Attachment 1 to GNRO-2013/00088 JC-Q1P81-90024 Rev. 3 Division III Degraded Bus Voltage Setpoint

ML13323A550
Person / Time
Site:	Grand Gulf
Issue date:	11/08/2013
From:	Entergy Operations
To:	Office of Nuclear Reactor Regulation
References
GNRO-2013/00088, TAC ME9764 JC-Q1P81-90024, Rev 3
Download: ML13323A550 (76)
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Text

Attachment I to GNRO-2013/00088 JC-QIP81-90024 Rev. 3 "Division III Degraded Bus Voltage Setpoint"

.LIANO-1. F1 ANO-2 *O.CYNS L IP-2 L[I P3 1PLP EI JAF [JPNPS EJRBS

• VY El W3 E].NP-GGNS -3 [lNp-RBS-3 CALCULATION (1)EC # 39554 "2)Page 1 of 75 COVER PAGE (3) Design Basis Calc. r] YES 0 NO (4) 0 CALCULATION r- EC Markup (5) Calculation No: : JC-QlP81-90024 ( Revision: 003 (7)

Title:

Division M Degraded Bus Voltage Setpoint Validation (T/S w Editorial 3.3.8.1) [_ YES 0 NO (9) System(s): PS1 / E22 e Review Org (Department): NPE (I&C Design)

(11) Safety Class: (2) Component/Equipment/Structure Type/Number:

0D Safety / Quality Related 1E22S004 IA701-127-2A

[] Augmented Quality Program 1A701-162-1 1A701-127-2B

[] Non-Safety Related 1A708-162-2 IA708-127-IA (l3 Document Type: J05.02 IA708-127-1B (14) Keywords (Descrlptionrfopicpl Codes): diesel generator, loss of offsite power, setpoint, uncertainty REVIEWS (1) Name/Signature/Date (1) Name/Signature/Date (1) Name/Signature/Date MmCfaoRobin Smith I esponsible Engineer 0 Design Verifier Supervisor/Approval E] Reviewer Comments Attached 7I Comments Attached

ft ENTERGY

(~~) CALCULATION SHEET SHEET 2 OF 37 CALCULATION NO. JC-Q1P81-90024 REV. 003 Revision ReOrd of Re'visio.n 0 Original issue.

I General Revision 2 Added Reset Point Eval.

Extended calibration interval of relays to 24 months + 25%, incorporated results of drift calculations JC-Q1 111-09004, JC-Q1 111-09005 and JC-Q1 111-09022. Updated M&TE for the time delay relay to agree with the current revision of the referenced document.

Added Doble F2250 specifications to attachments. Recalculated loop calibration errors 3 based on current revision of JS09. Incorporated new Analytical limits based on the current revision to the referenced documents. Provided recommended lower allowable values for undervoltage voltage trip and time delay based on calculated values and performed LER avoidance check using these values. Added TSTF section 7.0. Updated references and performed general maintenance.

U

A 2CALCULATION SHEET

___ ENTERGY SHEET 3 OF 37 CALCULATION NO. JC-Q1P81-90024 REV. 003 CALCULATION f2 CALCULATION NO: JC-0IP81-90024 REFERENCE SHEET REVISION: 003 I. EC Markups Incorporated NONE II. Relationships: Sht Rev Input Output Impact Tracking No.

Doc Doc Y/N

1. JS09 0 001 191 0

2. E100.0 0 007 191 0

3. 06-EL-1P81-R-0001 -- 102 1@ 0[

4. 07-S-12-71 -- 006 t1l 0

5. 07-S-12-83 -- 002 19 01

6. 460003606 0 300 M] 0

7. SDC10 0 000 N] 0_

8. A0630 0 012 NE 0[

9. E0010 0 011 19 0l

10. E0121 017 000 [] 0

11. E1009 0 009 E1@ 0

12. E1188 017 009 [] 0

13. J0501D 0 001 t1l 0

14. 304A3871 0 000 1@l 0

15. 945E475 001A 001 [] 0

16. 169C9488 001 015 191 0

17. 169C9488 002 015 [] 0

18. JC-Q1111-09022 0 000 [] 0

19. JC-Ql111-09004 0 000 M] 0

20. JC-QIIi1-09005 0 000 [] 0

21. EC-QIl111-90028 0 006 [] 0

22. JC-Q1P81-90027 0 002 0 [3l

23. MPGE86-0031 -- 0 t1l 0

24. 3758 013 001 [] 0[

25. 3779 005 001 [] 0[

26. 3779 004 001 11 0[

27. 3779 001 007 E9 0]

28. _0 0 _

29. 0 0[

30. 0 0

31. _0 0 _

32. 03 0[

33. _0 0:1

ER CALCULATION SHEET ft A

ENTERGY SHEET 4 OF 37 CALCULATION NO. JC-Q1P81-90024 REV. 003 Il1. CROSS

REFERENCES:

I. GGNS Technical Specifications, Section 3.3.8.1

2. Asset Suite Equipment Data Base (EDB)

3. AEIC-EEI-NEMA Standard for Instrument Transformers for Metering Purposes, 15KV and Less (EEI PUB. No. MSJ-1 1 & NEMA PUB. No. El 21-1973)

4. ISA RP67.04, Part II, Methodologies for the Determination of Setpoints for Nuclear Safety Related Instrumentation

5. Mathematical Handbook of Formulas and Tables, Murray R. Spiegel, 1968

6. GGNS Technical Requirements Manual, Section TR3.3.8.1

7. SOER 99-01: Loss of Grid

8. IB 7.4.1.7 Instruction Bulletin for ITE Undervoltage Relays IV. SOFTWARE USED:

Title:

N/A Version/Release: Disk/CD No.

V. DISK/CDS INCLUDED:

Title:

N/A Version/Release Disk/CD No.

VI. OTHER CHANGES:

Related references removed from the calculation:

470009582-3, WO00134224, WO00165833, WO00193811, MA100254979, MA100280516, 460000936

AI CALCULATION SHEET ENTERGY SHEET 5 OF 37 CALCULATION NO. JC-Q1P81-90024 REV. 003 TABLE OF CONTENTS SECTION PAGE 1.0 Purpose and D escription ............................................................................................ 6 2.0 R eferences ..................................................................................................................... 11 3 .0 G iven ............................................................................................................................. 13 4.0 A ssum ptions ............................................................................................................. 18 5.0 D evice U ncertainties ................................................................................................. 19 6.0 Loop U ncertainties ................................................................................................... 22 7.0 TSTF C alculations ................................................................................................... 32 8.0 C onclusion .................................................................................................................... 35 ATTACHMENTS 1 BBC Catalog Series 211 (lB 7.4.1.7-7) 12 pages 2 Vendor Documents 17 pages 3 Doble F2250 Specifications 4 pages 4 Design Verification 5 pages

B ENTERGY CALCULATION SHEET SHEET 6 OF 37 CALCULATION NO. JC-QlP81-90024 REV. 003 1.0 PURPOSE AND DESCRIPTION 1.1 The purpose of this calculation is to validate the Technical Specification Allowable Value and TRM Nominal Trip Setpoint for the 4160 V Division III Degraded Bus Voltage trip function.

1.2 The incoming breakers for the Div. III switchgear are automatically tripped on a degraded bus voltage condition after a time delay. The degraded bus voltage condition is detected by sensors employing a one-out-of-two-twice logic. An undervoltage between 88% and 73% of nominal is considered a 'Degraded Voltage'. (Ref. 2.13) 1.3 The time delay for a bus 'Degraded Voltage' condition is long enough to provide for the preferred power source (offsite power) to recover. This time delay duration is dependent upon the presence (or absence) of a LOCA signal. (Ref. 2.13) 1.4 The upper and lower analytic limits for the Division III degraded voltage setpoints and time delays are derived from the station specific load flow and voltage drop calculation (EC-QI I 111-90028), Byron Jackson HPCS Pump Test Curve (#PC 74 1-S-1404), GE HPCS Motor Time Current Heating Curve (# 455HA550), GE HPCS Motor Efficiency and Power Factor Vs. Load Curves (# 455HA549), NEDO 10905-1, and GE HPCS Motor Outline Dwg. (#992C937CF).

The lower analytic limit for the voltage sensors is based on the capacity to start and operate required Class 1E loads under accident conditions with degraded voltage levels present on the distribution system. Voltage sensing is performed by potential transformers located within the 4160 V switchgear for the division, and each potential transformer has a 4200 V/ 120V ratio. The HPCS system is designed to start and accelerate the HPCS Pump with 75% of 4000 V motor voltage (3000 V), per NEDO 10905-1. In order to continue operation indefinitely at the lower analytic voltage limit, motor heating must be limited to that imposed by curve #455HA550, which equates to rated current of the motor @ 434 A. Per PC 741-S-1404, the maximum power point for the HPCS Pump is less than 3100 Hp. At this operating point, the efficiency is 0.935, and the Power Factor is 0.93, per Curve #455HA549. Therefore, at the maximum power point, with the motor drawing 434 A, the terminal voltage at the motor would be 3538 V. Per EC-QI 111-90028, the voltage drop is very conservatively calculated to be 5.41 V. This places the 4160 V bus at 3543.41 V for a sustained undervoltage condition limit. This correlates to a voltage of 101.24 V on a 120 V basis, and is the lower analytic limit (Reference 2.27).

The upper analytic limit for the voltage sensors is based on prevention of unnecessary separation of the Class I E buses, under anticipated minimum voltage conditions of the offsite sources. Entergy System Planning Services performed, "Report on the Analysis of Potential for Sustained Degraded Voltage on the Off-Site Electric Grid at the Grand Gulf Nuclear Power Plant", dated November 9, 1990. This report provided the expected grid performance of the GGNS Offsite Sources under severe

• CALCULATION SHEET

_ ENTERGY "

SHEET 7 OF 37 CALCULATION NO. JC-Q1P81-90024 REV. 003 contingencies. The results of this study determined that the 500 KV switchyard voltage could be as low as 0.994 Per-Unit, and the 115 KV switchyard voltage could be as low as 0.976 Per-Unit.

Calculation EC-QI 111-90028, then conservatively analyzed the Class IE loads with the 500kV Offsite source at 0.975 Per-Unit and the 115kV Offsite source at 0.9675 Per-Unit. It was determined that the Class 1E system required loads would be adequately supported with 0.975 Per-Unit switchyard voltage available for the 500kV system and 0.9675 Per-Unit for the 115kV system. Therefore, it is appropriate that the upper analytic limit for the degraded voltage setpoint determinations be based on the corresponding voltage available at the respective 4160 V Class IE buses, with 0.975 Per-Unit 500kV system driving voltage or 0.9675 Per-Unit 115kV system driving voltage in each switchyard, under accident conditions. The lowest available transient voltage on the Division III 4160 V bus under these conditions has been calculated to be 3359.2 V, which occurs during the start of the HPCS pump, with bus voltage recovery to 3880.9 V within 5 seconds. This condition provides an initial terminal voltage at the HPCS pump motor of 3329.25 V, with voltage increasing as the motor accelerates. The second lowest transient voltage step is 3846.34 V, with bus voltage recovery to 3904.16 V, within 5 seconds. This interval is after the HPCS pump motor is already started, therefore the acceleration time of this load is not a factor. All other bus voltage steps are calculated to remain above 3880.9 V. The recovery voltages referenced include the start demand of the next sequence interval, therefore actual recovery voltages at the end of each step following load acceleration and prior to the next sequence would be above thesevalues. Therefore, if the HPCS motor can accelerate its load at the minimum transient voltage within the allowable time delay band, the recovery voltage predicted would form the upper analytic limit for degraded voltage considerations during the sequence when the HPCS pump motor starts. For all successive intervals, using the lowest available bus voltage step will ensure that other equipment sequencing will not inadvertently actuate the Division III bus degraded voltage sensors. As stated above, this correlates to a bus voltage of 3846.34 V. This value would bound all required conditions for the HPCS system to remain connected to offsite power, without prematurely separating from this source, provided that the time delay is set sufficiently to account for HPCS motor start time. Therefore, the overall bounding upper analytic limit is 3846.34 V (109.89 V on a 120 V basis), and the appropriate sensor time delay interval will also be based on this value (Reference 2.27).

Division III has two distinct time delays associated with degraded voltage sensing.

One time delay is active when no accident signal is present, and the other is active when a safety injection signal is present for Division III.

The lower analytic limit for the safety injection condition time delay is based on providing the capability to successfully start the HPCS pump at the lower analytic limit of the degraded voltage sensors without segregating from the offsite source. This requires that the time delay be of sufficient duration to allow for acceleration of the

A CALCULATION SHEET ENTERGY SHEET 8 OF 37 CALCULATION NO. JC-Q1P81-90024 REV. 003 HPCS pump motor under these conditions. Using the previously established minimum HPCS motor starting voltage available from a viable offsite source of 3329.25 V, the acceleration time for the HPCS pump motor has been determined to be no more than 3.28 Seconds. This condition conservatively bounds the acceleration time required at the lower analytic limit bus voltage of 3543.41 V. Therefore, 3.28 seconds is the lower analytic limit for the safety injection condition degraded voltage time delay.

The upper analytic limit for the safety injection condition degraded voltage time delay is derived from the required time response for the HPCS system to achieve necessary injection flow within 27 Seconds of accident initiation. This further requires that the HPCS system be connected to a viable power source within 10 seconds to achieve this goal. The limiting case for this upper limit is when offsite power is available but degraded (i.e, above the Loss of Voltage settings, but below the lower analytic limit for the degraded voltage sensors), with an accident signal present. This is because the degraded voltage function trips the incoming source only, therefore requiring the subsequent sensing and time delay from the Loss of Voltage function to connect the Emergency Diesel Generator (EDG) to the bus. The EDG receives a separate safety injection signal, so the EDG start time and the total voltage sensing sequence described will occur concurrently. This limits the allowed combined sense and actuate times for the degraded voltage and loss of voltage functions to no more than 10 seconds total. It is desirable that the degraded voltage time delay be of a longer duration than the loss of voltage time delay, based on original system design.

Therefore, a 6 Second upper analytic limit is allocated to the degraded voltage time delay. Correspondingly, a 4 Second upper analytic bound is thus established for the loss of voltage time delay by this selection.

The design for the Division III Degraded Voltage detection was provided by GE under FDDR JB 1-2099. The applicable setpoints were determined by this design document, without providing GGNS with documented basis justification at the time.

Subsequently, per GGNS request, GE provided a summary of an evaluation that was performed to justify the nominal 5 minute degraded voltage time delay, no LOCA setpoint (MPGE-86/03 1). The actual evaluation resides with GE, and was not provided to GGNS. This evaluation was based on nominal setpoint values, with no apparent consideration for uncertainties.

GE did not provide a Design Specification Data Sheet for the Degraded voltage function, possibly due to the unique application, i.e., the function did not meet the conventional "instrument loop" configuration. Because no Design Specification Data Sheet was generated, no definitive Analytic Limit determinations were provided to GGNS.

The appropriate method to determine an upper Analytic Limit for this parameter is to determine a minimum that the bus voltage could degrade to, and evaluate the maximum permissible time that the system could sustain this voltage without causing equipment damage or loss of function due to protective device actuations, such as

SHEET 9 OF CALCULATION NO. JC-O1P81-90024 REV.

circuit breaker or thermal protection trips. This is to ensure that the system will maintain the capability to automatically respond to a subsequent LOCA signal, without incurring functional impairment due to the offsite source degradation. While the capability to provide uninterrupted functional capability due to offsite source degradation has been a relevant consideration from original system design, the inherent historical assumption has been to consider the level of degradation that would be expected, and assume a loss of the offsite source completely below that point. This almost certainly formed the basis for the original system settings. During the Electrical Distribution. System Functional Inspections performed by the NRC in the early 1990's, certain utilities received questions relating to system performance if the voltage theoretically degraded below this level, but remained above the loss of voltage setpoint. Apparently, the transmission systems for some plants may have been marginally configured such that voltage degradation to sustainable values at the transmission system level could represent an extremely degraded value in the plant Switchyard. This consideration is further discussed as it relates to GGNS.

