ML20134M318
| ML20134M318 | |
| Person / Time | |
|---|---|
| Site: | Clinton  |
| Issue date: | 11/19/1996 |
| From: | ILLINOIS POWER CO. |
| To: | |
| Shared Package | |
| ML20134M310 | List: |
| References | |
| NUDOCS 9611250024 | |
| Download: ML20134M318 (37) | |
Text
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. . . . . . . . . _ _ . . Attachment 4 to U-602657, LS-94-013 Page 41 of 50
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nonder es % ec 21,199410:1T -- Enm 4105951055' -- Peseel ,d-
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- l. Attachment 4 CALCULATION 19.AN-19 REV2 VOLUME E '" 4
! DEPT /DIV. F/EPED .
Report Number: RC-6004 Revision: O Page 6 of 6 l @
' Temperatum Tests: ,
f Pickup Variation from Dropout Variation from
- Temperature Voltage Room Temperature volta 9e Room Temperature
' - .___ t I
258 C 100.04v S9.95v 0.00 % 99.94 --0. 01 % j O 100.04
-20 100.04 0.00 % - 99.94 -0.01%
40 100.11 44.07 % 99.93 -0.02%
55 100.15 40.11 % 99.96 E.01%
70 100.21 40.17 % 100.10 44.15%
Time Variation from .
Temperature Delay Room Temperature i l
- ~
_ l 25a C 0.997 sec 0 0.996 -0.15-
-20 0.993 -0.4% i
+40 0.998 44.1% l
+55 1.007 +1.0% 1
+70 1.013 +1.6%
~ 1 Results of Test: relay characteristics are stable with ' '
temperature and within published specifications.
Relay Tested: 211T6175 Date of Test: 10/15/82 Tester: W.C. Martin
~
Temperature Test with Harmonic Filter Option:
Pickup Variation from Dropout Variation from Temperature Volta 9e Room Temperature Voltage Room Temperature 228'C 100,12v 100.03v ,
-3 100.53 +0.415 100.43 44.40% l
-20 100.90 M.78% 100.81 +0.78%
+40 100.14 M.02% 100.05 *+0.02%
+55 99.88 -0.24'% 99.79 -0.24%
+70 99.30 -0.82% 99.26 -0.78%
Results of Test: relay operation is stable with temperature and within published specifications. ;
Relay Tested: 211T0175-HF Date of Test: 3/6/84 ,
Tester: C.L. Downs ' .
9611250024 961119 PDR ADOCK 05000461 p PDR
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Attachment 4 to U-602657, Ls-94-013 Page 43 of 50 (
.,I For enlibration Lab Precision , .
e 1
j 8 m pigits resolution Anachment 5 CALCULADON 19-AN-19 REV2 VOLUME E
- 0.1 pprn dcV linearity DBPT/DIV. P/BPBD y'*
I **4100 ppm acVabsolute accuracy PPat/yearoptionalstability ,
i
. l
- t 4 .I ,
! 18 the calibrationlab,you11 And the i
HP3458Ns 8:n ts to have exb- Reduced-errorresistance Easycalibration i
onlinarylinearky, wintamalnoise, TheHP 3458A doesn'tstop with The HP3458A gives j s accuratedeV.Similarmeasurement low cost of and ==aalle hort term stabuity.The ownership witha lineastyoftheHP3458NsMultistope mis adleved forsesistance,acV, ='='= two-source and current. You can measure nesistance calibration. thits superior A to Dconverter has been Am- knearky,the HP3458Ais fullycall-
' withstateefh e fromtopnto100withmidrange brated,inw4ading ai:, from a precision Josephsen Jaa'*8m' Usin8 of22 ppm.
intdasic 10 Vdesource anda precision 10 kn standands,linendtyhas y,theIW3458A,likeits HP
' measured dmag=t 2.o5ersofiset- resistor. All ranges and functions are within*0A5ppmoftoVolts.1he -
aue===Manyalibratedusing piecise HP3458A4 transferaccurar.yfor10 Voks deis 0.1 ppmoverI hour
- 0.5'C.
nr{n goo ' iOhmsonthe10O to g,,ti,ninne* the errors internalratio transfer enessurements
- intieduced smallsedes e relative to these external standards. In Internal noise nas been seduced to less offsets, =Ad1*Iaa theHP3458Nsinternal than0.01 ppm rasyleiding8tA forboth two- four- to
- =adard and resistance
.of usabienesolution.So, the stght ice wiseohms,the HP3458Asupplies a da current throughtheunleown adarecalibrated.Nowyou can foryourallbeation *=added dmmis personnaself w .y'-- "
the,w3458A. '
resistance, measures the voltage drop ahndaa relative toHP3458Ns tbself-oraut
' sets the current to zero,and measures,
' thnonagedropsgdhresukis low delft latemal standards at any time dcVstalbillII wl&6eACAI,n====ad So,ifyour ThelongtermaccuracyoftheHP3458A reduced errorforresistance l
e dmin% etivisonment danges, auto-is a semarkable8 ppmperyear- measurements.
4 calibtstion,,yGohyour moreaccieratethan measurementaccuracy.
damsareafteront a Precision acV 002
'n. 1MHP3458Aintroduces newheights Nua of true rasac volts performaneHvith a Calibiationsecu.r ity
- L.aespedfled 4 dolce of tradifianal Unlikeotherdmms,theHP3458A goes yearforthe utd'"*8* ~ ora new to greatlengths ob assume calibration i
- samplin6te&niquefor accuracy. secudty. IGut, a password secudty code Forcalibrationsources "lods' calibration values and the self-
~' waveforms from1Hzto10 the sh=Han 6=,84aa_ Next,youcan e HP3458A% ' sampun6 ;
is=i,.ue easilystoreandrecalla secuted i With160 a+ a-aa yaa:uracy. messa8eformatin'sitems suchas i =hmalate accusaly for ' calibestion date and due date. Plus, the 45 Hf.to or170 ppm absolute 1
accuracy to20 kHr HP3458Aautomaticallyincrements a i enhanceyourmeas theHP3458Awill cdibrationcountereach timeyou. l urementa Accuracy is maintainedto2for up,aah'
- unlock"thedmm-anothersafeguard -
8d==
years withonly asingle10 Volt de a6alast calibration tampedng. If you havea unique situation ordeshe piecision standaad. No ac standa~r ds are ultimate secudty, use the internal dmm necessary.For speed andless accurpcy, the hanhired s' witch to force removalof l true smsac theinstrumentcovers to perform
- technique has a = ad absolute calibration.
measurement of300 ppm using the same alibration procedure. With a width of10 Hz to 2 MHz andseadingintes to 50/second, the a techniqueis an excellent choice for throughput computer-aided testin8
%d
',i 1' pcn.
J' h
. Page 44 of 50 4- 3 :e ;. n : c f a_,5
- CALCULAMON 19 AN-19 REV2 VOLUhfB E
, HP 3458ALTei nical Spec.f .,
i ications N .. oByr./ptv B/EPED ,
1 i
! .mais -
- 1: oCVdaselt .
2: fleelstance12 Seesean egirdget Seedon8: Sysipe Ap=*=daris 24 o
\
l ,ssedes 3: OCCunent14 Soodon9: flade25 . 1 suchen4: ACVotage15 SeoGon10: Mahl%ndons25 j l .
- seasons
- ACounentto Secuen11: eenendspedicaronsas .. .
soo5ea6: FrequenopPeriodt1 SeoGon12: Onlednfldom8fnA27 .
? i j Introduccon I The W 3458A accuracy h spedied as a part per solarne sensuremed onw of he W 3458A' lor Example 5: Absolute Accuracy;90 Day i
- esion @ pad d sw seadno plus a ppa d rance lor vadastenperstnecondirons. Constant condloons Assuming he same consons as Example 4, but I
! dc40has,anddd. In acVand ad,he tares *aangle are: ,. now add = traceabay enor b estabrah absolute
- sp*8adioa ls paud d anding plus pacent d 10VoCinput accuracr !
8M86Ruo**w*wennanndsesesh,44 seyoc,,sge (4,g pp,,say3,paspp,xioy) , e,y i j 1 V,61% etc.; tange does not mean to td scale Tcela23'C- empwase ( pw*Ch t saiadne. e4 1 A V,12 % etc. These accuracies are 90dayaccuracyapooNicadons i sudd lor a specEc dme iram en tast catradon. $.15ppmr10V+0Alppar10V):10'C= 168V j Example 2: Opwadng temperatum is 28' C; HP factorytraaashmiryonwof 2 ppm:
l g g l
m W s458A accuracy apai+=sa,s am mladw to 8m edExudoa dendanis. Absoluis acewacy d e*
$ hamemicexinacydemw3458A wins ame<sibaden wei an epaadns ienpeanwe I* " * *I * * "Y W s4s8A k delennired by adding swee ahd* Totalabsoluleenor = 788V l darc.needssemundedhado es. -
aossades h ew tuossbay o(purcsExaden (4.1ppmx10V)e pAsppar10V) = 42pV seendenLForde% ppsksetraceabayenor
> tam tw W factory.That sneans tin te sinclule Totaiseladaenors 42* p V A&gdonalerrors
- eser selsde to fu ES. Nadenslinsinde d Example 8
- Opwadar -' is38*C; When tw HP 3458Ais opstaled at power line j Slandanis and Tedinology(NIST) is 2 ppm h cycles below 100, addidonal emxs due b noise and admon to 8m ddV accuracy ap=*=8aris. When WidiedACAL gain become signuicent. Exangle 6 Ilustrales the i
! mombransuHP3458A,puredug The opendo0 tempendwe c(#w & 3458Als 38'C. murconocdon at0.1 PLC.
