GE Industrial Control Systems Turbine Control Systems Salem, Virginia
HMI Turbine Screen Standards (Version 1.0 Released August 12, 1998)
© 1999 General Electric Company, USA All rights reserved Printed in the United States of America
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1.0 INTRODUCTION.......................................................................................................................................... 5 1.1 FILE NAMING CONVENTION ........................................................................................................................... 5 1.2 GENERAL DESIGN GUIDELINES ...................................................................................................................... 5 2.0 DESIGN PHILOSOPHY, FUNCTIONAL GROUPING AND OBJECT NAMING ................................... 7 2.1 INTERFACE FOUNDATION .............................................................................................................................. 7 3.0 7FA DESIGN STANDARDS........................................................................................................................ 21 3.1 OBJECT GROUPING AND NAMING ................................................................................................................. 22 Figure 3.1: Startup Screen Grouping........................................................................................................... 22 4.1 GENERAL FOUNDATION SCREEN .................................................................................................................. 24 4.2 NAVIGATIONAL BUTTONS............................................................................................................................ 25 4.3 ALARMS ..................................................................................................................................................... 26 4.4 TREND SCREENS ......................................................................................................................................... 26 5.0 DATA DELIVERY & ACTIVE CONTROL OBJECT TYPES................................................................. 29 6.0 BAR GRAPHS ............................................................................................................................................. 41 6.1 FSR BAR GRAPH ........................................................................................................................................ 42 Table 6.1: FSR ............................................................................................................................................ 42 6.2 BEARING TEMPERATURES ............................................................................................................................ 43 Table 6.2: Bearing Temperatures ................................................................................................................ 43 6.3 EXHAUST TEMPERATURES ........................................................................................................................... 44 Table 6.3: Exhaust Temperatures ................................................................................................................ 44 6.4 GENERATOR RTD TEMPERATURES .............................................................................................................. 46 Table 6.4 Generator RTD Temperatures...................................................................................................... 46 6.5 VIBRATION PROXIMETERS ........................................................................................................................... 48 Table 6.5: Vibration Proximeters................................................................................................................. 48 6.6 SEISMIC VIBRATION .................................................................................................................................... 49 Table 6.6 Seismic Vibration......................................................................................................................... 49 6.7 WHEELSPACE TEMPERATURES ..................................................................................................................... 51 Table 6.7 Wheelspace Temperatures............................................................................................................ 51 6.8 FLAME TEMPERATURES ............................................................................................................................... 54 Table 6.8 Flame Temperatures .................................................................................................................... 54 7.0 GRAPHIC SYMBOLS AND ANIMATION DYNAMICS ......................................................................... 55 7.1 FUEL LINES................................................................................................................................................. 55 7.2 GAS TURBINE ............................................................................................................................................. 56 7.3 DLN 2.6 PIPING & VALVING GRAPHIC ........................................................................................................ 57 7.4 DLN 2.6 NOZZLE GRAPHIC ......................................................................................................................... 59 7.5 EXHAUST THERMOCOUPLE GRAPHICS .......................................................................................................... 62 8.0 START CHECK SCREEN .......................................................................................................................... 64 9.0 TRIP SCREEN............................................................................................................................................. 66 10.0 LIQUID FUEL DELIVERY SYSTEM ..................................................................................................... 68 10.1 LIQUID FUEL DELIVERY............................................................................................................................. 68 11.0 WATER INJECTION SYSTEM ............................................................................................................... 71 12.0 STEAM POWER AUGMENTATION SYSTEM ..................................................................................... 73 13.0 FRAME ANIMATION .............................................................................................................................. 76
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14.0 MULTI-UNIT CONFIGURATION........................................................................................................... 77 14.1 OVERVIEW ................................................................................................................................................ 77 14.2 NAMING CONVENTION .............................................................................................................................. 77 14.3 TOOLS BUTTON ........................................................................................................................................ 79 14.3 VIEWER LIMITATIONS ............................................................................................................................... 79
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1.0 Introduction CIMPLICITY HMI standards have been developed for GE Powerplant Turbines for both Steam Turbines and Gas Turbines. The standards are applicable to all Frame sizes and are in both English and Metric. The standards represent maximum case scenarios and thus customization for a particular requisition does not require the requisition engineer to design new screens, they simply need to delete screens that do not pertain to their requisition (dual fuel, water injection, steam injection, etc). The design philosophy behind the standards, details of screen components including geometry information and color animation is documented. Adherence to the standards is strongly recommended since they will help to optimize operator usability and assure graphical uniformity. 1.1 File Naming Convention Individual standards are named so that requisition engineers can quickly identify the required standard for their requisition. For example a frame 7001EA with English units will be named ‘7001EA_English.cim’. Note: The standard must be renamed to ‘Unit_Control.cim’for navigation between the overview and synchronization screens to work properly. All Trend screens will be named according to the trend data that is to be displayed. The word ‘Trend’will precede the description of the data contained within that file. Thus the following are examples, Trend_Bearing_Drain.cim Trend_Bearing_Metal.cim Trend_Exhaust_Temp.cim Trend_Generator_RTD.cim A separate synchronization file is required for each unit that is to be controlled. These files will be named as follows. Synchronization_Unit1.cim Synchronization_Unit2.cim Synchronization_Unit3.cim
1.2 General Design Guidelines Some general design considerations have been adopted in the development of these design standards. These include the display of critical turbine parameters, including IGV angle, Compressor Delivery Pressure, Exhaust Temperature, Turbine Speed, on every screen. A minimum height of 24 pts and width of 30 pts is used with buttons to facilitate usage in touchscreen applications. In the selection of nomenclature acronyms have been avoided and English wherever feasible.
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2.0 Design Philosophy, Functional Grouping and Object Naming 2.1 Interface Foundation Level 0:
Overview Tools Alarms
!
When procedures access files separate from the Unit_Control.cim file, procedures are used. L0 Sometimes buttons are stacked upon on another and the UNIT_NO screen variable is used to set the buttons visibility. This feature allows unit specific procedures to be linked to what appears to be a single button.
synch
gt1 synch
gt2 synch
gt3 synch
gt4 synch
demand
gt1 demand
gt2 demand
gt3 demand
gt4 demand
Level 1:
Gas Turbine 1 Gas Turbine 2
Each turbine unit has a single pushbutton used to assign the UNIT, UNIT_NAME and UNIT_NO screen variables. All points within the Unit_Control.cim file (i.e., L1START, L4) are proceeded by the screen variable ‘UNIT’(Unit_L1START, Unit_L4, Unit_L4T). Thus the L1 buttons are used to navigate from Unit1 Control to Unit2 Control and the same CIMPLICITY file may be used.
Gas Turbine 3 Gas Turbine 4
This functionality simplifies revision control on multi-unit interfaces. The UNIT variable is assigned values such as ‘T1_’, ‘T2_’… for gas or ‘S1_’, ‘S2_’… for steam, depending on the number of units. Thus, when Unit3 Control is selected, the variable ‘Unit’is assigned. The UNIT_NAME variable is displayed in the upper right hand corner on the turbine banner. The UNIT_NO variable is used to assign object visibility’s to buttons like ‘Tools’or GT# Synch.
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Level 2:
Control
The second grouped of buttons on the right side of the Unit_Control screen are used for function mode navigation. Functionally these buttons break the DATA_CTRL frame containers navigation up into the following four groups; Control, Monitoring, Auxiliary and Tests.
Monitor Aux Tests
When one of these buttons is depressed the last set of buttons actually the NAV_CTRL frame container display will be affected. Mouse up set’s the NAV_CTRL screen variable and allows access to all Control options, Monitoring Options, Auxiliary Options or Test Options. The procedures for this level of navigation are preceded by L2, thus, allowing functional grouping of all navigation procedures (i.e., L1, L2 and L3). Additionally, the last user selected control option, monitoring option, auxiliary option or test option is maintained in memory. Thus allowing the user the option of toggling between a certain control screen(ex. DLN 2.6) and a particular monitoring screen(ex. Exhaust Temps) by depressing the level 2 navigation buttons (control/monitoring).
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Level 3:
The final set of navigation buttons (colored 170, 170, 170) are used for actual frame to frame navigation. The Level 3 options(button lists) are displayed using a frame container called NAV_CTRL and are set to a number between 1 and 4 corresponding with the value for Control, Monitoring, Ax or Tests.. These buttons assign the variable ‘DATA_CTRL’and allow navigation to all the control, monitoring, aux. and test frames(currently 26 possible frames). The Data control frames are named according to the Level 3 buttons that are used to get to these frames. For example, the ‘motors’ button will take you to the ‘motors’frame and the ‘trips’button will take you to the ‘trips’frame.
Control
Monitor
Aux
Tests
start-up
bearing temps
demand
contacts
dln
exhaust
flame
overspeed test
FSR control
generator rtd
gen capability
shaft voltage
gen/exciter
hydrogen
start check
IGV Control
proximeter vibe
static start
liquid fuel
seismic vibration
timers
motors
wheelspace
trip diagram
steam power aug water injection gt1 synch gt2 gt3 gt4
Screen File Names
All standards are max case scenarios. Standards are available for all frame sizes in either English or metric. Thus customization for a particular requisition does not require the requisition engineer to design new screens, they simply need to delete screens or frames that do not HMI Turbine Screen Standards 9 etc). pertain to their requisition(dual fuel, water injection, steam injection, Standards are named so that requisition engineers can quickly identify
Procedures
Procedures have been named to foster functional grouping. All alarm button actions are named using Alarm_. All navigation procedures are named with a L0_, L1_, L2_ or L3_. All controller functions are named using Ctrl_. All motor control functions are named Motor_.
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Scripts
Scripts are used to accomplish tasks that cannot easily be accomplished using available CIMPLICITY functionality. Scripts are written using visual basic. Scripts can attached to single objects, grouped objects or simply adhered to the foundation screen. Most scripts are adhered to the foundation screen. Consult the CIMPLICITY Base Manual for more information on editing or creating your own scripts.
