ 1t,. ,~. 'º~· ,,,,.. ,,,,, ...,. ,~.. "'
,·~.
1$1tc.
9 12'11
11'1-2
141~ IA.. l''ll.t 9 12:\\t 1o'r, 13"14 l)'r, 14 ~. 15'.~ 12'r,. ,2, 12''1.. 12.,,. 16!\\& 16 ,e•ii, 20~ ..
JO*N'
O' EXT.
'º'"'• 'º'"" "
17
~'
Courtesy of Fisher Controls
437
APPENDIX A: DIMENSIONAL DATA
DESIGN "A" SINGLE PORT IRON BODIES ,U.IN IONNIT SIZc
B
A
,,
125
250 $GRO Rf
G
,,
125
250
o
··.~
G
o
r••
PORT GUIO[O GUIDEO .... 4},o 3},. 311, 3'\\, 3"a
,~,'". , ,~. ''• '" ' Ho . . '''• ,.,. ,1; 1•,.. 1 .. '"~&lo. ,.,. n, .,,. I'/, ,· ~ . "• ,,. 9•,. "• ., ,11 • Y".I. '~ •.,.. •"'- ,...... • 2 ,.,.. 'º ,~ .. es,. ' 2',
1
o
$GRO 6
1'11
3
7,
3
. . 7 '•
l','z
3•~. 31~ 3,, 3 '• 3'"" 4'1\a
~.
"'!lo 17'1r. 18'1<1 21'9 26\; 21~
10
l'OlT GUIDED
--"""''-- .. u-.u .._.... ... ·
TOP' ANO IOTTOM GUIOEO
1~. I\;
$'14
5°A,
12Vt
1311
5 5 6~. 7~.
..~. ·.~· . ~.. . ,,.,,
10\;
G
4 .....
5"41
10\oz
1011\,
---· -~
1 ,.,,,.
13•~
f31/4
9~
7},
7°'4
7'~.
7'!'w.
101\
,n,. 13t;,.
1211, ,2,... 13~.
16
O 1.NOS
DESIGN "A" SINGLE PORT STEEL BODIES IXTINSION IONNIT PLAIN IONNIT
lo
o G
.1 POU GVIOED
G
TOP' ANO IOTTOM GUIOEO
A
-
TOP' ANO IOTTOM GUIOEO
l'OlT GUIOEO
B
GID
G I D
r• •
º'
'". "' "'• ,...., ,,. ~ "' "'• "" "' "'. ,, ,,,. . .. ,. . .. . . '"" "' ,._, . ' . ..... ..... ~ ...... ,.,. ... ,~. .,, . ....... ..'. . ,~. '"" '"" ' ·•~· ·~• . ,... . . '"" ,.,. ,.,. .,.,. .,. .,-. • ' •"'- •""" ..,. • ,,. ,.,. .... .. ' '"' . ,. . .. . . 'º ''"' ,·~ ..... ,,''-.,, ...... .,,,. • '' """' ' .,,. ,~. . ' ..,.... I"" .,. , . ..,. ..... ª"" ,.,,. . .. ~. • '°"" "' "• ,.,. .,.,. ,,,,. ' ... . . '"· .. . ...... '"°. ., ,•¡.,. ,,.,. •..,,. • ... . 'º"'" """'..~~ """ "~ ..,...... ... . . ... . . z,,-. "''" ,... . u~ "' ·~ ."'-,...... ,..,. ..''"'..,. ...,.., ''" '"" 13,,. ,....
SIZE
,,. 1/z
·~
SCIIO
1
2 2Yz 3
"'
1'1t 9'¡4
8
300
300 IIH
400
7\o,,
. ·~
711,
,t.
400 IITJ
t
el!.
1\,
•t.
10\f. ,o',,,
l)l\,
5 6
150
IITJ
7\,
1
114
150
ello
t
t)'a
11•,.
11\ot
,z ....
t7'11t
is•,.
u
7'
·~
SCIIO
3 l
17\; ot!>.
13 1111 1s•11,
to'Ao
Z4
" .... "'
300 300 400
]f.
l'lr. l~ 41\a 41',, 3f.
l'l\a
IITJ
4'9
50,. 5~ 5j,. &'!-,.
1,
7"11,,
to
1$0
IITJ
4
11\.
u~ nloa
ze ...
150
n 10 11 .... Z7 ~ lolllCD Aeor.c;lcao·~ OOl,M•MlltO t'#ICl:,n.J .. ~ f'\.MIK 8":anc..-lONIIO'l...a:tll0•,00...400-tlC)O.... Ul,A8 .... • O-CQ!OlltU.'t' ne ~ .t.s eoo 1..a .w • 01ic:ttll011AU ..'f ne ........ eoo u
.
7'\o
.,,,
11 101111 1314 ll'lt
fY'N ..>OINT
•!to
5'11. 11',. 1'11. 7~
t'II.. t~
400 IITJ
100
100
IITJ
PORT GUIOED
t
t
t t
30,.
1t'14 IZ''I
IZ!c. IZI\, 14'1!.
17'11, tallo ZI~
see
.
7 ....
PIPE DRAFilNG AND DESIGN
,t..
•l
41
3~
5'11.
t 1'1',.
•'2
•1-z
ElCT.
7 \..
,i,,
t
11\rt 11'1\a 11'\lo 14'i\o
..,.J
41\a 41\a
tulotD 3'1t 3\o,
7\o
10 12
,11.
3S...
l'l\o 5'•
·~·
1"-
,14 1•~ 1~
t
1()1\a
··~·
ltl\a lo'lla ,o•'II, 15 ..
13",\o
71a
'''i
12\o 13~. 9 'la 13~
8
oo'f..
IZ ,a 12 .....
,si.
,1,
11•,i.
16
8~
11~.
to
f;:=8F1IP PLAN
o
o
NUMBER OF SECTIONS
o o o
o
o
o
ce o
o
o
o
o
o
o o o
o
ELEVATION
LIQUID
VISIBLE GLASS
UNION CONNECTION
ce
2 2 2 2 2
15 18 21 24 27
22 25 28 31 34
3 3 3 3
30 33 36 39
37 40 43 46
4 4 4
41 44 47
49 52 55
LEVEL GAGE
LG 1, 2 & 3
r
1-5"1
_J
1
5"-5"
1
14"
10"
l
~1~
(
1
14"
MID RANGE
1
1 1
ce
(
-
1 MR 4"
'"""
ELEVATION
i
PLAN RANGE
ce
MR
14 24 34 44
14 24 34 44
54
54
7 12 17 22 27
LEVEL CONTROLLER
LC 1 & 2
440
APPENDIX A: DIMENSIONAL DATA
LINEAR CONVERSION
Fractlons of an lnch To Declmals of an lnch and to Mllllmeters
D•cl•••
Froctleft
1,4,
.015625 .03125 .046875 .0625
0.39688 0.79375 1.19063 1.58750
1,4,
.078125 .09375 .109375 .125
1.98438 2.38125 2.77813 3.17501
11-44
.140625 .15625 .171875 .1875
3.57188 3.96876 4.36563. 4.76251
.203125 .21875 .234375 .25
5.15939 5.55626 5.95314 6.35001
.265625 .28125 .296875 .3125
6.74689 7.14376 7.54064 7.93752
.328125 .34375 .359375 .375
8.33439 8.73127 9.12814 9.52502
.390625 .40625 .421875 ,4375
9.92189 10.31877 10.71565 11.11252
.453125 .46875 .484375 .5
11.50940 11.90627 12.30315 12.70002
ª/.11
3"'
•1t,
,,.., Sf..2
.,..,
Va ........................ %2 3/16
u-44 71.12
u-44
IA ........................ •1.11
ª!t, llf.i2
11.4, 1•,4, 21,4, u,4,
o/a ..... ··················· Uf.i2 11i. 11
hz
Mllllmeler
u.4, 21.4. u,4, J
'.4,
112 ........................
o........
Mllllm•t•r
.515625 .53125 .546875 .5625
13.09690 13.49378 13.89065 14.28753
.578125 .59375 .609375 .625
14.68440 15.08128 15.47816 15.87503
.640625 .65625 .671875 .6875
16.27191 16.66878 17.06566 17.46253
".4, º.4,
.703125 .71875 .734375 .75
17 .85941 18.25629 18.65316 19.05004
º.4,
.765625 .78125 .796875 .8125
19.44691 19.84379 20,24066 20.63754
,828125 .84375 .859375 .875
21.03442 21.43129 21.82817 22.22504
.890625 .90625 .921875 .9375
22,62192 23.01880 23.41567 23.81255
. 953125 .96875 .984375 1.0
24.20942 24.60630 25.00317 15.40005
Frocllen
•%2
•A, ••1.12
3S/u
ª%, ni, u.4,
% . ....................... 2%2 11/¡. Uf.i2 3,4
".4,
º/u
. ....................... U/32
1 ª!t,
211.12
11,4,
n,4, u,4,
Ya ........................ Uf.12 111i,
11,4, u,4,
11.4, 311.,i
1
ºIÍ,
. .......................
Courtesy of Crane Co.
