6/24/2016
Design Calculations of Lightning Protection Systems – Part seventeen ~ Electrical Knowhow
Home
PDF Courses
Electrical Courses
Download Library
Sizing MEP Equipment
Inspection Courses
Quiz and Answer
Follow Us
Search
Design Calculations of Lightning Protection Systems – Part seventeen In Article " Design Calculations of Lightning Protection Systems – Part Two ", I indicated the lightning protection design process involves a number of design steps as in below Fig.
ELECTRICAL LIBRARY
Electrical Design Criteria
Electrical Works’ Method Statements
Manufacturers Lists for Electrical Products
Electrical
Electrical Drawing Details
(3) Online PDF COURSES
Electrical Load Estimation Course An Introduction to Heating, Ventilation and Air Conditioning (HVAC) Systems An Introduction to Lighting Design
The Lightning Protection Design Process
An Introduction to Electrical Motor Basics
ELECTRICAL BOOKS
Step#1: Characteristics of the Structure to Be Protected Explained in Article " Design Calculations of Lightning Protection Systems – Part Two "
Loresco O
Electrical Books & Design Guides
Code of Practice for Energy Efficiency of Electrical Installations
Step#2: Risk Assessment Study
Guide for electrical design engineers
Maintenance Manager's Guide to Power Quality
Power Quality & Utilization Guide Engine Application and Installation Guide
Also, In above Article, I indicated that the risk assessment study can be done by (4) different methods as follows: Methods Of Calculations For Risk Assessment Study
Articles
Dwelling
Design Calculations of Lightning Protection Systems – Part
http://www.electricalknowhow.com/2014/05/RollingSphereMethodforLightningProtectionDesign.html
1/14
6/24/2016
Design Calculations of Lightning Protection Systems – Part seventeen ~ Electrical Knowhow Guide
Liquid Cooled Genset Application Manual
First: Manual Method (Equations And Tables Method) as per IEC 62305‐2
MV Design & Technical Guide
MV Application catalogue
Electrical and Traffic Engineering Manual
First: Manual Method (Equations And Tables Method) as per NFPA 780
ELECTRICAL SOFTWARE
Electrical Software Programs
Riesgo Software For Performing The Risk Assessment Study StrikeRisk V5.0 for performing the Risk Assessment Study RAPAL Software for performing the Risk Assessment Study EricoGEM Software Program for Earthing Calculations Visual Professional Edition Software (6) Print the Results by Using the Print Editor Visual Professional Edition Software (5) Inserting Calculation Planes
Second: Software Method For Performing The Risk Assessment Study Third: Excel Sheets Method For Performing The Risk Assessment Study Fourth: Online Calculators Method Used for Need for Lightning Protection calculations
Two Design Calculations Three Design Calculations Four Design Calculations Five Design Calculations Six Design Calculations Seven Design Calculations Eight Design Calculations Nine Design Calculations Ten Design Calculations Eleven Design Calculations Twelve
of Lightning Protection Systems – Part
Dwelling U
of Lightning Protection Systems – Part of Lightning Protection Systems – Part of Lightning Protection Systems – Part of Lightning Protection Systems – Part
GE Lightin
of Lightning Protection Systems – Part of Lightning Protection Systems – Part of Lightning Protection Systems – Part of Lightning Protection Systems – Part
Selective
of Lightning Protection Systems – Part
Design Calculations of Lightning Protection Systems – Part thirteen
Design Calculations of Lightning Protection Systems – Part Fourteen
Step#3: Selection Of External LPS Type and Material Explained in Article " Design Calculations of Lightning Protection Systems – Part Fifteen "
Visual Professional Edition Software (4) Inserting Luminaires Visual Professional Edition Software (3) Starting Steps
Step#4: Sizing of Air Termination System Components
Visual Professional Edition Software (2) Checking the Default Settings Visual Professional Edition Software (1) – Understanding the Program Interface CalcuLux Software(1) Main Window and Bar Menus
In Article " Design Calculations of Lightning Protection Systems – Part Sixteen ", I explained the following points: Types and forms of Strike Termination Subsystem,
CalcuLux Software(2) Checking The Default Settings CalcuLux Software(3) Example for Ligthing design of an Office
CalcuLux Software Part Four
CalcuLux Software Part Five
Sizing of Air Terminals Based on IEC 62305‐3 and Based on BS EN 62305‐3, Sizing of Natural Air Terminals, Positioning / Placement of Air Termination System Components. The Class of LPS/LPL influences on the (3) Positioning Methods. Today, I will explain in detail the (3) Positioning Methods for Air Termination system which were:
1. The Rolling Sphere Method (RSM), 2. The Protective Angle Method (PAM), 3. The Mesh Method.
CalcuLux Software Part Six
CalcuLux SoftwarePart Seven
For more information, please review the following Articles: IDSpec Software
Design Process for Lightning Protection Systems Design Calculations of Lightning Protection Systems – Part One
DIALux Lighting Software Program Blue Version
(8) differen DIALux Lighting Software Program Red Version
http://www.electricalknowhow.com/2014/05/RollingSphereMethodforLightningProtectionDesign.html
2/14
6/24/2016
Design Calculations of Lightning Protection Systems – Part seventeen ~ Electrical Knowhow
DIALux Indoor Lighting Calculations Menu Options
Step#4: Sizing and Positioning of Air Termination System Components ‐ Continued
HOW TO
1‐ The Rolling Sphere Method (RSM)
Conducto
Conducto
Write Technical Specifications for Lightning Protection Systems Determine The Number Of Down Conductors of LPS Perform Need for Lightning Protection Calculations by (4) Different Methods
: 1.1 The striking distance approach
Sizing Ove Perform Grounding Calculations by (6) Different Methods Size Earthing Conductors Using NEC Tables Size Earthing Conductors Using BS 7671
Select the Best Earthing System
For lightning flashes to earth, a downward leader grows step‐by‐step in a series of jerks from the cloud towards the earth. When the leader has got close to the earth within a few tens, to a few hundreds of metres, the electrical insulating strength of the air near the ground is exceeded.
Calculatio
A further “leader” discharge similar to the downward leader begins to grow towards the head of the downward leader: the upward leader.
Electrical
Upward leader will be launched at points of greatest electric field intensity (see Fig.1) and can move in any direction towards the approaching downward leader. It is for this reason that lightning can strike the side of tall structures rather than at their highest point.
Electrical
Electrical
Calculate Voltage Drop as per U.S. and European Methods Use NEC Annex B Tables in Conductor Ampacity Calculations Perform Conductor Ampacity Calculations Using NEC under Engineering Supervision Method Perform Conductor Ampacity Calculations Using NEC Section 310.15 Tables Size Overcurrent Protection Devices
Calculate the Total Demand Electrical Load for NonDwelling Buildings Calculate Electrical Demand Load for Dwelling Buildings as per NEC Optional Method Calculate Electrical Demand Load for Dwelling Buildings as per NEC Standard Method Calculate generaluse receptacles load in a dwelling unit Calculate Maximum Permissible Number Of Lighting Fixtures On A General Lighting Branch Circuit Calculate Track Lighting Load Calculate The Minimum Number Of General Lighting Branch Circuits For Any Building
Fig.1:Development of downward leader striking distance The distance of the last step of a downward leader is termed the striking distance and is determined by the amplitude of the lightning current. This striking distance can be represented by a sphere with a radius equal to the striking distance (see Fig.2). The striking distance r is given by:
r = 10 I 0.65 Where I is the peak current of the resulting stroke.
Calculate General Lighting Branch Circuit Load For Any Building Calculate Sign And Outline Branch Circuits Load Calculate Show Window Lighting Load Calculate The Minimum number of receptacle branch circuits for bank or office buildings Calculate the Maximum allowable number of receptacles on a branch circuit in a dwelling unit
http://www.electricalknowhow.com/2014/05/RollingSphereMethodforLightningProtectionDesign.html
3/14
6/24/2016
Design Calculations of Lightning Protection Systems – Part seventeen ~ Electrical Knowhow
Estimate Preliminary Load By Using Area Method
Checklist f Estimate Preliminary Load By Using The Building Area Method
Checklists
Estimate Preliminary Load By Using SpaceBySpace Method (Functional Area Method)
Checklist Commissi
Design Outdoor Lighting By Using Isolux Diagram Method Design Outdoor Lighting By Using The BeamLumen Method As Per IES Design Outdoor Lighting By Using The BeamLumen Method As Per CIE Design Outdoor Lighting By Using PointByPoint Method Design Interior Lighting By Using By Using Quick Estimate Charts
Fig.2: striking distance
Design Interior Lighting By Using Watt Per Square Feet Method Design Interior Lighting By Using Point By Point Method
Lightning
Notes to the above formulas:
Design Interior Lighting By Using The Zonal Cavity (Lumen) Method
The larger the amount of charge carried by the lightning leader, the larger the resulting lightning current, the greater will be the distance at which this happens.