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Variables
Variables are used to accomplish many different types of functions. Variables can attached to single objects, grouped objects or simply adhered to the foundation screen. Consult the CIMPLICITY Base Manual for more information on editing or creating your own variables.
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DATA_CTRL
This variable controls the frame position of the DATA_CTRL(data control) frame container. The data control frame container has twentysix positions and contains all the control, monitoring, auxiliary and test screens. The value data control variable is set by L3 procedural functions.
LAST_AUX_FRAME LAST_MON_FRAME LAST_TEST_FRAME LAST_CTRL_FRAME
These variables are used in conjunction with the SetLastFrame script and function to set the appropriate last frame screen variable to the value of the data control screen variable(DATA_CTRL). This allows the L2 navigation buttons to remember which control, monitoring, auxiliary or test frame was visited last. Enabling one button navigation from the control, monitoring, auxiliary and test buttons. The initial value of these variables can be set so that a favorite control, HMI Turbine Screen 18first monitoring, auxiliary or Standards test data control screen can be seen at the depression of the navigation control buttons. However, last defaults to the first screen control, monitoring, auxiliary or test screen set.
NAV_CTRL
This variable controls the frame position of the NAV_CTRL(navigation control) frame container. The navigation control frame container has four positions and contains all the buttons for accessing control, monitoring, auxiliary and test screens. The value of the navigation control variable is set by L2 procedural functions.
Control Monitor Aux Tests
POPUP
The POPUP variable is used in conjunction with a screen hot spot to access data about or control for certain motors, pumps and valves. When a screen is opened POPUP is initialized at a value of zero. Every popup is grouped and the group’s visibility is set using the control animation tab and the POPUP variables value. Thus only one popup object can be displayed at any one time. A X button in the upper right hand corner is used to set POPUP to zero and close the currently viewed popup object.
Speed Ratio Valve X Reference
###
#
Feedback
###
#
Data Popup Object Example
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SHOW_POINT_ID
The SHOW_POINT_ID screen variable is used with a single button to toggle from a data’s text description to the GE Point ID. This functionality is sited for the GEPPETTO’s next revision.
Exhaust
### ##
Speed
#### ###
Max Vibe
#.## ##
CPD
### ###
IGV
## ###
Watts
##.# ##
Vars
##.# ##
TTXM
### ##
TNH_RPM
#### ###
BB_MAX
#.## ##
CPD
### ###
CSGV
## ###
DWATT
##.# ##
DVAR
##.# ##
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3.0 7FA Design Standards A listing of the frames for a maximum case 7F machine are shown in the attached table. The Level 3 Procedure Names, associated Data_Ctrl Values which identify the order of the frames in the frame container are specified. In addition whether the screen frame is a requirement or optional depending on the requisition and the Navigation Control/ Classification for a maximum case 7F machine are provided. In a case where the optional frame is not required it will be necessary to perform the following steps 1) Open the main frame container, go to the required frame and delete the required frame using the delete button on the left-hand side of the screen. 2) Modify the LAST_CTRL_FRAME, LAST_MON_FRAME, LAST_AUX_FRAME or LAST_TEST_FRAME variable to reflect the reduced number of frames. The variables maybe located by closing the main frame container and under edit in the main toolbar selecting properties and the variable tab. 3) Delete the button associated with the deleted frame (Note: the buttons are in their own frame container.) Procedure DATA_CTR NAV_CTRL Classification Frame Name L Name Value Required Control Monitoring Aux. Tests L3_Startup 1 Yes 1 Frame_7F_Startup L3_DLN26 2 Optional 1 Frame_DLN26 L3_FSR_Ctrl 3 Yes 1 Frame_FSRControl L3_Gen_Exc 4 Yes 1 Frame_7F_GeneratorEX2 K L3_IGV_Ctrl 5 Yes 1 Frame_IGVControl L3_Liquid 6 Optional 1 Frame_7F_LiquidFuel L3_Motors 7 Yes 1 Frame_7F_Motors L3_SteamPA 8 Optional 1 Frame_7F_Steam L3_Water_Inj 9 Optional 1 Frame_7F_WaterInjection L3_Brg_Tmps 10 Yes 1 Bar_7F_BearingTemps.ci m L3_Exhaust 11 Yes 1 Bar_7F_ExhaustTemp L3_Gen_RTD 12 Yes 1 Bar_7F_GeneratorRTD L3_Hydrogen 13 Yes 1 Frame_Hydrogen Purity L3_VibProx 14 Optional 1 Bar_7F_Proximeter.cim L3_VibSeism 15 Yes 1 Bar_7F_Seismic.cim L3_Wheelspc 16 Yes 1 Bar_7F_Wheelspace L3_Flame 17 Yes 1 Bar_7F_Flame Temp L3_Gen_Cap 18 Optional 1 Frame_7F_Gen_Cap L3_StartCk 19 Yes 1 Frame_7F_StartChecks L3_StaticStrt 20 Optional 1 Frame_StaticStart L3_Timers 21 Yes 1 Frame_TimersCounters L3_Trips 22 Yes 1 Frame_7F_Trips L3_IO_Check 23 Yes 1 Frame_7F_IO_Check L3_OS_Test 24 Yes 1 Frame_Overspeed3600 L3_ShaftMon 25 Optional 1 Frame_ShaftVoltMon Totals 9 7 6 3 HMI Turbine Screen Standards
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3.1 Object Grouping and Naming
The grouping of objects has been carried out at multiple levels. At the lowest level similar objects were grouped and at the highest level all the objects in a single frame were grouped (excluding the objects in the Frame Foundation). This method was found to be the optimum in both the construction and modification of objects. Note: If an object is ungrouped then the name of the object will be automatically deleted. Example of Object Grouping and Naming Figure 3.1: Startup Screen Grouping
The objects which form the Start up Screen are shown in Fig: 3.1. All the objects in the screen are grouped at the highest level and are labeled “Startup Display”. The next level of grouping is at the individual object level as shown in Fig: 3.2. The individual objects are then sub-grouped into like objects. In the example the Status Data Group is made up of the Status Data Boxes, Status Data, Status Banner/ Text and Status Shadow. The naming of objects has been performed at all levels as an aid to understanding.
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Fig 3.2 Individual Object Grouping
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4.0 General Object Properties General Screen Characteristics
Background Colors Silver Screen Size 800x600 Color Depth At least 65,000 colors Default Fonts Text: 12 pt Arial (Regular) Data: 12 pt Lucida Sans Unicode (Regular) “LSU”
4.1 General Foundation Screen The general foundation screen comprises the Title Bar, RHS Navigation buttons and the Alarm Window. The title bar will contain: GE Logo Font
Font
Color - White GE Logo Font, Regular 22 Position 605.5, 5.85
Geometry
Width – 800 pt Height – 25 pt Gradient Shading Shade Style – Diagonal Up Color 1 – 66, 65, 66 Color 2 - White
Background
Color
Customer Name
Font
Arial Bold, 20 Color – White (Capital Case), Position 604, 40
To obtain a 3D effect a carbon copy of name is superimposed on the original with a slight offset. Controller Time & Date
Font
Black, Arial Bold, 12
Status Banner
Geometry
Width – 150 pt Height – 25 pt GT1 – color 248,193,111 GT2 – color 147,156,61 GT3 – color 0,195,198 GT2 – color 56,192,114 Position, 600, 650 Alignment, Top/Left
Color Animated with Unit name
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Unit Name
Font
White, Arial Bold Italic, 14 pt
Data_Ctrl Value Font
Font
Anchor Position, 599.9, 767.45 Arial Italic, 12 pt Alignment, Top/Left Anchor Position, 590.25, 652.55
4.2 Navigational Buttons The functionality of the navigational buttons is described in detail in Section 2.0. The buttons are physically located on the right hand side of each screen.
Overview Tools Alarms
!
Geometry Text
Width – 100 pt Height – 24 pt Black, Arial Regular 12
(Exception Alarm Button Text Exclamation Mark
Height - 63.9 pt White, Arial Bold 12 White, Arial Bold 48)
Colors
Gas Turbine 1 Gas Turbine 2 Gas Turbine 3 Gas Turbine 4
Overview Gas Turbine 1 Gas Turbine 2 Gas Turbine 3 Gas Turbine 4 Tools Alarms Control, Monitor Aux, Tests Frame Navigation Buttons
108,163,160 243,193,111 147,156,61 0,195,198 56,192,114 198,195,0 255,0,0 (Red) 0,128,128 (Teal) 170,170,170
Control
Monitor
Aux
Tests
start-up
bearing temps
demand
contacts
dln
exhaust
flame
overspeed test
FSR control
generator rtd
gen capability
shaft voltage
gen/exciter
hydrogen
start check
IGV Control
proximeter vibe
static start
liquid fuel
seismic vibration
timers
motors
wheelspace
trip diagram
steam power aug water injection
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4.3 Alarms Alarms allow for 4 priority classifications distinguished by the implemented color scheme. Ack/UnAck Unacknowledged Unacknowledged Acknowledged Acknowledged
Normal/Alarm Alarm Normal Alarm Normal
Text/Background White/Red Black/White Red/White Auto Reset
4.4 Trend Screens Trend Screens are associated with Bar Graphs and are opened by button actions located on individual Bar Graph screens. CIMPLICITY Trending can only be accomplished in a real time mode. Thus, trend screens must be open to continue trending.
General Screen Characteristics
Background Colors
Screen Size Color Depth
Buttons
Geometry, Color Font
Silver for Button Area, Gray for Chart Area & Time Interval Area 800x600 At least 65,000
Width – 90 pts, Height – 30 pts. 66, 65, 66 Black, Arial 10 pt
Trend screens, comprise of the title bar, trend options and time interval selections for which trend is required. The title bar is similar to the main screen title bar with the addition of the screen title.
