Text

LO-0520-70261 NuScale Power, LLC 1100 NE Circle Blvd., Suite 200 Corvallis, Oregon 97330 Office 541.360-0500 Fax 541.207.3928 www.nuscalepower.com May 28, 2020 Docket No.52-048 U.S. Nuclear Regulatory Commission ATTN: Document Control Desk One White Flint North 11555 Rockville Pike Rockville, MD 20852-2738

SUBJECT:

NuScale Power, LLC Summary of Impacts to eRAI 8930 Response and Discussion on the Exemption from General Design Criterion 33

REFERENCES:

1. Nuclear Regulatory Commission, Request for Additional Information No. 484 (eRAI No. 8930), dated May 29, 2018 (ML18149A640) 2.

NuScale Response to NRC Request for Additional Information No.

484 (eRAI 8930), dated September 14, 2018 (ML18257A308) 3.

NuScale Supplemental Response to NRC Request for Additional Information No. 484 (eRAI 8930), dated July 18, 2019 (ML19199A117) 4.

NuScale Supplemental Response to NRC Request for Additional Information No. 484 (eRAI 8930), dated November 27, 2019 (ML19332A120) 5.

Letter from NuScale Power, LLC to Nuclear Regulatory Commission, Submittal of Second Updates to NuScale Power, LLC Standard Plant Design Certification Application, Revision 4, dated May 20, 2020 (ML20141L787)

During public teleconferences on April 1 and April 14, 2020 with NRC staff, including reviewers from Reactor Systems Branch, NuScale Power, LLC (NuScale) discussed potential updates to the actuation of the emergency core cooling system described in the Final Safety Analysis Report (FSAR). As a result of these discussions, NuScale provided changes to the FSAR in Reference 5. to this letter provides a summary on the impacts of this update to NuScales previous response to eRAI 8930 (Reference 4) due to the design changes discussed in Reference 5. to this letter provides a discussion of analyses performed to support the exemption requested from General Design Criterion 33 in Part 7 of the NuScale Design Certification Application, for events which led to the design changes provided in Reference 5.

While the discussion in Attachment 2 shows that NuScale was able to demonstrate the events addressed were acceptable using deterministic assumptions and methods, NuScale would like to recognize that an opportunity was lost to take a risk-informed approach in lieu of performing these analyses. Specifically, as summarized in Attachment 2, implementation of

LO-0520-70261 Page 2 of 2 05/28/2020 NuScale Power, LLC 1100 NE Circle Blvd., Suite 200 Corvallis, Oregon 97330 Office 541.360-0500 Fax 541.207.3928 www.nuscalepower.com Commission direction in Staff Requirements - SECY-19-0036 - Application of the Single Failure Criterion to NuScale Power LLCs Inadvertent Actuation Block Valves, dated July 2, 2019 would seem to have resolved this issue. Although the opportunity to apply the Staff Requirement Memorandum (SRM) was missed in this case, we look forward to continue working with the NRC Staff to implement the Commissions SRM in the most effective manner for the scope and content of this application, and future NRC staff reviews.

This letter makes no regulatory commitments or revisions to any existing regulatory commitments.

If you have any questions, please feel free to contact Matthew Presson at 541-452-7531 or at mpresson@nuscalepower.com.

Sincerely, Zackary W. Rad Director, Regulatory Affairs NuScale Power, LLC Distribution: Gregory Cranston, NRC Prosanta Chowdhury, NRC Michael Dudek, NRC Michael Snodderly, NRC Christiana Liu, NRC Christopher Brown, NRC Marieliz Johnson, NRC Bruce Bavol, NRC : ECCS Setpoint and Riser Design Change Impact on NuScales Response to eRAI 8930 : Review of the NuScale Design Certification Application Exemption Request from General Design Criterion 33 (GDC 33) y, Zackary W. Rad Director Regulatory Affairs

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NuScale Nonproprietary ECCSSetpointandRiserDesignChangeImpactonNuScalesResponsetoeRAI8930



TheRAI8930supplement2responsesubmittedinNuScaleletterRAIO111968093anddated

November27,2019(ML19332A120)completelyreplacedtheprevioussupplementalresponseandthe

originalresponsesubmittedinRAIO071966323,datedJuly17,2019(ML19199A117),andRAIO0918 61810,datedSeptember15,2018(ML18257A308),respectively.TheRAI8930supplement2responseis

notimpactedbytheemergencycorecoolingsystem(ECCS)setpointchangesortheriserdesignchange

toaddflowholesasdiscussedbelow.

