ML20069F991

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Final Rev 5 to Degraded Vital Bus Undervoltage Setpoint
ML20069F991
Person / Time
Site: Salem  PSEG icon.png
Issue date: 11/26/1993
From: Matthew Mitchell
Public Service Enterprise Group
To:
Shared Package
ML18100B120 List:
References
S-C-4KV-JDC-959, S-C-4KV-JDC-959-R05, S-C-4KV-JDC-959-R5, NUDOCS 9406090183
Download: ML20069F991 (41)
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CALCULATION COVER STEET S-C-4kV-JDC-959 37,l Nuclest Decar1 ment ID NUMBER RXTEluDSCE m

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FINAL FI AJA L-l FUTURE CONFIRMATIOH REQUIRED:

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TOTAL PAGES 48 67 37 IMPORTANT TO SATETY Q

R YES 80 i

If yes, design verification required per DE-AP.ZZ-0010(Q) (Design verification, Ref.

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Exhibit i Rev. 0 9406090183 940601 T

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DEGRADED VITAL 084 BUS UNDERVOLTaGE s.C-4kV-JDC-959 SHEET i

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ISC-2269 ORIGINATOn AEF 2

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CONTINUATION SHEET PEER REVIEW Cr g7 M

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i TABLE OF CONTENTS i

SECTION TITLE PAGE COVER SHEET 1

TABLE OF CONTENTS 2

i i

A 1.0 OBJECTIVES 3

2.0 DESIGN BASIS.................

3 3.0 ASSUMPTIONS 4

4.0 ANALYSIS...................

4 5.0 RESULTS 10

6.0 REFERENCES

11 7.0 ATTACHMENTS 12 b

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DE. AP ZZ.0002(O)

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TITLE DEGRADED VITAL to NO.

I s.C-4kV-JDC-959 SHEET BUS UNDERVOLTAGE b

SETPOINT REFERENCE ISC-2269 3

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C//N)1 nh.2/43 1.0 OBJECTIVE To determine the setpoints of the Model 27N Undervoltage Relays for degraded grid protection at Unit #1 and Unit #2 g per Electrical Upgrade Project power system configuration.

The following components are affected:

1ASWGRUVLT1A1 1BSWGRUVLT1B1 1CSWGRUVLTIC1 1ASWGRUVLT1A2 1BSWGRUVLT182 1CSWGRUVLTIC2 1ASWGRUVLT1A3 1BSWGRUVLTIB3 1CSWGRUVLTIC3 2ASWGRUVLT2A1 2BSWGRUVLT2B1 2CSWGRUVLT2C1 2ASWGRUVLT2A2 2BSWGRUVLT2B2 2CSWGRUVLT2C2 h

2ASWGRUVLT2A3 2BSWGRUVLT2B3 2CSWGRUVLT2C3 2.0 DESIGN BASIS 2.1 The minimum allowable vital bus voltage is 94% (Ref.

6.2).

The undervoltage relay dropout setpoint should be above 94% with the sufficient margin to compensate a combined accuracy / repeatability error of the relays, potential transformers and testing equipment.

The dropout setpoint of 95.1 % will be considered in calculation.

The minimum value of a vital bus recovery voltage during the worst transient is above 97% (Ref.

6.2, 6.3 and 6.8). 'The 97% will be considered in calculation.

The undervoltage relay reset setpoint should be below the minimum bus recovery voltage.

The present technical specification time delay setpoint is 13 seconds and allowable value is 15 seconds (Ref.

6.5).

All voltage and time delay setpoints will be evaluated to determine if the accuracies resulting from using relays, pts and testing equipment are conservative, 2.2 It is required that the testing will be performed using i

j I

a Digital Fluke model #8600A or equivalent.

This model has an accuracy of 0.2% at 60 hz.

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mLI DEGRADED VITA 1.

C No BUS UNDERVOLTAGE s.C-4kV-JDC-959 i

SWEET SETPOINT "UEAENCE 15C-2269 4

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_n/nPtf 2.3 All repeatability errors are based on percent of dropout setpoint

( 113.0 VAC ), Per telecon with relay manufacturer.

2.4 Drift is considered in the accuracies given in the instruction

manual, per conversation with relay manufacturer.

2.5 In accordance with Technical Standard, DE-TS. ZZ-001(Q) a 20 (2

Sigma) accuracy is used within this calculation.

2.6 The voltage and time delay setpoints determined in this calculation for the degraded grid undervoltage protection are applicable for both Units. and will be used as input data for the Technical Specification b (Ref. 6.5).

3.0 ASSUMPTIONS

(

)

3.1 The ambient temperature range inside the associated cubicle will be between 65*F and 125 F.

Reference CBD states that the ambient room temperature is between 65 F and 105 F (Ref. 6.7).

3.2 Since the dropout (trip setpoint) is set as a percent of pickup (reset setpoint), it is assumed that both settings drift 61rectly proportional to each other.

3.3 A 3o (3 Sigma) accuracy can be assumed on accuracies given in the instruction

manual, per telecon with manufacturer.

testing, quantity of samples,This is based on the manufacturers and Class 1E dedication test program.

4.0 ANALYSIS 4.1 Dropout Setpoint Calculation 4.1.1 Vital Bus Voltage Base:

4160 VAC With PT ratio of 35:1, 4160/35

= 118.857 VAC l

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TTTLE DEORADED VITAL 80 e S-C-4kV-JDC-959 SHEET O-

  1. G BUS UNDERVOLTAGE SETPOINT
  1. UERENCE ISC-2269 OF ORIGWATOR AN 2

i CALCULATION DATE 3/21/93

-AM 4

_MDM 5

s////93

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CONTINUATION SHEET PEER REVIEW 5 T' f-2pp DATE 1/2dH thPM) 11/J1/93 37 4.1.2 Minimum Allowable Bus Voltage:

94% of 4160/35 volt (Refer to section 2.1)

(0.94) (118.857) = 111.726 VAC

=

4.1.3 Undervoltage Relay Trip Setpoint:

95.1 % of 4160/35 volt (Refer to section 2.1)

(0.951) (118.857) = 113.033 VAC

=

113.0 VAC Actual Trip Setpoint -

(Calibration tolerance: ~

JJ11to11313)

L 4.2 Error Effects:

l 4.2.1 Temperature Effect:

For relay with harmonic filter (Ref. 6.1) 10.75% from 32'T to 131'F (0 to +55'C) g (Dif f = 99'F)

TE = 0.75% = 0.0076%

99'T

'T Ambient temperature range = 65'F to 125'T (Diff = 60'F)

Temperature effect over the temperature range:

(Percent of Trip Setpoint)

TE =

(.0076)f60)

[113.0] = 0.515 VAC k

100 4.2.2 Repeatability over

" Allowable" DC control power range:

10.1% of Trip Setpoint (note: 100 - 140 VDC =

DC power range)

(Ref. 6.1) 0.1% of 113.0 VAC (0.001)(113.0) = 0.113 VAC l

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A TTTUE DECPADED VITAL 80

  • S-C-4kV-JDC-959 SHE ET t

BUS UNDERVOLTAGE SETP01NT

  • EFE N E b

ISC-2269 O

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4-MDM 5

O CALCULATION DATE 4'2 9/ f 3 s////13 3 /e/q 3 CONTINUATION SHEET PEER REVIEW 3#

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G4tW 1 n/12/93 0A 4.2.3 Repeatability at constant temperature and constant c.ontrol voltage:

10.1% of Trip Setpoint (Ref. 6.1) 0.1% of 113.0 VAC (0.001)

(113.0) = 0._lll_YAC 4.2.4 Fluke Accuracy:

10.2% + li Div. Least Significant Digit FA = 0.2% of Trip Setpoint + 0.05V (0.002)( 113.0 ) + 0.05

=

0.276 VAC

=

4.2.5 Potential Transformer Accuracy:

1 0.3% of Trip Satpoint

,G

()

r PTA = 0.3% of 113.0 VAC (0.003) (113.0) k

=

0.339 VAC

=

4.3 Relay Accuracy: (with 36 accuracy)

RA = (2/3) / ( 0.515 )# + ( 0.113 )' + ( 0.113 )3

= 0.3595 VAC 4.4 Total Error Calculation with Fluke and PT accuracies:

4.4.1 Total error for the Trip Setpoint.

Total Error = {(RA)2 + (73)2 + (PTA)2

=/(0.3595)*

+

(0.276)1

+

(0.339)1

= V0.3203

})

0.5659 VAC

=

0.566 VAC

=

1:

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TITLE DEGRADED VITAL ID No.