PIPE DRAFI1NG AND DESIGN
441
APPENDIX A: DIMENSIONAL DATA
LINEAR CONVERSION lnches to Mllllmeters (1 inch .. 25.4 mlllimeters)
o
ul
1 2 3 4
25.4 50.8 76.2 101.6
o.o
1.6 27.0 52.4 77.8 103.2
3.2 28.6 54.0 79.4 104.8
30.2 55.6 81.0 106.4
6.+ 31.8 57.2 82.6 108.0
7.9 33.3 58.7 84.1 109.5
9.5 34.9 60.3 85.7 111.1
11.1 36.5 61.9 87.3 112.7
n.1 38.i 63.5 88.9 114.3
14.3 39.7 65.1 90.5 115.9
15.9 41.3 66.7 92.1 117.5
17.5 42.9 68.3 93.7 119.1
19.1 44.5 69.9 95.3 120.7
20.6 46.0 71.4 96.8 122.2
22.2 47.6 73.0 98.4 123.8
23.8 49.2 74.6 100.0 125.4
5 6 7 8 9
127.0 152.4 177.8 203.2 228.6
128.6 154.0 179.4 204.8 230.2
130.2 155.6 181.0 206.4 231.8
131.8 157.2 182.6 208.0 233.4
133.4 158.8 184.2 209.6 235.0
134.9 160.3 185.7 211.1 236.5
136.5 161.9 187.3 21l.7 238.1
138.1 163.5 188.9 214.3 239.7
139.7 165.1 190.5 215.9 241.3
141.3 166.7 192.1 217.5 242.9
142.9 168.3 193.7 219.1 244.5
144.5 169.9 195.3 220.7 246.1
146.1 171.5 196.9 222.3 247.7
147.6 173.0 198.4 223.8 249.2
149.2 174.6 200.0 225.4 250.8
150.8 176.2 '101.6 227.0 252.4
10 11 12 13 14
254.0 279.4 304.8 330.2 355.6
255.6 281.0 306.4 331.8 357.2
257.2 282.6 308.0 333.4 358.8
258.8 284.2 309.6 335.0 360.4
260.4 285.8 311.2 336.6 362.0
261.9 287.3 312.7 338.1 363.5
263.5 288.9 314.3 339.7 365.1
265.1 290.5 315.9 341.3 366.7
266.7 292.1 317.5 342.9 368.3
268.3 293.7 319.1 344.5 369.9
269.9 295.3 320.7 346.1 371.5
271.5 296.9 322.3 347.7 373.1
273.1 298.5 323.9 349.3 374.7
274.6 300.0 325.4 350.8 376.2
276.2 301.6 327.0 352.4 377.8
277.8 303.2 328.6 354.0 379.4
15 16 17 18 19
381.0 406.4 431.8 457.2 482.6
382.6 408.0 433.4 458.8 484.2
384.2 409.6 435.0 460.4 485.8
385.8 411.2 436.6 462.0 487.4
387.4 412.8 438.2 463.6 489.0
388.9 414.3 439.7 465.1 490.5
390.5 415.9 441.3 466.7 492.l
392.'l 417.5 442.9 468.3 493.7
393.7 419.1 444.5 469.9 495.3
395.3 420.7 446.1 471.5 496.9
396.9 422.3 W.1 473.l 498.5
398.5 423.9 449.3 474.7 500.1
400.l 425.5 450.9 476.3 501.7
401.6 427.0 452.4 411.8 503.2
403.2 428.6 454.0 479.4 504.8
404.8 430.2 455.6 481.0 506.4
20 21 22 23 24
508.0 533.4 558.8 584.2 609.6
509.6 535.0 560.4 585.8 611.2
511.2 536.6 562.0 587.4 612.8
512.8 538.2 563.6 589.0 614.4
514.4 539.8 565.2 590.6 616.0
515.9 541.3 566.7 592.1 617.5
517.5 542.9 568.3 593.7 619.1
519.1 544.5 569.9 595.3 620.7
520.7 546.1 571.5 596.9 622.3
522.3 547.7 573.1 598.S 623.9
523.9 549.3 574.7 600.1 625.5
525.5 550.9 576.3 601.7 627.1
527.1 552.5 577.9 603.3 628.7
528.6 554.0 579.4 604.8 630.2
530.2 555.6 581.0 606.4 631.8
531.8 551.2 582.6 608.0 633.4
25 26 27 28 29
635.0 660.4 685.8 711.2 736.6
636.6 662.0 687.4 712.8 738.2
638.2 663.6 689.0 714.4 739.8
639.8 665.2 690.6 716.0 714.4
641.4 666.8 692.2 717.6 743.0
642.9 668.3 693.7 719.1 744.5
644.5 646.1 669.9 671.5 695.3 696.9 720.1 722.3 746.1 141.1
647.7 673.1 698.5 723.9 749.3
649.3 674.7 700.1 725.5 750.9
650.9 676.3 701.1 727.1 752.5
652.5 677.9 703.3 728.7 754.1
654.1 679.5 704.9 730.3 155.7
655.6 681.0 706.4 731.8 757.2
657.2 682.6 108.0 733.4 758.8
658.8 684.2 709.6 735.0 760.4
JO 31 32 33 34
762.0 787.4 812.8 '38.2 863.6
763.6 789.0 814.4 839.8 865.2
765.2 790.6 816.0 841.4 866.8
766.8 792.2 817.6 843.0 868.4
768.4 793.8 819.2 844.6 870.0
769.9 795.3 820.7 846.1 871.5
711.5 796.9 822.3 841.1 873.1
774.7 800.1 825.5 850.9 876.3
776.3 801.7 827.1 852.5 877.9
717.9 803.3 828.7 854.1 879.5
779.5 804.9 830.3 855.7 881.1
781.1 806.5 831.9 857.3 882.7
782.6 808.0 833.4 858.8 884.2
784.2 809.6 835.0 860.4 885.8
785.8 811.2 836.6 862.0 887.4
35 36 37 38 39
889.0 914.4 939.8 965.2 990.6
890.6 916.0 941.4 966.8 992.2
892.2 917.6 943.0 968.4 993.8
893.8 919.2 944.6 970.0 995.4
895.4 920.8 946.2 971.6 997.0
896.9 898.5 900.1 901.7 903.3 904.9 906.5 908.1 909.6 911.2 912.8 922.3 923.9 925.5 927.1 928.7 930.3 931.9 933.5 935.0 936.6 938.2 947.7 949.3 950.9 952.5 954.1 955.1 957.3 958.9 960.4 962.0 963.6 973.1 974.7 976.3 977.9 979.5 981.1 982.7 984.3 985.8 987.4 989.0 998.5 1000.1 1001.7 1003.3 1004.9 1006.5 1008.1 1009.7 1011.2 1012.8 1014.4
40 41 42 43 44
1016.0 1041.4 1066.8 1092.2 1117.6
1017.6 1043.0 1068.4 1093.8 1119.2
1019.2 1044.6 1070.0 1095.4 1120.8
1020.8 1046.2 1071.6 1097.0 1122.4
1022.4 1047.8 1073.2 1098.6 1124.0
1023.9 1049.3 1074.7 1100.1 1125.5
1025.5 1050.9 1076.3 1101.7 1127.1
1027.1 1052.5 1077.9 1103.3 1128.7
1028.7 1054.1 1079.5 1104.9 1130.3
1030.3 1055.7 1081.1 1106.5 1131.9
1031.9 1057.3 1082.7 1108.1 1133.5
1033.5 1058.9 1084.3 1109.7 1135.1
1035.1 1060.5 1085.9 1111.3 1136.7
1036.6 1062.0 1087.4 1112.8 1138.2
1038.2 1063.6 1089.0 1114.4 1139.8
1039.8 1065.2 1090.6 1116.0 1141.4
45 46 47 48 49
1143.0 1168.4 1193.8 1219.2 1244.6
1144.6 1170.0 1195.4 1220.8 1246.2
1146.2 1171.6 1197.0 1222.4 1247.8
1147.8 1173.2 1198.6 1224.0 1249.4
1149.4 1174.8 1200.2 1225.6 1251.0
1150.9 1176.3 llOl.7 1227.1 1252.5
1152.5 1177.9 1203.3 1228.7 1254.1
1154.1 1119.5 1204.9 1230.3 1255.7
1155.1 1181.1 1206.5 1231.9 1257.3
1157.3 1182.7 1208.1 1233.5 1258.9
1158.9 1184.3 1209.7 1235.1 1260.5
1160.5 1185.9 1211.3 1236.7 1262.1
1162.1 1187.5 1212.9 1238.3 1263.7
1163.6 1189.0 1214.4 1239.8 1265.2
1165.2 1190.6 1216.0 1241.4 1266.8
1166.8 1192.2 1217.6 1243.0 1268.4
773.1 798.5 823.9 849.3 874.7
50 1270.0 1271.6 1273.2 1274.8 1276.4 1277.9 1279.5 1'281.1 1282.7 1284.3 1285.9 1287.5 1289.1 1290.6 1292.2 1293.8
Courtesy of Grane Co.
