PLA-6997, Response to Request for Additional Information Regarding Changes to Technical Specification Surveillance Requirements to Increase Diesel Generator Minimum Steady State Voltage
| ML13130A130 | |
| Person / Time | |
|---|---|
| Site: | Susquehanna  |
| Issue date: | 05/10/2013 |
| From: | Franke J Susquehanna |
| To: | Office of Nuclear Reactor Regulation, Document Control Desk |
| References | |
| PLA-6997 EC-024-1031, Rev 0 | |
| Download: ML13130A130 (20) | |
Text
Jon A. Franke Site Vice President U.S. Nuclear Regulatory Commission Attn: Document Control Desk Washington, DC 20555-0001 PPL Susquehanna, LLC 769 Salem Boulevard Berwick, PA 18603 Tel. 570.542.2904 Fax 570.542.1504 jfranke@pplweb.com SUSQUEHANNA STEAM ELECTRIC STATION RESPONSE TO REQUEST FOR ADDITIONAL INFORMATION REGARDING CHANGES TO TECHNICAL SPECIFICATION (TS)
SURVEILLANCE REQUIREMENTS (SR) TO INCREASE DIESEL GENERATOR MINIMUM STEADY STATE VOLTAGE PLA-6997 Docket Nos. 50-387 and 50-388
References:
"Susquehanna Steam Electric Station Proposed Amendment No. 310 to License NPF-14 and Proposed Amendment No. 282 to License NPF-22:Change to Technical Specification Surveillance Requirements (SR) 3.8.1.9, 3.8.1.11, 3.8.1.12, and 3.8.1.19 to Increase Diesel Generator Minimum Steady State Voltage, " dated September 18, 2012.
- 2) Letter from NRC to PPL, "Susquehanna Steam Electric Station, Units 1 and 2-Request for Additional Information Regarding Request for Changes to Technical Specification Surveillance Requirements to Increase Diesel Generator Minimum Steady State Voltage (TAC Nos. ME9607and ME9608),"
dated February 22, 2013.
PPL Susquehanna, LLC (PPL) submitted a proposed amendment to the Susquehanna Steam Electric Station (SSES) Unit 1 and Unit 2 Technical Specification (TS)
Surveillance Requirements (SR) 3.8.1.9, 3.8.1.11, 3.8.1.12, and 3.8.1.19 in Reference 1.
On February 22, 2013, the NRC requested additional information (RAI) via Reference 2.
The enclosures to this letter contain PPL' s response to the RAI.
There are no new commitments contained in this letter.
Please direct any questions or requests for additional information to Mr. Duane L. Filchner at (610)774-7819.
TM
Document Control Desk PLA-6997 I declare under penalty of petjury that the foregoing is true and cmTect. - Response to NRC Request for Additional Information - Calculation EC-024-1 031, "DG Steady State Output Voltage for Surveillance Test in Isochronous Mode" Copy:
Mr. W. M. Dean, NRC Region I Administrator Mr. P. W. Finney, NRC Sr. Resident Inspector Mr. J. A. Whited, NRC Project Manager Mr. L. J. Winker, PA DEP/BRP to PLA-6997 Response to NRC Request for Additional Information to PLA-6997 Page 1 of2 Response to NRC Request for Additional Information NRC QUESTION 1:
Please address the intent of the voltage range in the SRs not being changed by the proposed LAR.
PPL RESPONSE:
The only specific voltage being changed by this proposed License Amendment Request (LAR) is the minimum steady state output voltage of the diesel generator (DG) when operating in the isochronous (emergency) mode. The steady state output voltage when operating in the droop (test) mode is not being changed because when operating in the test configuration the DG output voltage is determined by the electrical power grid to which it is connected.
The specified maximum steady state output voltage of 4400 V is not being changed in the SRs. This value is equal to the maximum operating voltage specified for 4000 V motors.