S-C-4kV-J DC-9 59 SHEET)

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BUS UNDERVOLTAGE SETPOINT REFERENCE 7

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MM CALCULATION DATE 4/7/93 U///73 O /10 /4 3 CONTINUATION SHEET PEER REVIEW 57 rr 2/P 37 /

DATE 4/7/91 f/1940 it/22]qb 4.5 Error Evaluation The error evaluation determines the minimum voltage which may cause the UV relay to trip. This considers the actual trip setpoint, calibration tolerances and total loop errors.

UV relay setpoint

= 113.000 VAC Calibration Tolerance

-0.500 VAC

=

Total error (4.4)

-0.566 VAC

=

Allowable " LOOP" Trip

= 111.934 VAC(94.17%)

which is greater than the minimum allowable bus voltage of 111.726 VAC (94%), therefore the UV relay setpoint of 113.0 VAC (95.1%) is acceptable.

y 4.5.1 Allowable Value (Maximum expected Trip Calibration Error)

The Allowable value for the Trip Setpoint considers only the part of the loop tested during surveillances (Relay and Test instrument). The calculated allowable value is the minimum voltage e

that ensures the relay would have functioned at or above the 94% setpoint.

Allowable value (AV) = Calculated Trip Setpoint (CSP) - Testing Inaccuracy (TI). CSP is the difference between the Analytical Limit and the Total Loop Accuracy (TLA). In this case, the limit not to be exceeded is a process limit (PL) which is the Minimum Bus Voltage ( 111.726 VAC or 94% )

and TLA is 0.566 VAC (s;ection 4.4.1).

CSP = PL + TLA 111.726 + 0.566

=

= 112.292 VAC TI

= 0.319 (section 4.6.4)

AV

= CSP - TI (r- ).

= 112.292 - 0.319

= 111.973 (94.2%)

A TITLE DEGRADED VITAL io No S-C-4kV-JDC-959 SHEET BUS UNDERVOLTAGE t

SETPOINT REFERENCE 73ggg 3

ORIGINATOR @

2 AN 4

[04) 6 CALCULATION DATE 4/7/93 6////93

////o/43 N

CONTINUATION SHEET PEER REVIEW r7 rr ter 37 OATE 212h UM9]

nin/93 4.6 Reset Setpoint Calculation 4.6.1 The reset setpoint of the degraded grid relays must be less than the minimum expected recovery voltage at vital bus.

The total error value from section 4.4.1

( 0.566 VAC) should be used in the reset calculation..

Minimum bus recovery voltage is 97% (Refer to section 2.1).

Relay reset setpoint plus total error s (0.97) (118.857) 5 115.291 VAC 4.6.2 The 0.9 % Deadband between trip and reset setpoints (99% dropout tap setting and internal potentiometer) is acceptable because of the following calculation:

Reset Setpoint = Trip setpoint/99.1%

= 113. 0/ (O. 991)

= 114.026 VAC Actual Roset Setpoint = 114.1 VAC (96.0 %)

(Calibration Tolerance: 113.6 to 114.6 VAC )

I 4.6.3 The maximum relay reset voltage combines the relay reset setpoint including calibration tolerance and total error.

Maximum reset = 114.600 0.566 115.166 VAC (96.9%)

=

which is less than the minimum bus recovery voltage 115.291 VAC.

Therefore, the undervoltage relay reset setpoint of 114.1 VAC is acceptable.

4.6.4 Allowable Value (Maximun Expected Roset Calibration Errors) :

(

f. 6.9)

Allowable value (AV) calculated Setpoint

=

(CS P) + Testing Inaccuracy (TI).

e a

e en

A nTLE DECRADED VITAL 50 W 5-C-4kV-JDC-959 SHEET i

BUS UNDERVOLTAGE

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SETPOINT REFERENCE ISC-2269 9

CF ORIGINATOR AN 2.

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NO 4

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V CALCULATION DATE 4/7/73

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S/28/Y3

(////D

_n ho/43 f.8 CONTINUATlON SHEET PEER REVIEW r"7 f-

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177.

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///f2/02 CSP is the difference between the Analytical Limit ( AL) and the Total Loop Accuracy (TLA).

For this case, the limit not to be exceeded is a Process Limit (PL) which is Minimum Bus Recovery Voltage (115.291 VAC or 97%) and TLA is C.566 VAC (section 4.4.1).

CSP o PL - TLA 115.291 - 0.566

=

= 114.725 VAC It temperature is assumed to be relatively consistant between each calibration, the TI combines relay repeatability over " Allowable" DC control power range (section 4.2.2), relay repeatability at constant temperature and constant control voltage (section 4.2.3), and Fluke accuracy (section 4.2.4):

i TI

= /(0.113 )2. + C:(o,113}1 +

(0.276)E

/0.1017

=

0.319

=

Therefore, Allowable Value for Reset:

AV = CSP + TI 114.725 + 0.319

=

= 115.046 VAC (96.8%)

4.7 Time Delay Evaluation:

Tech Spec Time Delay Setpoint: s 13 Seconds (Ref.6.5)

Tech Spec Allowable Value:

s 15 Seconds (Ref.6.5)

(Tech Spec Table 3.3-4, func unit #7b)

Time Delay Setting Tolerances:

1 ABB Model 27N Undervoltage Relay with time delay range of 2 to 20 seconds (Ref. 6.10)

=1 10% of setting'(Ref.6.1) g Doble FT-2 Power Timer

= 0.1% of range (Ref.6.6)

\\

27N Relay Error = (10%) (13 sec) l 1.3 see

=

Doble FT-2 Power Timer = (0.1%) (99.9 sec) = 0.1 see OE. AP Z2-0002101 A TT A C - v f *.* 2 :

-~~-

A TITLE DECRADED VITAL iO No.

BUS UNDERVOLTAGE S-C-4kV-JDC-959 Q

b SMEET 3

SETPOINT REFERENCE ISC-2269 G

ORtGlNATOR MP 2 __M 3

f&

4

_#/M 6

CF CALCULATION DATE 4/7/ t }

S/28/93 f////93

_it// o/13 CONTINUATION SHEET PEER REVIEW J/

07

_f7

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g 0 ATE

@ 7/41 17tMl 64tM93

_uf%l93 y7 Conservatively add errors:

Total Time Error = 1.3 + 0.1 = 1.4 seconds Total Time Error plus Technical Specification Time Delay must be less than allowable value of 15 seconds.

Time Delay 13.0 see

=

Total Error = + 1.4 see 14.4 see which is < 15 seconds This calculation verifies that the total error from the ABB Model 27H Undervoltage Relay and the Doble FT-2 Timer is acceptable because the total time is less than l d the allowable time of 15 seconds.

5.0 RESULTS 5.1 Trip Setpoint Result:

==

Conclusion:==

Recuired Trip Setpoint of 113.0 VAC

(

)

(+ / - 0.500 VAC

) or 95.1%

based on postulated accuracy / repeatability of protective and testing devices is acceptable.

5.2 Reset Setpoint Result:

==

Conclusion:==

Required Reset Setpoint of 114.1 VAC

(

+ / - 0.500 VAC

) or 96.0% based on postulated accuracy / repeatability of protective and testing devices is acceptable.

5.3 Time Delay Result:

==

Conclusion:==

Current time delay of 13 seconds is acceptable based on the ABB Model 27N l

Undervoltage Relay and Doble FT-2 Power Timer Specifications.

5.4 The relay setpoints listed above are applicable for Unit #1 and Unit'/2 of the Salem Nuclear Generating Station only after implementation of ISC-2269 package d 6 &7 and appropriate License Change Request.

l I

NOTE:

See Attachment #3 for pictogram of results.

OE 6 0 ?.Z n30?tOf

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k inu DEGRADED VITAL io W-5-C-4kV-JDC-959 SHEET Q

BUS WDERVOLTAGE E

SETPOINT REFEAENCE ISC-2269 O'

ORIGINATOR MP 2

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0F CALCULATION DATE 4/7/93 S/23/f3 4//t/f3 g

CONTINUATlON SHEET PEER REVIEW r~ ~~

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6.0 REFERENCES

6.1 ABB Manufacturers Instruction Manual for the Type 27N High Accuracy Undervoltage

Relay,
  1. IB 7.4.1.7-7; i

(Attachment #1).