PIPE DRAFilNG AND DESIGN
442
APPENDIX A: DIMENSIONAL DATA
LINEAR CONVERSION Declmala of an lnch to Mllllmetera (0.10 inch • 2.54mlllimeters) lnches 11
0.00
1
.01
.02
.03
.04
.os
.06
.07
.08
.09
11 lnchea
o.oo .10 .20 .JO .40
0.00 2.54 5.08 7.62 10.16
0.25 2.79 5.33 7.87 10,41
O.SI 3.05 5.59 8.13 10.67
0.76 3.30 5.84 8.38 10.92
1.02 3.56 6.10 8.64 11.18
1.27 3.81 6.35 8,89 11.43
1.52 4.06 6.60 9.14 11.68
1.78 4.32 6.86 9.40 11.94
2.03 4.57 7 ,11 9.65 12.19
2.29 4.83 7.37 9.91 12.45
0.00 .10 .20 .30
.so .60 .70 .80
12.70 15.24 17.78 20.32 22.86
12.95 15.49 18.03 20.57 23.11
13.21 15.75 18.29 20.83 23,37
13.46 16.00 18.54 21.08 23.62
13.72 16.26 18.80 21.34 23.88
13.97 16.51 19.05 21.59 24.13
14.21 16.76 19.30 21.84 24.38
14.48 17.02 19.56 22.10 24.64
14.73 17.27 19.81 22.35 24.89
14.99 17.53 20.07 22.61 25.15
.50 .60 .70 .so
7
8
9
.90
.40
.90
Mllllmeters to lnchea (1 mlllimeter = 0.03937 inch)
Millimctersll
2
O
3
s
4
6
I MilJimeters
o 10 20 30 4-0
0.00 0.39 0.79 1.18 1.57
0.039 0.43 0.83 1.22 1.61
0.079 0.47 0.87 1.26 1.65
0.118 O.SI 0.91 1.30 1.69
0.157 o.SS 0.94 1.34 1.73
0.197 0.59 0.98 1.38 1.77
0.236 0.63 1.02 1.42 1.81
0.276 0.67 1.06 1.46 1.85
0.315 0.71 1.10 1.50 1.89
0.354 0.75 1.14 1.54 1.93
o 10 20 30 40
50 60 70 80 90
1.97 2.36 2.76 3.15 3.54
2.01 2.4-0 2.80 3.19 3.58
2.05 2.44 2.83 3.23 3.62
2.09 2.48 2.87 3.27 3.66
2.13 2.52 2.91 3.31 3.70
2.17 2.56 2.95 3.35 3.74
2.20 2.60 2.99 3.39 3.78
2.24 2.64 3.03 3.43 3.82
2.28 l.68 3.07 3.46 3.86
2.32 2.72 3.11 3.50 3.90
so 60 70 80
100 110 120 130 14-0
3.94 4.33 4.72 5.12 S.51
3.98 4.37 4.76 5.16 5.55
4.02 4.41 4.80 S.20 S.59
4.06 4.45 4.84 5.24 5.63
4,09 4.49 4.88 5.28 5.67
4.13 4.53 4.92 5.31 5.71
4.17 4.57 4.96 5.35 5.75
4.21 4.61 5.00 5.39 5.79
4.25 4.65 5.04 5.43 S.83
4.29 4.69 5.08 5.47 5.87
100 110 120 130 140
150 160 170 180 190
5.91 6.30 6.69 7.09 7.48
5.94 6.34 6.73 7.13 7.52
S.98 6.38 6.77 7 .17 7.56
6.02 6.42 6.81 7.20 7.60
6.06 6.46 6.85 7.24 7.64
6.10 6.50 6.89 7,28 7.68
6.14 6.54 6.93 7.32 7.72
6.18 6.57 6.97 7.36 7.76
6.22 6.61 7.01 7.40 7.80
6.26 6.65 7.05 7.44 7.83
150 160 170 180 190
200 210 220 230 240
7.87 8.27 8.66 9.06 9.45
7.91 8.31 8.70 9.09 9.49
7.95 8.35 8.74 9.13 9.53
7.99 8.39 8.78 9.17 9.57
8.03 8.43 8.82 9.21 9.61
8.07 8.46 8.86 9.25 9.65
8.11 8.50
8.90
9.29 9.69
8.15 8.54 8.94 9.33 9.72
8.19 8.58 8.98 9.37 9.76
8.23 8,62 9,02 9.41 9.80
200 210 220 230 240
250
260 270 280 290
9.84 10.24 10.63 11.02 11.42
9.88 10.28 10.67 11.06 11.46
9.92 10,31 10.71 11.10 11.50
9.96 10.35 10.75 11.14 11.54
10.00 10.39 10.79 11.18 11.57
10.04 10.43 10.83 11.22 11.61
10.08 10.47 10.87 11.26 11.65
10.12 10.51 10.91 11.30 11.69
10.16 10.55 10.94 11 .34 11.73
10.20 10.59 10.98 11.38 11.77
250 260 270 280 290
300 310 320 330 340
11.81 12.20 12.60 11.99 13.39
11.85 12.24 ll,64 13.03 13.43
11.89 12.18 12.68 fJ.07 13.46
11.93 12.32 12.72 13.11 13.50
11.97 ll.36 12.76 13. IS 13.54
12,01 12.40 12.80 13,19 13.58
11.05 12.44 12.83 13.23 13.62
11.09 12.48 12.87 13.27 13.66
12.13 12.52 ll.91 13.31 13.70
12.17 12.56 12.95 13.35 13.74
300 310 320 330 340
350 360 370 380 390
13.78 14.17 14.57 14.96 15.35
13.82 14.21 14.61 15.00 15.39
13.86 14.25 14.65 15.04 15.43
13.90 14.29 14.69 15.08 15.47
13.94 14.33 14.72 15.12 15.51
13.98 14.37 14.76 15.16 IS.SS
14.02 14.41 14.80 15.20 15.59
14.06 14.45 14.84 15.24 15.63
14.09 14.49 14.88 15.28 15.67
14.13 14.53 14.92 15.31 15.71
350 360 370 380 390
Courtesy of Crane Co.
(conli11
poge)
PIPE DRAFI1NG AND DESIGN
90
443
APPENDIX A: DIMENSIONAL DATA
LINEAR CONVERSION Millimeters to inches-cont. 2
3
5
6
7
8
9
IIMillimeter•
15.75 16.14 16.54 16.93 17.32
15.79 16.18 16.57 16.97 17.36
15.83 16.ll 16.61 17.01 17.40
15.87 16.26 16.65 17.05 17.44
15.91 16.30 16.69 17.09 17.48
15.94 16.34 16.73 17.13 17.52
15.98 16.38 16.77 17.17 17.56
16.02 16.41 16.81 17.20 17.60
16.06 16.46 16.85 17.24 17.64
16.10 16.50 16.89 17.28 17,68
400
"50 460
17.7l 18.11 18.50 18.90 19.29
17.76 18.15 18.54 18.94 19.33
17.80 18.19 18.58 18.98 19.37
17.83 18.23 18.62 19.02 19.41
17.87 18.27 18.66 19.06 19.45
17 .91 18.31 18.70 19.09 19.49
17,95 18.35 18.74 19.13 19.53
17.99 18.39 18.78 19.17 19.57
18.03 18,43 18.82 19.21 19.61
18.07 18.46 18.86 19.25 19.65
450 460 470 480 490
500
19.69 l0.08 20.47 20.87 21.26
19.íl 20.12 20.51 20.91 21.30
19.76 20.16 20.55 20.94 21.34
19.80 20.20 l0.59 20.98 21.38
19.84 20,24 20.63 21.02 21.42
19.88 20.28 20.67 21.06 21.46
19.92 20.31 20.71 21.10 21.50
19.96 20.35 20.75 21.14 21.54
20.00 20.39 20.79 21.18 21.58
20.04 20.43 20.83 21.22 21.61
500 510 520 530 540
550
21.65 22.05 22.44 22.83 23.23
21.69 22.09 22.48 22.87 23.27
21.73 22.13 22.52 22.91 23.31
21.77 22.17 22.56 22.95 23.35
21.81 22.20 22,60 22.99 23.39
21.85 ll.24 22.64 23.03 23.43
21.89 22.28 22.68 23.07 23.46
21.93 22.32 22.72 23.11 23.50
21.97 22.36 22.76 23,15 23.54
22.01 22.40 22.80 23.19 23.58
550 560 570 580 590
600
23.62 24.02 24.41 24.80 25.20
23.66 24.06 24.45 24.84 25.24
23.70 24.09 24.49 24.88 25.28
23.74 24.13 24.53 24.92 25.31
23.78 24.17 24.57 24.96 25.35
23.82 24.21 24.61 25.00 25.39
23,86 24.25 24.65 25.04 25.43
23.90 24.29 24.68 25.08 25.47
23.94 24.33 24.72 25.12 25.51
23.98 24.37 24.76 25.16 25.85
610 620 630 640
650 660
670 680 690
25.59 25.98 26.38 26.77 27.17
25.63 26.02 26.42 26.81 27.20
25.67 26.06 26.46 26.85 27.24
25.71 26.10 26.50 26.89 27.28
25.75 26.14 26.54 26.93 27.32
25.79 26.18 26.57 26.97 27.36
25.83 26.22 26.61 27.01 27.40
25.87 26.26 26.65 27.05 27.44
25.91 26.30 26.69 27.09 27.48
25.94 26.34 26.73 27.13 27.52
650 660 670 680 690
700 710 7l0 730 740
27.56 27.95 28.35 28.74 29.13
27.60 27.99 28.39 28.78 29.17
27.64 28.03 28 • .f.3 28.82 29.21
27.68 28.07 28.% 28.86 29.25
27.72 28.11 28.50 28.90 29.29
27.76 28.15 28.54 28.94 29.33
27.80 28.19 28.58 28.98 29.37
27,83 28.23 28.62 29.02 29.41
27.87 28.27 28.66 29.06 29.45
27.91 28.31 28.70 29,09 29,49
700
750 760
29.53 29.92 30.31 30.71 31.10
29.57 29.96 30.35 30.75 31.14
29.61 30.00 30.39 30,79 31.18
29.65 30,04 30.43 30.83 31.22
29,68 30.08 30,47 30.87 31.26
29.72 30.12 30.51 30.91 31.30
JO.SS
29.76 30.16
30.94 31.34
29.80 30.20 30.59 30.98 31.38
29.84 30.24 30.63 31.02 31.42
29.88 30.28 30.67 31.06 31.%
750 760 770 780 790
31.50 31.89 32.28 32.68 33.07
31.54 31.93 32.32 32.72 33.11
31.57 31.97 32.36 32.76 33.15
31.61 32.01 32.40 32.80 33.19
31.65 32.05 32.44 32.83 33,23
31.69 32.09 32.48 32.87 33.27
31.73 32.13 32.52 32.91 33.31
31.77 32.17 32.56 32.95 33.35
31.81 32.20 32.60 32.99 33.39
31.85 32.24 32.64 33.03 33.43
800 810 820 830 840
890
33.46 33.86 34.25 34.65 35,04
33.50 33.90 34.29 34.68 35.08
33.54 33.94 34,33 34.7l 35.12
33.58 33.98 34.37 34.76 35.16
33.62 34.02 34.41 34.80 35.20
33,66 34.06 34,45 34.84 35.24
33.70 34.09 34.49 34.88 35.28
33,74 34.13 34,53 34.92 35.31
33.78 34.17 34.57 34.96 35.35
33.82 34.21 34.61 35.00 35,39
850 860 870 880 890
900 910 920 930 940
35.43 35,83 36,22 36.61 37.01
35.47 35.87 36,26 36.65 37.05
35.51 35.91 36.30 36.69 37.09
36.55 35.94 36.34 36.73 37.13
35.69 35.98 36.38 36,77 37.17
35.63 36.02 36.Q 36.81 37.20
35.67 36.06 36.46 36.85 37.24
35.71 36.10 36.50 36.89 37.28
35.75 36.14 36.54 36.93 37.32
35.79 36.18 36.57 36.97 37.36
900 910 920 930 940
950 960 970 980 990
37.40 37.80 38.19 38.58 38,98
37.44 37.83 38,23 38.62 39.02
37,48 37.87 39;27 38.66 39.06
37.52 37,91 38.31 38.70 39.09
37.56 37,95 38.35 38.74 3g,13
37.60 37,99 38.39 38.78 39.17
37.64 38.03 38.43 38.82 39,21
37,68 38.07 38.% 38.86 39.25
37.72 38.11 38.50 38.90 39.29
37,76 38.15 38.54 38.94 39.33
950 960 970 980 990
1000
39,37
39.41
39 • .S
39.49
39.53
39.57
39.61
39.65
39.68
39.71
1000
400
410 410 430
'"°
470 480 490 510 520 530 540
560 570 580 590 610 620 630 640
no
780 790 800
810 820 830
840
860
860 870
880
410 420 430 440
600
710 720 730 740
Courtesy of Crane Co.