It ensures that for a lightly loaded distribution system, the voltage at the terminals of 4000 V motors is no more than the maximum rated operating voltages.
The SRs for demonstrating OPERABILITY of the DGs are in accordance with the recommendations of Regulatory Guide (RG) 1.9 "Application and Testing of Safety-Related Diesel Generators in Nuclear Power Plants." The voltage ranges specified in the SRs are established consistent with RG 1.9.
The new minimum steady state output voltage of 4000 V is the value assumed in the degraded voltage analysis, which represents approximately 96% of the nominal 4160 output voltage. This value allows for voltage drop to the terminals of 4000 V motors whose minimum operating voltage is specified as 90% or 3600 V. It also allows for voltage drops to motors and other equipment down through the 120 V level where minimum operating voltage is also usually specified as 90% of name plate rating.
NRC QUESTION 2:
Describe how the steady state voltage requirements, cunently associated with the droop mode SRs, will demonstrate DG operability if the safety busses are below the minimum required 4000 Volts as proposed in the LAR.
The LAR proposes a new voltage range of>""" 4000 Volts and <= 4400 Volts for SRs 3.8.1.9, 3.8.1.11, 3.8.1.12, and 3.8.1.19. The cunent requirements of induction to PLA-6997 Page2 of2 motors and other voltage sensitive equipment vaty according to available voltage and frequency.
PPL RESPONSE:
The steady state output voltage of the DG, when operating in the droop mode, is established by the electrical power grid to which it is paralleled. The grid stability and voltage are ve1ified to be greater than 4000 V prior to performing the DG surveillances in the droop mode. This demonstrates the capability of the DG to produce >= 4000 V steady state output voltage and to supply the connected load on the grid.
The DG operability in the isochronous mode is demonstrated by perfmmance of Loss of Coolant Accident I Loss of Offsite Power (LOCAILOOP) surveillance testing. The acceptance criteria for this surveillance requires that the DG is capable of supplying loads at >= 4000 V when operating in the emergency mode.
NRC QUESTION 3:
Provide excerpts from calculations that validate DG loading when operating at extremes of the proposed voltage range.
PPL RESPONSE:
SSES DG loading calculations, in general, are based on nominal voltages. A formal calculation to validate DG loading when operating at the extremes of the proposed voltage range ( 4000 V-4400 V) was not perfmmed since the proposed LAR revises only the steady state lower voltage limit in the conservative direction.
The proposed DG steady state output voltage of 4000V was determined based on Calculation EC-024-1 031, Revision 0. (See Enclosure 2 below). The following should be noted as considerations and the results determined for the minimum acceptable DG steady state voltage:
Upper value of the degraded voltage relay reset voltage (3938.8V), see Section 3.1, Worst Case voltage drop from the DG to the 4kV bus (48.3V), see Section 4.4, Any unacceptable potential interactions with other bus voltage settings, see Section 4.6, Surveillance Steady State DG minimum output voltage determination of 4000 V, see Section 4.5.
to PLA-6997 Calculation EC-024-1031 DG Steady State Output Voltage for Surveillance Test in Isochronous Mode
For Information Only
- >>2. TYPE:
- )5. UNIT:
NUCLEAR ENGINEERING CALCULATION COVER SHEET NEPM-QA-0221-1 CALC
~3. NUMBER:
EC-024-1031 0
- )>6. QUALITY CLASS:
Q
- 1. Page 1 of 14 Total Pa es 14
~4. REVISION:
0 ------
>7. DESCRIPTION:
DG Steady State Output Voltage for SUJveillance Test in Isochronous Mode
- 8. SUPERSEDED BY:
- 9. Alternate Number:
N/A
- 10. Cycle: --'-"NI"""A,____ ____ _
- 11. Compu1er Code/Model used:
N/A
- 12. Discipline:
E
~ 13. Are any results of this calculation described in the Licensing Documents?