! , JubtyenwwEdependuponfwenorstem 14*C bepad fie sues,of Ted M*C. Medaal Esangle6: Cperadrg tempa'aswois 28'C;0.1 PLC sawcuddmuasExanple2,but 0:
I g Ngapp "."""
Einnple1: Reladw Accuracy;24 Hour
~
tengemessobsitedming 61ppmx1@ +SASppmx1@ sepV
$ (4.1 ppm x10V) +(OA5 ppm x10V) = 42 FV l
- Cpersdngtemperalureistoelit*C Tempeatse Coe5cient(specEcedmis per *Cp 4 (espper10V+0Afppmx10V)r14*C 71pV Relening to the Admonal Emxs diart and RMS Menos fut tu anti,ent temperahme for tw -
Noise IMfpiler table, ademd enor at 0.1 PLC k 1 menaeumsksahinM*Cetenhepasanof esAnaden(TosQ. The24houraccuracy (2 ppm x10V) +(0.4ppmx1 x3 x10V)= 32 FV Tddonws118FV spedadon for a 10 V do measummed on tw to V Toterelauw error =74yV
, sM0 sis 0.8 ppm +OASppm.1hataccuracy -
spedondonmeans: .
Example 4: Cperadng temperature is 30*C; 0.sppmeneaano+04sppednance Wuh ACAI.
' e'rsuhde scouracy,fa enor **aaeraiwilh tw Assumin0fasansanddes as W8,W F
- g. using ACALsignidaandy reduces tw enor due b hepasam mmenoe tom adbradan tempadure.
$5I1A0@00 x 1W) +(OASl1A0@00 x10Y) = Opsadng impaakse is 10'C bepnd tw danded .
15.5 pV or 0.55 ppm o(10V ran0e etTeelMPC.
- (4.1ppmx10V)+(OASppmx10V) 42pV Emns trom temperature changes- Tenperskan Coedded (spedlicadon is per *Cp 1heopdmumlediniceispahEaruof tw S15 ppe r10V 4 OAl ppm x (0Y) r10'C c16 pV W 3458A me based on sulo<sitxalon (ACAL) of 8m kuerumes wilhin fa previous 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> and Totalenor = 68pV fedoulng ambientlongerstwo dunees c(lees han e C.The HP 3458A4 ACAL capsbky conods for measuremord emxs reading Irom he dra of cruical
- ponadsnomInwandianpwaiwe.
ne losowing examples mostruie the error conec.
ilaulo<aRraGon by compuGno #W
{':
10 N4
Attachment 4 to U-602657, LS-94-013
! . Page 45 of 50 -a
! [. ; ,, . . . . . 73 q. . 2 ' v ': Auadument 5 CAIXXJI.A'!10N19.AN-19 REV2. VOLUME EE t. S . m e. g t .o i, 1. . . . y 1.; :. .?. s.M Af. 2
. . DEPTJDIV. B/EPED .f.jl$.h@hagOl:( -
4 l Generallnformation .
Um HMSSA appets em techniges W amemming tw as AC wheon, sed esang asp e The Med .
mesmamen technique k esiedad enugh to SETACV command.De ACV todzu mE tan npply en desen n.4m!
.)- breww.q=manosuonums.
j nw losowing sedion paides 's twist desertpron er en em opereson andes abno oth a summayisbie fielpu b l deosho ew exeniq= twe eded e pw specue nmaannamined. . .. .
SETACVSYNC SynchronouslySubeampl#Computedtruenastechnique.,
l This issnige paides acesent snesty and am ned amnie amannemme resues. a does i
! require that tw kyut signal be sepeerm (ad rendam noise lor exegne ).uw bandwide h this l
{ ,
modeiskom t see totek. ,
I i SETACVANA Analog Computing true nus conversion techn(que. ..
- uds is se mesmamen technique et power <p er losowing en instumedieset. This ande worts !
i was och any signal othh ks 10 ik k 2 lek bandsidte end pmWes lhe indad maannment
- soseds.'
l SETACV RNDM Random Sampled Computed true nas technique.
nas ischniqu eseh emuss oases snents hownw sw e==s ecows:r k en baen d e*
t .
ene andes.tdoesnoteqdea inpm along andis ihmeha mes sumed to midabend t poise maamammes. The kehk andekkostolkb telett.
SelecuonTable
. seat Assensstsec )
l Tecludess . Fmiu.norfg Asommer Asyded teaman usinun i
",;_" ..a .Satsangded lik 1064k OA10% Yes OA25 to ,,
Analog tolk tiek OA3% th CA 50 Random 6ampled 20lk f0 lek 0.1% No 0A25 45 ,
.- I 1
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Siynchronous Subcampled Mode gevama sencysna . , u ,,,,, ,, ew i
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1 MQi15%2d.0pF GA0140A001, 1 1Y tJ000000 100av Ac shegoest,eser 10V 12A00000 1pY 1 MQtt% dd40pF GA0140A001 auftrCdeurACAf tse 100V 120A0000 10pY f init%dd40pF GA01 + 0A001 '"g~ ,
1000V 700A000 - 100pY f 4AQit%dd40pF GA01 + 0A001 :WecmbrdssverkAcV an.sn Anttnun etomanyannia.f esossest v AC Accuracy, enorereYs rarwou
- 2tm H "
24 Hour to 2 Year (% c( Reading + % of Range)
.AC8AND5tiek 1 mto8 40mses gimws so twi.: soemia tooeme sooimio 1lamW R.noe 40 m ttm soute soem 100nm 300 km t lek 2 88
- 10snY 043+0A3 042 + 0411 CA3 + 0A11 0.1 + 0411 03 + 0A11 4A + 0A2 -
100mV 10V OA07 + 0.004 CA07 + 0A02 CA14 + 0A02 CA340A02 CA8 4 0.002 03 + 0A1 14041 1 A + 0A1 100V 042 + 0A04 CA2 4 0A02 CA2 4 0A02 CA35 + 0A02 0.12 4 0A02 0.4 + 0At 15 + 041 1000V 0.04+ 0.004 CA4 + 0.002 0.06 + 0A02 0.12 + 0A02 0J+0A02 -
Ac Amnq estumf en bio **4W
- 15
Attachment 4tod-602657,LS-94-013
,- ,, Page 46 of 50 ANachment 5 CALCULATION 19-AN-19 REV2 VOLUME E DEPT /DIV. E/EPED hA KAr4 4 .
~ p~ Tesu & Measuremenu .
. o l Catalog .
I I
l HEWLETT* !
d
- PACKARD l
= Rob Hansen i field Engineer gg Electrome instruments ,p,,g,,4 l
_ 30S/664-4053 2205 Esa Empire Street 3dd Fox 30$/664-4100 PO Box 3607 81oomengtog Niinois $1702-1607 j Parts to. si$n834804 ~
HP Direct 800/452-4844 A sm,:. 9 m t.hproca es I' l
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,4
- Publishedbythe
<, Test &MeasurementSector Sente Clars,Califomte Producedby RodgeteCommunicadons 4
SanFrancisco,Ce6fornia Printedby IUL0enneley& Sons WEerd,0hio i C ;::tc.se'evicesby Stiboostegraphics Mariette,Georgte J Designofintroductotypages MeteWestDesign Corp, Sen Frencisco,Cetifomia The bodyof tNs boot is printed on recycled paper 5091-8952EUS OO
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l- *..** pr.,.a , ,5 CALCULATION 19-AN-19 REV2 VOLUMB E.
l DBPT/DIV. B/BPED t m 6026n , ra- w o13 l
DIGITAL MULTIMETERS C*M jo 166 A System Multimeter with Both High Speed and High Accuracy
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MATE l HP 3458A STUTEMS l The HP3458Assaltimesershassess' T- "m+' -:- ---bar* Select a rate of 100,000 h-f - ^ Orachievehighest per second for =*et-as ofprecieloawickustoswdij
. rien of speed andscaracyen the psodaction test laseseasch and developssest, and in the cathradoa lab. I1ic HF is abe of aneasu;sessentsecoletionendo.1 mermuliontreasteraccian fastest, most fleshle, and anost acascate moldsseter e5esed by Add to this the HP3458A's ofoperation,andyou have j Hewlett-Packard.layoursystem oron time beach, the HP345EAsaws idealmuldsacterforyoursaast ing applicadoes.