PIPE DRAFilNG AND DESIGN
444
APPENDIX A: DIMENSIONAL DATA
WEIGHT OF FLANGED
VAL VES
*
NOMINAL PIPE SIZES
w
~
c.,
(/)
o,
~ w
::'<(.i >
w
rn
o
...J
c.,
---
3"
4"
6"
8"
1 O"
12"
14"
16"
18"
20"
150
55
95
140
240
400
630
830
1150
1580
1910
2350
300
75
145
215
420
700
1050
1490
2170
2800
3720
4640
400
115
194
270
530
940
1530
2000
2410
3500
600
330
720
1220
1880
2630
3200
4230
7200
9800
900
430
900
1569
2350
3500
4680
6500
1500
610
1410
2600 824
(/)
150
47
80
140
250
420
598
z
300
79
139
214
396
628
686
~
o::
400
90
160
233
476
820
o
600
115
191
318
782
1224
900 1500 150
215
460
490
920
665
1890
34
65
100
200
390
510
775
1200
1450
300
62
120
180
330
620
920
1290
1650
2050
c.,
w
2"
z ::) o o.
~
400
200
395
680
900
1250
I
600
260
530
900
1440
1970
900 1500
340
640
1180
2170
630
1360
2100
o w o
*
APPROXIMATE WEIGHTS IN lbs. SEE MANUFACTURER'S CATALOG FOR SPECIFIC
PIPE DRAFI1NG AND DESIGN
2420
WEIGHTS.
445
APPENDIX A: DIMENSIONAL DATA
HOT INSULATION THICKNESS CHART Temperature Range ºF
'º
'º
'º
'º
326° 375°
376° 425°
426° 475°
476° to 525°
526° to 575°
1/2"
1"
1"
1"
1"
1"
1"
1"
1"
1"
1 1 /2''
1 1 /2''
3/4"
1"
1"
1"
1"
1"
1"
1"
1"
1"
1 1t2"
1 1 /2''
1"
1"
1"
1"
1"
1"
1"
1 1¡2''
1 1/2''
1 1 /2''
1 1/2''
1 1 /2''
1"
1 1/2''
1
1 1/2''
1
1"
1
2"
1"
1"
41
21/2"
1"
1"
.f!.
'º
276" 325°
41
¡¡;
'º
226º 275°
1"
-
'º
176° 225°
11/2"
..,
'º
175°
Up to
1"
- -
--
--
1"
1"
1"
1"
1"
1"
1" 1/i'
-
112''
576° 625°
626° 675°
112''
1 \"
1
1 1/2''
1 /i' 112'' 1
1 1/2''
1
1/i'
1 1/2''
1 1/2''
1 1t2"
1 1 /2''
1 1 /2''
1 1t2"
2"
1 1/2''
1
1/i'
1 1/2''
2"
1/i'
o..
3"
1"
1"
1"
1"
e
4"
1"
1"
1"
1 \"
1 \"
1 1/2''
1 1t2"
2"
2"
2"
2"
z
6"
1"
1"
1 1/2''
1 \"
1 1/2''
2"
2"
2"
2"
2 1/2''
8"
1
1/i'
1 1/2''
1 1t2" 1/2" 1
1
1/i'
10"
1 1t2"
1 1/2''
1 1/2''
1 \"
1/2"
1/2"
~
·eo
1Z'
1 1/2''
1
14"
1 1t2"
1
112"
1
2"
112"
1
1 1/2''
2"
2"
2"
2"
2"
2"
2"
2 1/2''
2"
2"
2"
2"
2"
2"
2" 2
PIPE DRAFilNG AND DESIGN
1/i'
2
1/2"
2 1/2''
1
2
1/i'
2 1/2''
2
112''
2 1 /2''
21t2"
3"
2 1/2''
2 1/2''
3"
"«
21t2"
3"
2
446
APPENDIX A: DIMENSIONAL DATA
WEIGHT OF PIPE (POUNDS
INSULATION
PER LINEAL
THICKNESS
FOOT)
OF INSULATION
1"
1 1/2"
2,,
2 1 /2"
3"
3 1 /2"
2"
1 .O 1
1 . 71
2.53
3.48
4.42
5.59
3"
1.25
2.08
3.01
4.07
5.24
6.65
w
4"
1.62
2.55
3.61
4.66
6.07
7.48
9.1 O
-
6,,
2.11
3.28
4.57
6.09
7.60
9.82
11 . 5
8"
4.13
5.64
7.85
9.48
11 .5
13.8
o"
5.20
7.07
8.93
11 .O
13.2
15.5
N
(J)
w
o. o. _J
<(
1
4"
z -
12"
6.04
8.13
10.5
12.7
1 5.1
17.4
o
14"
6.16
8.38
10.7
1 3. 1
15.6
18.5
1 6"
6.90
9.33
12.0
14.6
17.5
20.5
18"
7.73
10.4
13.3
16.3
19.3
22.6
20"
8.45
11 . 6
14.6
17.7
21 . 1
24.6
2
z
3
1 . Based on calcium silicate weighing 11 lbs/ft . 2. Chart must be adjusted for other insulating compounds. 3. Chart includes banding and protective covering weights.
PIPE DRAFI1NG AND DESIGN
APPENDIX A: DIMENSIONAL
447
DATA
BUTTERFLY VALVE - Full lug style 1501b
D J= K
Size
2
No. of holes = Top size
2-1/2
3
4
A
9·3/8
10-3/16
10-11/16
13
B
4·1/4
4-15/16
5-7/8
6·15/16
e
1·3/4
1-7/8
1·7/8
o
3
3·1/4
3·11/16
E
5·3/8
5·15/19
6
F
6
6
6
G
8
8
8
5
6
8
10
12
14
15-3/16
17-3/4
20-1/2
23-1/2
7-3/4
8·3/4
11
13-3/8
16
2·1/8
2·1/4
2·1/4
2·1/2
2·13/16
3·1/8
4·13/16
5·1/4
5·7/8
6·15/16
8-3/8
9-13/16
7
7-9/16
7-15/16
9·3/16
10-1/2
12-1/16
6
6
6
10
10
10
11
11
11
16
16
16
:r--
H
6
7
7 1/2
9·1/8
10
ll·l/4
13 3/4
16
19
J
4
4
4
8
8
8
8
12
12
K
5/8·11
5/8·11
5/8·11
5/8-11
3/4-10
3/4-10
3/4·10
7/8·9
7/8·9
L
4-3/4
5·1/2
6
7·1/2
8·1/2
9·1/2
11·3/4
14-1/4
17
M
2
2·1/2
3
4
5
6
8
10
12
UNC
UNC
l.M'IC
UNC
UNC
UNC
PIPE DRAFilNG AND DESIGN
UNC
UNC
UNC
Appendix B: Alphabet of Lines
ALPHABET OBJECT UNE -
of LINES
SINGLE LINE PIPE
OBJECT UNE - DOUBLE LINE PIPE ANO EQUIPMENT
HIDDEN UNE
----
----
CENTER LINE
1-----
DIMENSION UNE
-1
---------
MATCH UNE
448
Appendix C: Review of Math ADDITION
and SUBTRACTION
of FRACTIONS
ADDITION 2"
i6
=
.3 ..
3" 2¡= 4 ~"a-
i
..