TheRAI8930responseevaluatedtheborondistributionintheNuScalePowerModule(NPM),with

focusonborontransportafterECCSactuation,andconcludedthattheboronconcentrationinthecore

remainedabovetheinitialconcentrationfor72hoursaftereventinitiation.Threeeventswere

evaluated:RCCW(ReactorCoreCoolingWater)linebreak,RRV(ReactorRecirculationValve)inadvertent

opening,andanRVV(ReactorVentValve)inadvertentopening.TheRRVinadvertentopeningeventwas

foundtobelimitingforborondistributionanalysis.

Alongtermcoolingtechnicalreport(LTC)(TR091651299)assessmentcomparedanRVVsteamspace

break(fivepercentandfull),aninjectionlineliquidbreak(fivepercentandfull),anddecayheatremoval

system(DHRS)cooldowneventsprogressionswithandwithouttheECCSsetpointchangesandriser

holeaddition.ThefullinjectionlineliquidbreakbehavessimilarlytotheRRVinadvertentopeningevent.

Thelowreactorcoolantsystem(RCS)pressureECCSsignalwasfoundtohavenoimpactonLTCanalyses

sincealllossofcoolantaccident(LOCA)casesassumelossofDCpower,sothatECCSactuationoccursas

soonastheinadvertentactuationblock(IAB)releasesetpointisreached.Inaddition,thesignalis

designedtopreventactuationduringnonLOCAevents.LoweringtheECCSactuationsetpointon

containmentvessel(CNV)levelhasnoimpactforsimilarreasoning,andthereforethechangestothe

ECCSsetpointshavenoimpactontheLTCanalyses.Forthelimitingborondilutionanalysispresentedin

responsetoRAI8930,likewise,theECCSsetpointchangeswillhavenoimpact,sinceallECCSvalvesare

openverysoonaftereventinitiationataboutthesametimeasseeninthefullinjectionlineliquidbreak

intheassessment.

Asshownintheassessment,theriserholesdonotsignificantlyimpactthelongtermmodulecooldown.

ForLOCAevents,theriserholeswillbeuncoveredafterECCSactuationandhavenoimpactlongterm.

Forsmallbreaks,asmalldifferenceinRCSdepressurizationratescanimpactthetimingofECCS

actuationonIABreleasepressure,butlongtermconditionstrendtowardthesamevalueregardlessof

differencesintiming.Forthefivepercenthighpointventlinebreak,coreinlettemperatureandRCS

pressuremergedatsevenhours,andtherewasnodeviationintheseparametersforthefullbreak.For

theinjectionlinebreak,boththefivepercentandfullbreaksexhibitedessentiallynodifferenceincore

inlettemperatureandRCSpressure.

TheRAI8930responseevaluated:

1. borontransportbetweentheCNV,downcomer,andcore;

2. boronvolatilityinthesteamgeneratedinthecoreandriser;

3. boronlossmechanisms;

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NuScale Nonproprietary

4. coreandriserboronmixing;

5. criticalheatinglength;and

6. reactivitybalanceinthecore Anevaluationfortheborondistributionwasalsoperformedforanextendedperiodoftimeoutto7

days,withmorerealisticassumptionsforthelimitingRRVinadvertentopeningevent,andisdiscussedin

theRAI8930supplementalresponse.

PriortoECCSactuation,theriserholeshavenegligibleimpactontheRCSthermalhydraulicresponse,

andprovideabenefittotheborontransportbehaviorforsmallerbreaksbeforeECCSactuation.TheLTC

assessmentshowednegligiblechangesintheRCSthermalhydraulicresponseand,byextension,

negligiblechangesintheborontransportbehaviorfollowingECCSactuation.Theremaybelocalflow

distributionchangesduetotheadditionoftheriserholes,howevertheimpactislimitedgiventheholes

arerelativelysmall,andonlyimpacttheliquidflowforashortperiodoftimeintheinitialtransient

phase.

Itisconcludedthatcoreandrisermixingassumptionsarenotadverselyimpactedbytheadditionof

riserholesduetominimalchangesintheRCSthermalhydraulicresponseandtheholesareuncovered

followingECCSactuation.Additionally,itisconcludedthatthecoreinletconditionsarenotimpacted

suchthatthecriticalboilinglengthcalculation,demonstratingthattheconservatismofthereturnto

poweranalysis,isnotadverselyaffected.