Build Preliminary Single Line Diagram Like Professionals
The head of the downward leader approaches the objects on the ground, unaffected by anything, until it reaches the final striking distance.
Make A Preliminary Design Like Professionals
It is more difficult for an air‐terminal to intercept a smaller lightning flash than a larger flash, as the smaller flash must approach closer to the air‐terminal before the upward leader is launched.
Write Electrical Design Criteria Like Professionals Specify The Required Type Of GeneralUse Receptacles For Each Area In A Dwelling Unit
To protect the structure against smaller lightning flashes, air‐terminals must be spaced closer together. For smaller lightning flashes there is a risk that an air terminal may not be close enough to intercept the down leader, thus a closer structural point releases an upward leader which intercepts the flash (i.e. the building is struck).
Distribute GeneralUse Receptacle Loads In A Dwelling Unit
Course EE
Course EE
Course EE
Course Lig
Select Receptacle Rating For A Branch Circuit In A Dwelling Unit
1.2 Relation between Lightning Protection Levels and Rolling Sphere Radius CONTACT FORM Name
The below Table#1 indicates the following: The Lightning Protection Levels LPL, Minimum current level to be protected against, Probability percentages that lightning may be greater than these levels,
Email *
The rolling sphere radius used in the rolling sphere design method.
Course E Message *
Send
Table#1 http://www.electricalknowhow.com/2014/05/RollingSphereMethodforLightningProtectionDesign.html
4/14
6/24/2016
Design Calculations of Lightning Protection Systems – Part seventeen ~ Electrical Knowhow
Also, The above Table#1 explains the relation between Lightning protection levels and rolling sphere radius as in the following examples:
Example#1: Suppose that a lightning protection system to provide LPL I such that 99% of all lightning flashes are intercepted (all those of 3 kA or greater). There is only a 1% probability that lightning may be smaller than the 3 kA minimum, and may not be close enough to an air‐terminal to be intercepted. It should be noted that flashes of less than 3 kA are rare, and typically would not be expected to cause damage to the structure. Protection greater than LPL I (99%) would require significantly more material, is not covered by the standard and generally is not required for commercial construction. Result: The lower lightning protection levels (LPL II, III & IV) each increase the air‐terminal spacing, reducing their ability to capture smaller lightning flashes, thus reducing overall the percentage of lightning events they can protect against.
Example#2: Suppose that a lightning protection system to provide LPL IV, designed using the rolling sphere method, would use air‐terminals placed using a rolling sphere radius of 60 m. These air‐terminals would be positioned such that they would capture all lightning flashes of 16 kA or greater, thus offering protection to at least 84% of the lightning (the term “at least” is used to indicate that the percentage of lightning captured might be greater, since smaller lightning flashes could be captured if they were closer to the air‐terminal). Result: To offer a greater lightning protection level (e.g. LPL I, II or III) a smaller rolling sphere radius would be used. This would result in a reduced spacing between air‐terminals (more air‐terminals), thus positioning the air‐terminals to capture smaller lightning flashes, and increasing the total percentage of lightning flashes captured.
1.3 The Rolling Sphere Method Protection Applications The rolling sphere methods can be used for the following applications:
1. Rolling sphere method with rod air‐terminations, 2. Rolling sphere method and mesh/catenary conductors, 3. Rolling sphere method and Tall structures.
1.3.1 Rolling Sphere Method With Rod Air‐Terminations When rods are to be used as the air‐termination for the protection of plane surfaces (see Fig.3), the following formula can be used:
d = 2 √ (2rh – h2) Where: d = distance between two rods (m) r = radius of the rolling sphere (m) h = height of the rods (m)
http://www.electricalknowhow.com/2014/05/RollingSphereMethodforLightningProtectionDesign.html
5/14
6/24/2016
Design Calculations of Lightning Protection Systems – Part seventeen ~ Electrical Knowhow
Fig.3: Rolling Sphere Method With Rod Air‐Terminations
The following Table#2 shows some examples of rolling sphere protection distance (distance between Air terminals) according to the Air terminals height and the Rolling Sphere Radius according to lightning protection level LPL.