For GGNS, the existing time delay settings are acceptable, provided that the degraded voltage remains sufficiently high to start the HPCS loads. This correlates to a motor terminal voltage of 75% of the motor base voltage for HPCS system motors. Review of calculation EC-Q 1111-90028, has determined that the bounding percent voltage drop from the offsite source to the HPCS pump motor is considerably less than 15%,

even under the motor start demand conditions. A 15% drop will be conservatively assumed for this discussion. The HPCS system motors are designed to start with 75%

of motor rated voltage. This is 3000 V for the HPCS pump motor. 3000 V is less than 73% of rated bus voltage (4160 V). Therefore, the HPCS pump motor would be expected to start for offsite source degraded voltage conditions down to 88% of rated offsite source voltage (73% + 15% = 88%). The remaining consideration for continued relay timing limitations would be the motor heating limits once the motor has started. Motor heating must be limited to that imposed by curve #455HA550. Per PC 741-S-1404, the maximum power point for the HPCS Pump is less than 3100 Hp.

At this operating point, the efficiency is 0.935, and the Power Factor is 0.93, per Curve

1. 455HA549. Therefore, at the maximum power point, with 3000 V available at the motor, the current would be 511.83A (1.18 PU) under these conditions.

Per the motor heating curve, operation at this current level can continue in excess of 600 seconds, which is significantly longer than the present time delay settings require.

Thus, the present settings are justified for offsite source degradation levels down to at least 88% of rated.

A discussion of the practical operating limits for the Entergy Transmission system and system generators, provides confirmation of the adequacy of this anticipated degradation level. The Entergy Transmission Planning Guidelines impose the requirement that substation bus voltage capabilities be maintained at no less than 92%

of rated, even under severe contingency analysis conditions. In fact, this represents an extreme case for system voltage level degradation limits, because the generation

CALCULATION SHEET

__ ENTERGY SHEET 10 OF 37 CALCULATION NO. JC-QlP81-90024 REV. 003 facilities generally are forced to reduce generation (including reactive generation for voltage support) at about 95% of rated voltage, to protect individual generators from thermal damage due to over-excitation. In the case of severe sustained degraded voltage conditions, this would almost certainly lead to load isolation or system voltage collapse. In either case, loss of the offsite source or system voltage recovery to acceptable levels for continued generation would be an expected consequence in very short order. Additionally, GGNS is located within the system such that transmission system voltage levels very closely match generation station Switchyard output voltages. GGNS 500 KV Switchyard nominal voltage is 1.02 PU. Thus any degradation seen in the GGNS Switchyard would also be seen by the supporting generation. Therefore, sustained degraded grid conditions below about 95% would not be expected to occur for GGNS, and System Planning Analyses ensure the capability to maintain at least 92% Substation voltage under severe contingency considerations.

With these considerations, it would be appropriate to select 600 seconds (10 min.) as the upper analytic limit for the Division III Time Delay, No LOCA. For additional conservatism, this limit will be set at 360 seconds (6 min.). This provides adequate time for voltage recovery to above the degraded voltage set-point, while ensuring the continued automatic availability of the system, should a subsequent LOCA signal be received. The lower analytic limit for this parameter should be based on a reasonable period to allow time for recovery. It is to be selected to provide an equivalent margin from the nominal trip setpoint as the margin allowed from the setpoint to the upper analytic limit (i.e. I min.). Therefore, the lower analytic limit for the Time Delay, No LOCA is 4 minutes.

1.5 The design consideration for the subject instrumentation is: Degraded Grid Voltage 1.6 This calculation is performed in accordance with the methodology of GGNS-JS-09, which is based on the 'square root sum of the squares' (SRSS) technique for combining statistically independent uncertainty components.

• CALCULATION SHEET ENTERGY SHEET 11 OF 37 CALCULATION NO. JC-QIP81-90024 REV. 003

2.0 REFERENCES

(* denotes EDMS Relational References) 2.1 GGNS JS09, Methodology for the Generation of Instrument Loop Uncertainty and Setpoint Calculations 2.2 ISA RP67.04, Part II, Methodologies for the Determination of Setpoints for Nuclear Safety Related Instrumentation 2.3

• GGNS E100.0, Environmental Parameters for GGNS 2.4

• GGNS Technical Specifications, Section 3.3.8.1 2.5

• GGNS Technical Requirements Manual, Section TR3.3.8.1 2.6

• 06-EL-1P81-R-0001, Surveillance Procedure 2.7 07-S-12-71, General Maintenance Instruction Time Delay Relays 2.8 07-S-12-83, General Maintenance Instruction Undervoltage Relays 2.9 IB 7.4.1.7-7, Instruction Bulletin for ITE Undervoltage Relays (attached) 2.10 460003606, Instruction Manual for Fluke 45 Multimeter 2.11 Not Used 2.12 AEIC-EEI-NEMA Standard for Instrument Transformers for Metering Purposes, 15KV and Less (EEl PUB. No. MSJ-I 1 & NEMA PUB. No. El 21-1973) 2.13 SDC 10, System Design Criteria ESF Div. III Power Distribution System 2114 Mathematical Handbook of Formulas and Tables, Murray R. Spiegel, 1968 2115 A0630, Control Building Fire Protection Plan 2,16 E0010, Sychronizing Diagram ESF Buses 15AA, 16AB, 17AC 2.17

• E0121-017, Summary of Relay Settings 4.16 KV Bus 17AC & D.G. 13 2.18 E1009, One Line Meter and Relay Diagram Bus 17AC 2.19 El 188-017, HPCS Power Supply Schematic 2.20 J0501 D, Control Building Plan at Elev. 111' 2.21 304A3871, Equipment Summary E22-S004 2.22 945E475-001 A, Metal Clad Switchgear Assembly 2.23 169C9488-001 and 169C9488-002, Purchase Part Drawing, Time Delay Relay

__ ENTERGY GCALCULATION SHEET SHEET 12 OF 37 CALCULATION NO. JC-Q1P81-90024 REV. 003 2.24 JC-QI 111-09022, Drift Calculation For Agastat Time Delay Relays 2.25 JC-Q1 111-09004, Drift Calculation For ITE 211T4175 Undervoltage Time Delay Relays (Undervoltage Function) 2.26 JC-Q1 111-09005, Drift Calculation For ITE 21 1T4175 Undervoltage Time Delay Relays (Time Delay Function) 2.27 EC-QI 111-90028, AC Electrical Power System Calculation 2.28 Not Used 2.29 SOER 99-01, Loss of Grid 2.30 MPGE86-0031, High Pressure Core Spray Second Level Under Voltage Protection Time Delay Setpoint Justification 2.31 3758 sheet 013, Performance Curve (PC 741-S-1404) 2.32 3779 sheet 004, Time Current Heating Curve (455HA549) 2.33 3779 sheet 005, Efficiency & Power Factor VS Load Curves (455HA550) 2.34 3779 sheet 001, Outline Induction Motor (992C937CF)

CALCULATION SHEET

_ ENTERGY SHEET 13 OF 37 CALCULATION NO. JC-p1 P81-90024 REV. 003 3.0 GIVEN 3.1 Under voltage time delay relays:

3.1.1 Manufacturer / model # - ITE / 211T4175 (Ref. 2.17)

3.1.2 Location

(Ref. 2.15, 2.18, 2.20) component room panel 127-1A 0C210 1E22-S004 127-1B 0C210 1E22-S004 127-2A 0C210 1E22-S004 127-2B 0C210 1E22-S004

3.1.3 Environment

(Ref. 2.3)

Normal & Accident Environment (N-055) pressure: 0.1 to 1.0 in. wg.

expected temperature: 104'F temperature range: 580F to 120'F relative humidity range: 10% to 60%

radiation: gamma (TID): 1.8

• 102 Rads 3.1.4 Uncertainty Effects - Undervoltage time delay relay (Voltage Setting):

(Ref. 2.9)

" Reference Accuracy (RA) + 0.2% Setting

" Temp. Effect (TE) + 0.20% Setting

" Humidity Effects (HE) Negligible - Reference Section 4.2

" Radiation Effects (RE) Negligible - Reference Section 4.2

" Power Supply Effects (PS) + 0.20% Setting

" Seismic Effects (SE) Negligible - Reference Section 4.3

" Static Pressure Effects (SPE) N/A for instrument type

" Overpressure Effects (OVP) N/A for instrument type

" Drift (DR) +/- 1.460 VAC for 30 months - Reference 2.25

" Temp. Drift (TD) N/A - Reference Section 4.4

ENTERGY CA*LCULATION SHEET SHEET 14 OF 37 CALCULATION NO. JC-Q1P81-90024 REV. 003 3.1.5 Uncertainty Effects - Undervoltage time delay relay (Time Delay Setting):

(Ref. 2.9)

" Reference Accuracy (RA) +/- 10% Setting

" Temp. Effect (TE) Negligible - Reference Section 4.10

• Humidity Effects (HE) Negligible - Reference Section 4.2

" Radiation Effects (RE) Negligible - Reference Section 4.2

" Power Supply Effects (PS) Negligible - Reference Section 4.10

" Seismic Effects (SE) Negligible - Reference Section 4.3

• Static Pressure Effects (SPE) N/A for instrument type

• Overpressure Effects (OVP) N/A for instrument type

" Drift (DR) +/- 0.327 sec for 30 months - Reference 2.26

" Temp. Drift (TD) N/A - Reference Section 4. 10 3.2 Time delay relays:

3.2.1 Manufacturer / model # - Agastat / ETRI4D3NO02 (Ref. 2.17)

3.2.2 Location

(Ref. 2.15, 2.17, 2.20) component room panel 162-1 0C210 1E22-S004 162-2 0C210 1E22-S004

3.2.3 Environment

(Ref. 2.3)

Normal & Accident Environment (N-055) pressure: 0.1 to 1.0 in. wg.

expected temperature: 104'F temperature range: 58°F to 120TF relative humidity range: 10% to 60%

radiation: gamma (TID): 1.8

• 102 Rads

CALCULATION NO. JC-Q1P81-90024 REV. 003 Uncertainty Effects - Time Delay Relay: (Ref. 2.23)

" Reference Accuracy (RA) +/- 5.0% Time Delay Setting

" Temp. Effect (TE) Negligible - Reference Section 4.8

" Humidity Effects (HE) Negligible - Reference Section 4.2

" Radiation Effects (RE) Negligible - Reference Section 4.2

" Power Supply Effects (PS) Negligible - Reference Section 4.9

• Seismic Effects (SE) Negligible - Reference Section 4.3

" Static Pressure Effects (SPE) N/A for instrument type

" Overpressure Effects (OVP) N/A for instrument type

• Drift (DR) + 26.725 sec for 30 months - Reference 2.24

" Temp. Drift (TD) Negligible - Reference Section 4.8

ACALCULATION SHEET ENTERGY SHEET 16 OF 37 CALCULATION NO. JC-Q1P81-90024 REV. 003 3.3 Typical Loop Block Diagram: (Ref. 2.19) 127-IA (4 SEC) 3.4 Operating Limits (Ref. 2.4, 2.5, Section 1.4)

Voltage Trip Upper Analytic Limit: 3846.34 V (109.89 V)

Upper Allowable Value: < 3763.5 V (5 107.53 V)

Plant Setpoint: 3661 V (104.6 V)

Lower Allowable Value*: > 3605.0 V (> 103.00 V)

Lower Analytic Limit: 3543.41 V (101.24 V)

CALCULATION SHEET

_~ _ENTERGY SHEET 17 OF 37 CALCULATION NO. JC-QIP81-90024 REV. 003 Time Delay - LOCA Upper Analytic Limit: 6 seconds Upper Allowable Value: < 4.4 seconds Plant Setpoint: 4 seconds Lower Allowable Value*: > 3.85 seconds Lower Analytic Limit: 3.28 seconds Time Delay - No LOCA Upper Analytic Limit: 6.0 minutes Upper Allowable Value: < 5.5 minutes Plant Setpoint: 5 minutes Lower Allowable Value: > 4.5 minutes Lower Analytic Limit: 4.0 minutes

• Recommended Values

• CALCULATION SHEET

_ ENTERGY SHEET 18 OF 37 CALCULATION NO. JC-QIP81-90024 REV. 003 4.0 ASSUMPTIONS 4.1 Assume all uncertainties given are to two standard deviations (2a) unless otherwise specified.

4.2 Assume Radiation Effects (RE) and Humidity Effects (HE) for the undervoltage and time delay relays are negligible. These components are located in a mild environment.

(Ref. Section 3.1.3 and 3.2.3) 4.3 Assume Seismic Effects (SE) are negligible for both the undervoltage and time delay relays. The relays are seismically qualified per GGNS QP 425.00 Vol. 1, Rev. 1.

4.4 Assume Temperature Drift (TD) is encompassed by the Temperature Effect (TE) for the undervoltage relays.

4.5 Insulation Resistance Effects (IR) are assumed to be negligible since the loop cabling is located in a mild environment (control building).

4.6 Not Used.

4.7 Per Reference 2.21 and 2.22, the potential transformers at the bus are G.E. type JVM-

3. This type of potential transformer has an accuracy class of 0.3 at W and X burdens when operated at 58% of rated voltage. Based on the available burden information for the circuit components depicted on Ref. 2.16 and 2.18, the burden is assumed to be less than X and the accuracy of the potential transformers is assumed to be 0.3. (See file documentation for available circuit component burden data) 4.8 Assume Temperature Effects (TE) and Temperature Drift Effect (TD) for the time delay relays are negligible. The normal ambient temperature at the relays is within the vendor specified normal ambient temperature (Ref. 2.23).

4.9 Assume Power Supply Effects (PS) for the time delay relays are negligible. The supply voltage variation is expected to be encompassed by the voltage variation margin available (+/-10% of rated voltage, Ref. 2.23).

4.10 The vendor does not specify a Temperature Effect, Temperature Drift or Power Supply Effect for the undervoltage relay timing function. These effects will be assumed to be negligible.