- you time and snomey wkh ; x-- '--'--I test system f a- " , 2 and accuracy, seven function measusement flexibility, sad lo'w cost of ownership.
{
l . High-Test SystemThroughput High-ResoluGon Digitizing Calibration t.ab Precision FasterTo GreaterWavefona SupestsTransfer Measurements
- Up to 1 stadings/s Resolutloa and Accuracy
- 8% digits resolados
- Internaltestsetups >344/s
- 0.1 ppas de vettsJiacarity
(\
v s'
- 168o34 bits sesolation 1 .'
- Programmablelategrationtimes a 100A00 to0.2sem
- 0.1 devolts treasier from 500 as y 1s
- 12MHz" '"' pics /s -
a resolution to 10 as
- 1 ppe ras laternal noise GreaterTestYleid
- IAss 100 ps timejitter
- Moreacascacyfortightertest
- Over75A00 cadinglaterna! ExtraordinaryAccuracy a saargins seemory
- 04 ppas for24 boers la de votts
- Up to 8% digits resolution a 2.2 ppe for 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> la G Fleutble oisillaing Software
- 100 ppe mid bhad sevolts Y,100 kO) software for Series cage creace i cat se 200f300 composers or HF Vectra
- with secesusennent copsocessor
' autoca forat
- Sabprograms forwaveform and tanges,lacteding ac 3 __ -- data transfer FIT.
IFl.and data presentation HP 3458 A Multimeter Perfonnance Features deVolta acVotts ac Current
- 5 ranges:0.1 V to 1000 V a 6 ranges:10 suV to 1000 V
- 5 ranges:100pA to 1 A
- 8% to 4% digits resoladon
- 1 Hz to 10 MHz bandwidth a 10 Hz to 100 kHz be,ndwidth
- Up to 100A00 scadings/s a Up 4o 50 readings /s with att
- Up to 50 readings /s (4% digits) readings to specified accuracy
- 500 ppm 24-hour accuracy
- Maximumsenskivity:10aV
- Choice of sampling or analog
- 0.6 ppm 24-hout accu true rms techniques
- 8 ppm (4 ppa opdonal r
- 100 ppm best accuracy voltage reTerence sta 1 0 dc Current Frequency and Period
- 9 ranges:10 O to 100
- 8 ranges:100 nA to I A
- Voltage or current ranges
- Up to 1,350 readings /s (5% digits)
- Prequency,.1 Hz to 10 MHz j
- 2 wire and 4 wire Q wth offset '
. compensation
- Maximum sensitivity:I pA
- Period:Iw as to I s g
- Up to 50.000 resdings/s
- 14 ppm 24-hour accurscy
- 0.01 % aceutscy (5% digits)
- se or de coupled l
t 8
- Manmum seasidvity:10pn 2.2 ppm 24-hour securacy i
I f 6- (
, Attachment 4 to U-602657, LS-94-013 yn .
Attachment 5 Page 48 of 50 l CALCULA'ITON 19-AN-19 REV 2 VOLUME E " - - -
l
? DEPT /DIV. E/EPED i jb 167 l o
F -
uaximum taput hut ##
g N,u'*4h,a*t I at 6H d ts its g3g 4x dIcs.(16 blu) H!So LO LO to Quard .
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' ted Technical Specifications ja"
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tosw e e e.s eJ + e.s > to on Tcad as* C m a ppm er mais% edisuoms enor br w bcsory e,-a.any g so no ia us tosN1 l Y.,,#, .sI. .N c e4 +
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tir wtc see & 34 teus and a f C et het AcN. Tcal a 8' C, Memory l such de sehne Standard Opden oot l er Ae gp gyNPLCtoQ. Readlngs Bytes Readings Bytes l h.,8 les se-ee.d enkse en udn h.pe.a.e
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- h. .
(48)' -
Math Functions: He HP 3458A performs the to math func-i ao NMR* acECMR deECMR tions os sc.T. cats:NUII., SCAI.A OFFSET, FILTER, l O 90 140 SINGLE POW FILTER. THERMISTOR LINEARIZATION, DB, i
r 80 150 140 DBM, % ERROR, PASS / FAIL IlMIT TESTING, and STATIS-
' - 00
- 150 140 11CS.Tuo math functions may be used at one time. 4 k 70 160 140 -
j "p00__ a0 170 140 GeneralSpecifications mennes k su to hed ow aats er en sie e.wancy owinner e, e, gego' 55 an C '
ass.usem h as es he wtc a t.orso as he wtc = m re sa Humidity Range:95% RH,0* to
" *5 88 '" *8 * * -
U- Storace Temperature: -40'to +77 C .
Powen 100/120 V.220/240 V
- 10%,48 to 66 Hr 360 to 420 Hz h
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< 80 VA seased. Fused at LS A @ 115 Voc0.5 A @ 230 V. <30 W.
k).
t Rated input Nondestructive Size: mm W x 88.9 mm H x 502.9 mm D (16.75 la x 3.5 la x
- 21'000 V 21200V ' 19Ala)
Weigtd: Het,12 kg (26.5 lb); shipplag.14.8 kg (325 lb) a200V 2 350
- 600V
- 1000 pk Y
- OrdedngInformation IIF 3458A Muldmeter (with HP-IB,20 KB reading
.P Q
($6.5n i Voltage -
Gubsampled Mode) mea OptGet=y,Extcoded and 8 ppm Reading stabuity) Memory (expands totat $570
- 4D de utto tE 0011 Igh Stabuhy(
Opt 005 Wawform Ana
) Reference ry for HP Series-g;lasagoo M 5 # ,"***8,*
,,,, y ,,,,,,,,,, 300 computers with BAS C 4.0 or greater and HP Vectru with Measurement Coprocessor Op(IRN MIt4TD-45662A Certificate of $203 u=== 'eE.
. . N t$ tuo!tE.$e,
- a. <m!$$,f Cata,raa M ..NN.u 18" Q
- 8sor ,g jg asgjjgg iun aNuesi <t40pt Op(1BP MIIAID-45662A Certificate of Calibration with data
$300 v Masooo nd ecee
/rN' e44 + omor Op(W30 Two additionalycars return-to HP $160 ear. sw ., ah rc Wor6dheteonte.
AcAL.do cM see peak e.f ec.
ect she 6, piamen tipiA.
embed ci.W h su 6A hardware suppott(sce page 624)
MR ppa W andh's aeshnd enw tx w smsory waaaabar et to vde Opt W31%ree-year customer return calibration coverage -
Op( 700 CIIL tanguage $1.080 Op(907 Proat Handle Kit $60 Op( 908 Rack Flange Kit $40 Opt 909 Rack Flange Kit (with handtes) $90 p
se a r a a r e-a L . a r , n.cas nr.,em.rew **ta o,.,
j-4 . '
Attachment 4 to U-602657, LS-94-013 Page 49 of 50 e
,= e
' WestIngtma Doctric Corporstion. . 44416 D WE A +
)* Sharon Trznsformer Ondslon Product Euseda .
f Sharon. Ps.1Gl40 4 * . Paget j
'4 l Attachment 6 CAlfULATION 19-AN-19 RBV 2 VOLUME E -
f DEFT /DIV. E/BPED j
July 16, t976 2400 Through 4800 Volts, outdur 60 Kv Bit.
yygg p Q.6Q .
New information '
- u.uo io
- c. o.cizo47too m ae* Voltage
! Transformers i
j '
}
i ,
L:
.l .
1 i
3
! ~
0 4
~.
3 i
- - . m., .
_ - . - . . . - - - - - - - - - - - - - ~ ~ ~ ~~ ~ ~ ~ ~'~~ ~ ^ ~ ~ ^ ~ ~ ~ ~ ~
I .. . .
Attachment 4 to U-602657, LS-94-013 i j ,
Page 50 of 50 CALCULAT10N 19-AN-19 REV2 VOLUME E '.- j AuM=t 6 .
44.ats EtWE A DBPT1DIV. B/BPBD. ; ,
f 1 Prochset-Ousetin i
i 92 e 4
5 AppGoetion Dimensions and Weights ~ *
} imoamM* Weight: 4tths.
The type PC040 voltage transformer is a meene s g,,,,,,g o ,,,
oost epony resin unk designed for outdo,or ;g j u ,,va, son, enetoring and
- relaying circoks. Smaa and 3
- eempact. Eigtd in weight, it is particularfy I '
daMa for pole top cluster bracket mounting. > ,_
! Acouracy .
43k ANSI metering accuracy class (60 Hertzj: 1 j- 9 CJ Class for Standard surdens W. x. M. Y 1.1Cisas for Standard Borden Z
~
gj 3 beg 4 1hermal Reting .