Table#2
When rods are to be used as the air‐termination for protection of roof top items/structures (see Fig.4) and The arrangement of the air‐termination rods, over which no cable is normally spanned, means that the sphere does not “roll on rails” but “sits deeper” instead, thus increasing the penetration depth () of the sphere. In this case the following formula of sphere penetration distance can be used:
p = r – √ (r2 –d2/4) Where: p = penetration distance (m)( part of the sphere below the horizontal lines between top of air terminals) r = radius of the rolling sphere (m) d = Distance between two air‐termination rods or two parallel air‐termination conductors (m)
http://www.electricalknowhow.com/2014/05/RollingSphereMethodforLightningProtectionDesign.html
6/14
6/24/2016
Design Calculations of Lightning Protection Systems – Part seventeen ~ Electrical Knowhow
Fig.4: Penetration distance of rolling sphere
The following Table#3 shows Rolling sphere penetration distance according to the distance between Air rods and the Rolling Sphere Radius according to lightning protection level LPL.
Table#3
Note: The height of the air‐termination rods h should always be greater than the value of the penetration depth p determined to ensure that the rolling sphere does not touch the structure to be protected.
1.3.2 Rolling Sphere Method And Mesh/Catenary Conductors Where the rolling sphere method is to be used to evaluate the protection provided by mesh conductors or network of catenary wires, the mesh must be mounted at some distance above the roof (see Fig.5), to ensure the rolling sphere does not touch its surface in a similar way to the catenary conductors.
http://www.electricalknowhow.com/2014/05/RollingSphereMethodforLightningProtectionDesign.html
7/14
6/24/2016
Design Calculations of Lightning Protection Systems – Part seventeen ~ Electrical Knowhow
Fig.5: Rolling Sphere Method And Mesh Conductors
Also, As with a free standing mast, catenary conductors can be used to keep the rolling sphere away from the structure to be protected (see Fig.6). One or more catenary conductors may be utilised to ensure that the sphere does not come into contact with any part of the structure’s roof.
Fig.6: Rolling Sphere Method And Catenary Conductors
If the system is required to be isolated from the structure then a conductor suspended between two free standing masts may be employed. This arrangement is suitable for small sensitive structures such as explosive stores. In a non isolated system, a catenary conductor may be used to protect larger items of roof mounted equipment from a direct strike (see Fig.7).
http://www.electricalknowhow.com/2014/05/RollingSphereMethodforLightningProtectionDesign.html
8/14
6/24/2016
Design Calculations of Lightning Protection Systems – Part seventeen ~ Electrical Knowhow
Fig.7: catenary conductors used to protect larger items of roof mounted equipment
The two formulas in the case of rod air‐terminations can be used also in case of using mesh/catenary conductors. The distance/height of the mesh/catenary replaces the rod distance/height. As in fig.4 Note that the distance for penetration or protection distance is the diagonal of the grid (distance between points A & B).
1.3.3 Rolling Sphere Method And Tall Structures Research shows that it is the upper 20% of the Tall structure that is most vulnerable to side strikes and potential damage (see Fig.8).
http://www.electricalknowhow.com/2014/05/RollingSphereMethodforLightningProtectionDesign.html
9/14
6/24/2016
Design Calculations of Lightning Protection Systems – Part seventeen ~ Electrical Knowhow
Fig.8: Rolling Sphere Method And Tall Structures
Case#1: Buildings Above 60 m High In the IEC standards, for buildings above 60 m, protection is required to the sides of the upper 20% of height. The same placement rules used for roofs should apply to the sides of the building. While the mesh method is preferable, particularly if using natural components, protection is permitted using horizontal rods and rolling sphere method. However, horizontal rods on most structures are impractical due to window washing access equipment, etc.
Case#2: Buildings Less Than 60 m High Note that for structures less than 60 m high the risk of flashes to the sides of the building is low, and therefore protection is not required for the vertical sides directly below protected areas.
Case#3: Buildings Taller Than 120 m High For structures taller than 120 m, the standard recommends that all parts above 120 m be protected. It is expected that due to the height and nature of such a structure, it would require a design to LPL I or II (99% or 97% protection level). For tall buildings, the actual risk of flashes to the side are estimated by the industry to be less than 2%, and typically these would be the smaller lightning flashes, e.g., from branches of the downward leader. Therefore, this recommendation would only be appropriate for high risk locations or structures.
Note For Buildings Taller Than 30 m: For buildings taller than 30 m, additional equipotential bonding of internal conductive parts should occur at a height of 20 m and every further 20 m of height. Live circuits should be bonded via SPDs.