6.2 Calculation ES-15.008 " Salem Unit 1 & 2 Degraded Grid Study", Rev.

2.

g 6.3 Calculation ES-15.004

" Load Flow & Motor Starting Calculation", Rev.

O.

6.4 Salem Generating Station - FSAR - Section 7.3.1.1.10.5 and Section 8.3.1.2, 4160-Volt System, Revision #8.

6.5 Salem Technical Specifications Engineered Safety Feature Actuation System, Table 3.3-4, page 3/4 3-26.

6.6 Doble Model FT-2 Power Systems Timer, Specification Sheet page 3, obtained from Salem (M&TE) Maintenance &

Q Test Equipment Dept; (Attachment #2).

6.7 Control Area Ventilation CBD, DE-CB.CAV-0013(Q).

~

6.8 Calculation ES-15.012 " Salem Unit 1 & 2 Bus Tr Rev.

1.

l 6.9 PSE&G Letter # ELE-92-0626 from J.

D.

Carey to R.

W.

Chranowski, " Method for Calculating Allowable Value" dated 11/19/92; (Attachment #4).

6.10 PSBP #316072, Rev. 2; (Selected pages, Attachment #5). d 6.11 Design Change Package (DCP) #1SC-2269.

6.12 License Change Request (LCR) #93-10.

l Ag\\PCE 6\\1$0 2269. CAL l

DE. AP ZZ.0002(On ATTACWENT 2

TITLE DECRADED VITAL 10 No.

s.C-4kV-JDC-959 SHEET BUS UNDERVOLTAGE SETPOINT REFERE E E ggg,77g9

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/10/4 6

p OF CALCULATION DATE 6//#/93 vho/02 CONTINUATION SHEET PEER REVIEW

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ll/nJ93 7.0 ATTACHHENTS

  1. 1 ABB Hanufacturers Instruction Manual for the Type 27N High Accuracy Undervoltage Relay, #IB 7.4.1.7-7.
  1. 2 Doble Model FT-2 Power Systems Timer, Specification g Sheet, page 3.
  1. 3 Pictogram for Final Trip and Reset Satpoint results.
  1. 4 PSE&G Letter # ELE-92-0626 from J.

D.

Carey to R.

W.

Chranowski, " Method for Calculating Allowable Value" dated 11/19/92.

See note below.

Note:

This letter provided the methodology for determining the Allowable Value as well as provides the Allowable Value. Since the issuance of this letter the Allowable Value has changed due to a change in the calibration tolerance; therefore the Allowable Value as listed in the letter is no longer valid. However, since the e'

methodology has not changed this letter is to remain as an attachment in order to provide the methodology used in calculating the Allowable Value.

  1. 5 PSBP #316072, Rev. 2, (Selected pages).

As\\PtX 7\\1st 2M9. CAL k

l.'ar, a

1 l OE-AP.ZZ 0002(O)

ATTACwvEa i 2 s

l ATTACHMENT #1 S-C-4kV-JDC-959 IB 7.4.1.7-7 Page g ot g Issue 04 13 37 INSTRUCTIONS, e

----------------...-----..._____________ Single phase Voltage Relays Type 27N HIGH ACCURACY UNDERVOLTAGE RELAY Type 59N HIGH ACCURACY OVERVOLTAGE RELAY Type 27N Catalog Series 211T Standard Case l

b Type 27N Catalog Series 411T Test Case Type 59N Catalog Serica 211U Standard Case Type 59N Catalog Series 411U Test Case h

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S-C-4kV-JDC-959 la f.4.1.7-7 singlo-Pheos voltcge noioys pags 2

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TABLE OF CONTENTS Introduction..................Page 2

precautions...................Page 2

Placing melay into service....Page 2

Application Data.

............pege 4

Testing.......................Page to i

INTRODUCTION These instructions contain the information required to properly install. operate, and test certain single-enase undervoltage relays type 27N. catalog series 2111 and 411T; and overvoltage relays, type 59N, catalog series 211U and 411U.

Tne relay is housed in a case suitable for conventional semiflush panel mounting.

All connections to the relay are mace at the rear of the case and are clearly numbered.

Relays of the 411T. and 411U catalog series are similar to relays of the 2117 and 2110 series.

Both sortos provide the same bastG tunct?ons and are of totally drawout construction; however, the 4117 and 4810 sectos relays provide integral test factitties.

Also, seguenced d1SCOnnects on the 410 series prevent nutsance operation during withdrawal or insertion of the relay if the normally.open contacts are used in the application.

Basic settings are made on the front panel of the relay, bonind a removable clear clastic cover.

Additional adjustment is provided by means of calibration potentto-metere inside the relay on the circuit board.

The target is reset by means of a pushbutton extending through the relay cover.

PRECAUTIONS (A

The following precautions should be taken when applying these relays:

1 Incorrect wiring may result in damage.

Se sure wiring agrees uith the connection diagram for the particular relay before energizing.

2.

Apply only the rated control voltage marked on the' relay front panel.

The proper polarity must be observed when the de control power connections are made.

3. For relays with dual-rated control voltage, withdraw the relay from the 1

case and j

check that the movable link on the printed circuit board is in the correct position for the system control voltage.

4 High voltage insulation tests are not recomunended.

See the section on testing i

for additional information.

5.

The entire circuit assembly of the relay is removable.

The unit should insert secothly. Do not use excessive force.

i

6. Follow test instructions to verify that the relay is in proper working order.

CAUTIGN: aince troubleshooting entsiis working nith energigod eeuioment, care shouid be. taken to eveld personel shock.

Only coneetant technicione familiar with good safety practices should service these devices.

PLACING THE RELAY INTO SERVICE

1. RECEIVING, MANDLING, STORA4E Upon receipt of the relay (when not included as part of a swi tchboa;'d ) examine for O

notify shipping damege.

If damage or Ioes te evident, file a claim at once and proostly Asea Brown Boveri.

Use normal care in handling to avoid mechanical demoge.

Keep clean and dry.

l 1

We Sing 10-Pm:so voltage Doloro ATTACHMENT #1 IB 7.4.1.7-7 S -C-4 kV-J DC-9 5 9..........'.'.".. 3

2. INSTALLATION Page [ of M

( (

mounting:

15 37 The outitne dimensions and onnel det11tng and cutout information to given in Fig.

1 connecttone:

troical enternal conneettons are shown

'n Figure 2.

Internal connectione and contact loste are shown in Figure 3.

Control colarity.

power must be connected in the proper r r relays with dual-rated contrul o

power:

before enerstaine, withdrew the relay its case and inspect that from the correct posttion for the system control voltage.the moveele itnk on the lower printed circu is in 1 (For untte rated stovac, the 11nk should be placed in the poestion marked 125vec.)

These relays have an external resistor wired to terminale 1 and 3 whten must be in place for normal operetten.

The resistor is supp1ted mounted on the relay.

These relays have metal front canels which are connected through printed circutt board runs and connector C

wiring to a terminal at the rear of the relay case.

terminal is marked "G*.

In all The aopitcations this teretnal should be wired to ground.

3. SETTINGS PICKUP The pickup voltage teos identify output contacts to transfer.

the voltage level which the relay will cause the OROPOUT The dropout voltage teos are identified as a percentage of the pickus voltage.

are provided for 70s.

405, 30s, and set of pickup.

or. 30s. 40s. 50s, and 60s of Teos pickup.

i Note:

operating voltage values other than the specific values provided by the can be obtained by means of an internal tape testing for eetting procedure.

adjustment potenttometer. See section on TIME DIAL The time dial taps are identified as 1.2.3.4.5.5.

Refer to the time-voltage charac.

teristic curves in the Application section.

relays with an Instantaneous operating characteristic. Time dial selection is not provided on The time delay may also be '

varied from that provided by the fixed tas by using the internal calibretton adjust-mont.

4 OPERATION IMOICATORS The types 27N and EgN provide a target indicator that to electronically actuated at.

the time the output contacts transfer to the trip condition.

The target must be manually reeet.

The target can be reset only if control power to avs11able. ANO if the input voltage to the relay returns to the " normal" condition.

i An led indicator is provided for convenience in testing and calibrating the relay and to give operating personnet the operation of this indicator.information on the status of the relay. See Figure a for Unite with a

"-L" suffix on the catalog number provide a green led to indicate the presence of control power and internal power supply voltage.