-- l
-1 l 1000 VA at 30*C emblent r owd tug a wah Heesar ~3g# 5 g 4g
- Eelootor Guide {oomseersou h8Ha' )
d l Pvtmary Winoing Style bT*"e"w s #2m Number g l
Veitage Rja lo %% gg Meter j 2400/4100Y 'd 1 4421A84G01 4200/4200Y 3b.1 442tA84G02 4
40:1 '4421A84G03 i
jy,
{ 4800/4800Y N
' X!.
I Construction c.atur.s - @y -NamegoHe M*%8r Cast Core and Colg
' *ie coE assembly is a progressive wwWing, g a j
A the high voltage wound direedy over
"** low voltage col. An octagonal WES- Termhais
(,,ws.ge-, .p._
21 O l jl, __._,_.L, k
- ji 1R2 coes loop, and end frames are then l
seltioned with the coR assembly, after which g 7k 3k'""* {
j the unit is encapsulated in epony resin. The i 4 j epowy compound used has high mechanicet
- strength, realatsace to electrical arcing and i tracidng, and can withstand the adverse ef- Performance Curve Typical ratio correction factors and phase angle values plotted for standard burdens. using i foots of - "E-k.ii. The result is a light and the Farber Method ("The Analytical and Graphical Determination of Complete Potential Tr&ns-j compact outdoor unit, with no sacrifice in former Characteristics" - Settles. Farber. Conner - AIEE Transaction Paper 601246. Oc-performance i
tober, t960).
i Tenninela ===========
l Petmery terminels are clamp type connectors. . teos oest of a bronse asey and electro 4in plated
. g- %A
- f. : T y
- j. Ier compete Elty with aluminum or copper. . '
i.. ETi f 1 i
- 1004 j Secondary terminals are brass inserts with I 1 .19042 tapped holes, complete with wash-ers and screws. }
j J
' toot
! A ground terminal, located above the X E eeoondary terminal. is also provided for l grounding the secondary circuit at the trans-
- "**' . u,oo .
~
1 Cocondary Junction Box N l The secondary box is en anodized afui. um
! costing and has tfiree one4nch conduk hubs. ,,,, _
It is anchored to the body of the transformer l *
- ocrews, and can easty be detached.
elmpGfying Instatation and changeout pro- .
i cedures. g,,g
) ] c,.,.....- . . . . . j. . . '
j 0
' O . . ',' ' -
j lfentification
- stainless steel nameptate with au pertinent j ((::1 y.% t' ; ';
- L 's s n~
~ ~ ~
g
" ' ' ' ~ ~
f sta is attached w the front of the unk. f> 30o.ss< -ao _
-to_ o
- no *to__ 43o g directly above the box. A large. easy to read vinyt decal for ratio identification es p(aced N % h M"*'*5 a
]
on each side.
l Attachment 3 l to U-602657 )
! LS-94-013 Page 1 of11 ;
1 l
1 i
Attached Marked-Up Technical Specification Page l
l l
I l
l
Page 2 of 11 LOP Instrumentation 3.3.8.1 3.3 INSTRUMENTATION 3.3.8.1 Loss of Power (LOP) Instrumentation i
l LC0 3.3.8.1 The LOP instrumentation for each Function in Table 3.3.8.1-1 shall be OPERABLE.
APPLICABILITY: MODES 1, 2, and 3, I When the associated diesel generator (DG) is required to be OPERABLE by LC0 3.8.2, "AC Sources-Shutdown."
ACTIONS
NOTE-------------------------------------
Separate Condition entry is allowed for each channel.
CONDITION REQUIRED ACTION COMPLETION TIME A. One or more channels A.1 Place channel in I hour inoperable. trip.
' AAND A.2 --------NOTE---------
1 Only applicable for Functions 1.c, 1.d, .I 1.e, 2.c, 2.d, and j; 2.e after Release for Operations (RFO) of the corresponding plant modification.
Restore channel to 7 days !
OPERABLE status.
B. Required Action and B.1 Declare associated DG Immediately l associated Completion inoperable.
l Time not met.
CLINTON 3.3-78 Amendment No. 96 l
, . Attachment 3 to U-602657, LS-94-013
, , Page 3 of 11 LOP Instrumsntation 3.3.8.1 SURVEILLANCE REQUIREMENTS
NOTES---....--------------------------...
- 1. Refer to Table 3.'3.8.1-1 to determine which SRs apply for each LOP
, Function.
r 1 2. When, a channel is placed in an inoperable status solely for performance af required Surve111ances, entry into associated Conditions and Required
. Actions may be delayed for up to 2 hours2.314815e-5 days <br />5.555556e-4 hours <br />3.306878e-6 weeks <br />7.61e-7 months <br /> provided the associated Function maintains DG initiation capability.
SURVEILLANCE FREQUENCY- -
. h_
SR 3.3.8.1.1 Oe/ (x :;ded);;;;;'
ih ^;i;C" -
^ ^ ;,;;n '
0-SR 3.3.8,1.2 Perform CHANNEL FUNCTIONAL TEST. 31 days -
SR 3.'3.8.1.3 Perform CHANNEL LIBRATION. 18 months SR 3.3.8.1.4 Perform LOGIC SYSTEM FUNCTIONAL TEST. 18 months CLINTON ~3.3-79 Amendment No.)MI
1
. . Attachmsnt 3 to U-602657, LS-94-013 l
, . Page 4 of 11 LOP Instrumentation 3.3.8.1 i Table 3.3.8.1 1 (page 1 of 1) .
Loss of Power Instrumentation REQUIRED CilANNELS PER SURVEll1ANCE ALLOWABLE ,
FUNCTION DIVISION REQUIREMENTS VALUE 5
- 1. Divisions I and 2 4.16 kV Emergency Dus Undervoltage
)
- a. Loss of Voltage 4.16 LV basis 6 SR 33.8.13 2 2345 V and s 3395 V i SR 33.8.1.4
- b. Loss of Vol&ge Time Delay 6 SR 33.8.13 s 10 seconds l SR 33.81.4 '
- c. Degraded Voltage Reset- 4.16 k V 2 SR 3.3.8.1.2 23876 Vands3901 V (a) basis SR 3.3.8.1.3 SR 3.3.8.1.4 Dropout 3848 3876 d e. Degraded Voltage A - 4.16 kV 2 - M" 2 3%3 V and s as33 V basis SR 33 8.13 (b) / >
SR 33.8.1.4 e d. Degraded Voltage Time Delay i SR 33.8.1.2 214 seconds and s 16 seconds !
SR 33.8.13 j SR 33.8.1.4
- 2. Divisions 3 -4.16 LV Emergency ;
Bus Undervoltage
- a. Loss of Voltage 4.16 kV basis 4 SR 33.8.13 - 2 2345 V and s 2730 V SR 3.3.8.1.4
- b. Loss of Voltage -Time Delay 1 SR 33.8.13 s 3.0 seconds !
SR 33.8.1.4 l m
- c. Degraded Voltage Reset- 4.16 k V 2 SR 3.3.8.1.2 23876 VandS3901 V (a) basis SR 3.3.8.1.3 '
SR 3.3.8.1.4 Dropout ,,,,,
3848 3876
- n. _ Degraded Vokage A - 4.16 kV 2 3(c b) gg ggy, 2 3%3 v and s as33 V (b) 00555 SR 33.813 l t d. Degraded Voltage -Time Delay i SR 33.8.1.2 214 seconds and s 16 seconds SR 33.8.13 SR 33.8.1.4
_ -~ m -
(a) This Function is to be used after RFO of the corresponding plant modification. Prior to RFO ofthe corresponding plant modification this function is not applicable.
(b) This value is to be used after RFO ofthe correspondingplant modification. Prior to RFO of the correspondingplant modification the Degraded Voltage Dropout - 4.16 k Vbasis Allowable Value shall be 2 3762 Vand S 3832 V.
(c) This value is to be used after RFO of the correspondingplant modification. Prior to RFO ofthe correspcmdingplant modification the Degraded Voltage Dropout- 4.16 k Vbasis Required Channels Per Division shallbe 3.
e w CLINTON 3.3-80 Amendment No. 95
Page 5 of 11 f
AC Sources-Operating ;
3.8.1 ;
1 rs ACTIONS (continued) l )l CONDITION REQUIRED ACTION COMPLETION TIME G. Three or more required G.1 Enter LCO 3.0.3. Immediately. '
. AC sources inoperable.
i i i i 1
l l SURVEILLANCE REQUIREMENTS SURVEILLANCE FREQUENCY l
l SR 3.8.1.1 Verify correct breaker alignment and 7 days l indicated power availability for each l offsite circuit.
l SR 3.8.1.2 -------------------NOTES-------------------
l 1. Performance of SR 3.8.1.7 satisfies ,
this SR. l i
! 2. All DG starts may be preceded by an 1
engine prelube period and followed by l a warmup period prior to loading.
l 1
- 3. A modified DG start involving idling and gradual acceleration to synchronous speed may be used for this SR as recommended by the manufacturer.
l
- When modified start proceduras are not used, the time, voltage, and frequency tolerances of SR 3.8.1.7 must be met.