ENTERGY B CALCULATION SHEET SHEET 19 OF 37 CALCULATION NO. JC-01P81-90024 REV. 003 5.0 DEVICE UNCERTAINTIES - Ax (Ref. 2.1) 2 2

+ (RE2) 2 + (PSX) 2 2 2 Ax = +V (RAx) 2

+ (TEx) 2 + (HEX) + (SEx) + (SPEx) + (OVPx) 5.1 Undervoltage Relay Uncertainties - Voltage Trip: (Ref. Section 3.1.4)

Reference Accuracy -"RA" RA v = + 0.20% of setting RA= + (2 (104.6))V RAv=+ 0.21 V Temperature Effects - "TE" TEv = + 0.20% of setting TEv = +/- 0.20 (104.6))V TEv= + 0.21 V Humidity Effects - "HE" Negligible - Reference Section 4.2 Radiation Effects - "RE" Negligible - Reference Section 4.2 Power Supply Effects - "PS" PSv = + 0.20% of setting Psv- (o (104.6)) V PSv=+ 0.21 V SSE Effects- "SE" Negligible - Ref. Section 4.3

.ft CALCULATION SHEET

_ENTERGY ~

SHEET 20 OF 37 CALCULATION NO. JC-Q1P81-90024 REV. 003 Static Pressure Effects - "SPE" N/A for instrument type Over Pressure Effects - "OVP" N/A for instrument type Total Undervoltage Relay Uncertainty (Voltage Trip) - Av:

2 2 2 2 Av = +_/(RAv)2 + (TEv) 2 + (HEy) 2

+ (SEv) 2 + (REv) + (PSV) + (SPEv) + (OVPv)

Av = +/-*(0.21)2 + (0.21)? + (0)2 + (0)2 + (0)2 + (0.21)2 + (0)2 + (0)2 Av=+/-0.36 V 5.2 Undervoltage Relay Uncertainties - Time Delay: (Ref. Section 3.1.5)

Reference Accuracy - "RA" RA =+ 10% setting RA 10 (4)) sec RAT = +/- 0.40 seconds Temperature Effects- "TE" Negligible - Reference Section 4.10 Humidity Effects - "HE" Negligible - Reference Section 4.2 Radiation Effects - "RE" Negligible - Reference Section 4.2 Power Supply Effects - "PS" Negligible - Reference Section 4.10 SSE Effects - "SE" Negligible - Reference Section 4.3

CALCULATION SHEET ENTERGY SHEET 21 OF 37 CALCULATION NO. JC-Q1P81-90024 REV. 003 Static Pressure Effects - "SPE" N/A for instrument type Over Pressure Effects - "OVP" N/A for instrument type Total Undervoltage Relay Uncertainty (Time Delay) - AT:

2 2 2 2 2 Ar = +/-V/(RAr) 2 + (TEr) 2 + (HEr) 2 + (SEt) + (RET) + (PST) + (SPEr) + (OVPT)

AT = +/-V,(RAr)2 + (0)2 + (0)? + (0)2 + (0)2 + (0)2 + (0)2 + (0)2 AT= RAT= +0.40 Seconds 5.3 Time Delay Relay Uncertainties: (Ref. Section 3.2.4)

Reference Accuracy -"RA" RATD + 5% setting RATD-- ( ( 3 0 0 )) sec RATD = 15.00 seconds Temperature Effects - "TE" Negligible - Reference Section 4.8 Humidity Effects- "HE" Negligible - Reference Section 4.2 Radiation Effects - "RE" Negligible - Reference Section 4.2 Power Supply Effects - "PS" Negligible - Reference Section 4.9 SSE Effects - "SE" Negligible - Reference Section 4.3 Static Pressure Effects - "SPE" N/A for instrument type

__ENTERGY

,CALCULATION

(

SHEET SHEET 22 OF 37 CALCULATION NO. JC-Q1P81-90024 REV. 003 Over Pressure Effects - "OVP" N/A for instrument type Total Time Delay Relay Uncertainty - AmD:

2

+ (SETD) 2 + (RETD) 2 + (PSTD) 2 + (SPETD) + (OVPrD) 2 2 2 ATD = +/-+(RArD)2 + (TETD) + (HETD)

ATD =+/--(RAro)2 + (0)2 + (0)2 + (0)2 + (0)2 + (0)2 + (0)2 + (0)2 ATD = RATD = +/-15.00 Seconds 6.0 LOOP UNCERTAINTIES (Ref. 2.1) 6.1 SRSS of all individual device uncertainties -"A," (Ref. 2.1)

Loop Device Uncertainty (Voltage Trip):

ALv= JA) = +/-Av = +/-0.36V Loop Device Uncertainty (Time Delay - LOCA):

ALM1 = +/-1(-A-)2 = +/-AT = +/-0.40 seconds Loop Device Uncertainty (Time Delay - No LOCA):

2 2 ALT2 = +/-+(AT) + (ATD)

ALTZ = +/-_ (0.40)2 + (15.00)2 = +15.01 seconds 6.2 SRSS of all Measurement & Test Equipment Effects - "Cl," (Ref. 2.1)

Per Reference 2.8, a Fluke 45 Digital Voltmeter (or Fluke 8600A) is used to monitor the trip point of the undervoltage relays during calibration. The uncertainty data for a Fluke 45, taken from Ref. 2.10, will be used to estimate the M&TE effects. The reference accuracy of the Fluke 45 is:

RAF 4s = +/-(0.2% reading + 0.1 V)

The reference accuracy above is for the 0-300V scale, medium resolution. This value is valid for ambient temperatures between 180C and 28 0 C (64.4°F to 82.4°F). Since the expected temperature at calibration (104TF, i.e. 40'C) is outside the given range, a temperature correction factor from Ref. 2.10 must be applied. This correction factor is stated as: '<0.1 times the applicable accuracy specification per degree C for 0C to 180 C and 28°C to 500 C (320 to 64.40 and 82.40 to 122 0 F). The temperature correction factor for this application is <0.1 (40-28) or 1.2.

The 'reading' will be assumed to be 104.6 V, the nominal trip setpoint.

ft ENTERGY CALCULATION SHEET SHEET 23 OF 37 CALCULATION NO. JC-QIP81-90024 REV. 003 RAF 4 5 = +/-1.2 * ((0.2*104.6/100) + 0.1) V = _+0.371 V The setting tolerance from reference 2.6 is +/-1.50 V. As the setting tolerance is larger than the reference accuracy of the undervoltage relay (+/-0.21 V) and the test equipment error, +1.50 V will be assumed for the M&TE error.

CLv = +1.50 V Per Reference 2.8, a Doble F2253 test set is used to measure the time delay for the undervoltage relays during calibration. Per Attachment 3, the timing accuracy of the F2253 is 0.0039% of reading. The 'reading' will be assumed to be 4 sec., the nominal setpoint.

RATF2253 = -40.0039*4/100= 10.000156 V The setting tolerance from reference 2.6 is +/-0.2 seconds. As the reference accuracy of the undervoltage relay (+/-0.4 seconds) is larger than the setting tolerance and the test equipment error, +/-0.4 seconds will be assumed for the M&TE error.

Therefore, the Loop Uncertainty for the time delay function with a LOCA signal present is:

CLTI = 10.4 seconds Per Reference 2.7, a Doble F2253 test set is used to measure the time delay for the time delay relays during calibration. Per Attachment 3, the timing accuracy of the F2253 is 0039% of reading. The 'reading' will be assumed to be 300 sec., the nominal setpoint.

RA RoF2253 =

=

0039 (300) = +/-0.0117 seconds oo100 The setting tolerance from reference 2.6 is +/-_15 seconds. As the setting tolerance and reference accuracy of the time delay relay (+/-15 seconds) is larger than the test equipment error, +/-15 seconds will be assumed for the M&TE error.

Therefore, the Loop Uncertainty for the time delay function with no LOCA signal present is:

CLT2 = J-SRSS (0.4, 15) z.+/-15.0seconds

-~-~

__ENTERGY ENTRGYCALCULATION SHEET SHEET 24 OF 37 CALCULATION NO. JC-Q1P81-90024 REV. 003 6.3 SRSS of all individual device drifts - "D1," (Ref. 2.1)

Undervoltage Relay Drift - DRy DRv = +/- 1.460 VAC for 30 months Undervoltage Relay Temperature Drift - TDv Negligible - Reference Section 4.4 Undervoltage Relay Time Delay Drift - DRT DRT = +/- 0.327 sec for 30 months Undervoltage Relay Time Delay Temperature Drift - TDT Negligible - Reference Section 4.10 Time Delay Relay Drift - DRTD DRTD = +/- 26.725 sec for 30 months Time Delay Relay Temperature Drift - TDD Negligible - Reference Section 4.8 Loop Drift (Voltage Trip):

DLV = +/- (DRv) 2 + (TDv) 2 DLv = +/-+(1.460)2 + (0)2 DLv = +/-1.460 V Loop Drift (Time Delay - LOCA):

DLT1 = +/- (DRr) 2 + (TDT) 2 DLT1 = +/-ý/(0.3272 + (0)2 DLT1 = +/-0.327seconds

MI __ENTERGY CALCULATION SHEET SHEET 25 OF 37 CALCULATION NO. JC-Q1P81-90024 REV. 003 Loop Drift (Time Delay - No LOCA):

DLT2 = +/-+I(DRT)2 + (TDT)2 + (DRroT) + (TDoD) 2 2

DLTZ = +/-*(0.327) + (0)2 + (26.725)z + (0)2 DLT2 = +/-26.728seconds 6.4 Process Measurement Uncertainty - "PM" No process measurement uncertainty is applicable to either the voltage or time delay setpoints.

6.5 Primary Element Uncertainty - "PE" The primary elements for each loop are the potential transformers at the bus. Per Section 4.7, the accuracy class of the potential transformers is 0.3. Per Reference 2.12, the limits of transformer correction factor for a 0.3 accuracy class potential transformer are 1.003 to 0.997 (i.e. +/-0.3%). Again assuming 104.6 V nominal output, the potential transformer uncertainty is:

(0.3 PE =- j- (104.6)) V PE =+/- 0.314 V No Primary Element Uncertainty is applicable to the time delay.

6.6 Insulation Resistance Effects - "IR" Insulation Resistance Effect for the voltage trip function is assumed to be negligible (Reference Section 4.5). IR effects are not applicable to the time delay function.

6.7 Loop Uncertainty - Voltage Trip LU, = +/-_(ALV)2 + (CLV) 2

+ (pM,) 2

+ (pEV) 2 + (oRV)2 LUv SRSS (0.36, 1.5, 0,0.314, 0)

LUv+ 1.58 1, 6.8 Total Loop Uncertainty - Voltage Trip TLUv = LUv + DLV

.... - CALCULATION SHEET

_ _-ENTERGY t_ -*

SHEET 26 OF 37 CALCULATION NO. JC-Q1P81-90024 REV. 003 TLUv= +/- (1.58 + 1.460) V TLUUv = +/-3.04 V 6.9 Loop Uncertainty - Time Delay (LOCA)

LUlT1 = +/-4(ALT1) 2

+ (CLTr) 2

+ (PMr) 2 + (PET) 2 + (IRT)2 LUTI = +/- SRSS (0.40, 0.40, 0,0,0)

L UTI = +/- 0.5 7 seconds 6.10 Loop Uncertainty - Time Delay (No LOCA)

+ (PMT) 2 + (PET) 2 + (IRr) 2 2

LUTz = +/-_(ALT2)2 + (CLT2)

LUT2 = +/--SRSS (15.01, 15.00, 0,0,0)

L Up = +/-21.22 seconds 6.11 Total Loop Uncertainty - Time Delay (LOCA)

TLUTI = LUTI + DLTI TLUTi = (0.57 + 0.32 7) seconds TL UTi = +/-0.90seconds 6.12 Total Loop Uncertainty - Time Delay (No LOCA)

TLUn = LU72 + DL2 TLUT2 = (21.22 + 26. 728) seconds TLUT2 = +/-4 7.95 seconds 6.13 Allowable Values - Voltage Trip Lower Allowable Value = Lower Analytic Limit + LU Lower Allowable Value = 101.24 V + 1.58 V Lower Allowable Value = 102.82 V Upper Allowable Value = Upper Analytic Limit - LU Upper Allowable Value = 109.89 V - 1.58 V

AI CALCULATION SHEET

_ ENTERGY SHEET 27 OF 37 CALCULATION NO. JC-QIP81-90024 REV. 003 Upper Allowable Value = 108.31 V 6.14 Nominal Trip Setpoint - Voltage Trip NTSP: >_(Lower Analytic Limit + TLU) & : (Upper Analytic Limit - TLU)

NTSP: _ (101.24 V + 3.04 V) & * (109.89 V - 3.04 V)

NTSP: _ 104.28 V & < 106.85 V 6.15 Allowable Values - Time Delay (LOCA)

Lower Allowable Value = Lower Analytic Limit + LU Lower Allowable Value = 3.28 seconds + 0.57 seconds Lower Allowable Value = 3.85 seconds Upper Allowable Value = Upper Analytic Limit - LU Upper Allowable Value = 6.00 seconds - 0.57 seconds Upper Allowable Value = 5.43 seconds 6.16 Allowable Values - Time Delay (No LOCA)

Lower Allowable Value = Lower Analytic Limit + LU Lower Allowable Value = 240 seconds + 21.22 seconds Lower Allowable Value = 261.22 seconds (4.36 min)

Upper Allowable Value = Upper Analytic Limit - LU Upper Allowable Value = 360 seconds - 21.22 seconds Upper Allowable Value = 338.78 seconds (5.64 min) 6.17 Nominal Trip Setpoint - Time Delay (LOCA)

NTSP: > (Lower Analytic Limit + TLU) & < (Upper Analytic Limit - TLU)

NTSP: > (3.28 seconds + 0.90 seconds) & < (6.00 seconds - 0.90 seconds)

NTSP: > 4.18 seconds & < 5.10 seconds

CALCULATION SHEET ENTERGY SHEET 28 OF 37 CALCULATION NO. JC-Q1P81-90024 REV. 003 As shown above, the calculated Total Loop Uncertainty yields a setpoint range that will not support the existing plant setpoint (4 sec). Calculation margin will be removed by re-calculating the Total Loop Uncertainty using margin reduction techniques as described in Ref. 2.1.

The reduced margin Total Loop Uncertainty is given by:

2 2 TLUT, = +/-J(LUr) + (DLT1)

TLUTI =+/-SRSS (0.57, 0.327)

TL UT) = +/-0.66 seconds The reduced margin Nominal Trip Setpoint range is therefore:

NTSP: > (Lower Analytic Limit + TLU) & < (Upper Analytic Limit - TLU)

NTSP: > (3.28 seconds + 0.66 seconds) & < (6.00 seconds - 0.66 seconds)

NTSP: > 3.94 seconds & < 5.34 seconds 6.18 Nominal Trip Setpoint - Time Delay (No LOCA)

NTSP: > (Lower Analytic Limit + TLU) & < (Upper Analytic Limit - TLU)

NTSP: > (240 seconds + 47.95 seconds) & < (360 seconds - 47.95 seconds)

NTSP: >287.95 seconds & < 312.05 seconds NTSP: > 4.80 minutes & < 5.20 minutes 6.19 LER Avoidance Analysis - Voltage Trip LER Avoidance probability is based on a number "Z" calculated as shown below. If the value of Z is > 1.28 then the probability of avoiding an LER is > 90%, the acceptance criteria (Ref. 2.1). The LER Avoidance Analysis will be performed using the Lower Allowable Value.

z IAV - NTSPI 01 Where:

AV = 103.0 volts (Recommended Value)

NTSP = 104.6 volts a, - Calculated as shown below

AI CALCULATION SHEET

_ ENTERGY SHEET 29 OF 37 CALCULATION NO. JC-QIP81-90024 REV. 003 With:

n = # of standard deviations used in specifying the individual uncertainty components 2 2 o- = n-V(ALV)2 + (CLv) + (DLV)

= 0. 5 *(SRSS(O. 36, 1.5, 1.460))

at = 1.07 V Therefore:

Z = 1103 - 104.61 1.07 Z = 1.49 From common statistical tables (Ref. 2.14), this value of Z yields an LER avoidance probability greater than 90%.

6.20 LER Avoidance Analysis - Time Delay (LOCA)

The margin between the recommended lower allowable value and the nominal trip setpoint is less than the margin between the upper allowable value and nominal setpoint and will provide the least LER avoidance. Therefore the LER avoidance probability will be determined using the lower allowable value.

= IAV -NTSPI Where:

AV = 3.85 seconds (Recommended)

NTSP = 4.0 seconds a, - Calculated as shown below With:

n = # of standard deviations used in specifying the individual uncertainty components 1

2 2 a,= [-(ALr) 2 + (CLr) + (DLr) n a,=0. 5 *(SRSS (0.40, 0.40, 0.32 7))

a 1 = 0.33 seconds

1*.7 . CALCULATION SHEET ENTERGY SHEET 30 OF 37 CALCULATION NO. JC-Q1P81-90024 REV. 003 Therefore:

Z = 13.85 - 4.01 0.33 Z = 0.45 From common statistical tables (Ref. 2.14), this value of Z yields an LER avoidance probability less than 90%.