I i

r

it T 4.1.7-3 ATTAClutENT f t pago 4 Sing 10-Choso volt:g3 ca10y3 S-C.4kV.JDC-959 APPLICATION DATA p,g,pg4fogjggr lg 37 s 'ag le-chase undervoltage releys and overvoltage relays are used to orovide a wide eenge of protective functions. including the protection of motors and generators. and to initiate bus transfer.

The type 27N undervoltage relay and type 534 overvoltage eslay are designed for those aoolications where exceptional long. term stan111ty are reoutred.

and accuracy. repostabtitty.

Tolerances and repeatability are given in the Ratings section. Remember that the I

accuracy of the stekuo and dropout settings with, respect to the printed dial markings is generatty not a factor, as these relays are usually calibrated tain the particular operettng values for the ecolication.

in the field to ob.

At the time of field cal-Nultiturn internal calibretton potentiometers providethe instruments used to set the relays

ibretton, the accuracy of factor.

adj u s tment means for accurate of the relay operating potnts, and allow and dropout to be set as low as 0.55 the difference between pickup The relays are supplied with instantaneous operating

time, or with definite-time delay characteristle.

The deftntte-ttmo untts are offered in two time delay ranges:

t.10 seconds, or 0.1 1 second.

An accurate peak detector is used in the types 27N and SDN.

Harmonic distortion in the 4C waveform can have a noticible effect on the relay operating point and on measuring instrumenta used to set the relay.

An internal hermonte filter is available as an option The harmonic filter attenuates all harmonics of the 50/40 Nr. input.for those apol tcations wher The relay then bestcally operates on tne fundamental component of the input voltage signal.

See I

figure 5 for the typical filter response curve. To specify the hermonte filter add the suffix

" NF" to the catalog number.

Note in the section on ratings that the addition of the harmonic filter does reduce somewhat the repeatability of vs. temperature vertation.

In applications where waveform distortion is a factor, it the relay may be desirable to operate on the peak voltage.

In these cases. the harmonic filter

'J would not be used.

CHARACTERISTICS OF CCeee0N UNITS Time Delay Catalog Numbers Type Pickup Range Oropout Ran Pickuo Dropout Std Case Test ca

...................................ge...............................................se 27N 40 - 110 v 70s - get Inst Inst 211701x5 411T01x5 Inst 1

10 sec 211741x5 411741x5 Inst 0.1 1

..................................................sec 211781x5 411781x5 70 - 120 v 70s - set Inst Inst 211703x5 411703 5 Inst 1 - 10 sec 211T43x5 411743x5 Inst 0.1 -1 s

..................................................ec 211TS3x5 411783x5 60 110 v 30s. 405 Inst Inst 211702x5 411702x5 Inst 1

10 sec 211742x5 411742x5

......................................... Inst 0.1 1 sec 211782x5 411TS2m5

$$N 100 150 v 705 - 995 Inst Inst 211001:5 411001:5 1

10 s Inst 211U41x5 411U415 0.1 1

...............................................e Inst 2110415 411U61x5 EN90tTANT NOTES:

1. Each of the listed catalog numbers for the types 27N and $9N contains an *m* for the control voltage designation.

To complete the catalog number, replace the "x" with the proper control voltage code digtt:

4s/125 vec.....

7 250 vec...... S 220 vec..... 2 48/110 vec...... O

\\

2. To specify the addition of the harmonic filter module, add the suffix
  • NF".

For enamole:

41174175.NF.

Normente ft)ter not avat1stle on type 27N with instantaneous deley timing characteristic.

ATTACKhENT ft Singlo-encco voltog3 Datore S-C-4kV-JDC-959 rs 7.4.1.r-7 Page[of fg'..........$.*!I.'

SetCtrICATIONS f7 37 Input Circuit: Rating:

type 27N 950v maximum continuous, type SSN 160v maximum continuous.

Burden:

less than 0.5 va at 120 vac.

Frecuency:

50/60 Hz.

Taca:

availabte models include:

Type 27N: otekuo - 60. 70. 80.

90, 100, 110 volts.

70

80. 90, 100 110 120 volts.

dropout-60. 70 80 90 99 percent of osckup.

30 40, 50 60 percent of otekup.

Type SSN:

pickuo - 100 110 120 130 140 150 volts.

dropout-60 70 80 90 99 percent of otckuo.

Operating Time:

See Time-voltage characteristic curves that follow.

Instantaneous models:

3 cycles or less.

h,e Roset Time:

27N: less than 2 cycles:

59N: less than 3 cycles.

(Type 27N resets when tnout voltate goes above etchuo (Type 59N resets when input voltage foes below dropout setting.)

setting.)

Output Circuit:

Each contact e 120 vac e 125 voc e 250 vec 30 amos.

30 amos.

30 mmos.

tripping duty.

5 amos.

5 amos.

5 nace.

continuous.

3 amos.

I amo.

0.3 mmo.

break. resistive.

2 amos.

0.3 amo.

0.1 amo.

break, inductive.

Doerating Temperature Range:

-30 to +70 deg. C.

Control Power: Models available for Allowable variation:

44/125 voc e 0.05 A man.

48 vde nominal 44/110 vde e 0.05 A man, 110 vec 34-58 vde 44-125 vde 220 vec e 0.05 A man.

125 vde 100-140 vdc

~

250 vdc e 0.05 A mar.

220 voc 178-246 vec 250 voc 200-250 vde

~

Tolerances:

(without harmonte filter option, after to minute warm-up)

Pickup and dropout settings with respect to printed dial merkings (factory calibration) = +/- 25.

Pickup and dropout settings, repeatatti tty at constant temperature and constant control voltage s +/- 0.15. (see note belowl pickup and dropout settings, repeatability over " allowable

  • de control 4

power range:

+/- 0.12.

(see note below)

Pickup and dropout settings. repeatabillity over temperatur9 range:

i

(

~20 to +55'c

+/- 0.45

-20 to +70*C

+/-0.tt 0 to +40*C

+/- 0.25

( see note below'#

i Note: the three tolerances shown should be considered independent and may be cumulative. Tolerances assume pure sine wave input signal.

Time Delay:

Instantaneous models:

3 cycles or less.

Definite time models:

+/- 10 percent or +/-20 milltsecs.

whichever is greater.

Harmonte Filter:

All ratings are tne same escept:

toottonal)

Pichus and dropout settings. repeatabili$y over temperature range:

0 to +55'c

</. 0.758

-20 to +70eC

+/-l.55

(

+10 tc +40*C

+/- 0.405 l

\\_

f %me 01 electric Strength:

2000 vac. 50/90 Mr.

80 seconds.

all circuits to gneund.

Setemic Capability: More than 69 ZPA Diantal broadband multifrecuency vibration without damage or malfunction.

( Ases! C37.90-19 78)

13 7.a.1.7 ?

Ps93 8 Steg10-Chr.00 VD1tC94 R310y3 ATTAtlutENT #1 5 - C - 4 k V. J D C - 9 5 9

)

i

' MR 18 37 O

&MB

=ili2i-dni-

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is IE 5:08 view s apoet viaw m y osa notts 4 >

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t E

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{M stue ssunseems en es teaca veces osasenescas Ane $

Figure 1: Relay Outline and Panel Drilling i

O NM MM N

n 52 u.ur-M Y

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ON u

g gg es

+

o.,

=

V sk c.wfe.a.k g o a.m.e.6 y,,

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Singlo-Phro voltcge Colcre ATTACHMENT #1 S-C-4kV-JDC-959 18 7 d i 7-7 Pcte 7 p,g q.

Og 19 37 Figure 3:

INTERNAL CONNECTION DIAGRAM AMO OUTPUT COttTACT LOGIC The foilowing table and diagram deftno the output contact states under eli posaible conditione of the measured input voltage and the control power supply.

  • AS SHOWN" means that the contacts are in the state shown on the internal the relay being conetoered.