I
' Verify each DG starts from standby As specified in-
'3870 conditions and achieves steady state Table 3.8.1-1
- l. voltage E6M9 Y and s 4580 V and frequency 2: 58.8 Hz and s 61.2 Hz.
4 (continued)
CLINTON 3.0-4 AmendmentNo.JHl
, , Attachment 3 to U-602657, LS-94-013
, , Page 6 of 11 5 of 10 -
Pcg*C A S:urcss-Operating 3.8.1 SURVEILLANCE REQUIREMENTS (continued)
SURVEILLANCE FREQUENCY SR 3.8.1.7 --------------- ---NOTE------------------
All DG starts may be precede.d by an engine prelube period.
Verify each DG starts from. standby 184 days 3870 condition and achieves, in s 12 seconds, voltage ar8M6 V and s 4580 V and frequency
- t: 58.8 Hz and s 61.2 Hz.
SR 3.8.1.8 ------------------NOTE--------------------
This Surveillance shall not be performed in -
l MODE 1 or 2. However, credit may be taken l for unplanned events that satisfy this SR.
l Verify automatic and manual transfer of 18 months unit power supply from the normal offsite circuit to the alternate offsite circuit.
I SR 3.8.1.9 -----------------NOTES--------------------
- 1. This Surveillance shall not be
[
performed in MODE 1 or 2. However,
, credit may be taken for unplanned I
events that satisfy this SR.
- 2. If performed with DG synchronized with offsite powe'r , it shall be performed at a power factor s 0.9.
1 ..........................................
Verify each DG rejects a load greater than 18 months or equal to its associated single largest post accident load and following load rejection, the engine speed is maintained
'less than nominal plus 75% of the difference between nominal speed and the overspeed trip setpoint or 15% above nominal, whichever is lower.
(continued)
CLINTON 3.8-6 Amendment No. Aff
.-. . . - - - _ . - . - - . . . . . . .. = . . - --. . --. - -
+
3.8.1 l SURVEILLANCE REQUIREMENTS (continued)
SURVEILLANCE FREQUENCY l
SR 3.8.1.11 -------------------NOTES-------------------
- 1. 'All DG starts may be preceded by an' .
engine prelube period. I
- 2. This Surveillance shall not be performed in MODE 1, 2, or 3. l However, credit may be taken for :
! unplanned . events that satisfy this SR.
. I 1
Verify on an actual or simulated loss of 18 months offsite poder signal:
- a. De-energization of emergency buses; ,
1
- b. Load shedding from emergency buses for Divisions I and 2; and
- c. DG auto-starts from standby condition and:
i
! 1. energizes permanently connected loads in s 12 seconds,
- 2. energizes auto connected shutdown l loads,
'l 3g10 3. maintains steady state voltage !
arSM6 V and :sl 4580 V, 1
. 4. maintains steady state frequency a 58.8 Hz and s 61.2 Hz, and l
l S. supplies permanently connected and
. auto-connected shutdown loads for l 2 5 minutes.
! (continued) i CLINTON 3.8-8 Amendment No. pJ
. . Attachment 3 to U-602657, LS-94-013
.
- Page 8 of 11
[
AC S:urces--Operating l
. 3.8.1 SURVEILLANCE REQUIREMENTS (continued)
SURVEILLANCE FREQlENCY
- SR 3.8.1.12 -------------------NOTES-------------------
- 1. All DG starts may be preceded by an j engine prelube period.
- 2. This Surveillance shall not be
- performed in H00E 1 or 2. However,
- credit may be taken for unplanned 1 events.that satisfy'this SR.
i 4
Verify on an actual or simulated Emergency 18 months Core Cooling System (ECCS) initiation ,
signal each DG auto-starts from standby condition and: ,
- a. In s 12 seconds after auto-start and '3870 - '
during tests, achieves voltage a:
V and sg4580,V;
- b. In s 12 seconds after auto-start and during tests, achieves frequency a: 58.8 Hz and s 61.2 Hz; and
- c. Operates for a: 5 minutes.
SR 3.8.1.13 r-----------------NOTE--------------------
This Surveillance shall not be performed in MODE 1, 2, or 3. However, credit may be taken for unplanned events that satisfy this SR. .
Verify each DG's automatic trips are 18 months bypassed on an actual or simulated ECCS initiation signal except:
- a. Engine overspeed;
- b. Generator differential current; and ;
I (continued)
CLINTON 3.6-9 Amendment No. 95'
.. - -. .- . . . . . . - . _ - . - . . . - . _ , -- ~ , . . - . - . . .-.
. . Attachment 3 to ';-o02657, LS-94-013 4
. . Page 9 of 11 l
l J
AC Sources-Op,erating l 3.8.1 l 1 <
, SURVEILLANCE REQUIREMENTS (continued)
'}i SURVEILLANCE FREQUENCY, l J
l SR 3.8.1.14 -------------------NOTES-------------------
l 1. Momentary transients outside the load -
{ and power factor ranges do not invalidate this test.
j 2. This Surveillance shall not be
- performed in MODE 1 or 2. However,
! credit may be taken for unplanned events that satisfy this SR.
l I Verify each DG operating at a power factor 18 months -
- s 0.9 operates for = 24 hour2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br />s
i a. For a 2 hours2.314815e-5 days <br />5.555556e-4 hours <br />3.306878e-6 weeks <br />7.61e-7 months <br /> loaded a 4256 kW for DG i 1A, a 4263 kW for DG 18, and a 2420 kW j for DG.1C; and i s
. b. For the remaining hours of.the test j - loaded a 3869 kW for DG 1A, a 3875 kW for DG 18, and a 2200 kW for DG IC.
1 l
? l SR 3.8.1.15 ------------------NOTES------------------- l
- 1. This surveillance shall be performed within 5 minutes of shutting down the DG after the DG has operated = 1 hour1.157407e-5 days <br />2.777778e-4 hours <br />1.653439e-6 weeks <br />3.805e-7 months <br /> loaded a 3869 kW for DG 1A, a 3875 kW for DG 1B, and a 2200 kW for DG IC.
- Momentary transients outside of the load range do not invalidate this test.
~
- 2. All DG starts may be preceded by an engine prelube period.
3870 . Verify each DG starts and achieves, in 18 months s 12 seconds, voltage ar99# V and s 4580 V
- and frequency = 58.8 Hz and s 61.2 Hz.
(continued) 3.8'10 CLINTON Amendment No..IHF
,s u e 4- e 4 J.s: A.m- A4=,,.. a- a-pe, y m.A n- waa m_,ao se _A A
- ,_,- ,,n -m .e
- Attachment 3 to U-602657, LS-94-013
- Page 10 of 11 AC Sources-Operating 3.8.1 SURVEILLANCE REQUIREMENTS (continued)
SURVEILLANCE FREQUENCY SR 3.8.1.19 -------------------NOTES-------------------
- 1. All DG starts say be preceded by an l engine prelube period.
- 2. This Surveillance shall not be performed in MODE 1, 2, or 3.
However, credit may be taken for unplanned events that satisfy this SR. -
Verify, on an actual or simulated loss 'of 18 months offsite power signal in conjunction with an ,
actual or simulated ECCS initiation signal: .
- a. De-energization of emergency buses;
- b. Load shedding from emergency buses for Divisions 1,and 2; and
- c. DG auto-starts from standby condition and:
- 1. energizes permanently connected loads in s 12 seconds, !
- 2. energizes auto-connected eir.orgency loads, 3870 3. a.chievds steady state voltage E 8 M 6 V and s 4580 V, ,
1
- 4. achieves, steady state frequency a 58.8 Hz and s 61.2 Hz, and
- 5. supplies permanently connected and auto-connected emergency loads for a 5 minutes.
(continued) l
\
~
(
i l
CLINTON 3.8-13 Amendment No. 98'
l Attachment 3 to U-602657. LS-94-013 )
. . Page 11 of 11 4
E dourcai-Opsrating 3.8.1 SURVEILLANCE REQUIREMENTS (continued)
SURVEILLANCE FREQUENCY SR 3.8.1.20 -------------------NOTE--------------------
All DG starts may be preceded by an engine prelube period.