6.21 LER Avoidance Analysis - Time Delay (No LOCA)

Using the equations from section 6.20 and the values derived for the Time Delay No LOCA:

Z= 1360-3001 0.5*(SRSS(15.01, 15.0, 26.728, 0, 0))

Z= 3.51 From common statistical tables (Ref. 2.14), this value of Z yields a LER avoidance probability greater than 95%.

6.22 Spurious Trip Avoidance Analysis - Voltage Trip The most severe recoverable voltage transient postulated, is that of clearing a nearby transmission system or in-plant distribution system bolted fault. The bus voltage level during such an event could dip below the voltage trip setting and begin the relay timing. Therefore, no spurious trip avoidance analysis will be performed for the voltage trip setting. Spurious segregation from the off-site source is prevented by the time delay function.

6.23 Spurious Trip Avoidance Analysis - Time Delay LOCA The probability of avoiding spurious trips is determined by calculating a value "Z" as shown below. If the value of Z is > 1.645, the probability of avoiding a spurious trip is

> 95%. (Ref. 2.1)

INTSP- Xrl (c)2 + (a,)2 Where:

NTSP - Nominal Trip Setpoint XT - Limiting Operating Transient Variation XT = X0 - T - To, if the process variable decreases to the Analytic Limit

AIR ENG

-~-ENTERGY

• CALCULATION SHEET SHEET 31 OF 37 CALCULATION NO. JC-QI P81-90024 REV. 003 X0 = maximum or minimum steady state operating value T = magnitude of the limiting transient variation TC = modeling bias or uncertainty Gn - The standard deviation associated with the limiting operating transient, typically zero when the limiting operating transient is based on existing documented operating restrictions.

a, - The standard deviation associated with the loop uncertainty, calculated as shown below:

1 2 2

+ (CLri) + (DLT1) + (PMT) + (PEr) 2 2

= -(ALTJ)

The most severe recoverable voltage transient postulated, is that of clearing a nearby transmission system or in-plant distribution system bolted fault. The maximum fault clearing time consideration for the applicable fault level circuit breakers would be 6 cycles. It is also prudent to assume an additional 10 cycles to allow for voltage recovery post-fault. This correlates to 0.267 seconds (16 cycles

• 0.0167 seconds/cycle = 0.267 seconds).

Z= 14.0 - 0.2671 0.5*(SRSS(0.40, 0.40, 0.327, 0, 0))

Z = 11.42 From common statistical tables (Ref. 2.14), this value of Z yields a spurious trip avoidance probability greater than 95%.

6.24 Spurious Trip Avoidance Analysis - Time Delay (No LOCA)

Using the equations from section 6.23 and the values derived for the Time Delay No LOCA:

Z= 1300 - 0.2671 0.5*(SRSS(15.01, 15.0, 26.728, 0, 0))

Z= 17.56 From common statistical tables (Ref. 2.14), this value of Z yields a spurious trip avoidance probability greater than 95%.

6.25 Reset Point Evaluation The pickup (reset) point of the undervoltage relays should be such that under the worst case transient conditions the bus is not spuriously segregated from the off site source.

NCALCULATION

__ ENTERGY SHEET SHEET 32 OF 37 CALCULATION NO. JC-QIP81-90024 REV. 003 As stated previously, with 0.975 Per-Unit switchyard driving voltage, the lowest transient voltage on the Division III 4160V bus has been calculated to be 3359.2V (95.80V on a 120V basis) which occurs during the start of the HPCS pump, with voltage recovery to 3880.9 V (1 10.88V on a 120V basis). This condition provides an initial terminal voltage at the HPCS pump motor of 3329.25 V. Assuming a constant terminal voltage of 3329.25 V (i.e. no voltage recovery as the motor accelerates) the acceleration time of the HPCS pump motor has been determined to be no more than 3.28 seconds. Therefore, the actual recovery time to at least 3880.9 V would be no more than 3.28 seconds (the Lower Analytic Limit of the time delay setting).

The present pickup (reset) point for the under voltage relays is 105.65 V and the dropout (trip) point is established by the 99% tap setting at 104.60V. Assuming worst case performance of the relays, the trip could occur at the Upper Allowable Value of 107.53 V and the reset could occur at 108.60 V (i.e. 1.01 x 107.53).

Given the above, the bus voltage would recover above the reset point of the relay 108.60 V (3801 V) to at least 110.88 V (3880.9 V) before the time delay times out (even with the worst case performance from the time delay). Therefore, the reset value will prevent spurious segregation from the preferred off site source and is acceptable.

7.0 TSTF CALCULATIONS (Ref. 2.1) 7.1 As-Left Tolerance ALTv - Undervoltage Relay (Voltage Trip) TSTF-493 Calculation ALTv = RAv

= +0.21V ALTT - Undervoltage Relay (Time Delay) TSTF-493 Calculation ALTT = RAT

= +/- 0.40 seconds ALTTD - Time Delay Relay TSTF-493 Calculation ALTD = RATD

= +/- 15.0 seconds 7.2 As-Found Tolerance (AFT)

The drift values used in this calculation were derived by statistical analysis, therefore per Reference 2. 1:

is ENERGCALCULATION SHEET IZ_* ENTERGY" " CT C' 11 [O "**

• I SHEET 33 OF 37 CALCULATION NO. JC-QI P81-90024 REV. 003 AFT = +/-DR AFTv- Undervoltage Relay (Voltage Trip) TSTF-493 Calculation DRv = +/-1.460 V for 30 months AFTv = DRv

= +/-1.460 V AFTT - Undervoltage Relay (Time Delay) TSTF-493 Calculation DRT = +/-0.327 seconds for 30 months AFTT = DRT

= +0.327 seconds AFTTD- Time Delay Relay TSTF-493 Calculation DR-D = +/-26.725 seconds for 30 months AFTTD = DRTD

= +/-26.725 seconds 7.3 Loop Tolerances ALTLV - As-Left Loop Tolerance Undervoltage Relay (Voltage Trip)

ALTLV = +/- SRSS (ALTv)

= +SRSS (0.21)

- +0.21V ALTLT - As-Left Loop Tolerance Undervoltage Relay (Time Delay) - LOCA ALTLT = +/-SRSS (ALTT)

= + SRSS (0.40)

= +/- 0.40 seconds ALTLTD - As-Left Loop Tolerance Time Delay Relay - No LOCA ALTLTD = +/- SRSS (ALTT, ALTTD)

= +/- SRSS (0.40, 15.0)

= + 15.0 seconds AFTLV - As-Found Loop Tolerance Undervoltage Relay (Voltage Trip)

AFTLv = +/- SRSS (AFTv)

= +/-SRSS (1.460)

= +/-1.460 V

,ft CALCULATION SHEET

_ENTERGY SHEET 34 OF 37 CALCULATION NO. JC-Q1P81-90024 REV. 003 AFTLT - As-Found Loop Tolerance Undervoltage Relay (Time Delay) - LOCA AFTLT - - SRSS (AFTT)

= + SRSS (0.327) seconds

= 4-0.327 seconds AFTLTD - As-Found Loop Tolerance Time Delay Relay - No LOCA AFTLTD - + SRSS (AFTT, AFTTD)

= + SRSS (0.327, 26.725) seconds

= 4-26.727 seconds

f NTEG CALCULATION SHEET SHEET 35 OF 37 CALCULATION NO. JC-QIP81-90024 REV. 003

8.0 CONCLUSION

Voltage Trip:

The calculated setpoint range and the Upper Allowable Value are conservative with respect to the existing plant settings. The existing Lower Allowable Value (101.67 V) is non-conservative with respect to the calculated value.

Time Delay - LOCA The initial calculated setpoint range would not support the existing LOCA Time Delay setpoint. Margin reduction techniques were used to remove some conservatism from the calculated values. With the reduced uncertainty, the existing plant setpoint was shown to be acceptable. The existing Allowable Value (3.6 seconds) is non-conservative with respect to the calculated Lower Allowable Value for the LOCA Time Delay..

Time Delay- No LOCA The calculated setpoint and allowable values are conservative with respect to the existing plant setpoints and allowable values. Therefore, the existing plant setpoint is acceptable.

The spurious trip and LER avoidance criterion is met for all values except the time delay lower allowable value. LER avoidance is not met using the recommended lower allowable value.

SUMMARY

OF RESULTS - Voltage Trip SYSTEM P81 - HPCS Diesel Generator (Electrical)

LOOP NUMBERS 127-IA/B, 127-2A/B TOTAL LOOP UNCERTAINTY +/- 3.04 V LOOP UNCERTAINTY +1.58 V LOOP DRIFT +/- 1.460 V LOOP CALIBRATION +/- 1.50 V UNCERTAINTY EXISTING CALCULATED Upper Analytic Limit 109.89 V Upper Allowable Value < 107.53 V < 108.31 V Nominal Trip Setpoint 104.60 V >104.28 V and <106.85 V Lower Allowable Value > 103.00 V* > 102.82 V Lower Analytic Limit 101.24 V ********I*****

Recommended Lower Allowable Value

A CALCULATION SHEET

--- ENTERGY SHEET 36 OF 37 CALCULATION NO. JC-QIP81-90024 REV. 003 SIJMMARY OF RFSIJIITS -Time lelay (IOCA']

SYSTEM P81 - HPCS Diesel Generator (Electrical)

LOOP NUMBERS 127-IA/B, 127-2A/B TOTAL LOOP UNCERTAINTY +/- 0.90 seconds (+/-0.66 sec. reduced margin)

LOOP UNCERTAINTY + 0.57 seconds LOOP DRIFT + 0.327 seconds LOOP CALIBRATION +/- 0.40 seconds UNCERTAINTY EXISTING CALCULATED Upper Analytic Limit 6 sec Upper Allowable Value :54.4 sec < 5.43 sec Nominal Trip Setpoint 4.0 sec >3.94 sec and <5.34 sec Lower Allowable Value >3.85 sec* > 3.85 sec Lower Analytic Limit 3.28 sec Recommended Lower Allowable Value

SUMMARY

OF RESULTS - Time Delay (No LOCA)

SYSTEM P81 - HPCS Diesel Generator (Electrical)

LOOP NUMBERS 127-IA/B, 127-2A/B, 162-1/2 TOTAL LOOP UNCERTAINTY + 47.95 seconds LOOP UNCERTAINTY +/-21.22 seconds LOOP DRIFT +/- 26.728 seconds LOOP CALIBRATION + 15.0 seconds UNCERTAINTY EXISTING CALCULATED Upper Analytic Limit 6.0 min Upper Allowable Value <5.5 min _<5.64 min Nominal Trip Setpoint 5.0 min >4.8 min and <5.2 min Lower Allowable Value >4.5 min > 4.36 min Lower Analytic Limit 4.0 min

_ _ ENTERGY fCALCULATION SHEET SHEET 37 OF 37 CALCULATION NO. JC-QIP81-90024 REV. 003 Summary of Calibration Tolerances As-Left Undervoltage Relay (Voltage Trip) TSTF-493 (ALTv) +/-0.21 V As-Left Undervoltage Relay (Time Delay) TSTF-493 (ALTT) +/-0.40 seconds As-Left Time Delay Relay TSTF-493 (ALTTD) +/- 15.0 seconds As-Found Undervoltage Relay (Voltage Trip) TSTF-493 (AFTv) +/-1.460 V As-Found Undervoltage Relay (Time Delay) TSTF-493 (AFTT) +0.327 seconds As-Found Time Delay Relay TSTF-493 (AFTmD) +/-26.725 seconds As-Left Loop Tolerance Undervoltage Relay (Voltage Trip) (ALTLV) +/-0.21 V As-Left Loop Tolerance Undervoltage Relay (Time Delay) - LOCA +/-0.40 seconds (ALTLT)

As-Left Loop Tolerance Time Delay Relay- No LOCA (ALTLTD) +/-15.0 seconds As-Found Loop Tolerance Undervoltage Relay (Voltage Trip) (AFTLV) +/-1.460 V As-Found Loop Tolerance Undervoltage Relay (Time Delay) - LOCA +0.327 seconds (AFTLT)

As-Found Loop Tolerance Time Delay Relay - No LOCA (AFTLTD) +/-26.727 seconds

I BBC BROWN SOVERI I!4 ".4.1.7-7 Issue C I NSTFrL5cT CNS ATTACHMENT2.OF PAGE j~ OF/.?

Single Phase Voltage Relays CATALOG SERIES 211 I TE-27N UNDER VOLTAGE RELAY ITE-59N OVERVOLTAGE RELAY Definite Time or High Speed Wo AM, RBr, Rrnwn Dowetwme.

10-7.4-.i-77 I-T-E SOLID STATE VOLTAGE RELAYS PACE Z ToATTACHM ENT 1.

MAC EPN alq- TABLE OF CONTENTS PAGE OF Introduction ....................... page 2 Precautions ........................ Page 2 Placing Relay into Service ......... Page 3 Built-in Test Function ............. Page 10 Application Data ................ peg Maintenance and Testing ........... page 9 INTRODUCTION These instructions contain the Information required to properly test I-T-E solid-state single phase voltage relays, ITE-27M and Install, operate, and ITE-$gN.

The I-T-E voltage relay is housed In a sami-flush drawout relay tional panel mounting. case suitable for convan- 4 All connections to the relay are made it terminals located on the rear clearly numbered. of the case and Voltage and time dial settings are located on the front panel cover. Provisions for a meter seal are included. behind a removable clear A target Indicator Is also mounted an the front panel. The target is reset by means, of a pushbutton extending through the relay cover.

An LED Indicator Is provided for convenlence In testing ind calibrating dropout settings. the pickup and PRECAUTION4 The following precautions should be taken whem applying these relays.

I. incorrect wiring may result in damage. se sure wiring agrees gram for the particular relay before the relay Is energized. with the connection dia-in the correct polarity before applying control power. Se sure control pV r. Is applied

2. Apply only the rated control voltagemerked on the front panel.

For relays with dual rated control voltage, withdraw the relay from the movable the case and check that link an the circuit board Is In the aorrect position for the system voltage. control

3. Do not attempt to menually operate target vanes return their Indication under shock, they can be damged on these relays. Although the targets by manual operation with . pencil or pointed object.

b. Do not apply high voltage tests to solid-state relays. If test Is required, partially withdraw the circuit board from th@ casea control wiring before applying the test voltage. to break the connections S. The entire circuit assembly of the voltage relay Is rmovable.

sert samothly. Do not use force. This board should in-

6. Note that removal of the tap block pin Is equivalent to setting the lowest tap.

7. follow test Instructions to verify that the relay is in proper working relay is found to be defective we suggest that It be order. If a immediate returned to the factory for repair.

replacement of the removable catalog number. We suggest that a complete element can be made from the factory& identify by spare relay be ordered as a replacement, and the (Mr.

erative unit be repaired and retained as a spare. By schematic and circuit description may be obtained from your specifying the relay catalog nmbder,t a to repair or recalibrate the relay. CAUTION: Since troubleshooting sales engineer should you desire energized equipment. caution should be taken to avoid entails working with personal shock. 0ely competent tech-nicians familiar with good safety practices should service these devices.

I-T-E SOLID-STATE VOLTAGE RELAYS 18-7.4-. 1.7-7 PAGE 3 PLACING THE RELAY INTO SERVICE

1. RECEIVING, HANDLING, STORAGE Upon receipt of the relay (when not included as part of a switchboard) examine for shipping damage. If damage or loss is evident, file a claim at once and promptly notify the nearest Brown Boveri Electric Sales Office. Keep the relay clean and dry and use normal care in hand-ling to avoid mechanical damage.

AYnAcHMNT2

2. INSTALLATION Mounti PAGE 3 OF /..2 The outline dimensions and panel drilling and cutout Information is given in Figure 1.

Cnctons All I-T-E Protective Relays have metal front panels which are connected through printed

.circuit board runs and connector wiring to a terminal at the rear of the relay case. The tar-minal Is marked "G". in all applications this terminal should be wired to ground.

Special care must be taken to connect control power in the proper polarity.