" TRANSFERRED

  • means the contacts areconnection diagram for state to that shown on the internal connection diagram.

in the oppostte Condition Contact State

........................................ Type 27N Type 59N Normal Control Power Transferred As Shown AC Input Voltage Selow Sr4 ting Norsesl Control power As Shown AC Input voltage Above Setting Transferred No Control voltage As

...........................................Snown as Shown 169311M Std. er Tes t Case j

r

&1 8

1 os ol 4

3 of 1

c r-o T

9 oss 35 19 13 12 tt as 4

Off On Pickup Voltage Level On Off Off On Dr< spout Voltage Level input n

Off Voltage input Voltage lacreasing Decreasing Off Start 5 tart Figure ke: IT[-27N Operation of Figure %b: IT[.$3m Operstloa of Dropout Indicating Light Pickup indlasting Light Figure 4: Operation of Pickup /Oropout Light-Emittint-Olode Indicator

\\

(

13 7.4.1.7 1 ATTACIDIENT it i

. $$ N............................41nglo-Fh3c3 voltce) Coleyo S.C.6kV.JDC-959 P a g e M o fg

\\

20 37 1

l-The voltaas mennecteurtice i

\\

insa vettaes cuanactamistice l

-i+=,,w,,,,'.===.-

.'"I e

ee I

' se l.

I I

e

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t I

\\

I en I

ee.

e i I.

.e e

e as u

u musemee m emessee ser,me e,ne a,

w.. e..

9 4 h.

6 em eu,, es 9

y.8 M

. men. =

a ameen,.. w e.

.m i. ese erg sm.. m.m. c..

s ame s.6, e..

ese sm t

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. mas emme -

Ls= = '== 1 I = = = - -

sureuser e

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se se se tse see see Peeeeeeer. werte Ffoure 5: Norme1igod Frequenty Response. CDttone1 HeregniC Fi1ter bleGW1e

sinolo-Ph co voltese malays ATTAC1 MENT #1 S-C-4kV-JDC-959 In 7.a.i.f.7

.........2I, g

Control 21 37 voltage selector s

plug I

l

~

ci.

. ca

\\

~Iew

~

  • !!.'. :l.. l m.,
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,ii ii, 0 3

9hli' O

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.a Ptekuo i

voltage

-,. g. -..,,,,

g[

l

.J'

! *t_

g Calibration Pot-

~~

a d, M Ed}._.3.h.l l*

,~

J s,, **

g 8

.I 18 0*'

I A*

27N: CCW to Incr.

e yg -..-. O L,,g sg [

.A-ni 59N: CW to Incr.

..c>U

.s, _.

2..

.a.. Ot M i. *

.c.e, i

4,8.i.,~Il t !:

c>

  • s j,!

y'--

'. g jfl i

i 0

WI J 25 3,

a.r

r. ~ _ _ s...g?

?; C is y

A tii.i.i.i.i.w 'ji Fd???ddr' "!!j,, a

" i m:'

at'=

C

'i iYnYnf'irin nyn i 3J*i--i ci i i r'd i"b 'i'i'n " '

T aa m

E Figure 8:

Typical Circuit toerd Layouts, types 27N and S9N t

. T... -

~

_ru

",i.>;*._} b.i u e

n1 W

E p-1,1 i;f I*I

=

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ATTACEMENT #1 1s 7.4.t.7-7 Singlo-rhaco voltag3 polays S-C-4kV-JDC-959 Pageg ofg 22 37 TESTIWG 1.

MAINTENANCE AND RENEWAL PARTS wo routine maintenance is reout red on these relays.

Follow test instructions to verify inst the relay is to proper working order.

we recompend that an inoper6tive relay be returnes to the factory for reDair:

however, a ctrcuit concription booklet CDP.4.1.7-7 -nich incluces schematic diagrams, can be prov10ed on request.

Renews)

)

parts will be cuoted by the factory on recuest.

I 211 Series Units i

Drawout circuit boards of the same catalog numeer are interchangtble.

A unit is identtfted by the catalog numoe r stamoed on the front panel and a serist number stamped on the bottom side of the drawout circut t board.

The board is removed by using the metal pull knobs on the front panel.

Aomoving the board wrth the unst tn service may cause an uncestred operation.

)

An 18 ootnt entender board ( Cat 200X0014 )

calibration of the relay.

is available for use in troubleshooting and dit Series Units Metal handles provide leverage to withdraw the relay assembly from the case. Removing the unit in an application that uses a normally closed contact wt11 cause an i

operation.

The essemely is identified by the catalog number stamped on the front panel i

and a sertal number stamped on the bottom of the circuit board.

Test connections are readily made to the drawout relay unit by using standard benana plug leads at the rear vertical circutt board.

This rear board is marked for easier identification of the connection points.

faportant: these relays have an external restator mounted on rear terminals t and g.

In order to test the drawout unit an soutvilent resister must be connected to l

terminals 1

& 9 on the rear vertical circutt board of the drewout unit.

The resistance value must be ?.he same as the resistor used on the relay. A 28 or 50 watt resistor wi1*

be sufficiant for testing.

If no resistor is available, the resistor assemely mounted on the relay case could be removed and used.

If the res is ter front the case is used, be sure to remount it on the case at the conclusion of testing.

Test Plug:

A test plug assembly, catalog numbe r 400x0002 to avatlable for use with the 410 sortes units.

This device plugs into the relay case on the switchboard and allows access to all esternal circutta wired to the case. See Instruction took IB 7.7.1.7-8 for dotatle on the use of this devtce.

i I

2. HIGH POTENTIAL TESTS High potentist testa are not recommended.

A ht-pot test was performed at the f actory before shipoing.

If a control wiring insulation test is reoutred, partially withdrew i

the relay unit from its case sufficient to break the rear connections before applying the test voltage.

3. BUILT-IN TEST FUNCTION to sure to take all necessary precauttons if the testa are run with the main circutt energized.

The built-in test is provided as a convenient functional test of the relay and aesoc-1sted circuit.

When you depress the button labelled TRIP. the measuring and timing circutta of t elay are actuated.

when the relay times out, the output contacts transfer to tr the ctreutt breaker or other associated circuitry. and the target to Ciselayed.

T test button must be held oown continuously until eseration to Cbtained.

1 ATTAC}UiENT fI singlo-Phsco voltage colays S-C-&kV-JDC-959 Is 7.4.t.7 7 AcespTAMes TasTS p,,,4y

........ ' ' **. 2 4

23 37 fon ow th. t..t proc.dur.e und.,.ac. graph s.

ror d.fintt..ti.e unit.,

e,iect T % 1 Dial 83.

For the type 27N. Check timing by dropping the voltage to gas of the dropout voltage set (or to aero volts tf preferred for simplification of the testl For the type 39N check timing by switching the voltage to excess man. input voltate rating.)

1055 of pickus (do not Tolerances should be within those shown on page S If the settinee reoutres for the particular application are known, use the proceeures in paragraan 3 to make the final adjustments.

5. CALIBRATION TESTS Test connectiona and Test Sourcea:

Typical test circuit connections are shown in Figure S.

Connect the relay to a proper source of de control voltage to match its nameplate rating setting for dual-rated units).

Genere11y the types 27N and SSN era used ininternal clug (and tions where high accuracy to reeutred.

applica-less than 0.35 harmonic distortion, such asThe ac te harmonics. A test source with corrector" is recommended.

transformer as the stabilizing and regulating device,Do not use a voltage source that e a

  • 1ine-I hermonte content in their output.

as these usually have high {

used must also be considered when calibrating these relays.The accuracy of the voltag i

If the resolution of the ac test source adjustment means is not adeeuate, the !

3 i

arrangement using two variable transformers shown in

  • fine
  • adjustmente is recommended.

Figure e to give *roarse* and i

l9 hen adjusting the ac test source do not onceed the maxim the relay.

um input voltage rating of l

/

LED Indicator!

light emitting diode is provided on the front panel for convenience in A

the pickup and dropout voltages.

determining !

level and the direction of voltage change,The action of the indicator depende on the voltage and is best explained by referring to - l Figure 4.

i The es11bration potentiometers mentioned in the following procedures are of the multi-turn type for excellent resolution and ease of setting.

units, the it point extender board provides easier access to the calibration pots.

For cata)og series 211 l

desired, the completion of the calibration procedure.the calibration potentiometers can be ret If Settine Pickue and Orr at valtamaa l

Pickup may be varied between the fixed tape by adjusting the pickup cattbration potentiometer R2F.

Pickup should be set first, with the drocout tap set at 333 on

  • low dropout unita").

Set (GOs The calibration potentiometer has approutestely athe pickup tag to the nearest val setting.

the voltage e/-St range.

Decreses adjust and repeat untti stekup occurs at procteely the desired voltage.unti Re-Potentiometer R1S te provided to adjust dropout.

lower tap to the desired value.