CHANGE TO THE COMMON BEFORE
+ 3 .r., 2-
16
4" 2" 1" 16 = 8 =¡
9
1Qi
U>" 8 -
FRACTIONS LEAST DENOMINATOR ADDING
"
REDUCE ANSWER TO THE LOWEST TERMS
5"
16 6"
16 =
3"
8
7"
16
8 .. _ 4"_2"
f6 - a-¡
_ 1'' - 2
21"_
•
5"
3116 - 2- 8 16
g"
16 10" 5" 16 = 8
0
11 " 16 12"
6"
16 = 8
SUBTRACTION 78s" 4" 3_ 8__
785" = 1"
_3----!;2
3"
=¡
16
14"
7"
is"
a"
16 = 8 1s· 16 15=5=¡
4"
2" =2=1
5"
1·_
4•
- 6 1-
1 "
4a
13"
12165•_ -1216
6 rn
1 "
61s
. 16+ ij
l.Q" - ~1' 1.9• - 1 6 1-º"+ 1.§"_ Z§" 1 7 ~a-..- 17 161\1616 15-15 u·_ 11 16u· - 11 16u" - 11 u" 1 1 1516
..
15"
516 .
J"_
24 -3 4 • 3" -17-88=
•
24-38 1 7' - 8
449
6"
23+1 2" 6 ' = L"\-38=23-15 8
i" =
,\,,1 ·
1 7' - 8
6
i = 1 7' - 8 i
Appendix D: U se of the Calculator
CONVERSION FROM FEET & INCHES TO DECIMALS OF A FOOT (USING
A CALCULATOR)
2' -9,?§" ITJ El rIJ G 1 0.8750 1 1 9.8750 1 0.8229
0
[±] [iJ E]
1'-o):¡"
OJ El m G 10.25001
1 El O] G ! [!] ITJ 1 = ! 1 2.8229 ! FT.
1 0.2500 10.0208
C±J El
@J
El I [!] [!] G ! 1.0208 1 FT. 1
@]
1'-5i"
Q'-7
0El~G
[}]ElwG
16
I o.5625 m m 0 l 5.5625 1 E] @] G 10.4635 ! [!] O] 1 = ! l 1.4635 ! FT.
®
1'-4~" 16 wEJ~G I o.3125 I
m [I]
~" 8
I o.6250 1
1
7.6250
J
1 0.6354
1
1
m ITl 0 El
@J
B
[!] [9J
G
B
l 4.3125 El ~ G J
1
0.3594
1
m O] G 450
11.3594
G
1
FT.
1 0.6354
1 FT.
451
APPENDIX D: USE OF 11-IE CALCULATOR
CONVERSION
FROM DECIMALS
OF A FOOT
TO FEET & INCHES (USING A CALCULA TOR)
CD
®
1.3594'
I
u594
1 0.35941 14.3128
I O QJ G
0 @] E] 1 El CD EJ
I o.3128 1 0 ~ 2.8229'
l 2.8229
1 [:]
1
= 1 ..--¡,,_........ t6--.·j 4
1 o.s3s4 I O [QJ G
1 0.6354 1 0
@] E]
l 7.6248 ! El [zJ El I o.62481 ím G 1°·-7
w
%·1
1. 0208'
w E]
1 0 @J 1= 1 liJii4!i_J El [IJ El i 0.87 48 ' 0 Cill E1
0.6354'
10.0208
1 El !0
¡0.2496
1 D
1,.0208
10.8229
I
l. . .-2· --9-=--Ja-....·
®
1 0.2496 1
1 O QJ G 10.4635 ! 0 @] E] 1 5.5620 1 El [TI El I o.5620 1 m im 0 14635
PIPE DRAFilNG AND DESIGN
@]
El
w0
w Cill G
1.4635'
1
[I] E]
-1,·-5~6-1
!
--o->.í-....·
.....-!, ·
452
APPENDIX D: USE OF THE CALCULATOR
CONVERSION FROM DEGREES & SECONDS TO DECIMALS (USING A CALCULATOR)
30º25' §El~G I o.4167 I [±] ~ G
0
0 \V
130.41671
45º36'
45.6000º
~EJ~E] 1 0.6000 1 [±] j 4sj
!4s.6oool-
1
=
0
mEJ~B
1 0.1167
[±]
1
ja3!
G
V j a3.11671
17º55' 1
[±] @!
83.1167º l a3.11671 G ~ G 1 0.1167 1 0 l]gJ G
m
17.9167º
~EJ~G
1 0.9167
G @l G
1 0.6000 1 0 ~ G ~
1 j45.sooo I
83º07'
0
30.4167º ! 30.41671 G ~ G I o.4167 1 0 ~ G !m
1=
! ! 17.9167 j
117.91671
G ITzJ G
I o.9167 1 0 ~ G ~
PIPE DRAFI1NG AND DESIGN
Appendix E: Architect's Scale ARCHITECT'S
,,., 1 eo
-,·.,
.
-
_.., ~
3 ¡s" = 1 , -
F
e
!!
. .
!
~
"
f f
1l
1l
o" ¡3'-3"--j
1
1
10
9
1
1
1
8
10
1
1
6
,1
4
,. 1
1
10
9
1 9
1
1
10
1
1
11
10
1
6
11
1 14
~
1
~
1
r'l"l"l"J ~
I
r,1111111111
1
1
1 2
1.3
r,1111111111 14
.,
7'- 7" 1
6
1
4
1
12
1
1
2
6'-3"
1
1
8
10
1
, .3
12
:: ~
SCALE
1
4
1
12
11
1
1
2
1
14
1.3
"' ~ 2
9'-9"
..,
.
12
10
9
8
6
11
10
4
12
o
2
13
14
-
3 8
R
_.., ~
... ~
p
1 O' -8" 1
1
10
9
1
6
11
10
1
1
1
8
4
12
1
1
2
1
2
13
1
14
!'l"l"l"J ~
I
!'l"l"l"J ~
I
11
~1--t ·-
p
1 2' -2" 1
10
9
1
10
1
1
8
6
11
12
453
1.3
1
14
Glossary
A
Accumulator Temporary storage tank for liquids and vapors. Actuator A hydraulic or pneumatic apparatus that will operate a valve by remote control. Air cooler Large fan-type coolers placed above or below a pipe rack, which draws air across the pipes in the pipe rack to cool them. Alarm Signals, via lights or horn, used to indicate whether the liquíd level, temperature, or pressure inside a vessel is too hígh or too low or whether there is no flow or reverse flow. Anchor Stationary support designed to restrict the movement of a pipe caused by vibration, turbulence, expansion, or other external forces. Anchor bolts Bolts that have been positioned in concrete prior to curring. Used to secure equipment, buildings, tanks, or other items to a concrete foundation. Area limit Boundary identifying the extents of the unit being drawn. B
Back-up ring A Ys" thick, washer-like, ring placed between two pieces of pipe to prevent the build-up of weld icicles inside the pipe during the welding process. Ball valve Valve having a hall with a hole through it that allows straight-through flow. A 90º turn of the wrench opens/closes the valves. Base plate Flat, metal plate welded to a vessel or other piece of equipment allowing it to be secured to a concrete foundation via anchor bolts. Battery limit Lines placed on a drawing to identify the perimeter limits of a unit. Bent One section of a piperack containing two vertical columns and one or more horizontal connecting members. Beveled end Any piping component having a tapered end used in butt-welding. Billet Near-molten, steel bar from which seamless pipe is formed. Bill of materials A detailed listing of components required to fabricate a run of pipe. Blind flange A flanged plate-like device used to terminate the end of a run of pipe, valve, or vessel opening.
Blow-down Commodity discharged from a relief valve. Boiler Vessel used to convert water into super-heated steam. Box heater Vessel used to raise the temperature of a feed before it begíns fractional distillation. See vertical heater. Branch A connecting tie-in of the same or smaller pipe size. Bridle A screwed or socket-weld piping configuration containing instruments that measure the liquid level in horizontal or vertical vessels. Bubble caps Small valve-like controls on a tray in a fractionating column that allow rísíng vapors to pass through. Butt-weld Weld made when two beveled ends are butted together and welded. Bypass valve Valve connecting the upstream and downstream sides of a control set that allows the control valve to be removed for repair or replacement. By-product Liquid fraction of raw crude.
e
Cage Metal enclosure surrounding a ladder provídíng worker safety. Cap Butt-weld fitting used to close the end of a pipe run. Carbon steel Chief manufacturing material of pipe and fittings used in industrial piping applications. Catalyst Compound used to induce a chernical reaction. Centrifuga} "Center-fleeíng" action caused by a spínning impeller. Charge Toe initial feed used in a fractional distillation process. Check valve Valve used to prevent backflow. Chemical plant Facility that converts semi-refined products into usable consumer products. Chiller One of the many types of exchangers used to reduce the temperature of a process commodity. Codes A collection of regulations and procedures for design, construction, and operation of a facility. Coefficient of expansion Toe numerical factor of expansion/ contraction of a substance based on a change in temperature.