Internal and external connections are shown in the APPLICATION section, page 7.

for relays with dual rated control voltage, before energizing the relay, the relay element should be withdrawn from its case, and a visual check be made to Insure that the movable control voltage selection link has been placed on the correct terminal for the system control voltage.

The location of this link is shown In Figure 5.

& SETWINGS P1CICUP The pickup taps are identified by the actual value of voltage which will cause the output contacts to transfer.

DROPOUT Dropout taps are identified as a percentage of the pickup voltage. Taps are provided for 70, 802, 90%and 992 of Pickup, OR 30*. 40%, 50%, 60% of pickup.

TIME DIAL The time dial taps are identified as 1,2,3,4,5, and 6. Refer to the time-voltage char-acteristic curves In the APPLICATION section of this maumal. Time dial selection is not pro-vided on relays with the high speed characteristic, SPECIAL NOTE Pickup and dropout voltages may be adjusted to values other than those provided by the - ,.

fixed ta*,. hv means of Internal calibration octentlometers. See section on TESTING for vro-cedures.

On units with a time dial, the operating time may also be adjusted to any specific value between those provided by the fixed taps.

PAGE 4 ir~SI1-TT ~.~~RLy A-P-P SOLID-STATE VOLTAGE RELAVS APPLICATION OATA I-T-E Single Phase Voltage Relays PrOviae a wide range of undervoltage protection of motors and automatic bus transfer. protective functions, including transient immunity allow the use of these relays in generating Inherently high seismic and the performance of electromechanlcal relays bmuld be marginal. stations or substations Wwere The unique design of the output circuit does not require sealsin contacts allowing simpli-fication of bus-transfer schemes. Operation indicators 're provided as standard features on all types.

The ITE-27N and ITE59N are designed for those applications khere exceptional accuracy, repeatabilicy, and long term stability are required.

Harmonic distortion In the AC aveform can have & notlcible effect on the relay operating point and on measuring Instruments used to set the relay. Sea discussion in the TESTING section of this book. An internal harmonic filter module will be available at a later date for those applications where waveform distortion is a factor.

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,-re "p "Relay Outline 121035 i~I -- - -Dimesons are Ua I I I - I IAToTTACHMENT.. _1. 1

"-aiej-%o PAGE 1Lj OFfI; chracteristics of c5W g;lls if-a OeRai, Control Catalog

.Type __ PickupRAng vagn Numer ITE-271i ~0- Ito v 702 - 3 last 1-10 set 50- 110 V 702 339 Inst 21 I111175 0.1-1 80c; WU125 Vdc vi-; 110 v Li'- ttns 21110175 Inst Jl IIII I

.W125 Vict 1.U-_. W/125 Vdc 21 IT0275 60- Ti0 V 30- 6* last -Inst ti0 V 32 - 602 lost 21110275 I00- .44/125 Vdc.

iTZ-s9N 150 V 702 - *3% I1!0 sec 21 1IT0I75 100- 352 0.1-1 sec #nst ISO V 702 - pnst W1l25 Wde 591 last 48/125 Vdc 21 IU617S 100- ISO v 702 - lnst 211110175

74E1.7-7 PA PAGE 5 I-T-E SOLID STATE VOLTAGE RELAYS RATINGS TACMENT input Circuit Rating

• ITE-27N ISO Vac Maximum Continuous IIT[-59N 160 Vac Maximum Continuous PAGE5 OF/Ua Burden Less than I VA at 120 Vec Frequency  : 50/60 Hz Output Circuit  : Each contact at 125 Vdc:

ICA tripping duty SA continuous IA break, resistive O.3A break, Inductive Control Power Rated '6/12S Vdc at 0.05 ampere max.

(must operate 341 60 Vdc for 48V nominal)

(must operate 70-142 Vdc for 11IS nominal)

Temperature ANSI range -20C to +SS*C oust operate -3@0C to +10C Tolerances Pickup and dropout settings with respect to printed dial (Without harMWonC markings (factory calibration) a +/- 2%.

filter module, Pickup and dropout settings, repeatability at constant tm-after 10 minute ature and constant control voltage - +/- 0.2. (See Note) warm-up.)

Pickup and dropout settin", repetabilIty over dc control power range of 100-140 Volts (38-57V) m 4k 0.22. (See Vote)

Pickup and dropout settings, repeatability over temperature ra0toe +

0 to +We .- 0.2 (See Note)

Tolerances Time Delay instantaneous model r. 3 cycles oqerating tcm.

Definite Time nadels (see pproprlate curve),

tlO% or t20 milliseconds, whichever is greater.

Reset Time  : Less than 2 cycles.

(ITE-27N resets when Input voltage goes above pickup setting.)

(ITE-5911 resets heusn Input voltage goes below dropout setting.)

Dielectric 2000 Vac INS, I Minute, all circuits to ground.

NOTE: The three toleranceS ShowM should be considored Independent and my be cumulative.

Tolerances assue pura sine wave input signal.

Harmonic Filter (Preliminary Oats) OPTIONAL The harmonic filter module attenuates al harmonics of the SO/Oft input. Therefore, the relay then operates basically on the fundamental -omponent of the input volta"e signal. Sae figure on page 6 for typical filter response curve.

Ratings are the Som as shonu above e*cept:

Pickup and dropout settings, repeatability over temperature ranges

-t0 to .55*C if- 1.5%

0 to 40*C 4k 0.112 Time Delay instantaneous model < 5 cycles operating time Aeset Tine Lesq than 3 vco

It 7.4-.b7-7 PAZE 6 I-T-f SOLIO STATE VOLTAGE RELAYS TIME VOLTAGE CHARACTERISTICS 71W VOLIAGE CHAfACIIRISVlca

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18 7.4.1.7-7 I-T-E SOLID STATE VOLTAGE RELAYS PAGE 7 CONNECTION DIAGRAMS OUTPUT CONTACT LOGIC The following tables define the output contact states In various conditions of the measured input voltage and the control power supply. AS SHOWN means the contacts are in the state shown on the internal. connection diagram for the relay being considered. TRANSFERRED means the contacts are in the opposite state to that shown on the internal connection diagram.

CONDIT ION CONTACT LOGIC ICTE-27T ITE-S2N a Normal Control Power Input vultage below dropout setting Transferred As Shown Normal Control Power input voltage above pickup setting As Shown Transferred No Control Power As Shown As Shown AC 4-) 1+1 INPUT II I I IY )6OI0 31,3 Note: External resistor must be connected for relay to operate.

Resistor I's I Figure 2: Internal Connections shipped mounted on the relay.

,ATTACHMENT 1 TO "ka FAPI-qtyHI TP1 71 POWERt 49 figure J: Typical External Connections

10 7J.4-.7-7 PAGE 8 I-T-E SOLID STATE VOLTAGE RELAYS Pickup Voltage Level 0 Dropout Voltage Level Input Voltage Input Voltage On Decreasing Figure ie: ITE-27N Operation of Figure 4b% ITV-59N Operation of Dropout Indicating Light Pickup Indicating Light 0 Coeameor 91 ve 0 ( )

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I-T-E SOLID STATE VOLTAGE RELAYS PAGE.-

PAGE 9 TESTING

1. MAINTENANCE AND RENEWAL PARTS No routine maintenance is required on these relays. Follow test Instructions to verify that the relay is in proper working order. Ve recommend that an inoperative relay be returned to the factory for repair; however, a circuit description and/or a schematic diagram are available for those who wish to attempt repairs. Contact your local sales engineer or contact the factory. These relays have a control relay as the output stage. This output relay may be ordered from the factory. Replacement target head assembly may be ordered should the target be mechanically damaged. (See page it)

Also avallable from the factory are circuit card extenders which are recommended for usa when calibrating the relays. All these relays use the 18 point extender, catalog 200XOOl8.

OlAWOUT ELEMENT Drawout circuit boards of the same catalog number are Interchangeable. The board is reaoved by using the metal pull knobs on the front pIael. The circuit board is identified by the catalog number on the front panel and a serial number stamped on the under side of the circuit board.

CAUTION A1TACH-MFN4T Simce troubleshooting entails working with energIzed equipment, caution -7O-*'I XTOJcIeRF should be taken to avoid personal shock. Only competent technicians PAGE C1 OF )

familiar with good safety practices should service these devices.

L. HIGMP0TNTIAL TEs Do not apply high potential tests to solid state relay circuits. If a control wiring Insu-lation test Is required, withdraw the circuit board from the case before applying the test voltage.

Partial withdrawal to disconnect circuit board from connector In rear of case is adequate.

L. ACCEPTANCE TESTS Follow calibration procedures under paragraph 4. Select Time Dial 13. For ITE-17N, Chock timing by dropping voltage to 503 of pickup. For ITE-S5N, by Increasing voltage to 110 percent of pickup. Tolerances should be within those listed on page S. Calibration wy be trImmd or adjusted to the final settings required for the application at this time.

CAUSUTN TESTS Connect the relay to the proper source of control voltag (to match the relay nameplate rating). for relays with dual rating, be sure the movable link an the circuit board is in the correct position. Connect the relay to the AC test source and to a timer. Typical test cir-cuits are shom in figure 6.. If very accurate settings are required for a particular applica-tion, say within -+311 of a given voltage, & stable, harmanlc free test source is required. We recommend a "lIne corrector" type device be used in these cases. See figure 7 for the reco-men-ded AC test source circuit. The line corrector typically has less than 0.32 hamonic distortion.

A light emitting diode indicator is provided an the front panel for convenience in testing. its action is Instantaneous, thereby removing the uncertainty caused by the time delay before the output contacts transfer. The action of the indicator depends an the voltage level and the direction of voltage change and is best explained by referring to figure 4.

Pickup my be varied between the fixed taps by adjusting the pickup calibration potentio-meter R27. Pickup should be set first, with the dropout tap set at 552, and the pickup tap sat at the nearest value to the desired setting. Decrease the voltage until dropout occurs, then recheck pickup by Increasing the voltage. ReadJust until pickup occurs at precisely the desired voltage.

18-7.A I.77 I-T-E SOLID STATE VOLTAGE RELAYS PAGE 10O Potentiometer R16 is provided to adjust dropout. Set the dropout tap to the next lower tap to the desired value. Increase the input voltage to above pickup and then lower until dropout occurs. Readjust R16 and repeat until the required setting has been made.

Similarly, the time delay may be adjusted higher or lower then the values shown on the time-voltage curves by means of the time delay calibration potentiometer R41. Time delay is initiated when the voltage falls from above pickup to below the dropout setting.

If the voltage does not return to above the pickup setting by the end of the time delay period, the output contacts will transfer.

The locations of the calibration potentliomters are shown in fIgure 5. The potentiometers are multi-turn types for excellent resolution and ease of setting.

BUILT-IN TEST FUNCTION A built-in test function is provided for convenience in functlonally testing the relay 0

and associated devices. CAUTION: tests should be made with the maim circuit de-energized. If tests are to be made on an energized circuit, take all necessary precautions. The test button is labelled TRIP. For the ITE-27N, when the button is depressed, at undervoItage condition is simulated, and the relay will operate. For the ITE-55N, an overvoltage condition is simulated. For relays with time delay function, you must hold the button in for as long as the set time delay to get an operation.

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Figure 6: Typical Test Circuit Connections

1-7. P.A.I I-I-T-E SOLID STATE VOLTAGE RELAYS pAG.E II The following AC test source arrangement is suggested when pickup or drop-out settings must be made and verified to accuracies better than 13 percent of the set point. The line corrector stabilizes the line voltage and has low har-monic content. Ferroresonant regulators are not acceptable due to high har-monic content of the output waveform. Two variable transformers provide coarse and fine voltage adjustments. The voltmeter accuracy must be sufficient for the setting being made: +/-1/4 percent is recommended. The relay should be energized for 10 to 15 minutes before settings are made, to allow the circuits to stabilize.

TI, T2 Variable Autotransforters (I.S amp rating)

T3 Fillmient Transformer (I amp secondary)

V AC Voltmeter TI TI T3 COARSz FINE Figure 7. Suggested AC Test Source Arrangement if desired, calibration potentiometers can be resealed with a drop of nall polish at completion of calibration procedures.

In Case of Difficulty Check wiring to the relay.

2. Be sure control power is applied and in correct polarity.

3. Check that the control power selection link on the circuit board Is In the correct position for the system control voltage.

4. Check AC Input voltage to relay and relay settings.

Control power selection for dual rated units Is accomplished by changing a wire on a 2 position terminal block on the circuit board or by moving a link.

The link is red and looks like:

TIf AT1TAC IMENT1FI PAGE Replacement of Target Head Assembly The relay target Is an electrically operated, magnetically hold device.

Should the orange/black target disk be damaged, It can easily be replaced.

Order target head assembly part 609283-102 from the factory.

Replacement procedure:

1. From the front qf the relay, pull the exlstlng plastic holder straight off using needle nose pliers.

2. Carefully place the new target assembly on the pole pieces with disk 4,

end closest to you.

3. With control power and normal AC voltage applied, press the target reset button. If the target shows orange, remove the assembly, rotate 180 degrees, and reinstall. Actuate target reset. Target should turn to black.

BBC BROWN BOVERI BBC Brown Baved, Inc.

35 Norm Snowdrift Road Allentown. PA 18106 Pthone: (215) 395.7333 Issue C (3/84)

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Attachment 2 to JC-Q1P81-90024 SHEET 1 OF 17 2400V to 4800V BIL 60 kV Application Indoor Voltage Designed for indoor service; suitable for operating meters. instruments, relays, and control devies.

JVM-3 Regulatory Agency Approvals 50/60 Hz UIL Recognized ........................................ File El 78265 Thermal Rating (Volt-Amperes) 55°C Rise above 300C Ambient .................... 750 30'C Rise above 55*C Ambient ............................... 500 Weight - Shlipplng/Not IappAoXIh*taW in pourds)

Unfused .......................... 35/30 With Fuses ................................................... ... 38/S3 Reference Drawings Accuracy Curve ........................................... 96589241268 Excitation Curve ................... 5454043 Outline Drawings:

Unfused ................................ 8949739 One/Two Fuse;,-040 and -042 ................ 9926292 One Fuse; -033, -31, -s2 .......................... 8949740 Two Fuse; -024, -18, -19 .......................... 8949741 Wiring Diagram .................... refer to page 42, figure 5 Accessories ........................... Catalog Number Fuses:

2400 Volt Class, I Ampere .................... 9F60AABOOI 4800 Volt Class, I Ampere ................... 9F60BBDOOI 4800 Volt Class, 0.5 Ampere ................ 9F60BBD905 Secondary Terminal Conduit Box ..... 9925183001 JV, ODATA TABLU Lhi'e-ToUn ANSI !S!!rý Carnlito 60 KU I c vg*luft I ToM [ B~uf Per ANN Drdn hmodanc For Peeunwis~ib Opara.tawat a*~ at PAMt Voltas" PftmaY Foss PrimCwean j Prim OspItI at j U% utt Opat asd at S$% Catio ROW A V V wv* d V~ IL Ratd Vo~tag v 0 VMmiba Unfunld 2400 2400 4180 2400 20:1 0.3W.X.M.Y: 1-2Z,.3W.x: Ili*M.YLaw" XV.for, YVIj* 76X21001 . -

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Attachment 2 to JC-Q1P81-90024 SHEET 2 OF 17 INSTRUCTION MANUAL FOR UNDERVOLTAGEI OVERVOLTAGE, AND UNDER/OVERVOLTAGE RELAYS MODEL NUMBERS: BEI-27, BE1-59, AND BEI-27/59 46 fI..000000t T A

- MIB Basler Electric Highland, Illinois Publication: 9 1706 00 990 Revision: B E-MCP92/ 105 1-E225004-4-4--is-' n

Attachment 2 to JC-Q1P81-90024 SECTION 1 SHEET 3 OF 17 GENERAL INFORMATION PURPOSE The BEI-Z7 Undervoltage, BE1-59 Overvoltage and the BEI-27/5g Under/Overvoltage Relays are solid-state devices which provide reliable protection for generators, motors and transformers against adverse system voltage conditions.