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Unit Name
Font
White, Arial Bold Italic, 14 pt
Data_Ctrl Value
Font
Anchor Position, 599.9, 767.45 Arial Italic, 12 pt Alignment, Top/Left Anchor Position, 590.25, 652.55
GE Logo Font
Font
Color - White GE Logo Font, Regular 22 Position 605.5, 5.85
Geometry
Width – 800 pt Height – 25 pt Gradient Shading Shade Style – Diagonal Up Color 1 – 66, 65, 66 Color 2 - White
Background
Color
Customer Name
Font
Arial Bold, 20
Color – White (Capital Case), Position 604, 40 To obtain a 3D effect a carbon copy of name is superimposed on the original with a slight offset. Font
Status Banner
Black, Arial Bold, 12
Geometry
Width – 150 pt Height – 25 pt Color Animate GT1 – color 248,193,111 with Unit GT2 – color 147,156,61 GT3 – color 0,195,198
GT4 – color 56,192,114 Position, 600, 650 Alignment, Top/Left
Trend Options
Trend Options are selectable by buttons, identified by point description. Individual Buttons are available to select Var/ Watts/ Speed; all point descriptions, maximum point value, clear display, show legend and hide legend.
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y Var, Watts, Speed Button
Point Description Buttons
Point Description Header
Time Interval
Time Interval Buttons
Geometry – Height 24 pts, Width 120 pts Color - Silver
Geometry – Height 24 pts, Width 90 pts Color – Silver Text, Black, Arial Regular 11
Text, Black, Arial Regular 11 Alignment Left/Top
The time intervals currently available for Trend Charts are 24hr, 5hr, 60min, 30min, 10min, 5min and 1min. These intervals maybe modified by the requisition engineer as required.
Geometry – Height 30 pts, Width 50 pts Button Color, Silver Text, Black, Arial Regular 12
Trend Chart Example
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5.0 Data Delivery & Active Control Object Types Data Delivery & Active Control Object Types
Data Groups, Enumerated Data Groups, Control Groups, Setpoint Control Groups, Motor Control Groups and Bar Graph Groups comprise the majority of data delivery and active control object types.
Data Group Specifics
Data Groups are divided into five lesser groups.
Data_Boxes
Height - 16 pts in height Widths divisible by 10 pts. Fill Color – Light Gray (231, 227, 231) Two white lines placed on the bottom and on the right are used to provide a shadowed look to this object. These boxes are vertically aligned and spaced 3 pts apart. Text is bottom aligned in the databox
Data
Data feedback using point ID. Text Color - Black Numeric Data using Lucida Sans Unicode 11pt, with a right/center anchor Text using Arial 11pt, with left center text anchor.
Accelerating Starting Enumerated State Text Data
Banner
789 3456 Numerical Data
TealTurbine box. Text descriptions are grouped and centered on the29 HMI Screen Standards banner.
Turbine Status
Exhaust
Turbine State
Speed
* Turbine Status is a Enumerated Description using the Controllers enumerated state variable NORMAL.
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EU_Label
Engineering units label, Text Color - Black, Arial 11pt, left/center anchor.
deg F rpm Shadow
Two boxes encompassing all data being displayed. One black, one white, slightly offset to provide a shadowed look appearance.
Data Group Example
Exhaust
### ##
Speed
#### ###
Max Vibe
#.## ##
CPD
### ###
IGV
## ###
Watts
##.# ##
Vars
##.# ##
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.Control Group Specifics
Control groups objects are divided into three major groups; the banner, the buttons and the shadow Data Groups are divided into five lesser groups.
Banner
encompasses the control objects title Text Color - White, Arial 12pt Teal box background for text contrast
Load Select Buttons
Text Color - Black, Arial 12pt, text. Geometry of 70 wide(or divisible by 10) and 24 high. Title case is used for text. Buttons are aligned and vertically spaced 0 pts apart.
Preselect Ld Base Load Peak Load Shadow
Two boxes encompassing all data being displayed. One black, one white, slightly offset to provide a shadowed look appearance.
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Control Group Example
Load Select Preselect Ld Base Load Peak Load
Setpoint Group Specifics Setpoint group objects are divided into five major groups; Data Boxes, Data Text and Banner, Data, Units and the Shadow
Data_Boxes
Height - 16 pts Widths divisible by 10 pts. Two white lines placed on the bottom and on the right are used to provide a shadowed look to this object. These boxes are vertically aligned and spaced 3 pts apart. Text is bottom aligned in the box
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Data Text & Banner
Text Color – White, Arial 11pt, right/ center anchor. The Banner is a Teal Box. The text descriptions are grouped and centered on the banner. Header Text - Black text, Arial 12 pt, left/ top anchor is placed above Banner.
IGV Mode Control Setpoint Reference IGV Angle Data
Data feedback using point ID. Text Color - Black, Numerical using Lucida Sans Unicode 11pt, with a right/center anchor and Text using Arial 11pt, with left center text anchor.
53.0 53.0 50.0
EU_Label
Engineering units label Text Color - Black, Arial 11pt, left/center anchor.
DGA DGA DGA
Shadow
Two boxes encompassing all data being displayed. One black, one white, slightly offset to provide a shadowed look appearance.
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Setpoint Group Example
IGV Mode Control Setpoint
53.0 DGA
Reference
53.0 DGA
IGV Angle
50.0 DGA
Motor Control Group
Motor control group objects are divided into four major groups; the banner, the buttons, status indicators and the shadow box.
Banner
Encompasses the control objects title (White, Arial 12pt) and the teal box background for text contrast
Hydraulic Supply Pump
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Buttons
Text Color - Black, Arial 12pt, text. Geometry of 70 pts wide and 24 pts high. Title case is used for text. Buttons are aligned and vertically spaced 0 pts apart. The text on the buttons is color animated and turns yellow when the button is in the active state.
#1 Lead
#2 Lead
#1 Lead
On
#2 Lead
Off
Off Active
Status Boxes
On
Inactive
Text Color – Black, Arial Bold 12 pt centered on the object. Geometry - Height 22 pts, Width - 68 pts wide. Two white lines placed on the top and on the left hand side are used to provide a raised look to this object. These boxes are vertically left aligned with the buttons directly above and have their middles aligned with the button to the right.
Running
Running Shading
The boxes and text are color animated Boxes: Running State, Color Red with center gradient shading of 255, 195, 198 Stopped State, Color 0,195,0 with center gradient shading of198, 255, 198 Text: Running State, Text “Running”with color Lime Stopped State, Text “Stopped”with color Red
Stopped
Running
Color Animation
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Shadow
Two boxes encompassing all data being displayed. One black, one white, slightly offset to provide a shadowed look appearance.
Motor Control Group Example
Hydraulic Supply Pump
Auto Rotate
#1 Lead
#2 Lead
On
Running
Running
Off
Enumerated Data Group Specifics
Enumerated Data Group objects consist of four objects, Enumerated Data Descriptions, Data Boxes, Data and Data Shadow.
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Data Descriptions
Text Color - White, Arial 11pt, right/center anchor. The text descriptions are grouped and centered on the Teal Box banner.
Turbine Status Turbine State Control Mode Fuel Control Tie Line Status IGV Control The Turbine Status is an Enumerated Description using the Controllers enumerated state variable NORMAL.
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Enumerated Data Boxes
Geometry Height - 16 pts Width of 130 pts divisible by 10 pts. Two white lines placed on the bottom and on the right are used to provide a shadowed look to this object. These boxes are vertically aligned and spaced 3 pts apart.
Enumerated Data
Text Color – Black, Arial 11pt, with left center text anchor
Accelerating Starting Manual Acceleration LP Sequence In Progress IGV Full Open
Shadow
Two boxes encompassing all data being displayed. One black, one white, slightly offset to provide a shadowed look appearance.
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Enumerated Group Example
Turbine Status Accelerating Turbine State Starting Control Mode Manual Fuel Control Acceleration LP Tie Line Status
Sequence In Progress
IGV Control IGV Full Open
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6.0 Bar Graphs
Gas Control Valves
###
### ###
## 200
## 100
### ###
### ###
### ###
###
## 100
160
80
80
120
60
60
80
40
40
40
20
20
0
Ref Fbk
SRV
0
Ref Fbk
PM1
Ref Fbk
PM2
Ref Fbk
PM3
Ref Fbk
0
QUAT
Axis Unit Font X-Axis Label Y-Axis Minor Label Y-Axis Major Label Label Alignment
Arial Reg. 10 pt, Color - Black 0,0,198 Arial Reg. 12 pt, Color - Blue Arial Reg. 10 pt, Color - Black Arial Reg. 12 pt, Color - Blue Parallel to Axis
Chart Lines
Black 0,0,198 Width: 0 pt Number of horizontal lines on graph should be minimized and placed behind bar graphs. Width: 20 pt Ht: 120 pt (Increment or decrement 10 pts) Color: Black Color: Light Gray Right hand side and bottom side shaded white to give a 3-D container effect. Grouping the RHS side and bottom side into a single object facilitates alignment. RHS should be 1 pt less than height of bar and anchored to the top of the bar. (If bar is 120 x 20 then shading should be 119 x 20).
Bar Geometry Bar Border Bar Fill Bar Shading
Bar Data Buttons
See Data Buttons above Width: 30 pts Height: 16 pts
Dynamic Pointers have been added to bar graphs to identify Alarm (Yellow) and Trip (Red) limits. The pointer levels are obtained using the actual constants in the controller.