454
GLOSSARY
See fractionation column. Also, a vertical steel or concrete member that supports structures, piperacks, buildings, etc. Companion flange Mating flange of the same size and pound rating as the nozzle, valve, or fitting to which it is bolted. Compressor Mechanical device used to compress gases or vapors. Compressed air Any air with pressure greater than atmospheric pressure. Concentric Reducer or swage having a common centerline. Condensate Toe liquid that has been removed from a gas or vapor. Condenser Mechanical apparatus that cools a gas or vapor to the point of condensing. Conduit Protective covering around electrical wires and cables. Control building Building from which monitoring and operation of remotely installed instruments are made. Control panel A cabinet or desk-type housing containing monitoring instruments. Control station A Ll-shaped series of valves and fittings that allows for the monítoríng, control, and regulation of flow or pressure through a piping system. Control valve Typically having a globe valve body, this valve provides a method to automatically and remotely control the fluid flow and pressure through a pipe. Controller A device used to maintain a specified liquid level, temperature, or flow inside a vessel or píping system. Cooler Mechanical apparatus used to reduce the temperature of a liquid commodity. Cooling tower A mechanical device that dissipates heat by evaporation of water sprayed into a forcedair tower. Cooling water Water used in any cooling process that will lower the temperature of a commodity. Coordinates Intersecting north-south and east-west lines used to position foundations, equipment, supports, buildings, etc., on a drawing. Corrosion Toe dissolving of surface material by chemical reaction. Corrosion allowance Toe amount of surface material allowed to be eroded by the commodity within a pipe while permitting the pipe to remain usable for the particular service for which it was installed. Coupling Fitting used to join two lengths of screwed pipe together. Also used as a branch connection on pipe or a nozzle connection on equipment. Crude oil Toe natural state of unrefined oil product. Primary source of fractionated hydrocarbon by-products, Column
455
D
Davit Crane-like device made of steel pipe or structural steel that allows replacement parts, tools, and small machinery to be raised and lowered from the tops of vertical vessels. Debutanizer A distillation column that receives the bottoms residue from a depropanizer whose overhead product is a mixture of normal and iso-butane. lts bottoms residue is a C5+ mixture (pentane). Deethanizer Toe first in a series of three distillation colurnns whereby heavier gaseous molecule hydrocarbons, or NGL (Natural Gas Liquids) are fractionated. Toe deethanizer distillation column's overhead product is ethane gas. Its bottoms residue is routed to a depropanizer for further processíng, Deiso-butanizer A distillation column that fractionates butane. Iso-butane is a refrigerant that is used to replace ozone layer-depleting gases. Demethanizer A fractionating column in a cryogenic low-temperature distillation process whereby lighter gaseous molecule hydrocarbons (methane) are fractionated from raw natural gas. Depropanizer A distillation colurnn that receives the bottoms residue from a deethanizer whose overhead product is propane. Its bottom residue is routed to a debutanizer. Diameter, inside The circumference measured around the interior wall of a pipe. Diameter, nominal Toe name given to a particular size of pipe. Diameter, outside Toe circumference measured around the outer wall of a pipe. Dike Typically an earthen dam or wall surrounding tanks creating a containment area in case of accidental discharge or rupture. Discharge Outgoing flow, typically with increased pressure as in the case of pumps or compressors. Distillation The process of extracting and separating molecular compounds from a supply product. Double extra strong Catagory of thíck-walled pipe. Double line Drawings used to represent piping systems 14" in diameter and larger. Double pipe exchanger Exchanger having a small diameter pipe inserted into a large diameter pipe. Double random length Length of manufactured pipe, typically 35' to 40' long. Downcomer Opening adjacent to a tray that allows overflowing liquids to fall to the tray below and begín refractionation. Drain Typically an underground piping system that transfers water runoff or waste materials to a processing facility for disposal or treatment. See 0.W.S. Drain funnel Often a reducer fitting placed at the opening of a drainage pipe that aids in the collection of disposable materials.
PIPE DRAFTING AND DESIGN
456
GLOSSARY
Drift Toe amount of water lost duríng the aeration and evaporation sequence in a cooling tower. Dummy leg A length of pipe or structural steel welded to the outside of a pipe that provides support for the line. E
Eccentric Reducer or swage having offset centerlines. Elbow Fitting used to make changes in direction of pipeline. Elbow, long radius Ninety degree elbow having a radius equal to one and one-half times the pipe's nominal size. Elbow, short radius Ninety degree elbow having a radius equal to the pipe's nominal size. Electric traced Electric leads coiled around a pipe to maintain a desired temperature. Elevation Sectional view of a facility showing vertical height dimensions. Extra strong Pipe and fittings havíng measurements equivalent to schedule 80. F Face Toe mating surface of flanged fittings or valves. Face-to-face Measurement from the mating surface on one end of a flanged valve to the mating surface on the other end. Feed Toe initial fluid material used in the fractional distillation process. Feed, boiler Water piped through a boiler to produce steam. Female thread Intemal thread grooves cut into pipes, fittings, or valves. Field pipe A run of pipe configured, cut, and pieced together at the time of installation. Fil ter Basket-type strainer used to collect solid waste and contarninants circulating through the piping system. Fin-fan See air cooler. Fired heater Mechanical device used to elevate circulating liquids to extreme temperatures. Fireproofing Generally brick, concrete, or gunite, applied around vessel skirts or structural columns to prevent damage in case of fire. Fitting Generic name for components used to make turns, branches, or reductions in a run of pipe. Flange Ring-shaped device that is welded or screwed on the end of a pipe that permits the pipe to be attached to other similiarly prepared piping components. Fiare stack Vertical column that uses an open flame to bum waste gases. Flash zone Toe position in a fractionation column where the incoming feed separates into vapor and liquid states. Flat face Flange facing that has no raised surfaces.
Floating roof Toe type of storage tank roof that is suspended by the commodity being stored. Toe floating prevents the collection of harmful gases and vapors in tanks that store flammable liquids. Flow diagram Schematic drawing depíctíng the equipment, piping, and instrumentation of a piping facility. Flow displacement meter lnstrument installed within a piping configuration that measures the flow rate of the comrnodity within the pipe. Flow element Set of orifice flanges used with test equipment that measures rates. Flow indicator A local or board mounted instrument that registers flow rates. Flow meter A device used to indicate or record the amount of comrnodity flowing through a pipe. Flow rate Toe amount of flow passíng a given point in a pipe for a predetermined amount of time, for example, gph, gpm. Flow ratio recording controller A combination of control valve and recorder that records the flow within a pipe then controls the flow as required. Flow recorder lnstrument that makes a permanent record of flow measurement. Flow recording controller A control val ve that records measurements of flow through a pipe. Foundation Grade-leve! concrete support for buildings, equipment, and structural members. Foundation location plan Plan drawing depicting the coordinate location of buíldings, equipment, and structural concrete supports. Fraction By-products of a feed supply. Fractional distillation Toe chemical process of separating a feed supply into its various molecular components (by-products). Fractionation column A vertical vessel havíng interna! plates, called trays, which aid in the separation and collection of the various molecular compounds of a feed stock (fractional distillation). Fuel oil Combustible material used as a heat source for fired equipment in a process facility. G
G-fin A U-shaped exchanger having a pipe within a pipe. Also known as a "hair pin" or "double pipe" exchanger. Gas Toe physical state of matter having the ability to diffuse readily and distribute uniformly throughout the container to which it is confined. Gasket Any of a wide variety of materials placed between mating surfaces to prevent leaks. Gate valve Valve designed for on or off control of a comrnodity flowing through a pipe. Gauge lnstruments that measure the liquid leve! inside a vessel or the temperature and/ or pressure in a piping system.
PIPE DRAFTING ANO DESIGN
GLOSSARY
Globe valve Valve designad to allow for the throttling of commodities flowing through a pipe. Grade Toe true or predetermined elevation of the ground-supported surface of a piping facility. Grade beam Structural member used to support grating or other flooring material at ground (grade) level. Gravity flow system Pípíng system constructed of sloped pipes that uses gravity as a meaos of moving the commodity inside. Grout A concrete mixture poured on the tops of equipment foundations to provide final leveling. Guide Type of pipe support that permits longitudinal but not lateral movement. H
Handrail Protective railing around platforms. Typically 3' to O" tall. Hanger Pipe support used on horizontal pipes that will suspend the pipe from a stationary object from above. Head Toe end enclosure of a vessel. Header Toe main run of pipe from which branches are connected. Headroom Vertical measurement that provides overhead clearances. Heater Píping equipment that uses a combustible material to increase the temperature of a commodity. Heat exchanger Piping equipment used to transfer heat from one fluid source to another without the two fluids mixing together. Hydrocarbon Any solid, liquíd, or gaseous compound whose molecular structure is made exclusively of hydrogen and carbon molecules.
457
Insulation rings Continuous circular rings welded to the exterior of a vertical vessel that support a vessel's insulation. Typically spaced on 12'--0" centers. K
Knock-out drum Used to collect any liquids present in the waste stream prior to entering a fiare system, especially important if substantial cooling of heavy liquids is necessary. L
Ladder Climbing apparatus that allows access to piping components at extreme elevations. Leve! alarm Instrument that detects high or low liquid levels within a vessel and alerts plant operators with an audible or visual signal. Leve! gauge (glass) A vertical transparent tube connected to the extemal surface of a vessel that allows visual inspection of intemal liquid levels. Level indicating controller lnstrument that indicates the liquid level of a vessel and can control the liquid level by transmitting signals to a control valve. Level recorder Makes a permanent record of liquid level in a vessel. Level recording controller Instrument that records the liquid level of a vessel and can control the liquid level by transmitting signals to a control valve. Lifting lugs Donut-shaped rings welded to the vessel's shell or head that allow the vessel to be raised and positioned during installation. Line Generic name given to reference a completed píping configuration. Liquid Toe physical state of matter possessing flow characteristics and minimal compressibility.