Application Electric power systems are designed for constant voltage operation. Loads utilizing commercial electric power are designed to operate at a constant input voltage level with some tolerance. Radical voltage variations on a power system are indicative of a system malfunction. Protective relays which monitor system voltage and provide an output signal when the voltage goes outside predeter-mined limits, find a variety of applications. Some of these applications include motor, and transformer protection, interface protection for cogeneration systems, and supervision of automatic transfer switching schemes.

Motor Protection When selecting the type of protection for motor applications, the motor type, voltage rating, horsepower, thermal capability during start-up, and exposure to automatic transfer restarting following a voltage interruption need to be con-sidered. During motor start-up, a low terminal voltage condition will inhibit the motor from reaching rated speed. The 8E1-27 undervoltage relay will detect this low voltage condition and trip. Critical applications requiring continuous motor operation and applications where overloads during start-up may be main-tained for a given time period, usually have a definite time or inverse time delay characteristic incorporated to avoid unnecessary tripping during low voltage dips. If the undervoltage condition persists for the established time delay, the relay output contacts are connected to the station aarm annunciator panel, allowing the station operator to take corrective action. The BEl-59 Overvoltage relay is applied to insure the voltage does not exceed the limits established by the machine manufacturer for proper operation. Overvoltage con-ditions stress the insulation level of the equipment and may cause a dielectric breakdown resulting in a flashover to ground.

Automatic Transfer Switching Distribution substations are sometimes designed with duplicate supply circuits and transformers to eliminate service interruptions due to faults located on the primary feeder. In order to restore service within a given acceptable time period, automatic transfer switching can be applied to initiate the throwover from primary power to the alternate power source. The BE1-27 Undervoltage Relay can initiate switching after a given time delay to void transfer switching during temporary low voltage conditions. To return the substation to normal service upon the restoration of primary voltage, the BEl-59 overvoltage relay supervises the transition to its normal operating condition.

1-1 9*WWa~e Ek-e"

Attachment 2 Cogenerati on to JC-QIP81-90024 SHEET 4 OF 17 utilities employ the use of a voltage check scheme to supervise reclosing at the substation when cogenerators are connected to a radial distribution feeder and the cogenerator is capable of supplying the entire load when the utility circuit breaker Is open. During a faulted condition, the utility requires the cogenera-tor to be disconnected from the system before reclosing the utility breaker. If the cogenerator is connected to the system, the utility will reclose to an energized line.

This could result in reconnecting two systems out of synchronism with each other. A BE1-27 undervoltage relay monitoring the line voltage will inhibit reclosing of the utility circuit breaker if the line is energized by the cogen-erator.

At the interface between the utility and the cogenerator, overvoltage and under-voltage relays are Installed as minimum protection to provide an operating-voltage window for the cogenerator. During faulted conditions, when the cogenerator may become overloaded, the BE1.27 Undervoltage Relay will detect the decline in voltage and remove the cogenerator from the system. The BE1-59 Overvoltage Relay will protect the system from overvoltage conditions that occur when power factor correction capacitors are located on the feeder.

Transformer Protection Voltage relays can be applied to protect large transformers from damage as a result of overexcitation. The concern for transformer overvoltage may be mini-mized in many power system applications where proper voltage control of the generating unit is provided. However, where a tap changing regulating trans-former is located between the generating source and the load, some form of voltage protection may be required to supplement the tap changing control and to prevent equipment damage due to over, as well as undervoltages resulting from a failure of the tap changing control. The BE1-27/59 Under/Overvoltage Relay is well suited for these applications.

Ground Fault Detection In a three-phase, three-wire system, a single conductor may break or the Insula-tion may deteriorate resulting in a high resistance ground fault which may not be detected by the overcurrent relays. This condition, however, may be sensed by an overvoltage relay connected to a grounded wye, broken delta set of poten-tial transformers (PT's) as illustrated in Figure 1-1. With this connection, and a sensitive relay setting, an unbalanced voltage condition, such as described above, can be quickly detected and isolated.

Y.i Figure 1-1. Ground Fault Detection 1-2 M.-.

-/Attachment 2 Ito JC-Q1P81-900 2 4 MODEL AND STYLE NUMBER SHEET 5 OF 17 The electrical characteristics and operational features included in a specific relay are defined by a combination of letters and numbers which constitutes the device's style number. The style number together with the model number describe the features and options in a particular device and appear on the front panel, drawout cradle, and inside the case assembly. The model number BE1-27/59 designates the relay as a Basler Electric Class 100 Under/Overvoltage Relay.

STYLE NUMBER tOENTIFICATION CHART t ap-- a.

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fl M2,1 W111nwe"" M V CO. "0 94 Sem k"0111111,a1m010 Lft mm,,a14 m3e .....

"I*we " *,me$*I*W C" tWUb#' mInumsumm *.4e-L40 Lef55 6"UwWdlmkv t Uge~rnWf VM w 1II 041 PUT sTee "NUMBER Ke "OF *"0@ - $s 11 o The style number identification chart above illustrates the manner in which a relay's style numlber is determined. For example, if the model number Is BE1-27/59 and the style number is A3F E13 AOS1F the device has the following features:

A) Single-phase voltage sensing

3) Sensing compatible input open with a pickup adjustment range of 55 to 160 vac output relays (one per function)

F) Two normally El) Definite timing for each functton r) Operating power derived from a 125 Vdc or 100/120 Vac source A) Two internally operated target indicators ,(one per function)

0) No instantaneous functions

3) Push-to-energize outputs (pushbuttons)

F) Two normally open auxiliary output relays (one per function)

F) Semi-flush J) ~~~ oe mounting drvdfoI ~ Oprtn 15Vco BC 0/10Vcsuc 1-3

Attachment 2 BEI-27/59 to JC-01P81-90024 SHEET 6 OF 17 SPECIFICATIONS Voltage Sensing Nominally rated at 50160 Hz, (120/240V or 100/200V) with a maximum continuous voltage rating of 360V (120V nominal) or 480V (240V nominal) at a burden less than I VA per phase. Frequency range is from 40 to 70 liz.

Power Supply Nominal In~pt siirde Type [l t Voltage at Voltale Rang eminsal K 48 VIc 24 to 6O VdC i's W j 125 We 62 to ISoTd 7.5 W 120 VIC go to 132 VIC 19.0 VA LQ Z4VdC It to 32 Y 7.0 W VY 40 V4 24 to 60WC 6.6 V lS Vdc ,ataS*, .. 7.5 W Z MSoV6 140 to W*a v 9.5W SJ* Vc ooto no vc n.oVA The Type Y PONr aply Is field selectable for 48 or In Vft.

Selectiaa atn be tai"Olmmtatthe time of intallatina.

This pomwr supply option Is factory set for 12t5 VdC.

I Type L PMWr suimply mUy rewire 14 Vdc tobegin operating. Once coarselln. the Woltage a" be reuced to 12 VWn.

Target Indicators Magnetically latching, manually reset target indicators are optionally available to indicate that a trip output contact has energized. Either Internally operated or current operated targets may be selected. Current operated targets require a minimum of 0.2 Adc flowing through the output trip circuit, and are rated at 30 A for 1 second, 7 A for 2 minutes, and 3 A continuously.

Internally operated targets should be selected if the breaker control circuit is ac powered, or if the relay has normally closed output contacts.

Output Contacts Output contacts are rated as follows:

Resistive 25IrVdci- make, break, and carry 7 A continuously.

250 Vdc - make and carry 30 A for 0.2 seconds, carry 7 A con-tinuously, break 0.1 A.

500 Vdc make and carry 15 A for 0.2 seconds, carry 7 A con-tinuously, break 0.1 A.

Inductive I Vac, 125 Vdc, 250 Vdc - break 0.1 A (L/R = 0.04).

1-4 LEBee Eleebie

Attachment 2 BEI1-27/59 to JC-QIP81-90024 SHEET 7 OF 17 Undervoltage and Overvoltage Continuously adjustable over the range of Pickup Range I to 40, 55 to 160, or 110 to 320 Vac as defined by the Style Chart. See Section 3, System Voltages for explanation of pickup ranges.

Undervoltage and Overvoltage

+2%or +0.5 volts of the pickup setting, Pickup Accuracy 'hichevier is greater.

Dropout Accuracy +2%of pickup.

Instantaneous Time Accuracy Less than 50 ms for a voltage level that exceeds the pickup setting by 5%or 1 volt, whichever is greater.

Definite Time Range Adjustable over the range of 0.1 to 9.9 seconds in increments of 0.1 seconds. A setting of 00 designates instantaneous timing.

Oefinite Time Accuracy Within + one half of the least signifi-cant diit time plus 50 ms.

Inverse Time Inverse curve types are defined by the Style Chart and are represented by the curves shown on pages 3-4, 3-5, and 3-6.

Inverse time is adjustable from 01 to 99 in increments of 01. Incrementing the time dial varies the inverse curve along the Y axis. A setting of 00 designates instantaneous timing.

Inverse Time Accuracy Within +5% or 50 ms (whichever is greaterT of the indicated time for any combination of the time dial setting and pickup setting and is repeatable within

+2% or 50 ms (whichever is greater) for

'Fy comtnation of time dial and tap setting.

Shock 15g in each of three mutually perpen-dicular axes.

Vibration 2g in each of three mutually perpen-dicular axes swept over the range of 10 to 500 Hz for a total of six sweeps, 15 minutes each sweep.

Isolation 2500 Vac at 60 Hz for 1 minute (1500 Vac for one minute across open contacts) in accordance with IEC 255-5 and ANSI/IEEE C37.90-1978 (Dielectric Test).

1-S k* EleeR00

Attachment 2 to JC-01 P81-90024 SHEET 8 OF 17 Surge Withstand Capability Qualified to ANSI/IEEE C37.90-1978, C37.90a-1974, and IEC 255.

Fast Transient Qualified to ASSI/IEEE C37.90.1-198X.

Impulse Test Qualified to IEC 255-5.

Temperature Operating -400C (-400F) to +704C (+1586F)

Storage -650 C (-850F) to +I00°C (+2120F)

Weight 14 pounds maximum.

Case Size All units supplied in an S1 size case.

1-6 gee,., Ete.tnc mm

Aottachment to JC-QIP81-90024 2 SHEET 9 OF 17 GENERAL ELECTRIC'S NEW TYPE 4725 FREQUENCY TRANSDUCERS

• New Compact Size.

• *0.8% Accuracy 0 +/-0.02% Voltage Rejection 1 me output (0-10K ohms Load Range)

• +/-0.02% linearity 0 :0.02% Load Resistance effect

• Readily Interchanged Elec-trically & Mechanc ally with Type 4701 FUNCTION TWO 4725 hcaro s =convwt oQwcy of 50. 60,8 W400WHz at 120 valo into do ffamlw (.A ma to +0.5 mi*. The toed may te O-OKOhnS.

OESCRIPTION noe ftWw CoMpas Tyvpe 4725 Fnpreicy Tim'Aducv emocro in btsatew ftiog to w-e a constt cturrm ouptd into a vlatm Mod wtodmee. OuNNN open" dchwWtb. much s tsea dw r-02% tame1r tntuo an 0wumW, wer -20*C to

+"6V - taftmtmposikwtmm geI*tua Swm the eod.,t do.

OWp. The asmonw*cm and k4owated dauie wam mounied on epoaV *br ga*eda baL T10 eotrw amuaeMd ma~rtw TYPOAL PER1OtMAMS CURM eommft at Mawes unito are mowrNed a n InbfI stlee au s housed in a welded w tm sleat e"leue. Since them Ieno put.

Ung. removo oEwo se*r ews'rde esy ac amseato "o e eai -

GENERAL APPUCATION 0 prebog" a awtlboao

• cavo et uws tthms*l"rn e.uomet

• Uv*,mghr, fIn.Ow'W 0 *ft*0 nMlor amle amu'd-umtaE~at e.t&n~eUMW40afiwul e

• oPWIA &~u The TV"e 4725 Frequs'say T-wwdaw Is ap" of dkt ownitor 111 ,1buskaerd at *ectasn ayd044 pofgenafu foo Do.

ViON emommwyedu 4# Tye 0a-16M 30.ud 40 altii-6, 3I TOMA M mm bOd sNMMlMl rype iWO Edowise; Type 1i or rype 106 n*s.

tef to"e 8 LOOKCOC' HORIZON UA*0POW iad n tefmaM CH

&Cr-tucodee Rwe~ncy tomawe Musd by 056s uNIne, aen cantwumambdwusetwimomL i~*i , *fD OPERATION ftowencY to do wdusm' I&eamluphed Mrwuh Me use of ad. l~~AVr DWMWMx -CKIII j-GA---- 1S ~ ' . ..~IN bid ffgctd*ton

• Otmmor and meiu pa*bo cws*

A Inputreisan deheusce wlint~ig ehos Zeasmeu ummng pov*ln w of sti Inut*1.wevtsim tihe t beIta lcairn w0e owftht 064 Z"e Grm~asef ofnftkwdwfw a wase Mhe krWu *w~ftchl ~l to ciWip stoe aid Wwsete & OhreW ecsion cugegh *e04ve elemmw t 0 an Vugmln eMOL. The do lwem I t'e ICmong a11e ISAamaoelped 1o a conowit cumrnt 0uA~m 819eMO the Ngh#gui o*ermionamplfl csa~ *%neq Surge ptIom ma ~purdl giuLm shudore employed W prOude, inVat loet, miod -mautmope Sehily. high recilf mi bud Sid

• • sMWty we pded ftough fe uase of O.hm pwe enralloe ew.

• EaM,4 pa.

2

( TYP1.4729PIEJNCYTRAOUcIRS Attachment 2 GENERAL SPECIFICATIONS to JC-QIP81-90024

=SHEET 10 OF 17 INPUTIOUTPUT& WIRING DATA Full Scale Calibration: see Table I Potantala Inputu

a. Nominal.85-135 volts

b. Overload withstand, continuous, 150.valts

c. Overload withstand, If minute, 200 volts

8. Burden at 120 volts, <2 vs, including amplifier power Frequmncy Span as Table 1: for other spans consult factory Opeastng Tempermtr Rafngn -20"C to +65 C M. Thmpeerture Effect on Acuracy:

<.O.2% of center frequency Full-Scato Outpu I me Output Lad Rango 0-10( ohms Unarit)y -t0.02% of center frequency Une V~lag Rejecion: :0,02% of center frequency DIMENSIONS Adjustmnmft 3 V16

a. zero, : 10% of center frequency, miirmum adlustment

b. caflbrate *20% of nomnual fuN scale values in Table I, 27/16 minimum awustability At Component On Output SlgnaLf <1%

Respons T1mi* 400 millilseconds M SPA 123 Olelhctatc Test: 1500 v RMS Weight 1.2 Ik 1 1/2 00L TABLE I. FREQUENCY TRANSBUCERS Thpkat Standard Model Calibrato.

i FrequmreW Span Hl afs Outpu Raqe 0C 134 01 IW Clawt"f 1W LA cowbl M*IA t~

45 50 S5 50-4?2500JSHB -03= U0.0 +0.Sim 0-10 55 60 65 50-472ZOOJKNO -ISma (Ome +.5'ma 0-104 330 40 420 50.47250 -03mOS- U=n +0m 01 Note: AN r-Oferevw eftpaweidton 6I3 oWag i Iiw K INSTRUMENT PRODUCTS DEPARTMENT r

40 FEDERAL STREET LYNN. MASS. 01910 GENERAL ; ELECTRIC W(SM)

INSTRUCTIONS GET-19OOSE SWPPZFDES GrIZ-9008D IAt achment 24 to JC-QIP81-900 SHEET 112 OF 17 mu FREQUENCY RELAYS TYPES MJFIA, IJF51B, and IJP52A GENERAL* ELECTRIC

%W4WrAývv@ 9 fquemny £~aa).aya -pe Las Attachment 2 to JC-Q1P81-9002 4 SHEET 12 OF 17 SEAL-IN L.