Set the dropout top to the nemt lower the voltage untti dropout occurs.Incrosse the inout voltage to above pickve. and then 'l setting has been made.

Readjust Ris and repeat untti the reeutred l 1

Settina Time helavt Similarly, the time delay may be adjusted higher or lower then the the time-voltate curves by means of the time delay calibration potentiometer #41 values shown on the type 27N. time delay is initiated when the voltage drops from On value to below the dropout value. On the type SSN, above the etchuo voltage increases from below dropout to above the pickup value. timing is inttisted when Eme the relay to

  • timing out" when the lost indicator is lighted.

Referring to Fig. 8 Entarnal Ramister valumat The following resietor values may be weed when teettne 8' 8 Series untts.

Connect to rear connection points i 4 p.

Relays rated 40/125 vec:

5000 ohms;

(-NF models with harmonic filter 4000 ohms 1 44/110 vec:

4000 ohne;

(-NF models with hermanic filter 3200 emmel 250 vde: 10000 shne?

(.MF madele eith hermenic f1lter 3000 ohnet 220 vec: 10000 ohns;

(~MF moesis with hermanic filter 3000 ohnei 1

l

ABB ATTAC10ENT #1 AstA enoww emini 5-C-4kV-JDC-959 Page M of g 24 37 ABS Power Trenanteston Inc.

Protective meter Divteton 35 N. Snowertft Rd.

Allentown. Ps. talog 215-395 7333 Issue O (2/89)

...................................................................Supersaces issue C

Z I-I To AC Test Source DC Control Source hy s.. Fis. s j

1 Timer START Input 08 O' 05 OS U2 Or gi Et IV E

tY

"") :

' a r-

'AF GNO QiG OtS One Os3 ()82 ()es Q 0h3 0

"ll-To Timer STOP Input Fleure 8: Typical fest connections T1 T2 variable Autotransformers

( t.5 ame rating)

T3 Ftlement Transformer (1 emo secondary)

V Accurate AC Voltmeter i

> x lo--

0Y sto vac Lina

~~"

l (v)

Me M..

CORatcTO, R ttova

? 4.3V Lint g

g t gyg p

==

f e-

,Z TI Tt T3 coansE Fint Figure 3: AC Test Source Arrentement These inatructione do not ourport to cover att detatis or var 1atione in oeutoment, nor to previes for every possinie contingency to be met in conjuneston atth installatton, ooerstion, or maintenance.

should oorticular probleme artee waten are not coveres surftetentir for the purchecer's purposes, the metter should be referred to Aeoa troen sovert.

ATTACllllEliT #2 S-C-4kV-JDC-959 Page of g 25 37 GENERAL he Occie Medal FT2 Power System Timer is 3 rugged. Dortsbie solid state electronic snstrument for measuring the alsosed time between two events that are marked by electrical signals. It measures intervals from 01 millisecond up to 999 seconds using five 3 digit decimal ranges and clifies Inc user at tne end of the interval. The FT2 is designed to coerate nifely anc retiaDly in the demanding environment of the power industry.

anc crevices accurate and recostabie measurements-without any enout ddlustments-*en Int prestrice el Wevele electrical noise. Continuous accuracy is assured by a cuartz crystal time standard.

The FT2 responds to a wide variety and range of electrical signais. Botn the START anc STOP terminals acceot signals from either dry contacts or switched ac or de potentials up to 250 Volta. Operating concitions are established Dy simple Sense $ witches which select the colarity of the trom to* transition that marks the starting and stopping events. A Range Switch selects the maximum measurement period. and automatically positions the decimal point and lights the correct units indicator. Should the interval exceed the selected ueirod. a Spit.L indicator is lignted and the disotay is blanked to avoid erroneous readings.

SPECIFICATIONS Time 8ase t MHz. crystal controlled Rangen 0 to 99.9/999 ms. O to 9.99/99.91999 s Resolution 1986t significant digil Accuracy it loest significant digit Display 3 decimal digits. 0.43 in high Indicators SPILL. (EC. MSEC. STOP input signals optically isolated Dry Contact Sensing 8 VISO uA vollege

  • 1-250 V dc or ao et 40-40K Mt Source Impedance 41KO Duration

>12.8 me Temperatura 0 to 50'C operating. -20 to 70'C storage Humidity 0-90Wnoncondensing Power 105-125 or 210-250 V. 47-83 HL l e

$lra 9.75 in (24.8 cm) wide.

6.25 in (18.8 cm) deeo.

8.26 in (18.1 cm) high Weight 4.88 fts (2.2 kg)

Case molded ABS O

/5\\

title DECPADED VITAL

D NO s.C-4kV-JDC-959 SHEET BUS U!iDERVOLTAGE 2.6 SETP0lHT REFERENCE
g3g, g

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ORIGf t4 A T OR AU 2.

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or 1

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/N C ALCULA TIOfg DATE 4/7/9 3

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COfdTlf4UA TIOt1 SHEET PEEf4 REVIEW

{-r 57 jfF 37 1

.f4/f3 e/rf'f) y/a f 91 0 ATE

_ ATTACllllEtiT # 3 DEGRADED VITAL BUS UNDERVOLTAGE SETPOINT PICTOGRAM FOR SALEM STATIONS UNIT I & 2 115.50 MINIM UM bus 115.40 RECOVERV VOLT ACE 111291 VAC (97.0%)

115.30 l

115.20 max tDOP ERROR RESET 111366 VAC (9(9 %)

115.10 MLA (o.s64) -

3:5644 VAC(9(r%XAV) 115.00

- TOTAL Loor ERROR k

CJ19 (TI) 114.90 YI TLA (n 46) 11(725 YAC(CSF) 114.80

!!]Cf3 CAUBRATION 114.70 g

--- - - - - - - - - - - - - - - - - - - - - - -> s s (60e VAC 114.60 A

114.50 CAUBRATION TO11RANCE 114.40 (o. soc) 114.30 114.20 l

RESET sETrOINT l

h 114.sooVAC(w.0%)

114.10 114.00

{

)

CAuBRADON TOLERANCE 113.90 (o.soo) 113.80 y

113.70 tow CAMBRADON

- - - - - - - - - - - - - - - - - - - - - - k 113.600 VAC 113.60 tricll CAUBRADON

- - - - - - - - - - - - - - - - - - - - - - -k 113.500 VAC 113.50 N

113.40 RELAY OPERATION ZONE 113.30 CAUBRATION TOLF.RANCE 113.20 (o.soo) 113.10

[

TRIP EriPOINT l

h 113.000 VAC(Pi1%)

113.00 112.90 112.80

- CAURRATION TOLERANCT 112.70 (o. soc) 112.60 1DW CAMBRATION

- - - - - - - - - - - - - - - - - - - k ! !1.500 VA C 112.50 112.40 112.30 TOTAL InOP ERROR s12.292 VAC (Csr) 112.20 Tt.a cous)

A {.3:,(Tr) 112.10 y y (o.566)

T siss?3 VAC (94 2%)(4Y) 112.00 stw LOor rRROR TRIP 111.934 V4C (941".)

111.90 1

111.80 si NI\\fUsf A1.LOWABLE 113.726 VAC (910*4) 111.70 bus VOLTACE 111.60 l,,

111.50 AllNI%ll'N AlJDWABLE BUS VOI TACE (41.2)

T1 = T F3 TING INACCURACV (411.4 6 4)

TRIP SETPOINT (41J)

\\fINIMUM BU5 RIWYERY VOLTACE (4 61)

TOTAL LOOP ERROR (ttt)

RESET SETPOINT(4 63)

TRIP CEP = TRTP CAlft.'t.ATED SETPOINT (Lif)

RESET CSP (4 Ed)

T RIP AV = TRIP ALIDWABt.E VAll'E (til)

RESET AV (4 &()

D C. p r 7 7 v.M i ^ +

2S.

5EM sw 22+ su 3-23 14:34 PSE&G EAPB-2154224500:: l' nuwsac:a.

ATTACIDENT #4 S-C-4kV-JDC-959 Fage Mfg 27 37 a.o..c swva enctne ano Gas cercany P o som 236 sanecen,s socoe New Jone y ososa Nuclear Oma^T.e t ELE-92-0626 TO:

R.

W. Chranowski Technical Engineer FROM:

J.

D.