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6.1 FSR Bar Graph
The color animation for the FSR bar graph is shown in Table 6.1. The range is 0 – 100% Table 6.1: FSR Parameter
Point Name
FSR SU ACC
T1_FSR T1_FSRSU T1_FSRCC
Normal Fill Color 0,195,198 0,195,198 0,195,198
SPD
T1_FSRN
0,195,198
TEMP
T1_FSRT
0,195,198
SD
T1_FSRSD
0,195,198
MAN
T1_FSRMAN
0,195,198
Color Animation Switch Non Non T1_L30F_ACN Eq 1 0 T1_L30F_ND Eq 1 0 T1_L30F_TMP Eq 1 0 T1_L30F_SD Eq 1 0 T1_L30F_MAN Eq 1 0
HMI Turbine Screen Standards
Color
Lime Blue Lime Blue Lime Blue Lime Blue Lime Blue
42
6.2 Bearing Temperatures
The color animation for the Bearing Temperatures is shown in Table 6.2. The temperature range is 0-300 deg F. The Dynamic Alarm Limit Pointer (Yellow), and its value is used in the color animation switch. e.g. for T1_LTTH1 the pointer value is given by the controller constant T1_LOKALM1 Table 6.2: Bearing Temperatures Parameter
Point Name
Lube Oil Header
T1_LTTH1
Normal Fill Color 0,195,198
Inactive Thrust Bearing #1 Inactive Thrust Bearing #2 Active Thrust Bearing #1 Active Thrust Bearing #2 Turbine Bearing 1 #1 Turbine Bearing 1 #2 Turbine Bearing #1 Drain Turbine Bearing 2 #1 Turbine Bearing 2 #2 Turbine Bearing #2 Drain Generator Bearing 1 #1 Generator Bearing 1 #2 Generator Bearing #1 Drain
T1_BTTI1_4
0,195,198
T1_BTTI1_8
0,195,198
T1_BTTA1_ 7 T1_BTTA1_ 14 T1_BTJ1_1
0,195,198
T1_BTJ1_2
0,195,198
T1_LTB1D
0,195,198
T1_BTJ2_1
0,195,198
T1_BTJ2_2
0,195,198
T1_LTB2D
0,195,198
T1_BTGJ1_ 1 T1_BTGJ1_ 2 T1_LTB1D
0,195,198
0,195,198 0,195,198
0,195,198 0,195,198
Color Animation Switch (T1_LTTH1 GE T1_LOKALM1) (T1_BTTI1_4 GE T1_BTKALM1) (T1_BTTI1_8 GE T1_BTKALM2) (T1_BTTA1_7 GE T1_BTKALM3) (T1_BTTA1_14 GE T1_BTKALM4) (T1_BTJ1_1 GE T1_BTKALM5) (T1_BTJ1_2 GE T1_BTKALM6) (T1_LTB1D GE T1_LOKALM2) (T1_BTJ2_1 GE T1_BTKALM7) (T1_BTJ2_2 GE T1_BTKALM8) (T1_LTB2D GE T1_LOKALM3) (T1_BTGJ1_1 GE T1_BTKALM9) (T1_BTGJ1_2 GE T1_BTKALM10) (T1_LTG1D GE T1_LOKALM4)
HMI Turbine Screen Standards
Animated Color Yellow Yellow Yellow Yellow Yellow Yellow Yellow Yellow Yellow Yellow Yellow Yellow Yellow Yellow
43
Generator Bearing 2 #1 Generator Bearing 2 #2 Generator Bearing #1 Drain
T1_BTGJ2_ 1 T1_BTGJ2_ 2 T1_LTG2D
0,195,198 0,195,198 0,195,198
(T1_BTGJ2_1 GE T1_BTKALM11) (T1_BTGJ2_2 GE T1_BTKALM12) (T1_LTG2D GE T1_LOKALM5)
Yellow Yellow Yellow
6.3 Exhaust Temperatures
The color animation for an Exhaust Temperature is shown in Table 6.3. The temperature range is 0-1400 deg F. The parameter designation X varies from 1 to 27 depending upon the thermocouple position; the color animation switches and colors are however are the same for all thermocouples. The red (trip) and yellow (alarm) dynamic pointers in the case of the exhaust tempertures are an indication of approximate alarm and trip limits, actual alarms and trips are generated using the mean exhaust temperature. The pointers are set as follows: Dynamic Alarm Limit – Color Yellow, (T1_TTKOT3 + T1_TTRXB) Dynamic Trip Limit – Color Red, (T1_TTKOT1 MIN (T1_TTRXB+T1_TTKOT2)) Table 6.3: Exhaust Temperatures Parameter
Point Name
Exhaust Temp # X
T1_TTXD_X
Normal Fill Color 0,195,198
Color Animation Switch T1_TTXD1_X GE (T1_TTKOTX + T1_TTRXB)
Animated Color Yellow
(T1_TTXD1_X GE (T1_TTRXB + T1_TTKOT2)) OR (T1_TTXD1_X GE T1_TTKOT1)
Red
HMI Turbine Screen Standards
44
Example: Exhaust Temp # 3
T1_TTXD1_3 GE (T1_TTKOT3 + T1_TTRXB)
Yellow
(T1_TTXD1_3 GE (T1_TTRXB + T1_TTKOT2)) OR (T1_TTXD1_3 GE T1_TTKOT1)
Red
HMI Turbine Screen Standards
45
6.4 Generator RTD Temperatures
The color animation for the Generator RTD Temperatures is shown in Table 6.4. The temperature range is 0-300 deg F. The Dynamic Alarm Limit Pointer (Yellow) is provided by the controller e.g. for T1_DTGSF1 the pointer value is given by the controller constant DTKGSF. Table 6.4 Generator RTD Temperatures Parameter
Point Name
Stator Coupling End #1 Stator Coupling End #2 Stator Coupling End #3 Stator Collector End #1 Stator Collector End #2 Stator Collector End #3 Stator Coupling End #1 Stator Coupling End #2
T1_DTGSF1
Normal Fill Color 0,195,198
T1_DTGSF2
0,195,198
T1_DTGSF3
0,195,198
T1_DTGSA4
0,195,198
T1_DTGSA5
0,195,198
T1_DTGSA6
0,195,198
T1_DTGSC7
0,195,198
T1_DTGSC8
0,195,198
Color Animation Switch (T1_DTGSF1 GE T1_DTKGSF) (T1_DTGSF2 GE T1_DTKGSF) (T1_DTGSF3 GE T1_DTKGSF) (T1_DTGSA4 GE T1_DTKGSA) (T1_DTGSA5 GE T1_DTKGSA) (T1_DTGSA6 GE T1_DTKGSA) (T1_DTGSC7 GE T1_TGKSFA) (T1_DTGSC8 GE T1_TGKSFA)
HMI Turbine Screen Standards
Animated Color Yellow Yellow Yellow Yellow Yellow Yellow Yellow Yellow
46
Cold Gas Coupling End #1 Cold Gas Collector End #1 Cold Gas Collector End #1 Cold Gas Collector End #2 Cold Gas Collector End #3 Hot Air Coupling End #1 Hot Air Coupling End #2 Hot Air Collector End #1 Hot Air Collector End #2 Frame Cold Gas
T1_DTGSC9
0,195,198
T1_DTGGC1 0 T1_DTGGC1 3 T1_DTGGC1 1 T1_DTGGC1 2 T1_DTGGH2 8 T1_DTGGH2 9 T1_DTGGAC 23 T1_DTGGAH 17 T1_DTGGK2 4
0,195,198 0,195,198 0,195,198 0,195,198 0,195,198 0,195,198 0,195,198 0,195,198 0,195,198
(T1_DTGSC9 GE T1_TGKSFA) (T1_DTGGC10 GT T1_TGKGCA) (T1_DTGGC13 GT T1_TGKGCA) (T1_DTGGC11 GT T1_TGKGCA) (T1_DTGGC12 GT T1_TGKGCA) (T1_DTGGH28 GT T1_TGKGHA) (T1_DTGGH29 GT T1_TGKGHA) (T1_DTGAC23 GE T1_TGKGCA) (T1_DTGAH17 GE T1_TGKGHA) (T1_DTGGK24 GT T1_DTKGGK)
HMI Turbine Screen Standards
Yellow Yellow Yellow Yellow Yellow Yellow Yellow Yellow Yellow Yellow
47
6.5 Vibration Proximeters
The color animation for the Vibration Proximeters is shown in Table 6.5. The vibration range is 0-10 ins/sec. Table 6.5: Vibration Proximeters Parameter Axial Position Z1 Axial Position Z2 Turbine Bearings 1X Turbine Bearings 1Y Turbine Bearings 2X Turbine Bearings 2Y Generator Bearings 3X Generator Bearings 3Y Generator Bearings 4X Generator Bearings 4Y
Point Name T1_TVT96VS1Z1 T1_TVT96VS1Z2 T1_TVT39VS1X T1_TVT39VS1Y T1_TVT39VS2X T1_TVT39VS2Y T1_TVT39VS9X T1_TVT39VS9Y T1_TVT39VS10X T1_TVT39VS10Y
Normal Fill Color 0,195,198 0,195,198 0,195,198 0,195,198 0,195,198 0,195,198 0,195,198 0,195,198 0,195,198 0,195,198
HMI Turbine Screen Standards
48
6.6 Seismic Vibration
The color animation for Seismic Vibration is shown in Table 6.6. The range is 0-1.2 ins/sec. The dynamic alarm pointer (Yellow) and the dynamic trip pointer is (Red) are provided by the controller e.g. for T1_BB1 the alarm pointer value is given by the controller constant T1_LK39VA1 and the trip pointer by T1_LK39VT1.