~ Yes, Refer to NDAP-QA-0730 and NDAP-QA-()731 0 No
} 14. Is this calculation changing any method or evaluation described in the FSAR and using the results to support or change the FSAR? (Refer to PPL Resource Manual for definition of FSAR) 0 Yes, 50.59 screen or evaluation required.
183 No
} 15. Is this calculation Prepared by an External Organization?
0 Yes
[8] No EG771 Qualifications may not be required for individuals from external organizations (see Section 7.4.3).
>>16. Prepared by1:
J. Rothe Pnnt Name(EG771 QualifiCation Required)
>>17. Reviewed by1:
M. Desai Pdnt Name(EG771 Qualir~eation Required)
- lo>18. Verified by:
M. Desai
}19. Approved by:
Ptfnt Nama (EG771 & QADR Quallf!Cat/on 9d)
~Bmd Plfnt Nama (Qualified per NEPM-QA-0241 and comply with Section 7.8 of NEPM-QA.(J221)
~20. Accepted by:
N/A Print Name(EG771 Qualification Required Signature Datil and comply with Section 7.9 of NEPM-QA-0221) 1For Fire Protection related ~!culalions see Section 7.4.3.n for additional qualification requirements.
ADD A NEW COVER PAGE FOR EACH REVISION
~Verified Fields
} REQUIRED FIELDS FORM NEPM-QA-0221-1, Re~. 11, Page 1 of 14 (Electronic Form)
EC-024-1 031 Page2
- 1.
Purpose The purpose of this calculation is to determine a minimum DG steady state output voltage value for use in DG surveillances in the isochronous mode.
Acceptance criteria The DG steady state output voltages used in the applicable surveillances should be above minimum required steady state equipment voltages and be above the upper value of the degraded grid relay reset voltage.
- 2.
Conclusions A value of 4000 VAC steady state AC volts meets the acceptance criteria and is acceptable for use in the DG surveillance procedures.
- 3.
Inputs 3.1 Upper value of degraded grid relay reset voltage 3938.8 volts per EC-004-1031.
3.2 DG A-D continuous rating 4000 KW at 0.8pf per FSAR.
3.3 DG-E continuous rating 5000 KW at 0.8pf per FSAR.
3.4 Cable impedances from PPL ETAP library etaplib5.1ib at 90 degrees C. The library values are from EC-004-1034 with temperature correction to 90 degrees
- c.
3.5 Unit 1 and Unit 2 Technical Specification Bases 3.8.1 indicate that the existing steady state surveillance value of 3793 volts meets minimum required steady state equipment voltages. Specifically, both the Unit 1 and Unit 2 Technical Specification Bases state, "Where the SRs discussed herein specify voltage and frequency tolerances, the following summary is applicable. The minimum steady state output voltage of 3793 V is the value assumed in the degraded voltage analysis and is approximately 90% of the nominal 4160 V output voltage. This value allows for voltage drop to the terminals of 4000 V motors whose minimum operating voltage is specified as 90% or 3600 V. It also allows for voltage drops to motors and other equipment down through the 120 V level where minimum operating voltage is also usually specified as 90% of name plate rating."
Accordingly, the more limiting of the acceptance criteria is to be above the upper value of the degraded grid relay reset voltage which is greater than 3793 V.
3.6 For the purposes of this calculation, due to the conservatisms of this calculation and the balanced nature of a large percentage of the DG loads, it is reasonable to consider the DG to have balanced loads.
- 4.
Method 4.1 Method Overview The method used is to determine the worst case voltage drop from the Diesel Generator to an associated 4 KV switchgear bus. This worst case voltage drop is then added to the upper value of degraded grid relay reset voltage {Input 3.1). This method is used because the degraded grid voltage is at the 4KV bus and the surveillance voltage value is based on the DG output voltage. A voltage value equal to or above this summed value
EC-024-1031 Page 3 is selected. This establishes a steady state DG voltage that would not result in actuation of the degraded grid relay scheme. The selected value is then evaluated to ensure that it is compatible with other setting values to which it might be related. Determining the worst case voltage drop requires determining the worst case cable impedance between the Diesel Generator and the 4KV bus and determining the maximum steady state current. This allows calculation of the associated voltage drop and of the required DG voltage to meet the acceptance criteria.