Carey Salem IEC Supervisor h ; [

ID.M y

SUBJECT:

METHOD FOR CALCULATING ALLOWASLE VALtJE DATE:

November 19, 1992 For the setpoint calculation of concern no Technical Specificati Allowable value Allowable Values (Maximum Expected Calibfation Errors) on as inputs to the safety analysis.are typically calculated only for setpointerused exista.

left To assist you in ex descr/as found values and setpoint calculation S-C-4KV plaining as iption for the method of calculating allowable values is, a JDC-0959 provided below:

O value is based on the direction provided in ISA-sR6 Draft 10 of the Recommended Practice " Methodologies for the Determination of Satpoints for Nuclear Safety-Related Instrumentation".

Calculations, DE-TS.ZZ-1001(Q)Our technical standard for Instrument setpoin incorporate this direction.

is currently being revised to The recommended practice states that "The allowance between the allowable value and.the trip setpoint should contain that portion of the instrument channel being tested for the surveillance interval (monthly, quarterly, or refueling) no more than:

and should account for drift (based on surveillance interval)

Instrument calibration uncertainties for the portion of the instrument channel tested and

... instrument uncertainties during normal operation that are measured during testing.

The method adopted is to first subtract the Total Loop Accuracy (TLA) from the Analytical limit (AL) to ensure margin between the Analytical Limit and the setpeint.

and TLA is a fictitious number called the calculated setpointThe difference be (CSP).

The instrument uncertainties as discueeed above should O

then be addad to the calculated setpoint allowable value.

(CSP) to determine the he Energy people

-u. a.,

3-:2-83 14 34 PSEE EAPB-2154 :4500 :

ATTACHMENT #4 S-C-4k9-JDC-959 Page[28of g 37 R.

W. Chranowski 11/19/92 AL - TLA = CSP AV = CSP + Errors expected during testing (as noted above)

For this case, the limit not to be exceeded is a Process Limit (PL) which is 110.418 Vac.

(110.418-0.549 Vac)

The TLA is 0.549 Vac. The PL - TM 0.02 Vac or (109.87 Vac-109.85 Vac).= 109.47 Vac which leaves a positive mar The errors ex testing should consist of 0.309 Vac as shown below.pected during Therefore tt Maximum Expected Calibration Errors (Allowable value) set at 110.179 Vac or lower.

should be From Calculation S-C-4KV-JDC-0959:

Section 4.2.2 (Repeatability) = 0.1089 Vac Section 4.2.3 (Repeatability) = 0.1089 Vac Section 4 2.4 (TA)

= 0.2678 Vac Testing Inaccuracy = ( (0.2 678) '2+(0.1089) ~2+(0.1089) *2)' *1/2

= 0.309 Vac O

Conservatively, temperature was assumed to be relatively Note:

consistent between each calibration.

1 If you have any questions or comments concerning this matter, please call Sandy Jannetty at extension 1802.

SJJ:ngh Attachment C

L. Rajkowski S. Jannetty.

M. Nortarulo O

5DT BY:

3-23-33 : a.4.:35......... tPSE&G E&PB-1 2134224,300:: 3'l a,ua 4-vogo; ITITLE l

REFERENCE :

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i 110.J99 Vac 110.179 Vac i

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1 Testing Inaccuracy (.309) 1 l Loop l

l l IRRoR (TLA) i calculated setpoint t

l 0.549 Vac (step 4.4.2)

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l 109.7 Vac Min. Allowed Rosat 109.6 Vac i

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(.5% of 109.05) i Max. Calibration Tol.

109.05 Vac TECH. SPEC. SETPoINT

,108.9 Vac (91.6%

LCCP i ERRon I 0.438 Vac (Step 4.4.1)

Max Loop Error Trip E

10s.462 Vac i

T.S.

ALLOWABLE VALVE 108.16 Vae (91.040 I

.l' ATTACHMENT #4 5-C-4kV-JDC-959 Page M f k

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DE-AP. zz-0002 (g)

ATTACMMENT 8

j ATTAC10ENT #5 30 37 S-C-4kV-JDC-959 Page)( of fff I

REVIEW / APPROVAL FORM / OVERLAY PSEGG Q

f 3/40*72 02 K ACTIVE - APPROVED DOCUMENTATION O APCP

- APPROVED, PENDING CHANGE PACKAGE D ERP2

- APPROVED, PENDING EQUIVALENT REPLACEMENT O CAN.

- CANCELLED, NOT P" QUIRED 2a,MhAs2 OATE/4h5 9/

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SLAMITTED DGIVIDUALLY Ale TM LATEST REVISION MAY NO i

PLEASE CONRAT TM DOCLDENT CONTROL SYSTEM DATABASE T LATEST REVISION.

ATTACHMENT #5 S-C-4kV-JDC-959 Pegegof fff Adds *ndum to IB 7.4.1./-?(D)

AstA BROWN SOYED 31 37 INSTRUCi1ONS Hi

--.--- ------ -. - - - --. ------..g h - Ac c ur a c y Un d er v o l t a q n R e l a y y

INranP tr.TinN Th s.s. addendum cava.ru models with the Defi ni t e-l.ong-Ft me dnl ay charactertstic.

These mcdel s are identified by catalog numbers that have the di rit t "5" directiv Following the letter "T"

in the catalog number 1.u.:

catalog numbcrs of the form 411T5xnx.

TIMING CHARACTERISTIC The overcall timing range of these relays in 2-20 seconds.

The time-voltage characteristte is definite-tame as shown on page B of the main instruction book. wi th the time-delav values versus time-dial sel ecti on as followet Time Dial Tap Fin Pos2 tion Nominal Delay Time - Seconds

  1. 1 2 seconds
  1. 2 4
  1. 3 6

44 to

  1. 5 14
  1. 6 20 CATALOG NUMBERS and CHARACTERISTICS rime Delay Type Pickup Range Dropout Range Pickup Dropout Catalog No.

27N 60-110v 70-987.

Inst 2-20sec 411T5175 70-12Oy 70--907.

Inst 2-20sec 411T5375 Catalog numbers shown are for d. awuu t-teest-case model s, which are preferred for new applications.

i Uni ts in the standard-case, catalog strisa 211T5xxx would have the same electrical characturtstsen.

Rev 0 (9/91) i

.l' ASS Power AM wemen,T&OComesay o

tese manes.e men.s. sue :

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CD 7,4,1,7 7 j

Issue A CIRCtrIT DESCUPTION HICH ACCURACY VOLTACE RELAYS 4

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O 34 37 CD 7.4.1.7-7 VOLTAGE RELAYS PACE 2 INTRODUCTION The ITE-27N and ITE-59N are companion high accuracy under and overvoltege relsys respectively.

Basic information on application and testing is in-cluded in IB 7.4.1.7-7.

This publication describes only the operation of the relay circuitry.

For the purpose of the following discussion PICKUP is defined as the high input voltage condition and DROPOUT as the low voltage condition.

For the ITE-27N Undervoltage Relay, PICKUF is the normal or reset condition and DROPOUT is the trip condition.

For the ITE-59N Overvoltage Relay, PICKUP is the trip condition and DROPOUT is the normal or reset condition.

POWER SUPPLY AND REFERENCE The relay's power supply is derived from the DC controi power input (ter-minals 7-8).

RV2, b,1un coil BT1 and C13 provide transient protection.

O Voltage selector plug VSP sets the dropping resistors for either a 48 or 125VDC supply.

Zoner diodes VR1, VR2 provide +/-15VDC voltages for the circuitry.

Integrated circuit U4 provides a highty stable 10 volt re fer-for the voltage measuring circuit.

ence l

INPUT CIRCUIT Transformer T1 reduces the 120V nominal input signal by a 10:1 ratio.

The gain of operational amplifier U1 is adjusted by the FICKUP tap selection

( R3 th ru R8 ).

The gain is set to give a 10 volt peak signal when the input voltage to the relay equals the pickup tap voltage selected. Calibration potentioaster R27 provides additional gain adjustment to allow the relay to be calibrated for any voltage between the fined tap settings.

FICKUF CIRCUIT U2 is an operational amplifier used open loop as a compariter. The 10V reference is applied through R10 to pin 3 of U2.

When the peak AC stenal on pin 2 exceeds 10 volts (input voltage above pickup) a negative pulse is obtained on output pia 6.

Resister R11 provides some positive feed-back to streteh the pulse. The negative signal is filtered by especiter C9 and applied to U3 pia 2.