Table 6.6 Seismic Vibration Parameter Turbine Forward #1
Turbine Forward #2
Turbine Aft #1
Point Name T1_BB1
T1_BB2
T1_BB4
Normal Fill Color 0,195,198
0,195,198
0,195,198
Color Animation Switch (T1_BB1 GE T1_LK39VA1) AND (T1_BB1 LT T1_LK39VT1)
Animated Color Yellow
(T1_BB1 GT T1_LK39VT1) (T1_BB2 GE T1_LK39VA2) AND (T1_BB2 LT T1_LK39VT2)
Red
T1_BB2 GE T1_LK39VT2 (T1_BB4 GE T1_LK39VA4) AND (T1_BB4 LT T1_LK39VT4)
Red
(T1_BB4 GE T1_LK39VT4)
Red
HMI Turbine Screen Standards
Yellow
Yellow
49
Turbine Aft #2
Generator Aft #1
Generator Aft #2
Generator Forward #1
Generator Forward #2
T1_BB5
T1_BB7
T1_BB8
T1_BB9
T1_BB10
0,195,198
0,195,198
0,195,198
0,195,198
0,195,198
(T1_BB5 GE T1_LK39VA5) AND (T1_BB5 LT T1_LK39VT5)
Yellow
(T1_BB5 GE T1_LK39VT5) (T1_BB7 GE T1_LK39VA7) AND (T1_BB7 LT T1_LK39VT7)
Red
(T1_BB7 GE T1_LK39VT7) (T1_BB8 GE T1_LK39VA8) AND (T1_BB8 LT T1_LK39VT8)
Red
(T1_BB8 GE T1_LK39VT8) (T1_BB9 GE T1_LK39VA9) AND (T1_BB9 LT T1_LK39VT9)
Red
(T1_BB9 GE T1_LK39VT9) (T1_BB10 GE T1_LK39VA10) AND (T1_BB10 LT T1_LK39VT10)
Red
(T1_BB10 GE T1_LK39VT10)
Red
HMI Turbine Screen Standards
Yellow
Yellow
Yellow
Yellow
50
6.7 Wheelspace Temperatures
The color animation for the Wheelspace Temperatures is shown in Table 6.7. The range is 0900 deg F. Table 6.7 Wheelspace Temperatures Parameter
Point Name
First Stage Forward Inner #1
T1_TTWS1FI 1
First Stage Forward Inner #2
First Stage Aft Outer #1
First Stage Aft Outer #2
T1_TTWS1FI 2
T1_TTWS1A O1
T1_TTWS1A O2
Normal Fill Color 0,195,198
0,195,198
0,195,198
0,195,198
Color Animation Switch (T1_L3 EQ 1) AND (T1_TTWS1FI1 GE T1_WSKALM1)
Animated Color Yellow
(T1_L3 EQ 0) AND (T1_TTWS1FI1 GE (T1_WSKALM1+T1_ WSKALM9)) (T1_L3 EQ 1) AND (T1_TTWS1FI2 GE T1_WSKALM1))
Yellow
(T1_L3 EQ 0) AND (T1_ TTWS1FI2 GE (T1_WSKALM3+T1_ WSKALM9)) (T1_L3 EQ 1) AND (T1_TTWS1AO1 GE T1_WSKALM3)
Yellow
(T1_L3 EQ 0) AND (T1_TTWS1AO1 GE (T1_WSKALM3+T1_ WSKALM9)) (T1_L3 EQ 1) AND (T1_TTWS2FO1 GE T1_WSKALM4)
Yellow
(T1_L3 EQ 0) AND
Yellow
HMI Turbine Screen Standards
Yellow
Yellow
Yellow
51
Second Stage Forward Inner #1
Second Stage Forward Inner #2
Second Stage Aft Outer #1
Second Stage Aft Outer #2
Third Stage Forward Inner #1
Third Stage Forward Inner #2
T1_TTWS2F O1
T1_TTWS2F O2
T1_TTWS2A O1
T1_TTWS2A O2
T1_TTWS3F O1
T1_TTWS3F O2
0,195,198
0,195,198
0,195,198
0,195,198
0,195,198
0,195,198
(T1_TTWS2FO1 GE (T1_WSKALM4+T1_ WSKALM9)) (T1_L3 EQ 1) AND (T1_TTWS2FO1 GE T1_WSKALM4)
Yellow
(T1_L3 EQ 0) AND (T1_TTWS2FO1 GE (T1_WSKALM4+T1_ WSKALM9)) (T1_L3 EQ 1) AND (T1_TTWS2FO2 GE T1_WSKALM4)
Yellow
(T1_L3 EQ 0) AND (T1_TTWS2FO2 GE (T1_WSKALM4+T1_ WSKALM9)) (T1_L3 EQ 1) AND (T1_TTWS2AO1 GE T1_WSKALM5)
Yellow
(T1_L3 EQ 0) AND (T1_TTWS2AO1 GE (T1_WSKALM5+T1_ WSKALM9)) (T1_L3 EQ 1) AND (T1_TTWS2AO2 GE T1_WSKALM5)
Yellow
(T1_L3 EQ 0) AND (T1_TTWS2AO2 GE (T1_WSKALM5+T1_ WSKALM9)) (T1_L3 EQ 1) AND (T1_TTWS3FO1 GE T1_WSKALM6)
Yellow
(T1_L3 EQ 0) AND (T1_TTWS3FO1 GE (T1_WSKALM6+T1_ WSKALM9)) (T1_L3 EQ 1) AND (T1_TTWS3FO2 GE T1_WSKALM6)
Yellow
(T1_L3 EQ 0) AND (T1_TTWS3FO2 GE (T1_WSKALM6+T1_ WSKALM9))
Yellow
HMI Turbine Screen Standards
Yellow
Yellow
Yellow
Yellow
Yellow
52
Third Stage Aft Outer #1
Third Stage Aft Outer #2
T1_TTWS3A O1
T1_TTWS3A O2
0,195,198
0,195,198
(T1_L3 EQ 1) AND (T1_TTWS3AO1 GE T1_WSKALM7)
Yellow
(T1_L3 EQ 0) AND (T1_TTWS3AO1 GE (T1_WSKALM7+T1_ WSKALM9)) (T1_L3 EQ 1) AND (T1_TTWS3AO2 GE T1_WSKALM7)
Yellow
(T1_L3 EQ 0) AND (T1_TTWS3AO2 GE (T1_WSKALM7+T1_ WSKALM9))
Yellow
HMI Turbine Screen Standards
Yellow
53
6.8 Flame Temperatures
The color animation for the Flame Temperatures is shown in Table 6.8. The range is 1200 counts. Table 6.8 Flame Temperatures Parameter
Point Name
Flame Detector #1 Flame Detector #2 Flame Detector #3 Flame Detector #4
T1_FD_INTEN S1 T1_FD_INTEN S2 T1_FD_INTEN S3 T1_FD_INTEN S4
Normal Fill Color 0,195,198
Color Animation Switch Non
0,195,198
Non
0,195,198
Non
0,195,198
Non
HMI Turbine Screen Standards
Color
54
7.0 Graphic Symbols and Animation Dynamics All Symbols will change color according to the following. When the color changes the entire symbol 'fill color' will change unless otherwise specified. Graphic Symbols will be placed in a Cimview screen to form a Symbol Library.
7.1 Fuel Lines
Gas Line
Color, Olive (128, 128, 0) Width, 2pts Visibility – IF L83FGI eq 1 or L83FM eq 1
Liquid Line
Color, Olive (128, 128, 0) Width, 2pts Visibility – IF L84TL eq 1 or L84MXT eq 1
Steam Line
Color, Maroon Width, 2pts
Control Valves Gas Line
SRV Valve Color Animation:Inactive – Color Green Active - Red SRV Line Color Animation:Inactive - Gradient Color1 – Green Color2 - Lime Active - Gradient Red (IF FSGR gt 1) Control Valve Color Animation:Inactive – Color Green Active - Red Control Line Color Animation:Inactive - Gradient Color1 – Green Color2 - Lime Active - Gradient Red (IF FSGR gt 1)
HMI Turbine Screen Standards
55
Control Valves Liquid Line
LCV Valve Color Animation:Inactive – Color Green Active - Red LCV Line Color Animation:Inactive - Gradient Color1 – Green Color2 - Lime Active - Gradient Red (IF FQROUT gt 1)
Control Valves Steam Line
LCV Valve Color Animation:Inactive – Color Green Active - Red LCV Line Color Animation:Inactive - Gradient Color1 – Green Color2 - Lime Active - Gradient Red (IF L33CJ1C eq 0)
7.2 Gas Turbine
The gas turbine graphics have been developed using the BOLT standard as a template. To the template, Modulating IGV’s, Generator Breaker and Bleed Heat have been added. Gas Turbine Graphics
Modulating IGV’s
Color Animation Inactive, Gray (Gradient Shading), VALID LT 1 Active, Compressor, Green (Gradient Shading) Combustor, Red (Gradient Shading) Hot Section, Yellow (Gradient shading) Flame Color Gradient Color1 222,130,0 Color2 Yellow External Edge, Black, Width 2 pt Fill Color, Gradient Shading Vertical Color 1, Silver Color 2, White Internal Border Color, 132, 255, 255 HMI Turbine Screen Standards 56
Bleed Heat
Generator Breaker
Color Animation Active, Line Color 0, 195, 198, Rectangle Color Red Inactive, Line Color Black, Rectangle Color Green Geometry Line, Width 2pt Internal Rectangle, Width 12.5 pt, Height 2.8 pt External Rectangle, Width 27.2 pt, Height 6.6 pt
.Color Animation, Breaker Open – Green Breaker Closed – Red Geometry,
Lines, Width 20 pt, Height 0 pt Circles, Diameter 9pt Black Circle, Width 1pt
Buttons,
Color, Silver Text Color, Black Font, Arial 11 Geometry, Width, 30 pts, Height 20 pts
7.3 DLN 2.6 Piping & Valving Graphic The properties for the DLN 2.6 piping and valving graphic are shown below
HMI Turbine Screen Standards
57
Piping
PM1 Valve
Color, Gradient Shading Color 1, Olive Color 2, 255, 255, 198 External Border, Black, Width 0 pt
Control Valve The control valve consists of series of objects with the following colors and geometry. 1. Color, Black (Fill) ;Geometry Width 32.3 pts, Height 11.45 pts 2. Color, Black (Rectangle); Geometry Width 32.3 pts, Height 11.45 pts, Width 0 pts. 3. Color, Gradient Shading from Center Color 1, 234, 190, 15 Color 2, 255, 255, 198 External Border, Black, Width 0 pt Geometry, Width, 32.25 pt, Height, 11.45 4. Color, Black (Rectangle); Geometry Width 32.3 pts, Height 11.45 pts, Width 0 pts Valve Orifice The valve orifice consists of a series of objects with the following colors and geometry. 1. Color, 127,127,127 ; Geometry Width 39 pts, Height 17.95 pts 2. Color, 153,153,153 ; Geometry Width 39 pts, Height 16 pts 3. Color, 178,178,178 ; Geometry Width 39 pts, Height 12.4 pts 4. Color, 204,204,204 ; Geometry Width 39 pts, Height 8.6 pts 5. Color, 299,299,299 ; Geometry Width 39 pts, Height 5.95 pts 6. Color, White ; Geometry Width 39 pts, Height 2.3 pts 7. Gradient Shading ; Geometry Width 39 pts, Height 17.95 pts Color 1, 66, 65, 66 Color 2, White Valve Stem The valve orifice consists of a series of objects with the following colors and geometry. 1. Color, 127,127,127 ; Geometry Width 2.85 pts, Height 11.6 pts 2. Color, 178,178,178 ; Geometry Width 2.15 pts, Height 11.6 pts 3. Color, 299,299,299 ; Geometry Width 1.5 pts, Height 11.6 pts 4. Color, White ; Geometry Width 0.45pts, Height 11.6 pts 5. Color, Black ; Geometry Width 0 pts, Height 11.6 pts 6. Color, Black ; Geometry Width 0 pts, Height 11.6 pts Font Arial, Bold, 12 pt