4.2 Worst case cable impedance Figures 1 through 4 illustrate cable types and lengths for the situation where DG-E is substituted for DG-A through D respectively. Figure 5 provides a typical and more comprehensive illustration showing when DG-E is not substituted and DG-A is aligned to the 4KV bus.
Referring to Figure 5, when DG-E is not substituted, the cable lengths shown from DG-E to OA510A02 are replaced by DG-A cables AFOG2401F and G (F10's) at 49ft each and AFOG2401 J and Hat 114ft each (H01's). These cables add up to less impedance compared to using the cables when DG-E is substituted. A review of Table 1 for the analogous cables for DG-B, C, and D shows that in all cases, as expected, the lengths when DG-E is substituted are greater than when DG-E is not substituted, and the corresponding circuit impedance is greater with DG-E substituted.
Also, in all cases the cable length to the 4KV buses for Unit 2 is greater than that to the 4KV buses for Unit 1. Total lengths are based upon 4KV buses for Unit 2 and it is conservatively assumed that all current from each DG is supplied to its 4KV bus for Unit
- 2. This provides the worst case voltage drop for each case.
The worst case cable lengths are for DG-E substituted for A, and DG-E substituted for D.
The worst case impedance can be determined as follows:
F rom ETAP l'b t
l'b5 l'b t d
1 rafY e apll
- 1 a 90 egrees c Material Cable Code R/1000 ft X/1000 ft Cu H01 0.022 0.089 AI F10 0.025 0.0341 DG-E for A Length*R/2000{Note 1)
Length*X/2000 tNote 1J Len_g_th H01 780 0.00858 0.03471 Length F10 615 0.007688 0.010486 Total Rand X 0.016268 0.045196 Total Z 0.048035 Angle 70.18 degrees (SQRT(R2+X2))
DG-E forD Length*R/2000 (Note l)
Length*X/2000 {Note 1>
Length H01 810 0.00891 0.036045 Length F10 552 0.0069 0.009412
Total Rand X Total Z 0.048128 iSQRT(R2+X2))
0.01581 Angle 70.82 degrees EC-024-1031 Page4 0.045457 Note 1: Note that all conductors are doubled up, cuttmg the effective resistance in half.
This is why the devisor is 2000 and not 1000. Where the paralleled cable lengths are different, the longer length is conservatively used.
To determine which case represents the worst voltage drop will require determining the voltage drop for each case.
4.3 Maximum steady state current It is appropriate to base the maximum steady state current on the DG-A through D rating rather than the higher rating of DG-E. This is because steady state loads must stay within the capability of the lower machine rating.
The highest DG load shown in the FSAR diesel loading tables is in FSAR table 8.3-3 which shows a maximum steady state diesel load of 3976.85 KMI (DG-A). This is close to the 4000 KW machine nominal rating. For purposes of determining the maximum steady state current, a steady state loading of 4000 KW will be used. Using a power factor of 0.8 from the FSAR yields a KVA of 4000/0.8 = 5000 KVA.
Amps =KVA*1000/ (4160*SQRT 3) =
5000*1000/ (4160*SQRT 3) =694.75 amps. Round to 695 amps Maximum steady state current = 695 amps 4.4 Voltage Drop Since the machine rating of 5000 KVA and 4000 KW uses a 0.8 power factor, the voltage drop calculation will also use that power factor. Per input 3.6, the calculation is based on balanced loads.
The following formula is the approximate formula for line to neutral voltage drop:
Vdrop line to neutral = I(R cos e +X sin B)
Reference:
Industrial Power Systems Handbook page 234.
The error introduced by using the approximate formula is minor, and is enveloped by the rounding of values in the subsequent section, "Determination of surveillance voltage."