UNIT TAP

.StATONAfff 8RlJS 4J AND CONTACT ASSEMSLY SEAL.- I-N Ny UNIT CONTROL SPRING AND ADJUSTING TRGETR . RING MOVING CONTACT, AA MAGNET 6.9 Flo. I Tjpe IN Relay Rev4e From Case (Fmot View) 3

'a ADJUSTABL, I N

@1 lb RES*UOIr L s OPERATNG ,.)

OWIL

)

Nig. 2 Type 1JF elay Pmved Frm Case (Rear View) 2

FREQUENCY RELAYS Attachment 2 4

to JC-Q1 P81-9002 TYPE IF SHEET 13 OF 17 INTRODUCTION These are relays of the induction disk type back of the case. The cases and cradles are so intended for the prutection of apparatus against the constructed that the relay cannot be inserted in the effects of overfrequency or under/requency. cae upside down. The connecting plug, besides making the electrical connections between the re-The Type IJF Is an induction disk type relay Te ctive blocks of the cradle and case, also lock mounted in a single unit drawout case. It has two latch In place. The cover which is fastened to shaded-pole U-magnet type driving elements acting the case by thumbscrews, holds the connecting plug on opposite sides of the disk. One of these, the in place.

oerating element, is designed to drive the disk in e direction to close the left contacts and the To draw out the relay unit the cover is first other, the restraining element to drive le disk It removed, and the plug drawn out. Shorting bars are the contact-openingdirectionon relays having single- provided in the case to short the current transformer throw contacts and to close the right contacts on circuits. The latches are then released, and the relays having double-throw contacts. The disk relay unit can be easily draw out. To replace the shaft Is restrained by a spiral spring, the principal relay unit, the reverse order is followed.

purpose of which is to hold the contacts open when the relay is do-energized. The motion of the disk A separate testing plug can be inserted In place is retarded by permanent magnets to give the of the connecting plug to test the relay in place on correct time delay for closing the contacts. the panel either from its own source of current and voltage, or from other sources. Or, the relay unit There is a seal-in unit mounted to the left of can be drawn out and replaced by another which has the shaft on the Type IJF5IA and UFSIB relays. been tested in the laboratory.

The Type IJF52A relay has a seal-in unit mounted on both sides of the shaft. This element has Its APPLICATION coil in series and its contacts in parallel with the main contacts such that when the main contacts The Type UJF frequency relay. are recom-close, the seal-in element picks up and seals In. mended for protection of synchronous apparatus When the seal-in element picks up it raises a against overapeed or underspeed conditions caused target Into view which latches up and remains by loss of load In the case of generators, or loss of exposed until released by pressing a button beneath supply power In the awse of motor and condensers.

the lower left corner of the cover. The relays can be used to operate protective de-vices, or to sound an alarm whenever the frequency The case is suitable for either surface or of the circuit varies by a predetermined amount semaflush panel mounting and an assortment of above or below normal.

hardware is. provided for either mounting. The cover attaches to the case and also carries the RATINGS reset mechanism when one is required. Each cover screw has provision for a sealing wire. These relays are available in frequency rating from 25 to 60 cycles and voltage ratings of II and The case has studs or screw connections at 230 volts.

both ends or at the bottom only for the external connections. The electrical connections between The current closing rating of the contacts is the relay units and the case studs are made 30 amperes for voltages not exceeding 250 volts.

through spring backed contact fingers mounted in The current-carrying ratings are afected by the stationary molded Inner and outer blocks between selection of the tap on the seal-in coil as Indicated which nests a removable connecting plug which In Table L completes the circuits. The outer blocks, attached to the case, have the studs for the external con- TABLE I nections, and the inner blocks have the terminals for the internal connections.

7 1 ,.t~n Amperes, AC or DC The relay mechanism is mounted in a steel 2-Amp TaplO .2 Amp Tap framework called the cradle and is a complete unit with all leads being terminated at the inner block. Tripping Duty 30 5 This cradle is held firmly in the case with a latch 3$

at the top and the bottom and by a guide pin at the carry continuously 0.3

- ~ -

Thea.snas c~a db not purport to o@m'r all details or iuaiations in equitinte nr ev prvvid* for

• vizry possible contingency to bo mat in conection wiith **u~jtaj",a Vpacation or aefatasano. Shou~ld tr=ha intonation be derized or should pseticular Vzoh.1e arie whicb ame WCt 00Md sufficiently~ lot the puscham.:ae purposes, the mutter should be rofazred to the ceneral Zidotrig Coxpwg.

To the ewtwnt reaquird M& produwoe bsarihu hesen Moot MAPpJcabe ANSY # Z= a d MM~raena~rdf but no such d5asguflos Is qiven with rwese to local codes and ordinances becase thug vean gmotly.

a

GEI-19008 Frequency Relays Type U?

Attachment 2 to JC-1PB-90024 SHEET 14 OF 17 nm~m. ,

0l10*0.A* 10J cDou i338 lV401 OIfaI.

IU 1 CL U II ALI 1*SM o" 11 11 Os.

, * .! . S I I

p I £ A ,

V v I I 9, a

S U V I'.

• I1N C:

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i Ia 0

1.*............................... - kJ- - -- - -

41 40 M gi I

-u-I" a . ......

L - .h I

• I I z U

up Flo, 3 Type lJFSIA Relay, Voltage-Frequenvy Fig. 4 TYPO 1*11*A Rtelay. TUMa-uttweqei Citaracteristics Ctiaradwirstics MR A~~idftf= !rT4 vw I

I I

S

&0 tV S U I IA.

U I

IS )

U I

U

'Ott.~r

£0111 U II..

Figs 5 Iype 105111 Meayo Voltage-Frvquency F12- 6 TYP@ lJF513 Relay, TlueFroquewoq )

Characteristics Characteh tid es 4

Attachment 2 Frequency Relays Type U7F GEl-19008 0 2 4 , SHEET 15 OF 17 toJC-Q1P81-90 The 2-ampere tap has a d-c resistance of 0.13 8URDENS Ohms and a 60 cycle impedance of 0.53 ohms while the 0.2-ampere tap has a 7 ohm d-c resistance and Burden data for the 55-60 cycle under frequency a 52 ohm Go cycle Impedance. The tap setting used relay and 60-65 cycles overfrequency relays are on the seal-in element is determined by the current given in Table I at 115 volts 80 cycles.

drawn by the trip coiL Burdens listed are total burden of relay.

The 0.2-ampere tap is for use with trip coils TABLE 17 that operate on currents ranging from 0.2 up to 2.0 amperes at the minimum control voltage. 1f this Relay Amps volt Factor Power Wts tap Is used with trip coils requiring more than 2 amperes, there Is a possibility that the 7-ohm FW51A 8.7 .99 8.6 resistance will reduce the current to so low a value IJVSIB 5.8 j 798 that the breaker will not be tripped. 57 Total burdens for the Type IMZA relay at 115 volts are as follows.

The 2-ampere tap should be used with trip coils that take 2 aptes or more at minimum control voltage, p ded the tripping current does not TABLE IM exceed 30 amperes at the maximum contro Voltage.

If the trtpptng current exceeds 30 amperes 2A Volt Power watts Amps Factor auxiliary relay should be used, the connections being such that the trUping current does not paes througthe contacts or the taget and seal-in coils of the protective relay.

25 6010.7 6.3 .9

.89 1 6 9.5 RECEIVING, HANDLING AND STORAGE These relays, when not included as a part of a pWur g or thethe rela Adsin order that none ot the parts are disturbed.

control panel, w be shipped in cartons designed to protect them against dmunae. Immediately upon receipt of the relay, an mination should be made If the relays are not tobe Intalled Immediately, for any damage sustained during shipment If they should be stored In their original c a or damage resultlng from rough handlin isevident, place that is free from moisture, dust,=r4 metallic a claim should beflledatoncewith the transprta chips. Foreign matter collected on te outasie of company and the nearest Sales Office of the General t ce may find its way inside when the cover is Electric Company notified promptly. removed and came trouble In the operti of the Reasonable care should be exercised In un- relay.

INSTALLATION LOCATION AtDCIUA.tZZS When external capacitors, and In same cases The location should be clean and dry, free from resistors, are funished with relays they are Ide-dust and excessive vibration, and well lighted to tifled by means of serial number. These numbers facilitate inspection and testing. ae of the form X-lO2 or OA.-155 The purpose of these numbers is to insure that emrlay, when MOUNTING installed, will be provided with the samb-Wuxlaries The relay should be mounted on a verta with which it wan calibrated at the factorM surface. The outine and panel diagram Is shown In Fig. 12. The reason for this precaution Is to eliminate the variatlon In callbablons of the relays which would otherwise result from the variation tn elec-CONNECTIONS trical properties of the auxillaries.

Internal connection diagrams for the various ADJUSTMENTS relay types are shown in Fig. 7 to 9 inclusive. TARGET AND SEAL-IN ELEMENT Typical wiring diagrams are given in Fli lOand 11.

For trip coils operating on currents ranging One of the mounting studs or screws should be from 0.2 up to 2.0 amperes at he minimum cntrol permanently grounded by a conductor not less than voltage, set the targt and seal-in tap plug in the No. 12 B&S gW copper wire or its equivalent. 0.2-ampere tap.

5

6~

BURDENS IMPOSED ON POTEMirAL TRANSFORMERS (Data o* for one etomenl and based on 120 volts at rate*d frmquenty; wheam no speclfic frquency raling is assignaed, date are for 60 cyclea.)

42,9 MING. ........ . i -et VOLTMETERS 8.30.12.25-1 .13! 0 1 0 30204 2"4 o.52 4,5 4.7 0,9 0.18 A-I 51 &16-361 Sl.pg.6a Sull t30 60 24001 1170 4&0 6.0 4 A7 7 "7 A1-40 I 40 Io90o 324 Ai ,.11 ,g 394 0,%

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- .7 'rs-150 Uto 123

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Attachment 2 to JC-Q1 P81-90024 I

SHEET 17 OF 17 Potential Transformer aftlecI -or is onmAll. so small that it ean be neglected VZASZ ACCURACY CLAS32S FOR ?OTL4IMAL in all tx the Most etifg measuremem. TRANSFORMERS In general ternmi a Ratio Correction Factor 'Limits of Ratsiti Colf tLimi~ts 1 wrFc (RCF) greater than I-for instance, I .002-will ca- c Accuracy. retonF or so I oweru F1~ac.

Me" , Transformer Cor* -" t*%'2"'-°-* Load the meters and inlsrumebts in the secondar" circuit to rection Factor gre.... .o.d read low (0.2 percent low for an RCF of 1.002).

A negative (lagging) phme-angle error will cuse 1.2 1.012-0,9a 0.6-1.0 a wattmetet in the secondary circuit of a potential trnmfotmer to read high (for the normna situation of 0.A I106-0.4 0.6-10 lagging line power factors). This results from the fact tha-, t 12n" potenial phase-amnigIerror decreases the OJ IJo-o /06-,

power acto- angle of the secondary ch'ut over what The 4Wdh iIusm for eo* nV de* esebsV 10 pe,,¢, *6vwm

.4I i w ina e primary rcuit. by dmcesing deogle ftoel "b"* to 10e 0 mm u'euged ngedm. o.feted hwty,

• ad ftrm aso bardm - Ike wu *go t. 0 upedd by which the current lap the voltage as shown in Fig. brdenm.

9. Snce diewatm readiN resuli frorn the prod= of the voltage, currt, sad power f=or (cosine of The A44 C.ar ama Fmr (RCF) hu been defined power-factor nge), adecreased angle gives n appar- as the fictor by which the marked tatio must be ent higher poaer factor which nakes the w mamer multiplied in order to obain the true ratio.

read high. The Tmmfnr Carmi Fmor (TC) repre-seInsaI thod of setting down in aoc number, die STANDARD ACCURACY CLAICATION combined effe= of the ratio error and the phase-angie The USASi stan* rot iastmumm Tra.- UI 0an wg*umTt or similar measurements where the formers, USAS C57.1 3, has standardized on a methd change in power factor from primary to secondary cir-of classifying pottial mnsfomers as to accuracy. cuits enters the measurement. TCV is defed as the As the :ccamy is dependent on the burden, standard factor by whach wutmeter nmcaV must be multiplied burdens have been designated, and these re the bur-to correct for the combined of=ec of the

• den at which the accuracy is to be chaifed.

transformer ratio correction factor and phase angle.

C "Thestandd burden have been chosen to cover The limit of TCF. as indiated in the table above, have been set up by USASI for the rane of load the range notmally encoumvred in serice and arm power Factor sea oh in the table If the power factor listed by the letters W, X, Y, Z. and 2. as follows: of the primary circu is outside this range, dhe TCF ofte trunfome dao may be outside the limits spe-USAS1 VrANDARD BURDNS FOR POTZNTAL ified, evec thoigh the trsim er is noretly listed TRMNFORMBR3 aS oe which wl meet a ctMin aurcy cLa.

Burden Volt.m1mpea Burden Since published data on ptensial-tras*frmer atuln Wo Power 1o rair characteristics. as well u the dam given on tormer W

calibration certificaes. are usually given in the forM ILS CI1O X 2.0 W0.

of ratio correction factor and phase-angle eror, it is Y 75.0 0.85 neIe:sary to have a mesm of h6erpreti* des damA Z 000.0 05 in tems of dte accuracy dssifleatiou given in the ZZ 4O0.0 GuS rible. This is dine as follows:

"00-JU., 5"awd us " Womiosd bu4... for **saw For may known ratio correction &cwr of a given AW awlmmet d" have Th -e wo -eupe , eed PWW.f"e potential ctranstfer, the positive and negative limiting Ad ~.for 4 6it - G& values of the phase-angle error (7) in minutes may It should be pointed n that mhe burden of any specific be adequately expresed asfollows:

mecer or intrument may approximate , but seldom is ,-2600 (U&c -ROC)t.

the same s any one of the standard burdens. The standa. burden serves merely as a standardized refec.

ance point at which the accuracy of the transformer t,.e (MOWN-" -2i.CTCF-RCF)-a. ow"hM husl s o Fit.

10 duwwedl ftm Isan awazinatw ooly. TUcow meorml is-may be stated.

CoO*6?+vr)mO.8tr 1fowem. Owe*ppvximntw falwmta Ie'.

The aci:cracy dusiflcation as given by USASI "tIdumvery lintmoe iMc* sA rl"iaa "adis etirely dquat is to follows: for om palPe .

11

Attachment 3 to JC-101 P81-90024 SHEET 1 OF 4 SPECIFICATIONS F2253 is the only 12250 POWER SYSTEM SIMULATORS productoffered General Specifications by Doble in Source Operation: Accuracr. From 0( to 5# C, F2250 series. Accuracy specifications include aP errors t0.0005% or +/-5 PPM; at 60Hz contributed by variations in power line voltage, load regulation, stability, and frequency accuracy is F2251 and F2252 temperature, up to full output power. Stable +/-0.0003 Hz are no longera source operation in four quadrants: load mawI mne dc. ac: base frequency of power factor from I to 0, leading or lagging. 50/60 Hz, up to 20th and partof Doble The F2250 Family is supplied with a Certifi- the 100th harmonic cate of Calibration traceable to the National productline. Institute of Standards and Technology. F2010 Mlnicontroller/Automation Ranges and Resolutions:

Source Power:

Range: 0.1 to 9999.9 lz May be lower than the maximum rating at frequencies other than 50/60 Hz or DC. Range is dependent on the frequency selec-tion on the simulator. When the frequency Electrostatic Discharge Immunity: selection on the simulator is60 (50) Hz.