The remaining control valves PM2, PM3, the Quaternary Valve, Vent Valve and the SRV valve are identical in design to the PM1 with the control valve shaded as follows:
HMI Turbine Screen Standards
58
7.4 DLN 2.6 Nozzle Graphic PM2 Valve
Control Valve Color, Gradient Shading from Center Color 1, 247,27,2 Color 2, White
PM3 Valve
Control Valve Color, Gradient Shading from Center Color 1, 56, 192,114 Color 2, White
Quaternary Valve
Control Valve Color, Gradient Shading from Center Color 1, Color 1, 77, 124, 172 Color 2, Color 2, White
Vent & SRV Valves
Control Valve Color, Gradient Shading from Center Color 1, 127, 127, 127 Color 2, White
Outer Circle
Geometry, Width 240 pts, Height 240pts. Color, External border, White, Width 0 pts Fill Color, Gradient Shading from Center Color 1, 66,65,66 Color 2, White HMI Turbine Screen Standards
59
Quaternary Circle
Geometry, Width 220 pts, Height 220pts. Color, External border, White, Width 0 pts Fill Color, Gradient Shading from Center Color 1, 77, 124, 172 Color 2, 231, 227, 231
Quaternary Animation
Geometry, Width 185 pts, Height 185 pts. Color, External border, Black, Width 0.5 pts Fill Color, Black Color Animation Fill Color, Red (L30QGCV & L28FDX eq 1)
Inner Circle
Geometry, Width 165 pts, Height 165 pts. Color, External border, White, Width 1 pts Fill Color, Gradient from Center Color Animation Fill Color, Red (L30QGCV & L28FDX eq 1)
Quaternary Text
White, Arial, Regular 12
PM3 On
Geometry, Width 50 pts, Height 50 pts Color, External border, Black, Width 0.5 pts Fill Color, Black Color Animation Fill Color, Red (L30PM3_C & L28FDX eq 1)
PM3 Off
Geometry, Width 34 pts, Height 34 pts Color, External border, Black, Width 0.5 pts Fill Color, Gradient Shading from Center Color 1, 56,192,114 Color 2, 198,255,255 Text, Arial 11, Bold, Alignment Center\Center
PM2 On
Geometry, Width 50 pts, Height 50 pts Color, External border, Black, Width 0.5 pts Fill Color, Black Color Animation Fill Color, Red (L30PM2_C & L28FDX eq 1)
PM2 Off
Geometry, Width 34 pts, Height 34 pts Color, External border, Black, Width 0.5 pts Fill Color, Gradient Shading from Center Color 1, 56,192,114 Color 2, 198,255,255 Text, Arial 11, Bold, Alignment Center\Center
HMI Turbine Screen Standards
60
PM1 On
Geometry, Width 50 pts, Height 50 pts Color, External border, Black, Width 0.5 pts Fill Color, Black Color Animation Fill Color, Red (L30PM1_C & L28FDX eq 1)
PM1 Off
Geometry, Width 34 pts, Height 34 pts Color, External border, Black, Width 0.5 pts Fill Color, Gradient Shading from Center Color 1, 234, 190, 15 Color 2, 255, 227,198 Text, Arial 11, Bold, Alignment Center\Center
HMI Turbine Screen Standards
61
7.5 Exhaust Thermocouple Graphics An Upstream schematic of the Exhaust thermocouples for a 7FA machine is shown below.
Heading
Black, Arial, Regular 10, Alignment Left\Top
Point Description
Black, Arial, Bold 8, Alignment Center\Top Color Animation Color 1, Navy, L30TXA eq 0 & L86TXT eq 0 Color 2, Yellow, L30TXA eq 1 & L86TXT eq 0 Color 3, Red, L86TXT eq 1
Lines
Black, Width 2 pts
Outer Circle
Geometry, Width 148 pt, Height 148 pt Black, Width 2 pts Fill Color, Gradient from Center Single Color, Olive
Burners
Geometry, Width 17.8 pt, Height 17.8 pt Color 66,65, 66, Width 0.5 pt Text, Black, Arial, Bold 14 pt Fill Color, Gradient from Center Single Color, 66,65,0 Color Animation Gradient, L28FDX eq 1 Color 1, 255, 255, 132 Color 2, 255, 130, 0
Inner Circle 1
Geometry, Width 72 pt, Height 72 pt Color Black, Width 2 pt Fill Color, Pattern Color, Teal Pattern Color, White HMI Turbine Screen Standards
62
Inner Circle 2
Geometry, Width 58 pt, Height 58 pt Color Black, Width 2 pt Fill Color, Gradient from center Color 1, Gray Color 2, 231, 227, 231
Inner Circle 3
Geometry, Width 25 pt, Height 25 pt Color Black, Width 2 pt Fill Color, Gradient Horizontal Color 1, Silver Color 2, White
Center
Geometry, Width 14 pt, Height 14 pt Color Black, Width 2 pt Fill Color, Pattern Color 1, Maroon Color 2, White
HMI Turbine Screen Standards
63
8.0 Start Check Screen Start Check 0
Bus Undervoltage L27BN or L27BN Comp Inlet Thermocouples Disagree L86TCI Gas Fuel or IGV Control Valve Fault L3VLVFLT Customer Permissive to Start L3CP Spare SPARE Spare SPARE Spare SPARE
NOT READY T O START
The Start Check Screen provides a list of signals which all must be in the proper state GREEN to permit a start. Therefore, a green signal is required to start the unit. If signals are RED then a start request is inhibited.
When a RED signal is present then the text in the Data Box turns red and the “NOT READY TO START”signal is displayed. When all signals are green then the Data Box displays the “READY TO START”signal in green.
READY TO START
Start Check Buttons
Geometry, Width 220 pts, Height 27 pts Color Animation Fill Color, Lime L3TCK0 eq 1 Fill Color, Red L3TCK0 eq 0 Text, Black, Arial, Bold 11
Data Boxes
Geometry, Width 220 pts, Height 27 pts Color Animation Normal Fill Color, Red Fill Color, Lime Text, Black, Arial Regular 12, Alignment Center\ Bottom Shading, two white lines placed on the bottom and on the right are used to provide a shadowed look to this object. These boxes are vertically aligned and spaced 2 pts apart.
HMI Turbine Screen Standards
64
The start permissives for a maximum case 7FA machine are listed in the table below. Point Description
Point Name
Normal Color
Color Animation Switch
Animated Color
Start Check 0 Bus UnderVoltage
T1_L27BN
Red
Lime
T1_L86TCI
Red
T1_L27BN Eq 1 or T1_L27BZ eq 1 T1_L86TCI eq 0
T1_L3VLVFLT
Red
T1_L3VLVFLT eq 0
Lime
T1_L3CP
Red
T1_L3CP eq 1
Lime
T1_L26QN
Red
T1_L26QN eq 1
Lime
T1_L28FDSCK T1_L430 T1_L86HD
Red Red Red
T1_L28FDSCK eq 1 T1_L430 eq 0 T1_L86HD eq 0
Lime Lime Lime
T1_L52GX
Red
T1_L52GX eq 0
Lime
T1_L3SS_RS
Red
T1_L3SS_RS eq 1
Lime
T1_L30EX_SS
Red
T1_L30EX_SS eq 0
Lime
T1_L86CBA
Red Red
T1_L86CBA eq 0
Lime Lime
T1_L4Y
Red
T1_L4Y eq 1
Lime
T1_L38BHSTCK
Red
Lime
T1_L3STCK_HGE N T1_L94SSX T1_L4INHIBIT_ST
Red
T1_L86MP
Red
T1_L38BHSTCK eq 1 T1_L3STCK_HGEN eq 1 T1_L94SSX eq 0 T1_L4INHIBIT_ST eq 0 T1_L86MP eq 0
T1_L4T
Red
T1_L4T eq 0
Lime
T1_L43DIAG T1_L39VD3 T1_L3TFLT T1_L14HM
Red Red Red Red
T1_L43DIAG eq 0 T1_L39VD3 eq 0 T1_L3TFLT eq 0 T1_L14HM eq 0
Lime Lime Lime Lime
Compressor Inlet Thermocouples Disagree Gas Fuel or IGV Control Valve Fault Start Check 1 Customer Permissive to Start Lube Oil Tank Temp Normal Flame Detector Trouble Control Mode = OFF Hydraulic Protective Trouble Generator Breaker Closed LCI(Static Start) Ready to Start EX2000 Status S Exciter Alarm Start Check 2 Compressor Bleed Valve or IGV Pos. Lockout Loss of Master Protective Compressor Operating Limit BH Start Check Hydrogen Start Check Static Starter Shutdown Static Start Inhibited from other unit Master Protective Startup Trip Start Check 3 Loss of Master Protective Off-Line Diagnostics Vibration Start Inhibit Loss of CDP Bias HP Speed –Minimum Firing Speed
Red Red
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Lime Lime Lime Lime
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Start Check AA 20AA System Start Check enable Upstream AA Hi/Lo Position Fault 20AA Position Feedback Fault Downstream AA Hi/Lo Position Fault
T1_L3STAA_ENB
Red
T1_L3STAA_ENB eq 0
Lime
T1_L30AA1PO_A LM T1_L30AAFB_AL M T1_L30AA2PO_A LM
Red
T1_L30AA1PO_ALM eq 0 T1_L30AAFB_ALM eq 0 T1_L30AA2PO_ALM eq 0
Lime
Red Red
Lime Lime
9.0 Trip Screen The Trip screen provides a list of Protective trips for the 7FA. The trips are normally GREEN and turn RED when activated. Some signals are not latched, so the data logger must be checked for an accurate chain of events, leading to any highlighted trips that may appear on the display.