Vdrop DG-E substituted for DG-A:
Vdrop line to neutral= 695*({0.016268*0.8) + {0.045196*0.6)) = 27.89 volts Vdrop= line to line= (SQRT(3))* Vdrop line to neutral= 48.3 volts Vdrop DG-E substituted for DG-D:
EC-024-1031 Page 5 Vdrop line to neutral= 695*((0.01581*0.8) + (0.045457*0.6)) = 27.74 volts Vdrop= line to line = (SQRT(3))* Vdrop line to neutral ::: 48.1 volts DG-E substituted for A is the worst case voltage drop of 48.3 volts 4.5 Determination of surveillance voltage The principle used was that the DG steady state output voltages used in the applicable surveillances should be above minimum required equipment voltages ( part of the existing Tech Spec bases) and be above the upper end of the degraded grid relay reset value.
The diesel surveillance measures DG output voltage. The degraded grid relays monitor voltage at the 4KV bus. Therefore, the value chosen as the minimum acceptable DG steady state voltage needs to consider:
(1) The upper end of the degraded grid relay reset value (3938.8 volts) (Input 3.1)
(2) The voltage drop from the DG to the 4 KV bus (48.3 volts) (Calculated in 4.4)
(3) Any unacceptable potential interactions with other settings. (None on basis of the principle for the surveillance test that voltages be above degraded grid reset value.)
Rounding voltages yield the following:
3940 volts + 50 volts = 3990 volts.
Per discussion with System Engineers R. Bogar and L. Casella, this is rounded to 4000 volts.
4.6 Potential Interaction with other settings Other settings provided by relay and test, S. Brylinsky:
PDP-4 DG VR Emergency Setpoints 4050-4350
Reference:
Procedure MT-RC-063 This setting indicated that the DG voltage regulator will control voltage to a minimum value of 4050 volts which is above the proposed surveillance voltage. As such, these settings would not prevent the surveillance from being successful.
27-1&2 Permissive to Close Diesel Breaker 3945 - 4106 Reference : Calculation EC-SOPC-0607 Rev. 0 applies. The associated RSCN's82-663,
-664, -665, and-666 specify 115 V for relay pick-up. MT-RC-026, Rev. 6 specifies a tolerance of+/- 2% which is 2.3 volts. The values shown above are the corresponding DG voltage levels. (The potential transformer is 102 V to 4200V. For ex.
(115+2.3)*4200/120 = 41 06)
EC-024-1031 Page 6 For the DG breaker supplying the 4KV bus to auto-close, this setting should never be above the DG output voltage when breaker auto-closure is otherwise indicated.
However, that situation could potentially occur with the existing setpoint range. CR 1315904 identifies this potential and will require a setpoint change. Resolution of that issue is outside the scope of this calculation and is tracked by the CR.
5.0 Results The result is that a steady state surveillance value of 4000 Volts for DG output will meet the acceptance criteria of this calculation.
6.0 References 6.1 CR 1302829, DG ISOCHONOUS SURVEILLANCE LOW VOLTAGE ACCEPTANCE CRITERIA IS NOT TECHNICALLY SUPPORTABLE 6.2 CRA 1312458, CR 1302829 PROCEDURES REQUIRING EXPEDITIOUS REVISION AND REQUIRED VOLTAGE VALUE 6.3 AR-EWR 1315923, CREATE A FORMAL CALCULATION FOR THE 4000 V CRITERION ESTABLISHED VIA CRA 1312458 6.4 CR 1315904, THE POTENTIAL EXISTS FOR THE SETPOINT FOR THE EDG BREAKER CLOSURE VOLTAGE PERMISSIVE RELAYS TO BE SET AT A HIGHER VALUE THAN THE UPPER VALUE ALLOWED FOR THE AUTO VOLTAGE REGULATOR (AVR) WHEN AN EDG IS FUNCTIONING IN EMERGENCY MODE.