I
Impeller Rotating device in a pump that forces the incoming commodity to be expelled at a greater pressure. Indicator A device used to indicate the líquíd level, temperature, pressure or flow rate inside a piping system. Instrument One of many monitoring devices that can sense, measure, transmit, or control. Instrument air Compressed air free of contaminants that is used to operate pneumatic control devices. Instrument air line Piping system containing clean air used to operate instrumentation throughout a piping facility. Instrumentation Toe use of monitoring instruments to perform duties not permissible by human workers. Insulation Exterior covering on pipe or equipment that maintains a constant temperature. Also protection for workers from hígh temperature surfaces.
M
Malleable iron Cast iron that has been heat-treated to improve its tensile strength. Mandrel A long, pointed shaft used to pierce molten steel billets to form seamless pipe. Manhole Similar to large nozzles that allow workers entry points into a vessel. Generally 18" ID. Manhole hinge A hinge that creates a pivot point allowíng the blind flange attached to the manhole to be easily removed for worker entrance. Manifold A main pipeway having numerous branch connections. Manway See manhole. Match line Lines used to divide the plot plan into small drawing areas. Material take-off Toe gathering of descriptions, quantities, and prices for various components of the pípíng system, that is, pipe, flanges, fittings, valves, bolts, gaskets, etc.
PIPE DRAFTING AND DESIGN
458
GLOSSARY
Meter run A clear run of pipe having a set of orifice flanges that is used to measure flow rate through the pipe. Mixer Device used to combine liquid, semi-liquid or bulk materials needed in the refining process. N
Naphtha Colorless, flammable by-product of crude petroleum used in the manufacture of gasoline. Nipple A short length of pipe used to connect screwed or socket-weld fittings to one another. Nominal pipe size A name given to a pipe with reference to its size in diameter. Only for pipes 14" and larger in diameter does this represent an exact dimensional measurement. Nozzle Toe connecting point of the pípíng configuration to the vessel or equipment. Nozzles are provided in locations where a commodity is either introduced or removed from a vessel or piece of equipment. Nozzle arrangement Toe positioning of nozzles on a piece of piping equipment. Nozzle orientation Plan drawing depicting the location of nozzles around the perimeter of a vessel using angular measurements from Oº.
o
Octagon An eight-sided concrete foundation placed below vertical vessels that distributes the vessel's load over a broader area. 0-lets Any of severa! fittings used to make branch connections for welded, screwed, or socket-weld pipe. Operator Device used to activate valving. Orifice flange Flange with a hole drilled into the flange face perpendicular to the pipe that permits testing equipment to be inserted. Orifice flange union Pair of orifice flanges, orifice plate, bolts, nuts, jackscrews, and gaskets. Primary components of a meter run. Orifice plate Metal plate with a hole of predetermined size sandwiched between orifice flanges. OWS (Oily water sewer) An underground píping system used to collect and transfer contaminated discharge to a treatment facility. p P&ID Piping and instrumentation diagram. Pedestal See foundation. Pipe guide See guide. Pipe hanger See hanger. Pipe rack Structural framework consisting of a series of vertical columns connected with horizontal members. Major thoroughfare for pipes traveling in a process facility.
Pipe support Structural member that carries the weight of a piping configuration. Piping Generic term used to describe pipes, fittings, flanges, and valves in a facility. Piping drawing index Created from the plot plan, the index uses match lines to divide the piping facility into small drawing areas. These areas are assigned drawing numbers and distributed to drafters/ designers for creation. Plain end Any pipíng component havíng square ends used for socket-weld connections. Plant air Compressed air used to drive pneumatic hand tools. Platform An elevated walkway around a vessel or other píping equipment, Plot plan A master drawing showing the locations of all buildings, structures, and equipment in a piping facility. Plug Screwed fitting havíng externa! threads that terminates a piping configuration. Plug valve A particular valve having a rectangular shaped hole through a tapered plug. Uses one-quarter tum of a handle to align the hole with the valve port. Pressure alarm lnstrument designed to signa! dramatic changes in interna! pressure. Pressure controller A control valve that regulates interna! pressure of a pipe or vessel after receiving a signa! from a transmitter. Pressure differential recording controller Controls the pressure differential between two pipes or vessels by means of a control valve. Pressure indicator Dial instrument that indicates interna! pressure of a pipe or vessel. Pressure indicating controller Control valve with an indicating transmitter that controls interna! pressure on a pipe or vessel. Pressure recorder A recording instrument that makes a permanent record of interna! pressures within a pipe or vessel. Pressure recording controller lnstrument similiar to a pressure recorder and having the capability to transmita signa! to a control valve. Pressure safety valve An automatic pressure-relieving device actuated by excessive interna! pressure of a pipe or vessel. Process equipment Pipíng equipment having the capability to alter the chemical makeup of the commodity it contains. Pump Mechanical device used to move fluids under pressure from one location to another. Purge Toe act of removing foreign matter from the interna! surfaces of a pipe or vessel. R Raised face Type of flange facing used with flat ríng gaskets. 150# and 300# raised face flanges have a Yi6'
PIPE DRAFTING ANO DESIGN
459
GLOSSARY
raised face, and 400# and above flanges have a 1A'' raised face. Reactors Changes the chemical composition of a commodity through the introduction of a reagent or catalyst. Rebar Short form of reinforcing bar. A metal rod used in the reinforcement of concrete. Reciprocating pump Piping equipment with parts similar to a piston or plunger that moves back and forth to create pressure. Recorder A device used to record the liquid level, temperature, pressure or flow rate inside a vessel or píping system throughout a specified period of time. Reducer A pipe fitting with one end larger than the other that allows reductions in the diameter of a run of pipe. Refinery Process facility that breaks crude petroleum down into usable byproducts such as butane, propane, fuel oil, and lubricants. Reflux A liquid product returned to a fractionation column that aids in the fractionation process. Reinforcing pad A plate contoured to the shape of a vessel shell. lt is positioned around nozzles to provide additional strength in the areas where metal was removed from the shell. Restriction orifice Standard orífice union assembly including spectacle blind used to create smooth flow. Ring-type joint Flange face that uses a steel ring rather than flat or full ríng gasket. Root gap The 1/16" space between two butt-weld fittings prior to welding. Rotary pump Displacement-type pump using pistons, gears, or screws to discharge a commodity. Run Generic name for any length of pipe. Rung Horizontal member of a ladder.
s
Saddle U-shaped structural support welded to horizontal vessels and exchangers. Saddles are bolted to concrete foundations and create a craddle-like support in which the vessel can rest. Schedule Wall thickness of pipe. Scrubber Used to separate contaminants from gases duríng the refining process. Seal pan Installed below the bottom tray in a vessel to prevent liquids from bypassing the trays. Seamless Pipe manufactured without any resulting welded connection. Separator Any collection-type vessel used to separate liquids from gases or other liquids during the refining process. Shape roller Mechanical apparatus that sizes and shapes rolled plate to forro pipe. Shell The cylindrical walls of a vessel.
Shell and tube Type of heat exchanger having tube bundles contained within an outer vessel shell. Shoe Structural member welded to the bottom side of a pipe having insulation. Designed to prevent the insulation from beíng crushed when the pipe rests on a steel support. Skelp Plate that has been rolled and shaped into the forro of a pipe. Skirt A cylinder-shaped support for a vertical vessel. One end is welded to the base plate allowing it to rest on the foundation, and the other end is welded to the bottom head of a vertical vessel. Skirt access opening An 18" ID hole 2' to 16" above the foundation that allows workers entrance for inspection and maintainence. Skirt fireproofing Brick or granite material applied to the interior and occasionally exterior surfaces of a vessel skirt to prevent damage in the event of a fire. Skirt vents Equally spaced hales approximately 3" to 4 in diameter bored near the top of the vessel skirt that allow toxic and explosive gases to escape. Sleeper Near grade-leve! structural support used to support horizontal piping runs. Slip-on flange Flange with a low hub that allows pipe to be inserted prior to welding. Slotted anchor Saddle or other support having elongated bolt holes that allows for movement due to heat expansion. Specifications Guidelines established by governmental agencies, standards associations, and vendors, for plant design and construction. Spectacle blind A figure 8-shaped plate placed within an orifice flange assembly. One end has a hole through which flow can pass to create smooth flow for accurate instrument readings. Spiral weld Type of pipe formed by twisting metal plate in spiral shapes then welding. Spool Type of isometric or orthographic drawing containing dimensions and callouts for fabrication. Spring hanger Pipe hanger using a coil spring to absorb movement within a pipe. Steam Toe vapor phase of water. Steam, dry Steam that is devoid of suspended water particles. Steam, saturated Steam that exceeds boiling point temperature for an equivalent pressure. Steam traced Tubing coiled around a pipe containing steam to help maintain a desired temperature. Steam turbine Pump or generator driver using high pressure steam to power the turbine's impeller. Stem Threaded shaft within a valve that raises and lowers the valve wedge or disc by rotating the handwheel. Stub-in Branch connection made on a run of pipe without the use of a fitting. 11
PIPE DRAFTING AND DESIGN
460
GLOSSARY
Suction Toe inlet or incoming side of a pump or compressor. Swage Typically a screwed or socket-weld type of fitting used to make a reduction in the diameter of the síze of pipe.
Tube bundle Removable section of an exchanger containing interna! tubes. Tube sheet Vertical plate separating the shell side from the channel end of an exchanger. Turbulence Uneven flow produced by directional changes or obstructions within the pipe.