Verify, when started simultaneously from 10 years ;
standby condition. each_DG achieves, in yg7o) __
s 12 seconds, voltage FW40 V and s 4580 V and frequency 2: 58.8 Hz and s 61.2 Hz. , ,
1 s
I 1
l l
l l
l
)
l i
I i
CLINTON 3.8-14 Amendment No. 95' l
Attachment 5 to U-602657 LS-94-013 Page 1 of 14 Attached Marked-Up Pages of the Technical Specification Bases l
i l
- . -. - - . . . - -. -. . . . ~ - . . . . . - .-. . _. .-. .. _ _ . _
j ., .. Attachment 5 to U-602657 LS-94-013 Page 2 of 14
~
i E0P Inst'rurentaticn B 3.3.8.1 ,
. B 3.'3 INSTRUMENTATION (
j B 3.3.8.1 Loss of' Power (LOP) Instrumentation
- BASES h CKGROUND Successful operation of the required' safety functions of t.he Emergency Core Cooling Systems (ECCS) is dependent upon the 2 availaibility of adequate power sources for energizing the various components such as pump motors, motor operated valves, and the associated control components. ~The LOP instrumentation monitors the 4.16'kV emergency buses.
~
Offsite power is the preferred source of power for the 4.16 kV emerge'ncy buses. If the monitors determine that .
i insufficient power is available, the buses are disconnected from the offsite power sources and connected to the onsit'e j ~
i diesel generator (DG) power sources. ,
l Each 4.16 kV emergency bus has its own independent ' LOP
- instrumentation and associated trip logic. The voltage for
-l the Division 1, 2, and 3 buses is monitored at two levels, j which .can be considered .as two different undervoltage j functions: loss of. voltage and degraded voltage.
l The LOP instrumentation causes various bus transfers and -
)
disconnects. Each Division 1 and 2. emergency bus Loss of j
Voltage Function is monitored by two undervoltage relays on -
j the emergency bus and two undervoltage' relays on each of the two offsite power sources. The outputs of these relays are-arranged in a two-out-of-two taken three times logic i configuration._ Each of these relays is an inverse time _
delay rel . uun n1a v m on rv cy l
o e Func n.is- tored by un rvol i a for ac e ency bi whose ou ts ar arrap he.ou'
- aFA d
! [ a ate o-o of-two ogic c nute + = time A guration v *al av at 11 he Division 3 l
emergency bus Loss of Voltage Function is. monitored by (continued) i 4
I i
i i -
! CLINTON B 3.3-222 Revision No. 1-1 4
i
- - _ - - . ~ _ _ . . - _ - . . - . . - - .
Attachment 5 to U-602657, LS-94-013 Page 3 of 14
' y y ,
h%h a15isn / OI con 2 sossegot 3s ed$yenc LOP instrumentation I
- bw e ade. fogg 6y, cad on s's are4 f 3.3.8.1 -
I
', " dEP e. re er eac4 e coe $
" wo leje m wu om ksc Mpts ten ed in d are [a
- e. 4 as j 6 to p
ske My ay Qef y,
, ~.
i ggggg -
^-
)
i four undervoltage relays whose outputs aie arranged in a j
- BACKGROUND N
- mut J one-out-of,two taken twice logic configuratie at (continued) of this 1611c inputs. to a time delay relay.Q- rproivt 93- H ncy Ws Degr ea von.a .runc;1 1s- sito yo
- {
rvo age re with e outp cont sa ion. he tput ngsd i
,[
f
- re ut-of- ree log configu t j
c inou to a ti delav av /
i APPLICABLE The LOP instrumentation 'is' required for the Engineered .-
l SAFETYANALdES, Safety Features to function in any accident with a loss of j LCO, and offsite wnter. The required channels of LOP instrumentation i APPLICABILITY ensure tiat the ECCS and other assumed systems powered from
' the bGs provide plant grotection in the event of any of!the -
analyzed accidents in teferences 2, 3, and 4 in which a loss of offsite powe.r is assumed. The' initiation of the DGs on
- . loss of offsite power, arid subsequent. initiation of.the-l ECCS, ensure that the fuel peak claddii@ temperature remains below the ' limits of 10 CFR 50.46.
l Accident analyses' credit the loading of the DG based on the - -
loss of offsite power during. a loss of coolant accident (LOCA). The diesel starting ahd loading times have been .
included in the dela'y time associated with each safety .
system component requiring DG supplied power following a loss of offsite power. ,
The LOP instrumentation satisfies Criterion 3 of the NRC Policy . Statement. ,
The OPERABILITY of the LOP instrumentation is dependent upon .
the OPERABILITY of the individus1 instrumentation channel Functions specified in Table 3.3.8.1-1. Ea'ch Function must have a required number of OPERABLE channels per 4.16 kV emergency bus! with their setpoints within the specified A11'owable Values. A channel is. inoperable if its actual t'rip setpoint is not within its, required Allowable *Value.
The actual .setpoint is calibrated consistent with applicable setpoint methodology assumptions.
The Allowable. Values are:specifIed' for each Function in the Table. Nominal trip setpoints are specified in the setpoint calculations. The nominal setpoints are selected to ensure that the setpoint does not exceed the Allowable.- Value between CHANNEL CALIBRATIONS. Operation with a trip setpoint less conservative than the nominal trip setpoint, (continued)-
T
~
l CLINTON 8 3.3-223 Revision No. 1-1
- . . - . ,- . .- - - - ~ . . .- - . . .. - . .- . . - . .
Attachment 5 to U-602657, LS-94-013 t Page 4 of 14 INSERT for TS Bases at page B 3.3-223 r .
Prior to Release for Operations (RFO) of the associated plant modification (i.e.,
modification AP-027 for Division 1 or AP-028 for Division 2 ), each Division I and Division 2 emergency bus Degraded Voltage Function is monitored by two undervoltage relays for each emergency bus whose outputs are arranged in a two-out-of-two logic 3
configuration. The output of this logic inputs to a time delay relay for each emergency ,
bus (Ref.1). Prior to RFO of modification AP-029, the Division 3 emergency bus !
Degraded Voltage Function is monitored by one undervoltage relay with three output contacts arranged in a three-out-of-three logic configuration. The output of this logic
' inputs to a time delay relay. Following RFO of the associated plant modification, each Division 1, Division 2, and Division 3 emergency bus Degraded Voltage Function is :
+
monitored by two undervoltage relays for each emergency bus whose outputs are arranged in a two-out-of-two logic configuration. The output of this logic inputs to a ,
time delay relay for each emergency bus.
I I
i I
1 6
4 l
I
. ~ . - - -_- . _ ~ - . . - - - .
. . Attachment 5 to U-602657, LS-94-013
. . Page 5 of 14 a
LOP 7nstrumentation i B 3.3.8.1
~)
BASES
! APPLICABLE 1.a. 1.b. 2.a. 2.b. 4.: 6 kV Eneraency Bus Undervoltaae l SAFETY ANALYSES, (Loss of Voltaae) (cont'nued). -
< LCO, and l APPLICABILITY required equipment. The time delay specified for the
- Divisions 1 and 2 4.16 kV Emergency Bus Loss of Voltage Functions corresponds to a voltage -at the 120-volt Basis
- trip setpoint of k 67 volts and s 97 volts. Lower voltage i c.onditions will result in decreased trip times. The
- Division 3 4.16 kV Emegency. Bus Loss of Voltage Function
- 120-volt Basis trip setpoint is a 67 volts and s 78 volts.
i ~~
Six channels of 4.16 kV Emergency Bus Undervoltage (Loss of Voltage) Function >er associated emergency bus for Divisions I and 2 and four ciangels for Division 3 are only required
- i. OPERABLE to ensure that no single instrument fail.ure can
- preclude the DG function. (Six channels input to ea'ch of
)' the Division 1 and Division 2 DGs and four channels input to
- the Division 3 DG. Each of the six channels for Division 1 and six channels for Division 2 is an inverse time delay i relay. Each of these time delays are considered to be separate channels'. For Division 3 the Loss of Voltage
!. Function logic inputs to a single time delay relay. Thus, i
- only one time delay channel is associated with Division. 3.)
! Refer to LC0 3.8.1', "AC Sources-0perating," and LCO 3.8.2,
!- "AC Sources-Shutdown," for Applicability Bases for the DGs.,
1.'c. 1 .c. 2. .16 kV Emeraency Bus Undervoltaae 1 (DearadEvoltaaerJ A reduced. voltage condition on a' 4.16 kV emergency' bus
- indicates that while offsite power may not be completely
- last to the respective emagency bus, power may be i insufficient for starting large motors without risking j .
damage to the motors that cou ,d disable the ECCS function.
Therefore, power supply to the bus is transferred from offsite power to onsite DG power when the voltage on the bus drops below the Degraded Voltage Function Allowable Values (degraded voltage. with a time delay). This ensures that adequate power will be available to the required equipment.