IEC 801-2: 1.E.C. performance level 1 @ range is 0.1 Hz to 99,999 Hz with 0.001 Hz 10 KV: normal performance within specifica- resolution. When a hgher level of harmonic tions. IE.C. performance level 2 @ 20 KV. is selected on the simulator, then the range no permanent damage. is the base range (0.1 - 99.999 Hz) multi-Surge Withstand Capability: plied by the selected level of harmonic, and ANSW/IEEE C37.90. The F2250 functions as a the resolution is equal to the order of the source during surge withstand capability tests, harmconic times (0.001 Hz).

when the specified isolating drcut is inter- Example 1: Ifthe base frequency selection posed between the F2250 and the test rety. is 120 (or 100) Hz, which is the second AC Amplitude Accuracy: harmonic, then the range is 0.2 Hz to 199.99 From 20° to 3W0 C, +/-0.4% of reading maxl- Hz with a resolution of 0.002 Hz.

mun at 50/60 Hz From 0" to 509 C, ;O.5% Ecample 2: Ifthe base frequency selection is of reading absolute maximum Typically 0.2% 300 (or 250) Hz, which is the fifth harmonic, of reading. then the range is 0.5 to 499.99 Hz with a Distortion:

resolution of 0.005 Hz, Low distortion sine waves; total harmonic RAMP/SET:

distortion: 0.2% typical; 2% maximum at RAMP Continuously increments/decre-50/60 Hz. ments voltage, current, and phase angle at Noise: different ramp rates. Insures smooth, linear

-80 dB of range changes invalue carred to next significant digit, by changing the least significant digit.

Phase Angle: Ramp Rates - Least Significant Digits e Range: 0 to + 359.9. (Lead) / 0 to Second (L.S.D-fs).

-359.9 (Lag)

Accuracy: +/-0.25" at 50/60 Hz Ampiltude: 1,5,10, 100 and 1000 L.S.Dis "a

a Phase Angle: 1,2,5, 360 LS.D./s.

Resolluton: ;L0,1" at 50160 Hz SET: Individually sets each digit, with next Frequency: significant digit carry over, Range: dc: ac from

/ ~,

0.1 Hzto 10kHz

Attachment 3 to JC-1Q1P81-90024 General Specifications - continued SHEET 2 OF 4 Logic Outputs: Multi-Mode Digital Tinter: Battery Simulator (optional):

Two sets of galvanically isolated Logic Outputs, Accwaorac +/-0.0005% of reading, t one Ranp, 48 V, 125 V, 250 V-dc each set has a normally open (Form A) termi- least significant digit, +/-50 Power, 60 w nal, shared common terminal, and a normally microSeconds.

closed (Form B) terminal.

Enclosure:

Resolultim 10 microSeconds. (1 least High inpact, molded, flame retardant ABS Switching Power? 10 watts maximum significant digit).

- Meets National SafeTransit Associatn testing InputVoltage: 300 V-dc and (or) Ranges: 0 - 9999.99 tridliseconds; specification ac peak maximum 0 - 9999,99 seconds; No. IA for immunity to severe shock and Switching Current 0.2 A make or 0 - 9999,99 cycles; vibraton break maximum GPS time of day may be displayed when using the F2895 GPS Option Dimensions:

Carry Current 0.3 A maximum 9.5 x 19.75 x 22 inches or 24 x 50 x 55.8 cm Operate Time: 1 millisecond Line Power Supply:

105 - 132 V or 210 - 264 V (field selectable) Weight:

maximum at 47-63 Hz 50 IbsJ22.7 kg LogictSignal Inputs: Audible Noise:

Two sets of galwincaly isolated LogwcSignal Operating Temperature: 0o to 50° C Measured at 2 meterm ANSI Type 2 Inputs, each set has a voltage sensing tenrni'al Storage Temperature: -250 to +700 C for ac or do voltage, a shared common terminal. Typically: Front: 52.5 dEA Rear: 55 dRA and a dry contact sensing terminal. Humidity: Up to 95% relative humidity, L.H: 54 dBA R.H: 52.5 dBA non-condensing.

Contact Sense Mode, for dry contacts:

Displays: 0.3' High Intensity filtered LED Open Circmt Test Voltage: 30 volts nominal Short Circuit est Current 90 mA nominal Interfaces:

Threshold: 460 ohms nominal RS232 remote control to PC Voltage Sense Mode, for ac and dc voltages IEEE 488 instrument Inter-communications Input Voltage: 420 volts dc network and (or) peak ac D232 for F201 0 Minicontroller maximum External Signal inputs for voltage and current input Impedanc: 100 K ohms conditioning amplifier nominal Threshold: 1,5 volts nominal

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F2253 VOLTAGE AND CURRENT SOURCES Attachment 3 to JC-1Q1P81-90024 SHEET 3 OF 4 MODE 1: Source I Voitage Source 2 Current Power 50/S0iHz & DC Rangs (Resolution)

Source 1 AC Voltage Continuous Power 150 VA-rmns 75, 150, 300 V-rms (0.01V)

Source I CC Voltage Continuous Power 150 watts 106 212, 424 V-dc (0.6 1V)

Source 2 AC Current 1.5 second Transient 675 VA-rms 15, 30, 45.60, 90 (001A), 180 A-rms (0.1A)

Continuous Power 450 VA-fns 7.5, 15,22.5,30, 45 (0.001A), 90 A-fmS (0.01A)

Source 2 DC Current 1.5 second Transient 675 watts 15. 30. 45,60, 90 (0.01A); 180 A-dc (0.1A)

Continuous Power 450 watts 5, 10, 15, 20, 30 (0,001A), 60 A-dc (0,0iA)

MODE 2: Source I Current Source 2 Current Power 50/60/Hz & DC Ranges (RePsoution)

Source I AC Current 1.5 second Transient 225 VA-mms 15, 30,60 A-rms (0.0IA)

Continuous Power 150 VA-rms 7.5, 15, 30 A-rms (0.001A)

Source 1 OC Current 1.5 second Transient 225 watts 15. 30. 60 A-do (0,01A)

Continuous Power 150 watts 5,10, 20 A-dc (0-001A)

Source 2 AC Current 1.5 second Transient 450 VA-rms 15, 30, 60 (0.01A), 120 A-rms (0.1A)

Continuous Power 300 VA-rms 7.5, 15, 30, 60A-rms(0.001A)

Source 2 DC Current 1.5 second Transient 450 watts 15. 30, 60 (0.01A), 120 A-dc (0.1A)

Continuous Power 300 watts 5,10,20,40 A-dc (O.01 A)

F2252 VOLTAGE AND CURRENT SOURCES MODE 1: Source I Voltage Source 2 Current Power SOW60/Hz & DC Ranges (Resolution)

Source 1 AC Voltage Continuous Power 150 VA-rms 75, 150, 300 V-ins (0.01,V)

Source I DC Voltage Continuous Power 150 watts 106,212, 424 V-dc (0.01V)

Source 2 AC Curent 1.5 second Transient 450 VA-rms 15, 30. 60 (0.01 A), 120 A-rms (0.1A)

C_,ontuous Power 300 VA-rms 7.5, 15, 30, 60 A-un (0.001A)

Source 2 OC Current 1.5 second Transient 450 watts 15, 30. 60 (0.0 IA), 120 A-tc (0.1Al Continuous Power 300 watts 5, 10, 20, 40A-dc (0.001A)

Attachment 3 to JC-101P81-90024 MODE 2: Source 1 Current SHEET 4 OF 4 Source 2 Current Power S060/fz &DC Ranges (Resoltn)

Source 1 AC Current 1.5 Second Transient 225 VA-rms 15. 30,60 A-rms (0.01A)

Continuous Powxer 150 VA-rms 7.5, 15, 30 A-rrns (0.001A)

Source 1 DC Curent 1.5 Second Transient 225 watts 15, 30, 60 A-do (0.01A)

Continuous Power 150 watts 5, 10, 20 A-do (0,01A)

Source 2 AC Current 1.5 second Transient 225 VA-mis 15, 30,60 A-mis (0.01A)

Continuous Power 150 VA-rms 7,5, 15, 30 A-ns (0,001A)

Source 2 DC Current 1.5 second Transient 225 watts 15, 30, 60 A-dc (0.01 A)

ContiniUOLs Power 150 waits 5,10, 20 A-dc (0.OO1A)

F2251 VOLTAGE AND CURRENT SOURCES Power 50W60/l &DC Ranges (Resolution)

Soe1 AC Voltage Continuous Power 150 VA-rms. 75, 150,300 V-rrns (0.01VN Source 1 DC Voltage Continuous PIwer 150 watts 106, 212, 424 V-de (0.01V)

Somrce 2 AC Current 1.5 second Transient 225 VA-rms 15, 30.60 A- mis fO.01A)

Continuous Power 150 VA-rms 7.5, 15, 30 A-rms (0.001A)

Source 2 DC Current 1.5 second Transient 225 watts 15. 30, 60 A-dc (0,01 A)

Contfnuous Power 150 watts 5, 10, 20 A-dc (0O-01A)

Sp afnsaeasst to citeng wv.hot notka For more information, contact fserieshelp@doble.com Doble Engineering Comnpany 85 Walnut Street 3 Watertown, MA 02472 USA 1:u tel +1 617 926 4900 Doble is certified ISO 9001:2000 fax +1 6179260528 Doble is an ESCO Technologies Company MMMEABUOOýý MM M*T-SL-F2250TS-09/08

Attachment 4 to JC-Q1P81-90024 Page Iof 5 DESIGN VERIFICATION COVER PAGE Sheet 1 of 1 DESIGN VERIFICATION COVER PAGE

[I ANO-1 Q ANO-2 Ej IP-2 0] IP-3 El JAF El PIP

[JPNPS H VY 0GGNS 0 RBS 0 W3 El NP Document No. JC-Q1P81-90024 Revision No. Page 1 of 4 3

Title:

Division IlI Degraded Bus Voltage Setpoint Validation (T/S 3.3.8.1) 0] Quality Related [] Augmented Quality Related DV Method: G1 Design Review Q Alternate Calculation Q] Qualification Testing VERIFICATION REQUIRED DISCIPLINE VERIFICATION COMPLETE AND COMMENTS RESOLVED (DV print, sign, and date)

LI Electrical Lii Mechanical 0 Instrument and Control Robin Smtll///

Li Civil/Structural I] Nuclear LI F1 Marv Cnffarn I 72 &#Jf(tiIAS' Pr(ti/Si#bate After torninents Have Been Resolved

Attachment 4 to JC-QIP81-90024 Page 2 of 5 DESIGN VERIFICATION CHECKLIST Sheet I of 3 IDENTIFICATION: DISCIPLINE:

Document

Title:

Division III Degraded Bus Voltage Setpoint Validation (T/S 3.3.8.1) EeCivi/Structural r-Electrical Doc. No.: JC-Q1P81-90024 Rev. 3 QA Cat. 1 [Eli & C Robin Smith 4Z OMechanical Ve rifier: Print sign Date ONuclear

-Other Manager authorization for supervisor performing Verification.

0 N/A Print Sign Date METHOD OF VERIFICATION:

Design Review 0 Alternate Calculations E0 Qualification Test 01 The following basic questions are addressed as applicable, during the performance of any design verification. [ANSI N45.2.11 - 1974] [NP QAPD, Part I1,Section 3][NP NQA-1-1994, Part I, BR 3, Supplement 3S-11.

NOTE The reviewer can use the "Comments/Continuation sheet" at the end for entering any comment/resolution along with the appropriate question number. Additional items with new question numbers can also be entered.

1. Design Inputs - Were the inputs correctly selected and incorporated Into the design?

(Design inputs include design bases, plant operational conditions, performance requirements, regulatory requirements and commitments, codes, standards, field data, etc. All information used as design inputs should have been reviewed and approved by the responsible design organization, as applicable.

All inputs need to be retrievable or excerpts of documents used should be attached.

See site specific design input procedures for guidance in identifying inputs.)

Yes 0 No [ N/A [I

2. Assumptions - Are assumptions necessary to perform the design activity adequately described and reasonable? Where necessary, are assumptions identified for subsequent re-verification when the detailed activities are completed? Are the latestapplicable revisions of design documents utilized?

Yes 0 No [] N/A El

3. Quality Assurance - Are the appropriate quality and quality assurance requirements specified?

Yes 0 No [] N/A E]

Attachment 4 to JC-Q1P81-90024 Page 3 of 5 DESIGN VERIFICATION CHECKLIST Sheet 2 of 3

4. Codes, Standards and Regulatory Requirements -Are the applicable codes, standards and regulatory requirements, including issue and addenda properly identified and are their requirements for design met?

Yes CD No [] N/A E]

5. Construction and Operating Experience - Have applicable construction and operating experience been considered?

Yes Z NoD N/A D1

6. Interfaces - Have the design interface requirements been satisfied and documented?

Yes 0 No E] N/A []

7. Methods - Was an appropriate design or analytical (for calculations) method used?

Yes Z No D] N/A []

8. Design Outputs - Is the output reasonable compared to the inputs?

Yes Z No [] N/A D]

9. Parts, Equipment and Processes - Are the specified parts, equipment, and processes suitable for the required application?

YesD No D] N/A [D

10. Materials Compatibility - Are the specified materials compatible with each other and the design environmental conditions to which the material will be exposed?

Yes E] No [] N/A Z

11. Maintenance requirements - Have adequate maintenance features and requirements been specified?

Yes 0 No [D N/A []

12. Accessibility for Maintenance - Are accessibility and other design provisions adequate for performance of needed maintenance and repair?

Yes E] No [D N/An

13. Accessibility for In-service Inspection - Has adequate accessibility been provided to perform the in-service inspection expected to be required during the plant life?

Yes [] No [] N/A 0

14. Radiation Exposure - Has the design properly considered radiation exposure to the public and plant personnel?

Yes ED NoD N/A [D

15. Acceptance Criteria - Are the acceptance criteria incorporated in the design documents sufficient to allow verification that design requirements have been satisfactorily accomplished?

Yes [] No D] N/A 0

Attachment 4 to JC-Q1P81-90024 Page 4 of 5 DESIGN VERIFICATION CHECKLIST Sheet 3 of 3

16. Test Requirements - Have adequate pre-operational and subsequent periodic test requirements been appropriately specified?

Yes E I No 1:1 N/A LI

17. Handling, Storage, Cleaning and Shipping - Are adequate handling, storage, cleaning and shipping requirements specified?

Yes LI No 11 N/A [

18. Identification Requirements - Are adequate identification requirements specified?

Yes LI No [] N/A E

19. Records and Documentation - Are requirements for record preparation, review, approval, retention, etc.,

adequately specified? Are all documents prepared in a clear legible manner suitable for microfilming and/or other documentation storage method? Have all impacted documents been identified for update as necessary?

Yes E No 1:1 N/A LI

20. Software Quality Assurance- ENN sites: For a calculation that utilized software applications (e.g., GOTHIC, SYMCORD), was it properly verified and validated in accordance with EN- IT-104 or previous site SQA Program?

ENS sites: This is an EN-IT-104 task. However, per ENS-DC-126, for exempt software, was it verified in the calculation?

Yes [] No fl N/A Z

21. Has adverse impact on peripheral components and systems, outside the boundary of the document being verified, been considered?

YesZ* No -- N/A R

Attachment 4 to JC-Q1P81-90024 Page 5 of 5 Comments / Continuation Sheet Question Comments

_ __ _Resolution

_ I_ Initial/Date 1 Comments provided by markup Comments resolv*dmments incor d1*8I15-12 Comrr 1 1- -t I 1 1- -t 1 1 1 1- I I

-t t I I I