T
Tank Storage vessel used for the collection of process materials. Tank farm Area within a process facility where severa! storage tanks reside. Tee Three-way fitting used to make branch connections on a run of pipe. Temperature alarm lnstrument designed to signa! dramatic changes in interna! temperature. Temperature controller A control valve that regulates interna! temperature of a pipe or vessel after receiving a signal from a transmitter. Temperature control valve Valve using fluctuations in temperature to make adjustments in commodity flow. Temperature element Thermocouple that allows portable test equipment to be inserted to measure the temperature of the commodity within a pipe or vessel. Temperature indicator lnstrument that indicates temperature of the commodity in a pipe or vessel (thermometer). Temperature recorder A recording instrument that makes a permanent record of temperature within a pipe or vessel. Temperature recording controller Instrument that provides simultaneous recordíng and regulation of the temperature within a pipe or vessel by sendíng a signa! to a control valve and recorder. Temperature well (Thermowell) lnserted into a coupling to protect the temperature instrument bulb. Thermal expansion Growth of pipe due to the application of heat. Threaded end Any piping component having interna! or externa! threads. Threads, external Pipe component having screw threads cut into the exterior surface (male threads). Threads, interna! Pipe component having screw threads cut into the interior surface (female threads). Tower Vertical vessel or colurnn. Transmitter Instrument that sends signals to indicating, controlling, or recordíng devices. Trapeze Pipe hanger consisting of two vertical rods connected with a horizontal support member. Tray Flat metal plates spaced approximately 30" apart inside a vertical vessel that aid in the fractionation of crude petroleum into by-products.
u
Union A three-piece fitting placed within a screwed or socket-weld configuration that permits quick disassembly of the configuration. Utility One of many plant services required for the efficient operation of the facility, for example, air, water, steam, sewer, and fiares. Utility air Compressed air used to drive pneumatic tools, clean equipment, and perform other maintenance services. V Valve Device used to control the flow of a commodity through a pipe. Vapor Toe gaseous state of any substance that is liquid or solid under ordinary circumstances. Vapor lock Trapped air or vapor in a pipe that prevents the flow of a commodity through the pipe. Vendor A third-party supplier of parts, equipment, or other components of the piping facility. Vendor drawing A drawing or rendering that depicts descriptive information pertaining to the equipment or pipíng component that a supplier or manufacturer delivers to the piping facility. Vertical heater Device used to raise the temperature of a commodity to the point at which it can be used in a process system. Vessel Generic term used to describe any closed container housing liquid, vapor, or gaseous commodity.
w
Wedge Sealing component of a gate valve. Weir Dam-like plate welded on a tray that allows a fractionated by-product to collect and be extracted by a nozzle. Welding ring See back-up ring. Weld neck flange Flange with a tapered neck for buttwelding to other bevel-end piping components.
PIPE DRAFTING ANO DESIGN
lndex
A Abbreviations, 159, 166-169 Accumulator,see Horizontalvessel Actuator,92 Anchors directional, 246 fixed, 245 Arrangementdrawings, 186-187 dimensioning,233 layout procedures,187 As-built drawings,2
B
Back-up ring, 7 Base ell, 250 Base plate, 125 Battery limits, 176, 230 Bell and spigot, 9 Benchmark,170 Beveled end, 7 Boiler see Heater Bolts, 65-67, 80 Branch, 22 Butt-weldedpipe, 4, 5
e
Cage, 113 Cast iron, 4, 9-10 Cathodicprotection, 266 Center-to-end,14-15, 19, 26 Chain operator,92 Chiller, 123 Codes piping, 154 Cold spring, 156, 243 Compressor, 116-117, 123, 125 Condensate,260 Conditions design, 134-135 operatíng,134-135 Control valve manifold, 91, 260-262 drawing of, 261-262 Cooling tower, 119-121, 123 Corrosion allowance, 159 Coupling, 10, 32, 33, 43 Cutting plane, 230, 234
D Datum elevation, 234, 237 Debutanizer,123 Deethanizer,123 Deiso-butanizer, 123 Demethanizer,123 Depropanizer,123
Dike, 122-123 Double random length, 5 Downcomer,125 Drift, 121 Dummy leg, see Field support
Elbow
E
45°, 20
drawing oí, 22 drawingsymbols,22 90°, 14 center-to-end,14, 15 drawing of, 15-16 drawing symbols, 15 long radius, 14-15 mitered, 18-20 reducing, 16-18 rolled at 45°, 22 short radius, 16 Elevation abbreviations, 159 callouts, 159 examples of, 159 invert, 176, 234 types,234 Ell, see Elbow Equipmentlocation drawing, 176, 179 Exchanger air fan, 119 defined,117 double pipe, 118 hairpin, 118 reboiler, 118-119 shell and tube, 117
F
Feed, see a/so feed stock, 124-125 Field supports base, 250 dummy,251 pick-up,255 Fins, 118 Fitting make-up, 37 dimensioning, 38 Fittings, 13 butt-weld, 13 casi iron, 45 flanged,44 plastic, 45 screwed,38 socket-weld, 38 Flange blind, 64
461
belting, 65 defined, 56 face type, 56-57 lap-joint,61-62 length-thru-hub, 60 orifice, 64 pound ratings, 56 raised face, 57 face thickness, 57 reducing, 62 ring-type joint, 57-58 slip-on, 60-61 socket-weld, 62 threaded, 62 types of, 58 weld neck, 59 drawing of, 59-60 drawing symbols,59 Flash zone, 119, 125 Flow diagrams abbreviations, 145 drawingsymbolsfound on, 140-145 mechanical, 135 example,137 process, 134 example,136 types, 134-135 uses, 134 utility, 135 example,138 Foundationlocation drawing, 176 Fraction, 124 Fractional distillation, 112, 124 Frationationcolurnn,see Vessel: vertical
Gaskets,67 materials, 68 thickness,68 types, 68 Grade, 171
G
H
Hanger rods, 254 rod and clevis, 254 spring hanger,255 trapeze, 255 Head, 125 2:1 semi elliptical, 128 Header,22 Heater, 123 Heat expansion, 243 Horizontal vessel, 112 drawing of, 128, 130
462
INDEX
I lnside diameter (JO), 5 lnstrumentation groups, 135 types, 135 alarms, 138 controllers, 138 gauges, 138 indicators,138 recorders, 138 symbols, 135, 138 Isometrics (isos), 269 dimensioning, 278 drawing of, 275--278 notes/ callouts,278 offsets, 278 dimensioning,279-280 multiple angles, 280-283 rolling, 283 dimensioningof, 285--287 symbols,270, 271-272 tuming point, 270 lnsulation ring, 125 lnsulationshoe, 24~247
J
Jack screws, 64
Kettle reboiler, 222 Knock-outdrum,123
K
L Ladder,113 Lead and oakum, 9 Lifting lugs, 125 Line list, 237 Line number, 156 Line spacing chart, 244
M Machine bolts, 67-68 Manhole, 125 hinge,126 Manway, 112 Material take-off,269 Mechanical equipment, 112 Meterrun,64,214,263 location of, 265 Mixer, 123
N Nominal pipe size, 5 North arrow, 170 Nozzle, 56, 126 orientation, 126 projection, 126
O-lets,31 Operators, 91
o
Orifice flange unión, 64 Orífice plate, 263-265 Outside diameter(00), 5
p P&ID, 135 Pipe calculating inside diameter, 6 drawingof, 11 flexibility,242-243 joining, 6 history, 4 manufacturingmethods, 4-5 plastic, 10 schedule, 5--6 sizing,5 thickness, 5--6 weight,5 Pipe anchor, 245-246 Pipe guide, 247 Pipe loop, 243 Pipe nipple, 43 Pipe shoe, 247 Pipe spans, 247 Pipe spools, 2 Pipe rack, 242 drawingof, 242 spacing, 242-243 Plainend,8 Plant coordinate system, 170 Plant elevationsystem, 170-176 Platform, 113 Plug,43 Pocket, 247 Pound ratings, 56 Pump centrifugal,114 defined,114 drivers, 116 nozzle arrangements, 115-116 reciprocating, 114-115 rotary,115
R Reactor, 123 Reducer drawing of, 34 drawing symbols,34 types,32 Reinforcing pad, 126 Rolling offsets, 283 dimensioning oí, 285--287 Rootgap, 7
Saddles, 126 Scrubber, 123 Sections, 233-237 Sea! pan, 126 Seal weld, 62 Seamless pipe, 4 Sewer systems, 266
s
Shapers, 4 Shell, 117 Single random length,5 Site plan, 176 Skirt, 126 access opening, 126 fireproofing, 126 vents, 126 Specifications,155 classes, 159 piping, 156 sample oí, 155-158 Spiral weld, 4 Standard piping detail, 242 Steam trap, 260 Storage tank, 121-123 Stripping steam, 125, 259-260 Stub-in,30 drawing symbols,30 reinforcements,31 welding minimurns, 31 Stud bolts, 67 Swage,44
T Tabor abrasion test, 10 Tank farm, 122 Tee,22 Threaded end (TE), 7 Thread engagement,8 Toree-dimensionalmodeling,307 Tick marks l.gaskels), 69-70 Tray, 112, 126 double-pass, 126 single-pass, 126
u
Underground piping system,266 Union,41 Unit plot plan, 176 Utilities, 259 air systems,260 fiare systems, 260 fuel oil/ gas, 260 water systems, 259-260 Utility station, 262
V Valve angle, 82, 85 ball,~7 block,261 butterfly,87-88 bypass, 261 check,85-86 control, 88-91 defined, 79 drain, 261 face-to-face,80 gate, 79, 83, 84 drawing oí, 81-82 globe,82
463
INDEX
plug, frl pressure safety, 88 relíef, 88 stem,80 Vendor defíned, 128 drawings, 128 Vessel
horizontal,112 vertical,112-113
w
Weir,125 Weldcap,36 drawing symbols, 37
Weldingsaddle, 31 Weld tee, 22 drawing of, 26 drawing symbols, 26