The Bus Undervoltage Allowable Values are low enough to prevent inadvertent power supply transfer, but high enough IMSM7~- to ensure that sufficient power is available to the required g- '9Y1N" Ii. !!1' T5 Ti Dii 55 able (continued)
CLINTON B 3.3-225 Revision No. 1-1
Page 6 of 14 INSERT for TS Bases at page B 3.3-225 l
.I P '
% f~ N e
) Asbestated available above, theECCS purpose functionof thisa LOCA.
instrumentation is to ensure that sufI i
to support the during During a LOCA, the ECCS and other safety systems will be initiated at the start of the event. This large loading of i the safety buses results in a voltage transient of sufficient magnitude to start the degraded :
voltage timers. If the degraded voltage relays do not reset, which requires the voltage to !
be restored to a level above the relay reset setpoint, the bus undervoltage time delay '
relays will trip, resulting in bus transfer to the DGs. Thus, the relay reset (pick-up) setpoint must be high enough to ensure adequate voltage for the safety-related loads. I
( Prior to RFO of the corresponding plant modification (i.e., modification AP-027 for l' Division 1, AP-028 for Division 2, or AP-29 for Division 3), the Degraded Voltage Function Allowable Value specified is the allowable value for the relay dropout ::tpcin:. ;
The A!!c=:b!: Value h= = 120 vc!: h=l: cf 2107.5 veh :nd c109 5 veh 'Ref. 5). r .!
I Following RFO of the corresponding plant modification, the Degraded Voltage Function j Allowable Values specified are is4he for the relay dropout and the relay reset ::pcir:. ;
Because the dropout and reset settings are not independently adjustable for the relays ;
utilized for the Degraded Voltage instrumentation prior to RFO of the associated ;
l: modification, only the dropout setting is applicable as explained in Table 3.3.3-1 by footnote (a). The A!!c v 5!: Value h= = 120 veh h=!: cf 211108 veh:: d c!!!.82 = ;
ap::!f: d in IP C !: !: !rr 19 AN 19 (Ref. 5)- l The Allowable Values to be used after RFO are as determined within IP Calculation 19-
./ AN-19 (Ref. 5). The basis for the reset Allowable Value upper limit is the avoidance of ;
shifting to the onsite source when the offsite source is acceptable as specified within ;
(
GDC 17. The basis for the reset Allowable Value lower limit is the minimum voltage required to support the LOCA loads. The basis for the dropout Allowable Value upper limit is the practical limit of the reset Allowable Value lower limit. The basis for the dropout Allowable Value lower limit ensures adequate voltage to start plant equipment
) !
under non-LOCA loading conditions. Because of the voltage transient experienced at the start of a LOCA, the specified Degraded Voltage drop-out Allowable Value lower limit provides significant margin to the setting required to mitigate a LOCA. This value was L selected based on other licensing basis events descussed in USAR, Section 8.3.1.1.2 (Ref.
~ 1) and calculated in IP Calculation 19-AN-19.'
Y / % s ~ -
l l
l i l l l 4
Attachment 5 to U-602657, LS-94-013 Page 7 of 14 l .
.l j
LOP ~ Instrumentation B 3.3.8.1 BASES.
- 1. c. 1. c. 2, .16 k'V Emeraency Bus Undervoltaae
! APPLICABLE 4
SAFETY ANALYSES, (DearadeDoltaae)qdontinued)
- LCO,.and -
i APPLICABILITY Values are long enough to provide time for the offsite power -
supply to recover to normal voltages, but short enough to ensure that sdfficient' power is available to the required
)
equipment. ( gggr~ A
- i 1tage (Degraded
(> Two cliannels of 4.16 kV ' Emergency Bus Unde us for Divisions Voltage). Function per associated emergene 1 and 2 and tir:: cirrre'- #~ at SS: 3 re only required, ll to3 be OPERABLE when the associated DG is required to be
- l /M3N OPERABLE to ensure that no single instrument failure'can*
i
' ( i) preclude
{
the Divisionthe DG L t-ffunction..
"t fSS: 2 (Two.
3 60e andchannels input toh-d thr:: :h:::
tre-4he-0444e4eh 3 DBSP The Degraded Voltage Function logic each of N
for each Divisich inputs to a single time delay relay.
Thus, only one time delay channel is associated with each JgSgg7~C Division. ~ Refer'to LCO 3.8.1 and LCO 3.8.2 forj w .
11 cab]i ity Bases for the'DGs. w {
ACTIONS A Note has been pro'vided to modify the ACTIONS related to ,
LOP instrumen' cation channels. Section 1.3, Completion -
J Times, :pecf fies that once a Condition has been entered, subsequent divisions, subsystems, components, or var.iables expressed in the Condition discovered to be inoperable or not within limits will not result .in separate entry into the Condition. Section'1.3. also 'spe.cifies that Required Acti6ns of the Condition continue to apply for each additional ~
failure, with' Completion Times based on initial entry into .
~ the Condition. However, the Required Actions for inoperable
. LOP instrumentation channels provide ' appropriate '
com>ensatory measures for separate inoperable channels. As suci, a Note has been provided that allows separate .
-. Condition entry for each inoperable LOP instrumentation
~
channel.
ena A.1 ]
With onior more channels of a Function inoperable, the ~
Function may not be capable of performing the intended .the function. Therefore, only I hour is allowed to restore (continued)
CLINTON B 3.3-226 Revision No. 1-1
.. . Attachm:nt 5 to U-602657, LS-94-013
.
- Pags 8 of 14 INSERT A for TS Bases at page B 3.3-226 (except 3 channels ar+ equired for Division 3 prior to RFO of modification AP-029 )
INSERT B for TS Bases at page B 3.3-226 (except that 3 channels input to the Division 3 DG prior to RFO of modification AP-029)
INSERT C for TS Bases at page B 3.3-226 Footnotes (a), and (b), and (c) to Table 3.3.8.1-1 identifye* plain that the TS changes are not effective untilupon RFO of the corresponding plant modification. The planned modifications are: AP-027 for Division 1, AP-028 for Division 2, and AP-029 for Division 3.
~
At$achment i to b~-6U 65 b S-94-013
', ," Page 9 of 14 LOP Instrumsntation B 3.3.8.1 BASES --
_- -. =
Qt,,,,py,f4,g,g,,,
(
an ACTIONS ( d A.Q )
contTnued 9 inoperable channel to OPERABLE status. If the inoperable f channel cannot be restored t'o OPERABLE status within the' allowable out of service time,'the channel au h -i M _t
~
the tripped condition per Required Action A.1 ac ng um inoperable channel in trip would conservative 1 ompensate L for t inoperability and allow operation to 41 Thus, f.tr.;t:e f it is not desired to place th. continue..rMfffA e channel in Kple.g.,7s in the case where placing the channel in trip would result in a DG initiation)nCondition 8 must be
' entered and.its Required Action taxen. 'hwgr3 -
The Complation Time is intended to allow the operator tJme evaluate _a re air anv discovered _inonarmhn 4+1 - ,
4=neue comblo ion _ mes_4e*lece~ptable because st45nimizer a' lowhir timeTor restoraT. ion or^ sripping or - -
channels. ,.
4 MS M C.
U ,
N If any Required Action and associated Completion Time is not met, the associated Function'may not be capable of .
>erfoming.the ~ intended ~ function. Therefore, the associated
, M(s) are declared inoperable 'immediately. This requires entry into applicable Conditions 'and Required Actions.of
- - LC0 3.8.1 and LCO 3.8.2, which provide appropriate' actions for the inoperable DG(s). .
' SURVEILLANCE As noted'at the beginning of the SRs, the SRs'for each LOP REQUIREMENTS Instrumentation Function are located in the SRs column of Table 3.3.8.1-1.
The Surveillances are modified by a Note to indicate that -
when a channel is placed in an inoperable status solely for performa'n ce of required Surve111ancies', entry into associated .
Conditions and Required Actions may be delayed for up to
~
6 hours6.944444e-5 days <br />0.00167 hours <br />9.920635e-6 weeks <br />2.283e-6 months <br /> provided the associated Function maintains DG initiation capability. Upon completion of the Surveillance, or expiration of the' 6 hour6.944444e-5 days <br />0.00167 hours <br />9.920635e-6 weeks <br />2.283e-6 months <br /> allowance, the channel must be returned to OPERABLE status or the applicable Conditi'on entered and Required Actions taken.
(continued)
Y CLINTON B 3.3-227 Revision No. 1-1
- .. _ - , - . . . - - - . ... .. .. - . . .. - . ~ . . . .- .-
, . Attachasnt 5 to U-602657, LS-94-013 )
.. . Page 10 of 14 i
4 4
i i
- j. INSERT A for TS Bases at page B 3.3-227 ;
I i
However, for Degraded Voltage Functions, placing the inoperable channel in trip may not conservatively compensate for the inoperability. Because of the assumptions used in the setpoint calculations, the setpoint for the remaining OPERABLE channel (s) may not .
~
ensure reset of the relay within the required voltage range. As a result, operation with an 4
inoperable Degraded Voltage channel (s) in trip is limited to 7 days. !
t I
- t. INSERT B for TS Bases at page B 3.3-227
- l
- i. or if the inoperable channel (s) is not restored to operable status within the allowable out !
of service time
!~ t INSERT C for TS Bases at page B 3.3-227 .