6.5 EC-004-1031, Rev. 4, PLANT AC LOADFLOWANALYSIS 6.6 CRIMP 6.7 ETAP library etaplib5.1ib 6.8 EC-004-1034, Rev. 1, POWER CABLE DATA FOR ETAP 6.9 Industrial Power Systems Handbook, Donald Beeman, McGraw-Hill, 1955 6.10 FSAR text 8. 3.1.4, Rev. 68 in NIMS 6.11 FSAR table 8.3-3 Table Rev 56 in NJMS 6.12 Schematic drawing E-23, Sheet 6, Rev. 28 6.13 Schematic drawing E-23, Sheet 6B, Rev. 2 6.14 Schematic drawing E-23, Sheet 6C, Rev. 7 6.15 Schematic drawing E-23, Sheet 6D, Rev. 2 6.16 Schematic drawing E-23, Sheet 6E, Rev. 10
6.17 Schematic drawing E-23, Sheet 6F, Rev. 2 6.18 Schematic drawing E-23, Sheet 6G, Rev. 9 6.19 Schematic drawing E-23, Sheet 6H, Rev. 2 6.20 Schematic drawing E-23, Sheet 10, Rev. 10 6.21 Schematic drawing E-23, Sheet 13, Rev. 9 EC-024-1031 Page 7 6.22 Procedure MT-RC-026, Rev. 6, CS (POT. & BRUM.) RELAY CALIBRATION PROCEDURE 6.23 RSCN's82-663 through 666 6.24 EC-SOPC-0607, Rev. 0, RELAY SETTING CALCULATION FOR DIESEL GENERATOR A&B&C&D&E VOLTAGE PERMISSIVE FOR LOADING SUPERSEDES 1-20204-13 REV 1 6.25 MT-RC-063, Rev. 1, STANDBY DIESEL GENERATOR AUTO VOLTAGE REGULATOR POWER DRIVEN POTENTIOMETER ADJUSTMENT PROCEDURE 6.26 Unit 1 Technical Specification Bases 3.8.1, Rev. 6 6.27 Unit 1 Technical Specification Bases 3.8.1, Rev. 8
OG501E
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oM10p~**
- . **. -.* -* __.* **i *.*.~u~.. -.*-*.-.* *.*-.***. *_***
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au~.:**-_.-....
of\\~1oAo~....
HFOA0391C 106ft Cu HFOA0391D 106ft Cu HFOA0391A 83ftCu HFOA0391B 83ft Cu AFOG2405A 481 ft Cu AFOG2405B 481 ft Cu AFOG2401K 110ft Cu AFOG2401 L 110ft Cu AFOG2401A 615 fl AI AFOG2401 B 599 ft AI Cu is cable code H01. Total H01length is 780ft for any one conductor path AI is cable code F10. Total F10 length is 615ft for any one conductor path EC"024"1031 Page 8 Figure 1 Note: Each cable number represents 3 conductors for a total of 2 conductors per phase AFOG2401C 471 ft AI AFOG2401 D 473ft AI 1A2ri104 > :**..
OG50~E Oy520E oA1'i1o08... *... *
- .Bus*.*
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- .*.. *. BUS<*.**
\\OA~10B01******* *******.***.*.
2M0204 HFOA0391C 106 It Cu HFOA0391D 106ft Cu HFOA0391A 83ft Cu HFOA0391B 83ft Cu BFOG2405C 465ft Cu BFOG2405D 465ft Cu BFOG2402K 108ft Cu BFOG2402l 108 ft Cu BFOG2402A 593ft AI BFOG2402B 599 ft AI Cu is cable code HOi. Total H01 length is 762 ft for any one conductor path AI is cable code F10. Total F10 length is 599ft for any one conductor path Figure 2 EC-024-1031 Page 9 Note: Each cable number represents 3 conductors for a total of 2 conductors per phase BFOG2402C 451 ft AI BFOG2402D 445 ft AI 1A202()4
OG.501E
- . OC520E OA~100B *.. *.**.. ****.