A negative input on U3-2 easses the U3 out-O put to go high. 1.ID tedicator Dg1 is off.

Ftf Q1 is la the eseducting state. The selected dropout tap resistor (117-R20) causes the referosee voltage at pia 3 of 02 to be lower than 10V.

Calibration resister att provides additional adjustment between tape. This is the dropoet vettage reference value.

ATTACHMENT #5 3f 37 S-C-hV-J DC-959 Page g of A8'"

VOLTACE FILAYS CD 7 4 1.7-7 PACE 3 The dropout condition is reached when the input viltage to the retay drop such that the peak voltage at U2-2 is below the r eference voltage.

U2-6 then goes high, output Output U3-6 goes low.

LED D31 turns on.

F3T QL turns off. re establishing 10 volts as the re ference at U2-3 (pickup voltage ref-erence value).

TIMING CIRCUIT

'(Not Used on ITE-27N Instantaneous Models)

The output of timer IC 05, pin 3. is normally high.

When the output pin UJ-6 goes low (dropout condition), a trigger puise is applied through C19 to US pin 2.

Capacitor C20 is then allowed to charge through the selected time delay tap resistor (R63-R48).

When the volenge on C20 reaches a threshold vlaue. U5 output pin 3 goes low.

to provide for timing calibration.

R41 adjusts the threshold value When the input voltage to the relay returns above pickup, QS turns on, causing U5 to be immediately reset and its output to return high.

OUTPUT AND TARCET CIRCUIT!,

O For the output relay to be energized, the signal through D6 from the pickup circuit and the signal through D12 from the timer must be low.

This allows 03 to turn on, then Q2 to turn en energizing the :oit of output relay Kl.

At the same time. Q4 is energized to discharge Cl.l through the target thus changing the target status to orange.

(On ese ITE-27N with instan-

coil, taneous timing, the timing circuitry is not used to the output responds directly to the signal from U3-6.)

ITE-59N The operation of the ITI-59N relay is almost identical' to that of the ITE-27N.

The difference being that op amp U3 La changed to a dual type, with the U3-8 section used to invert the logic, so that a high voltage condition causes the LED to light, the timer to run, and the outpu: circuit to operate.

KARMONIC FILTER For applicatiets where waveform distortion would lie significant, a harmonic filter may be added. This filter preserves the 30 or 60M: content of the input signal.

(It does not determine the RMS value of the signal.)

The filter is inserted between U1 and U2.

(19 is reseved.) The gain of the filter is adjusted to 1.0 so that the basic e.ilibration of the relay f-(

is retained.

__ATTACHMINT #5 36 37 S-C-4kV-JDC-959 8"# I W VOLTACE R.1 LAYS CD 7.4.1.7 7 PACE $

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FORM NC.DE AP.ZZ-0010-1 CERTIFICATION FOR DESIGN VERIFICATION Reference No.

YC -

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SUMMARY

STATEMENT TMG_ 6cc.?E op.7t.its BGshi stE124plC4k,J bi As to s2ENGQ C2Extisic w 4-CHAwQr:c, To f t.(E. /%NE QG FERCw(FD (A t.c ca hcAI. 7bE OL*S16ed

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The undersigned hereby certifies that the design verification for the subject document has been completed, the questions from the generic checklist have been reviewed and addressed as appropnate, and all comments have been adequately inc rPorated.

4c. Fe66aaese i

L. 3 E.C h s1G[

h1% 93 Design Venfier Assigned By Signature df Demgn Verifier / Date Design Venfier Asmaned By Signature of Design Verifier / Date Design Venfier Asmgned By Signature of Design Verifier / Date Design Venfier Assigned By Signature of Design Verifier / Dase Page _,of _

Nuclear Common Page 2 of 4

~

1/1/92

FORM NC.DE-AP.ZZ 0010 2 I

(

GENERIC VERIT CAT!ON CHECKLIST RITERENCEDOCUMENTNUMBER/REVhS

<; <-4 42N

'3 o c - 959

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YES NO N/A WHERE FOUND COMMENTS PAGE NO.

(Y/N) wERE DE51CW 14 PUTS CORRIC?u SELECTED AkD

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{Iht:RPORATEDthTODES:N Ybb g

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ARE ASSUMPfl0NS NECEssART TO PERFORM THE DESIGN

/

ACTIVITY ADEQUATELY DESCRIBED AND REASONASLE7 WNERE NECE$sART. ARE THE ASSLMPTIONS IDENTIFIED FOR

$UBSEQUENT RE-VERIFICATION WHEN THE DETAILED DESIGN ACTIVITIES ARE COMPLETED 7 3.

ARE THE APPROPRIATE QUALITY AND QUALITY ASSURANCE

[

REQUIREMENTS SPECIFIED?

4.

ARE THE APPLICABLE CODES, STANDARDS AND REGULATORY REQwiREMENTS INCLUDiWG 155UE5 AND ADDENDA PROPERLY IDENTIFIED AND ARE THEIR REQUIREMENTS FOR DESIGN MET 7

[

5.

MAVE APPLICABLE CONSTRUCT!DN AND OPERATING EXPERIENCE BEEN CONSIDERED?

/

Eltc4Wd 6.

MAVE TWE DESIGN INTERFACE REQUIREMENTS BEEN

$AT!$FIED?

CoAtt et. U ^.

"2 f C M 7 WA5 AN APPROPRIATE des!GN METNCS USED7

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2-OCol[G 8.

13 THE OUTPUT REASONABLE COMPARED TO INPUTS 7 9 ARE THE SPECIFIED PARTS, EQUIPMENT, ul0 PROCESSES SUITABLE FOR THE REQUIRED APPLICATION 7

/

10. ARE THE SPECIFIED MATERIALS C W ATIBLE WITN EACM CTMER AND THE DESIGN ENVIRowENTAL COWITIONS TO VNICN

/

THE MATERIAL WILL SE EXPOSED 7

11. MAVE ADEcuATE ItLINTEmett FEATLNtES AND REQUIREMENTS

[

SEEN SPECIFIED?

12. ARE ACCES$1BILITY AS OTHER DESIGN P90VI$10NS ADEQUATE FOR PERFORMANCE OF IEEDED MAINTENANCE AND

/

REPAIR 7

13. NAS ADEcuATE ACCES$181LITT BEEN PROVIDED TO PERFORM THE IN SERVICE INSPECTION EXPECTED TO BE REQUIRED DURING TWE PLANT LIFE 7 g

Nuclear Departamt Page 1 of 2 1/1/92

l i

1 FORM NC.DE AP.ZZ-0010-1 CERTIFICATION FOR DESIGN VERJFICATION REFERENCE DOCL MENT NO. REV $ C -4M V 'l O(_- 999, REV.4-i i

COMMENTS RESOLUTION pages 9 4u were_

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i FORM NC.DE-AP.ZZ-0010-I Q

CERTIFICATION FOR DESIGN VERIFICATION Reference No.

S-C-4KV-JDC-0959. REV. 5

SUMMARY

STATEMENT A DESIGN VERIFICATION OF REVISION 5 TO THIS CALCULATION WAS PERFORMED IN ACCORDANCE WITH PROCEDURE NC.DE-AP.ZZ-0010. THE DESIGN VERIFICATION METHOD USED WAS AN DESIGN REVIEW OF THE PACKAGE. THE EXTENT AND DEPTH OF THE VERIFICATION INVOLVED A CHECK OF THE CHANGES ASSOCIATED WITH REVISION 5 OF THIS CALCULATION, AND THE DESIGN APPROACH USED. NO ENGINEERING JUDGEMENT WAS USED DURING THE VERIFICATION PROCESS WHICH REQUIRES INCLUSION IN THIS

SUMMARY

STATEMENT.

THIS DESIGN VERIFICATION HAS DETERMINED THAT THE CALCULATION IS CORRECT AND SATISFACTORY O

The undersigned hereby certifies that the design verification for the subject document has been completed, the questions from the generic checklist have been reviewed and addressed as appropriate, and all comments have been adequately incorporated, kJ. RAJKOWSKI V. FREGONESE

// !

Design Verifier Assigned By

$t'/re'of Design Verifier /Date Design Verifier Assigned By Signature of Design Verifier / Date Design Verifier Assigned By Signature of Design Verifier / Date Design Verifier Assigned By Signature of Design Verifier / Date

)

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Page _of a Nuclear Common Page 2 of 4 I/I/92

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