1.4 How To Apply The Rolling Sphere Method for Lightning Protection Design?
http://www.electricalknowhow.com/2014/05/RollingSphereMethodforLightningProtectionDesign.html
10/14
6/24/2016
Design Calculations of Lightning Protection Systems – Part seventeen ~ Electrical Knowhow The basic concept of applying the rolling sphere to a structure is as follows: Step#1: Scale The building / structure to be protected (e.g. on a scale of 1:100) (see Fig.9) Depending on the location of the building under design, it is also necessary to include the surrounding structures and objects with the same scale of the building, since these could act as “natural protective measures” for the building under design.
Fig.9: Scaled Building and Scaled Rolling Sphere of LPL I
Step#2: calculate The radius of the sphere which must be equal to the striking distance associated with the minimum current level for the chosen lightning protection level.
Step#3: Scale the radius r of the “rolling sphere” calculated from Step#2 with the same scale of the building (see Fig.9). (For example, if the building with scale 1:100, from Table#1 for a lightning protection levels I, the rolling sphere radius will be 20 cm and for LPL II will be 30 cm and for LPL III will be 45 cm).
Step#4: Make a circular path around the building under design with distance apart equal to the scaled rolling sphere radius (see Fig.10). This circular path will terminate on the corner of the building.
Fig.10: Circular path around the building http://www.electricalknowhow.com/2014/05/RollingSphereMethodforLightningProtectionDesign.html
11/14
6/24/2016
Design Calculations of Lightning Protection Systems – Part seventeen ~ Electrical Knowhow
Step#5: Roll an imaginary sphere over the surface of the structure in all directions (see Fig.11).
Fig.11: imaginary sphere rolled over the surface of the structure in all directions
Note: the rolling process of the imaginary sphere is controlled by the distance between Air terminals as given in part#3 in this Article i.e. each roll is far from the previous one by the allowable distance between air terminals calculated from part#3.
Step#6: Where the sphere touches the building, A lightning protection would be needed by placing Air Terminal. Using the same logic, the areas where the sphere does not touch the Building (see shaded area in Fig.11) would be deemed to be protected and would not require protection. Note: Generally a lightning protection system is designed such that the rolling sphere only touches the lightning protection system and not the structure i.e. The air termination system is placed such that the sphere only touches the air‐terminations, and not the structure.
In the next Article, I will explain other Positioning Methods for Air Termination system: The Protective Angle Method (PAM) and The Mesh Method. Please, keep following.
Back To Course Lightning‐2: Lightning Protection System Design and Calculations
http://www.electricalknowhow.com/2014/05/RollingSphereMethodforLightningProtectionDesign.html
12/14
6/24/2016
Design Calculations of Lightning Protection Systems – Part seventeen ~ Electrical Knowhow You might also like:
Design Calculations of Lightning Protection Systems – ...
Design Calculations of Lightning Protection Systems – ...
Design Calculations of Lightning Protection Systems – ...
Design Calculations of Lightning Protection Systems – ...
Design Calculations of Lightning Protection Systems – ... Linkwithin
+3 Recommend this on Google
Post a Comment Leave a comment to help all for better understanding
Enter your comment...
Comment as:
Publish
Unknown (Google)
Sign out
Notify me
Preview
<< Design Calculations of Lightning Protection Systems – Part Eighteen
Home
Design Calculations of Lightning Protection Systems – Part Sixteen >>
Subscribe to: Post Comments (Atom)
Join this site with Google Friend Connect
Members (2370) More »
Already a member? Sign in
NEW ARTICLES
HOW TO JOIN OUR SITE?
POPULAR ART
Electrical Wiring Diagrams for Air Con Two Classification of Electric Motors Electrical Motors Basic Components
Electrical Wiring Diagrams for Air Con One
Elevators Types and Classification P
Basic Elevator Components Part Tw Classification of Electric Motors Part
http://www.electricalknowhow.com/2014/05/RollingSphereMethodforLightningProtectionDesign.html
13/14
6/24/2016
Design Calculations of Lightning Protection Systems – Part seventeen ~ Electrical Knowhow
Basic Elevator Components Part On
Electrical Wiring Diagrams for Air Con Three Phase ShiftingTransformers
Invite your friends on Facebook
ElectricalKnowhow Like Page
7.6k likes
CopyRight @ 2013 Electrical Knowhow Privacy Policy
http://www.electricalknowhow.com/2014/05/RollingSphereMethodforLightningProtectionDesign.html
14/14