M aster Protective Trip
Protective Status Trip L4PST Pre-Ignition Trip L4PRET Post-Ignition Trip L4POST Starting Device Trip L3SMT Inlet Guide Vane Control Trouble Trip L4IGVT TCEA 5E/PB Circuit Status L5E_TCEA
A list of the protective trips for a maximum case 7FA is shown in the table below. Point Description Master Protective Trip Protective Status Trip Pre-Ignition Trip Post-Ignition Trip Starting Device Trip Inlet Guide Vane Control Trouble Trip TCEA 5E/PB Circuit Status Protective Check 1 Low Lube Oil Pressure Trip Fire Indication Trip Generator Differential Trip Lockout
Point Name
Normal Color
Color Animation Switch
Animated Color
T1_L4PST T1_L4PRET T1_L4POST T1_L3SMT T1_ L4IGVT
Lime Lime Lime Lime Lime
T1_L4PST eq 1 T1_L4PRET eq 0 T1_L4POST eq 0 T1_L3SMT eq 0 T1_ L4IGVT eq 0
Red Red Red Red Red
T1_L5E_TCEA
Lime
T1_L5E_TCEA eq 0
Red
T1_L63QTX
Lime
T1_L63QTX eq 0
Red
T1_L45FTX T1_L86TGT
Lime Lime
T1_L45FTX eq 0 T1_L86TGT eq 0
Red Red
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TCEA External Trip Transfer Differential Trip Lockout Exhaust Pressure High Trip Protective Check 2 Vibration Trip Startup Fuel Flow Excessive Trip Loss of Protective HP Speed Inputs Customer Trip Input Protective Check 3 Control Speed Signal Lost - HP Protective Speed Signal Trouble Control Speed Signal Trouble GCV Not Following Reference Trip Secondary GCV Not Following Ref Trip Quaternary GCV Not Following Ref Trip PM3 GCV Not Following Reference Trip Protective Check 4 Control System Fault Trip Pre-Ignition Trip Auxiliary Check (Servos) Pre-Ignition Trip Auxiliary Logic Post-Ignition Trip Post Ignition Trip Auxiliary Loss of Flame trip High Exhaust Temperature trip Exhaust Overtemperature trip Compressor Bleed Valve Pos. Trouble Trip Load Tunnel Temperature High - Trip
T1_L4_RLYT T1_L86TT
Lime Lime
T1_L4_RLYT eq 0 T1_L86TT eq 0
Red Red
T1_ L63ETH
Lime
T1_ L63ETH eq 0
Red
T1_L39VTRIP T1_L2SFT
Lime Lime
T1_L39VTRIP EQ 0 T1_L2SFT EQ 0
Red Red
T1_L12H_FLT
Lime
T1_L12H_FLT EQ 0
Red
T1_L4CT
Lime
T1_L4CT EQ 0
Red
T1_L12HF
Lime
T1_L12HF EQ 0
Red
T1_L12HFD
Lime
T1_L12HFD_P EQ 0
Red
T1_L12HFD_C
Lime
T1_L12HFD_C EQ 0
Red
T1_L86GCVT
Lime
T1_L86GCVT EQ 0
Red
T1_L86GCVST
Lime
T1_L86GCVST EQ 0
Red
T1_L86GCVQT
Lime
T1_L86GCVQT EQ 0
Red
T1_L86GCV3T
Lime
T1_L86GCV3T EQ 0
Red
T1_L3SFLT
Lime
T1_L3SFLT EQ 0
Red
T1_L3ACS
Lime
T1_L3ACS EQ 1
Red
T1_L4PRETX
Lime
T1_L4PRETX EQ 0
Red
T1_L4POSTX
Lime
T1_L4POSTX EQ 0
Red
T1_L28FDT T1_L30SPT
Lime Lime
T1_L28FDT EQ 0 T1_L30SPT EQ 0
Red Red
T1_L86TXT
Lime
T1_L86TXT EQ 0
Red
T1_L86CBT
Lime
T1_L86CBT EQ 0
Red
T1_L30LTT
Lime
T1_L30LTT EQ 0
Red
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10.0 Liquid Fuel Delivery System The liquid fuel screen comprises of the liquid fuel delivery system, the purge air system and piping for water injection. The components, pumps, valves are obtained from the Bolt Standards and are constructed from a large number of individual objects, as a result detailed descriptions of component geometry’s are not provided.
10.1 Liquid Fuel Delivery
Piping
Geometry, Pipe Width 7pts Border Color, Black 0 pt Color, Gradient shading Color 1, Olive Color 2, 198, 195, 0 Note: direction of shading is consistent with direction of pipe.
Pumps
Pump body Fill Color, Gradient Shading from Center Color 1, Gray Color 2, 231, 227, 231 Text, Black, Arial Bold 12
Liquid Control Valve
The liquid control valve is color animated to show the state of the reference and feedback signals. Fill Color, Red, from Left Range: 0, 100 Units: Percent Text, Black, Arial Bold 12 HMI Turbine Screen Standards
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Stop Valve Solenoid
The text in the Stop Valve Solenoid is color animated Text: Valve Open, Text “Open”with color Red Valve Closed,Text “Closed”with color Lime
Check Valve
Object Color, Gradient Shading Diagonal Up Color 1, Yellow Color 2, 255, 255, 210
Round Light Border Color, Black 2 pts, Geometry, Width 19.6 pts, Height 20 pts Line Color, White Geometry, Width 8.15 pts, Height 6.25 pt The object is color animated Object Color, Olive. Animated Color, Yellow based on {Point_to_Change_Color} variable Flame
External Border, Black 1 Pt Fill Color, Gradient Horizontal Color 1, Olive Color 2, 255, 255, 198 Internal Border, Aqua 1 Pt Fill Color, Black Flame, color animated Normal Color, Black, T1_L28FDX eq 0 Animated Color, Gradient, Vertical, T1_L28FDX eq 1 Color 1, 198, 65, 0 Color 2, Yellow Water Injection, Visibility is set by T1_L30WATERON eq 1.0 Fill Color, Aqua, gradient from center
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10.2 Purge Air System
Piping
Geometry, Pipe Width 7pts Border Color, Black 0 pt Color, Gradient shading Color 1, Green Color 2, 198, 225, 198 Note: direction of shading is consistent with direction of pipe.
Purge\ Isolation Valve
The text in the Stop Valve Solenoid is color animated Text: Valve Open, Text “Open”with color Red Valve Closed,Text “Closed”with color Lime
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11.0 Water Injection System The water injection screen comprises of the water injection delivery system and the purge air system. The components, pumps, valves are obtained from the Bolt Standards and are constructed from a large number of individual objects, as a result detailed descriptions of component geometry’s are not provided.
Pumps
Pump body Fill Color, Gradient Shading from Center Color 1, Gray Color 2, 231, 227, 231 Text, Black, Arial Bold 12
Piping (Water Injection)
Geometry, Pipe Width 7pts Border Color, Black 0 pt Color, Gradient shading Color 1, Olive Color 2, 198, 195, 0 Note: direction of shading is consistent with direction of pipe.
Piping (Purge Air System)
Geometry, Pipe Width 7pts Border Color, Black 0 pt Color, Gradient shading Color 1, Green Color 2, 198, 255, 198 Note: direction of shading is consistent with direction of pipe.
Check Valve
Object Color, Gradient Shading Diagonal Up Color 1, Yellow Color 2, 255, 255, 210 HMI Turbine Screen Standards
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Stop Valve\ Isolation Valve
The stop valve is color animated for open and closed states Open, Color Red, T1_L33WP1O eq 1 Closed, Color 0,195,0 T1_L20WP1C eq 1 Text, Black Arial bold 11
Text
Text, Black Arial bold 11
Data_Boxes
Height - 16 pts Widths divisible by 10 pts. Two white lines placed on the bottom and on the right are used to provide a shadowed look to this object. These boxes are vertically aligned and spaced 3 pts apart. Text is bottom aligned in the box
Data
Data feedback using point ID. Text Color - Black, Numerical using Lucida Sans Unicode 11pt, with a right/center anchor and Text using Arial 11pt, with left center text anchor.