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OA510C01**.*. ********.. *.** **..*.*
- .. :: *..:-::***:*=.::***:.*:..=.::*:.
i Q(!520C * *..
HFOA0391C 106ft Cu HFOA0391D 106ft Cu HFOA0391A 83ft Cu HFOA0391B 83ft Cu CFOG2405E 462 ft Cu CFOG2405F 462 ft Cu CFOG2403K 108ft Cu CFOG2403L 108ft Cu CFOG2403A 553 ft AI CFOG2403B 556 fl AI
~Az03M*************
Figure3 EC-024-1 031 Page 10 Note: Each cable number represents 3 conductors for a total of 2 conductors per phase CFOG2403C 424ft AI CFOG2403D 432 ft AI Cu is cable code H01. Total H01 length is 759 fl for any one conductor path AI is cable code F1 0. Total F10 length is 556 fl for any one conductor path
f)G501E OC52QE *..
oAs1ooa
.*.*.** \\
- .*****BUS.*****..
- ..*.. OA51004 sus**********
HFOA0391C 106ft Cu HFOA0391D 1 06 ft Cu HFOA0391A 83ft Cu HFOA0391 B 83 ft Cu DFOG2405G 507 ft Cu DFOG2405H 507ft Co OA?.1~6o1******************** ****.
DFOG2404K 114ft Cu DFOG2404L 114ft Cu DFOG2404A 552 ft AI DFOG2404B 547ft AI Figure 4 EC-024-1031 Page 11 Note: Each cable number represents 3 conductors for a total of 2 conductors per phase DFOG2404C 411 ft AI DFOG2404D412 fiAt
- 1A20404 Cu is cable code H01. Total H01 length is 810 ft for any one conductor path AI is cable code F10. Total F10 length is 552 fl for any one conductor path
OG501E
... OC520E;
. OA51008
- BUS OA5l~Ol. *.* **... *****
HFOA0391C 106 It Cu HFOA0391 0 106 ft Cu HFOA0391A 83 ft Cu HFOA0391B 83 It Cu AFOG2405A 481 ft Cu AFOG2405B 481 ft Cu EC-024-1031 Page 12 Figures Figure 5 is a more detailed representation which shows that the cable length when OG-E is NOT substituted is less than the cable length when DG*E is substiluled. This is typical for when OG-E is substituted. DG*A Is shown.
Note: Each cable number represents 3 conductors for a total of 2 conductors per phase
\\,/ / \\
oA510A~~
AFOG2401 K 110 ft Cu AFOG2401l 110HCu AFOG2401A 615 !tAl
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OA510A01. ***
AFOG2401H 114 HCu AFOG2401J 114ft Cu
- ..* PC$20A :*
AFOG2401 F 49 fl AL AFOG2401G 49ft AI QG501A.*. *..
AFOG2401B 599 !tAl flr-t;:=================::;=ji II IIAFOG2401C471 HAl I/
l AFOG24010 473 !tAl
- .*.******* ~A2~;04 Cu Is cable code H01.
AI is cable code F10.
Table 1 EC-024-1031 Page 13 SELECT TRAK2000_ CABL.l D, TRAK2000_ CABL. FROMEQ, TRAK2000_ CABL. TOEQ, TRAK2000_ CABL. CODE, TRAK2000 _ CABL.l LEN, TRAK2000 _ CABL. OLEN FROM TRAK2000_CABL WHERE (((TRAK2000_CABL.ID) Like "?FOG240[1-4]?" Or (TRAK2000_CABL.ID) Like
"?FOG2405[A-H]")) OR (((TRAK2000_CABL.ID) Like "HFOA0391[A-D]"))
ORDER BY TRAK2000_CABL.ID;
Use design length (OLEN) if installed length (I LEN} is blank.
EC-024-1031 Page 14