' Required Action A.2 is modified by a Note which states that the Required Action is only l 1
applicable for Functions 1.c,1.d,1.e,2.c, and 2.d, and 2.e following RFO of the
- corresponding plant modification (i.e., modification AP-027, AP-028, or - AP-029). The [
[~ day limitation is imposed as a result of assumptions associated with the setpoint calculations for the modified Degraded Voltage Function instrumentation. ;
l 4
. - Attachment 5 to U-602657. LS-94-013 j
- ' Page 11 of 14 l
i '
' LOP Instrumentation l
' B 3.3.8.1 :
8ASES
.) .
S RV LLAN SR- 3.3.8.1.1 7 Aj, y 93 g ggg ontinued) f .... ..'.e. _ _ _....c; _ _ ;f,_ t, h,; C:'"_.","E,l ".".
CC."_ _c:::
.,........_ ._ : ::-- =,se .. . =:r:
. . , , ,,,,, ,,. a
- u. ...
.r.
mo...._; J,... __
.. ,.... oer,.... .. .._..,.. .... ..,, . .. ,,. ....... . _ ______ __
.. p..
.L___
1
_AL.A a
A .. ., . . . . . . . .
.. .. u...a
........4.].._.,p.. _--..m__._.i.....,__
- o. n. . . . i _..
,,.. . ... _ ,si.,..
_t.._.._.. .
. . _ _ _, , , . . . y.._.,.,.,__..___..-
..yv ___.,.e..-
,,...a _
,...a.
1 24.,_...__._ , , ,
- 4 + 4. ,
.. ...a..._ .. o_me
. . ...,....___,.......,i......i.,.._..___ _..,u____.t
. -_____ 4.. . _ . . . . . . . . , . .
,L -
,,,,r. e_ry, - 4 3. .
- 4. .. c h_a , . '. ' . . ' . ' . . - . . - -r '.
^
.. . , _ *+'..'--,-^i..-.-.i.,'.v>u'--
g._i _-... ........ ___i.,._.,. ..
.,..... .. .,.._ i.,. u ._ . ..
i l manig n
)
\, . f. , ___,
. . . . . ..-. . . _ .,_. _. ., .c,,.. ~ ... , , __, . . . . . . .. - - .. . .
a ce ,i. e;.,ien e' th: l.e..r.:' 'n.t-" cit ;r.:_ . _rta, _ _ _ _ int,' .
k f.. 3, . 2 4 .. . . . . , 4 ,i . ._ ,_ i. n . . ,+
- ._. _ . _ .,e
_. 2. u. . i. n ,.
- e. r. .- . . . . . . . . . ...
. . 2 "u ...2. *.i..... _ . . _ _ . .4+. a., . - ,. . u s . . . < nd t ,.2,*n* ~o..
,. _ . . s. t.. . ...
4 l
... trr- r.t has dr-15ted-octside'its li it
! equency-44-based vu veers.tir; .x v i'er th .
j p;.;r.si.. ete:
os , ____. ,chann,e'. f:thr; i: :, .' 'he. CHANNEL--6H ._o.
.._i._._..___
ye.. .... .. . . . . . .
..er.r.; . i- durir.i-r.ormal-.operaMonal ,=_ _c,f the-dispie" 2 . .w
... . ... .... .._. . . ..,,......e,.i..__.......u-SR 3.3.8.1.2.
J A CHANNEL FUNCTIONAL TEST is performed on each required channel to ensure that.the entire channel will perform the intended function. .For Series Functions, a separate CHANNEL FUNCTIONAL TEST is not required for each Function, provided j each Function is tested.
'Any setpoint adjustment 'shall be consistent with the assumptions of the current plant specific setpoint methodology.
The Frequency of 31 days is based on plant operating' experience with regard to channel OPERABILITY that demonstrates that failure in any 31 day interval is rare.
(continued)
CLINT0'N B 3.3-228 Revision No. 1-1
Attachment 5 to U-602657, LS-94-013 l' * ' Page 12 of 14 LOP Instrumentation B 3.3.8.1 i
,. 8ASES i
4 SURVEILLANCE SR 3.3.8.1.3 i REQUIREMENTS A CHANNEL CALIBRATION is a complete check of the instrument (continued) loop and the sensor. This test verifies the channel responds to the measured parameter within the necessary
- range and accuracy. CHANNEL CALIBRATION leaves the channel adjusted to &ccount for instrument drifts between successive calibrations consistent with.the plant specific setpoint ,
methodology.
- The Fr'equency is based on the assumption of the magnitude of equipment drift in the setpoint analysis.
i SR 3.3.4.1.4 .
The LOGIC SYSTEM FUNCTIONAL TEST demonstrates the l OPERABILITY of the required actuation logic for a specific channel. The system functional testing performed.in LC0 3.8.1 and LCO. 3.8.2 overlaps this Surveillance to provide complete testing of. the assumed safety functions.
s The 18 month Frequency is based on the need to perform this Surveillance und.er the conditions that apply during a plant outage and the potential for an unplanned transient if the Surveillance were performed-with the reactor at power.
Operating experience has shown these components usually pass the Surveillance when performed at'the 18 month Frequency.
~
REFERENCES 1. USAR, Section 8.3.1.1.2. ,
~
- 2. USAR, Section 5.2.2.
- 3. USAR, Section 6.3.3. - - - -
- 4. USAR, Chapter 15. (5. 2[ w CAlcgIden-Il 4
B 3.3-229 Revision No. 1-1 CLINTON
- o Attachment 5 to U-602657, LS-94-013
- Page 13 of 14 j
. AC Sources-Operating i B 3.8.1 BASES (continued)
SURVEILLANCE -The AC sou'rces are designed to permit inspection and I REQUIREMENTS testing of all important areas and features, especially those.that have a standby function, in accordance with .
10 CFR 50, GDC 18. (Ref. 8). Periodic component tests are supplemented'by extensive functional tests during refueling outages under simulated accident conditions. The SRs for demonstrating the OPERABILITY of the DGs are in accordance with the recommendations of Regulatory Guide 1.9 (Ref. 3),
- Regulatory Guide 1.108 (Ref. 9), and Regulatory Guide 1.137 (Ref. 10).
Where the SRs discussed herein specify voltage and frequency-tolerances. .the minimum and maximum steady state output oltages of"9MC V and 4580 V respectively, are equal to 10% of the nominal 4160 V output voltage. The specified minimum and maximum frequencies of the DG is 58.8 Hz and 7N *aA + 61.2 Hz, respectively, are equal to i 2% of the 60 Hz r- nominal frequency. The' specified steady state voltage and frequency ranges are derived from t c andations civen in _ Regulatory _Gu'ide 1.9 (Ref.' 3). NowevtffAe m/Almum T Wigr
- - t*Was gc.rease.4 to e.asiAP4 #dA$4&kt Vehjt. h ).
- 88 sa --ety.relatea /..As de/n9 a DB A (A 9 ty-3.8.1.1 - - - -
v _
This'SR ensures ' proper circuit continuity for the offsite AC electrical power supply to the onsite distribution network and availability of offsite AC electrical power. The. breaker alignment verifies that each breaker is in its correct position to e.nsure that distribution buses and loads are connected to their preferred power source and that a>propriate independence of offsite circuits is maintained.
Tie 7 day Frequency is adequate since breaker position is not likely to change without the operator being aware of it ,
and because its. status .is displayed in the control room. j i
SR 3.8~.1.2 and SR 3.8.1.7 These SRs help to ensure the availability of the standby electrical power supply to mitigate DBAs and transients and
, maintain the unit in'a safe shutdown condition.
(continued)
)
CLINTON B 3.8-13 Revision No. 0
- .-. - .. -- . .~ . . . .
[ Page 14 of 14 7
AC Sources--Operating
! B 3.8.1
~~'
BASES ,
SURVEILLANCE Diesel Generator Test Schedule (conti.nued)
REQUIREMENTS A test interval in excess of 7 days (or 31 days, as appropriate) constitutes a failure to meet SRs and results in the associated DG being declared inoperable. It does not, however,-constitute a valid test or failure of the DG, and any consecutive test count is not reset.
REF'ERENCES .. 1. 10 CFR 50, Appendix A, GDC 17.
- 2. USAR, Chapter 8. j
- 3. Regtglatory Guide 1.9.
- 4. USAR, Chapter 6.
- 5. USAR, Chapter 15.
- 6. ' Regulatory Guide 1.93.
I
- 7. Generic Letter 84-15, July 2,1984. ]
- 10. Regulatory Guide 1.137. .
- 11. ANSI C84.1, 1982.
- 12. NUMARC 87-00, Revision 1, August 1991.'
IEEE Standard 308.gy, fh(dlab'on li'AN-II
- 13. l
~
CLINTON B 3.8-32 Revision No. O
1 Attachment 4 to U-602657 LS-94-013 Page1of50 1
i l
I l
1 IP Calculation 19-AN-19 (Revision 2, Volume E) i i
l l
1
. _ _ _