Water Injection
External Border, Black 1 Pt Fill Color, Gradient Horizontal Color 1, Olive Color 2, 255, 255, 198 Internal Border, Aqua 1 Pt Fill Color, Black Flames, have four modes of color animation Mode 1, T1_L28FDX eq 1 NOT T1_L84TG eq 1 Line, Gray 0.5 pt Fill, Gradient Color 1, Yellow Color 2, 198, 65, 0 Mode 2, T1_L28FDX eq 0 or Mode 3, T1_L28FDX eq 1 T1_L84TG eq 1 Line, None Fill, None Mode 4, 1 Color 2, Yellow Line, None Fill Color, Yellow
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The components, pumps, valves are obtained from the Bolt Standards and are constructed from a large number of individual objects, as a result detailed descriptions of component geometry’s are not provided.
Water Injector
The water injector is constructed from 4 individual objects Object 1, Geometry Width 7.75 pt, Height 6.4 pt Fill Color Black, Gradient to Corner Object 2, Geometry Width 3.9 pt, Height 9.7 pt Fill Color 215, 215, 215 Gradient Vertical Object 3, Geometry Width 7.75 pt, Height 9.7 pt Fill Color 114, 114, 114 Gradient Vertical Object 4, Geometry Width 7.75 pt, Height 6.4 pt Fill Color 97,97,97, Gradient to Corner
Water Spray
The water spray consists of two sets of identical objects. Each object consisting of 4 lines Color Aqua, Width 0.5 pts Geometry Line 1, Width 18.65 pts, Height 8.7 pts Line 2, Width 17 pts, Height 12.3 pts Line 3, Width 14.75 pts, Height 14.7 pts Line 4, Width 11.15 pts, Height 15.75 pts
12.0 Steam Power Augmentation System
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The steam injection schematic shows the steam system, fuel delivery system and purge air system (in green, not fully shown). The valves are obtained from the Bolt Standards and are constructed from a large number of individual objects, as a result detailed descriptions of component geometries are not provided.
Piping
Geometry, Pipe Width 7pts Border Color, Black 0 pt Color, Gradient shading Color 1, Red Color 2, 255, 130, 132 Note: direction of shading is consistent with direction of pipe.
Stop Valve Header Text, Black Arial bold 12 The text in the Control Valve is color animated Text: Valve Open, Text “Open”with color Red Valve Closed,Text “Closed”with color Lime Valve is color animated for open and closed states Open, Gradient Shading, T1_L33PL2O eq 1 Color 1, Red Color 2, 255, 227, 198 Closed, Gradient Shading, T1_L33PL2O eq 0 Color 1, 0, 195, 0 Color 2, 198, 255, 198
Status Indicator
Steam Valves
The text in the Status Indicator is color animated Text: Valve Open, Text “Open”with color Red Valve Closed,Text “Closed”with color Lime
Header Text, Black Arial bold 12 Control Valve uses Gradient Shading Color 1, 56, 192, 114 Color 2, White Valve Orifice is color animated for open and closed states Open, Gradient Shading, T1_L30PM3_C eq 0 Color 1, Red Color 2, 255, 195, 198 Closed, Gradient Shading, T1_L30PM3_C eq 1 Color 1, Green Color 2, 198, 255, 198
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Steam Injector
Steam
The Steam injector is identical to the water injector and constructed from 4 individual objects. Object 1, Geometry Width 7.75 pt, Height 6.4 pt Fill Color Black, Gradient to Corner Object 2, Geometry Width 3.9 pt, Height 9.7 pt Fill Color 215, 215, 215 Gradient Vertical Object 3, Geometry Width 7.75 pt, Height 9.7 pt Fill Color 114, 114, 114 Gradient Vertical Object 4, Geometry Width 7.75 pt, Height 6.4 pt Fill Color 97,97,97, Gradient to Corner
The steam object consist of 8 lines Color Aqua, Width 0 pts Geometry Line 1, Width 12.8 pts, Height 13.75 pts Line 2, Width 12.8 pts, Height 11 pts Line 3, Width 12.8 pts, Height 8.25 pts Line 4, Width 12.8 pts, Height 5.5 pts Line 5, Width 12.85 pts, Height 5.5 pts Line 6, Width 12.85 pts, Height 8.25 pts Line 7, Width 12.85 pts, Height 11 pts Line 8, Width 12.85 pts, Height 13.75 pts
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13.0 Frame Animation
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14.0 Multi-Unit Configuration 14.1 Overview CIMPLICITY design standards are directly applicable to multi-unit applications. A single set of screens is used for a multi-unit system using pushbuttons on the Foundation screen for navigation between units. Data for individual units is obtained is by setting the screen variables UNIT, UNIT_NAME and UNIT_NO. In a multi-unit system a CIMPLICITY server can access its own data and can act as a viewer for a maximum of two other computers. The screen variable LOCAL_PROJECT is used to determine if the HMI is operating as a server or as a viewer (LOCAL_PROJECT =0 for Viewer, LOCAL_PROJECT =1 for Server) A Remote system can operate as a server or a viewer Each turbine unit has a single pushbutton used to assign the UNIT, UNIT_NAME and UNIT_NO screen variables. All points within the Gas Turbine 1 Unit_Control.cim file (i.e., L1START, L4) are proceeded by the screen variable ‘UNIT’(Unit_L1START, Unit_L4, Unit_L4T). Thus the L1 buttons Gas Turbine 2 are used to navigate from Unit1 Control to Unit2 Control and the same Gas Turbine 3 CIMPLICITY file may be used.
Gas Turbine 4
This functionality simplifies revision control on multi-unit interfaces. The UNIT variable is assigned values such as ‘T1_’, ‘T2_’… for gas or ‘S1_’, ‘S2_’… for steam, depending on the number of units. Thus, when Unit3 Control is selected, the variable ‘Unit’is assigned. The UNIT_NAME variable is displayed in the upper right hand corner on the turbine banner. The UNIT_NO variable is used to assign object visibility’s to buttons like ‘Tools’or GT# Synch.
14.2 Naming Convention Consider a Multi-Unit system with three servers (SVR1, SVR2, SVR3, a viewer VWR1 , and a remote viewer. The naming convention is shown in the Table. The Unit Variables are initialized at start up Computer Name SVR1 SVR2 SVR3 REM1 Project Name SVR1 SVR2 SVR3 REM1 Unit Variable \\SVR1\Tn_ \\SVR2\T2_ \\SVR3\T3_ \\REM1\Tn_ . For server SVR1 the navigation button Gas Turbine 1 initiates a procedure L1_Gas_Turbine_1 with the associated actions. The variable LOCAL_VARIABLE is set to 1 on SRV1. For the remaining procedures, L1_Gas_Turbine_2 and L1_Gas_Turbine_3 the variable is set to 0 as shown in the example below where n is the unit number.
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For Server SVR1 L1_Gas_Turbine_1 – UNIT, \\SVR1\Tn_ UNIT_NAME, “GTn” UNIT_NO,1 LOCAL_PROJECT,1 L1_Gas_Turbine_2 – UNIT, \\SVR2\T2_ UNIT_NAME, “GT2” UNIT_NO,2 LOCAL_PROJECT,0 L1_Gas_Turbine_3 – UNIT, \\SVR3\T3_ UNIT_NAME, “GT3” UNIT_NO,3 LOCAL_PROJECT,0 For Server SVR2 L1_Gas_Turbine_1 – UNIT, \\SVR1\Tn_ UNIT_NAME, “GTn” UNIT_NO,1 LOCAL_PROJECT,0 L1_Gas_Turbine_2 – UNIT, \\SVR2\T2_ UNIT_NAME, “GT2” UNIT_NO,2 LOCAL_PROJECT,1 L1_Gas_Turbine_3 – UNIT, \\SVR3\T3_ UNIT_NAME, “GT3” UNIT_NO,3 LOCAL_PROJECT,0 For Viewer VWR1, VWR2… . L1_Gas_Turbine_1 – UNIT, \\VWR1\Tn_ UNIT_NAME, “GTn” UNIT_NO,1 LOCAL_PROJECT,0 L1_Gas_Turbine_2 – UNIT, \\VWR1\T2_ UNIT_NAME, “GT2” UNIT_NO,2 LOCAL_PROJECT,0 L1_Gas_Turbine_3 – UNIT, \\VWR1\T3_ UNIT_NAME, UNIT_NO,3 LOCAL_PROJECT,0
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For Remote REM1 L1_Gas_Turbine_1 – UNIT, \\REM1\Tn_ UNIT_NAME, “GTn” UNIT_NO,1 LOCAL_PROJECT,1 L1_Gas_Turbine_2 – UNIT, \\REM1\T2_ UNIT_NAME, “GT2” UNIT_NO,2 LOCAL_PROJECT,1 L1_Gas_Turbine_3 – UNIT, \\REM1\T3_ UNIT_NAME, “GT3” UNIT_NO,3 LOCAL_PROJECT,1 Note: If REM1 is acting as a Server then Local_Project is a 1 and when it is acting as a Viewer it is 0
14.3 Tools Button The tools button in a multi-unit system consist of a number of buttons equivalent to the number of units grouped together as a single object in CIMPLICITY. The visibility of each individual button is controlled by the screen variable UNIT_NO. This button color is OLIVE. This object (group of buttons) overlays a second button color GRAY which has visibility controlled by the screen variable LOCAL_PROJECT.
14.3 Viewer Limitations When CIMPLCITY HMI is acting as a “Viewer”certain functions are not available. These include • • • • •
Valve Calibration Setting Hardware Jumpers Demand IO_Check Viewer Synchronization
These functions are activated by buttons which execute procedures on the CIMPLICITY HMI screens. These buttons overlay duplicate buttons whose visibility is controlled by the variable LOCAL_PROJECT. When the system is a viewer the LOCAL_PROJECT variable is set to zero and the Viewer buttons become. These buttons have a dark gray faceplate. A screen text is also activated which alerts the operator to the viewer limitation.
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