Volatilityandboronlossmechanismsarelikewisenotnegativelyimpactedduetotheminimalchanges

intheRCSthermalhydraulicresponse.Volatilityismainlydependentonthecoreandriserboron

concentrationandthermalhydraulicconditions.Asvolatilityisarelativelysmallerboronlossterm,and

themostsignificantlossterm(boronintheCNVliquidbelowtheRRVelevation)isnotdependentonthe

designchanges,boronlossmechanismsarenotsignificantlyimpacted.

Fortheextended7dayevaluation,thethermalhydraulicconditionsbeyond72hoursarequasisteady stateandcoreheatremovalisperformedbyECCS.TheRCSthermalhydraulicresponseintheLTC

evaluationshowedthattheeventsevaluatedwithandwithouttheriserholesproducedidenticalresults

beyondaboutsevenhoursaftereventinitiation.Thiscomparisoncanbeextendedtotheendofthe

7dayperiodduetotheRCSquasisteadystateconditions.Therefore,theconclusionsofthe7day

analysisdiscussedinthelastsupplementtotheRAI8930responseisstillapplicable.

Inconclusion,thepriordiscussiondemonstratesthattheECCSsetpointchangesandtheriserhole

additionhaveminimalimpactontheRAI8930response.Inaddition,itisnotedthatnocredithasbeen

givenfortheriserholeadditionintheRAI8930transientcasestomitigatetheadverseimpactsofboron

redistributionpriortoriserholeuncovery.





LO-0520-70261 Page 1 of 8



NuScale Nonproprietary ReviewoftheNuScaleDesignCertificationApplicationExemptionRequestfromGeneralDesign

Criterion33(GDC33)



AspartoftheNuScaleDesignCertificationApplication(DCA),anexemptionwasrequestedfromGDC33

anddescribedinDCAPart7.TheFinalSafetyAnalysisReport(FSAR)providesanalysesthat

conservativelydemonstratethattheautomaticemergencycorecoolingsystem(ECCS)functionsensure

thatspecifiedacceptablefueldesignlimit(SAFDL)violationswillnotoccurforeventsresultingindesign

basiseventleakage,i.e.,thatfallwithinthedefinedscopeofapplicabilityandcriteriain10CFR50.46.

Additionally,NuScalehasperformedanalysesthatdemonstrateautomaticECCSfunctions(safety relatedactuationsorinherentdesignfeatures)willensurenoSAFDLviolationswilloccurforleakrates

belowthatscopewithassumedinitialconditionsbeyondthoseexpectedorlikelytooccurduringnormal

operations.Theseconditionsconservativelyoverlaypotentialnormaloperationalcoolantleaks

describedinthetechnicalspecificationlimits.

Coolantlossandeffectsduringnormaloperationarerequiredtobeidentifiedandrespondedtoby

operatoractionsspecifiedintheplantoperatinglicenseastechnicalspecificationrequirements.These

actionsarerequiredtobetakenandsubjecttocontrolatthesamelevelasotherlimitsestablishedin

theplanttechnicalspecifications.



ReviewofAnalyses

Thefollowingdescriptionssummarizetheanalysesprovidedfortheconsiderationofboron

redistributionandpotentialforcoredilution.



NonLossofCoolantAccident(NonLOCA)Transients

NonLOCAtransientswereevaluated,includingaspectrumofprimaryandsecondaryinventory

conditions(reflecting,forexample,achemicalandvolumecontrolsystem(CVCS)breakoutside

containment,orincreaseinfeedwaterflowtransients).Resultsshowedacceptableborondistribution

resultsthatprecludecoredilutionconcernsbyensuringthedowncomerconcentrationsremain

conservativelyabovecriticalboronconcentration(CBC),accountingforuncertainties,foruptoa7day

period.



LossofCoolantAccident(LOCA)Transients

LOCAtransientswereanalyzedforthefullLOCAspectrum,asdefinedbyCVCSmakeupcapacity,to

demonstratesufficientlyearlyECCSactuationpriortoanysignificantdowncomerdilutionoccurring.Due

totherapidnatureofECCSactuationandlowCBCsatthetimeofECCSactuation,thesescenariosare

wellboundedbyextendeddecayheatremovalsystem(DHRS)operatingscenarios.



ReactorCoolantSystem(RCS)Leakage

RCSleakratefromarangeofapproximately6gpmupto40gpmwasalsoevaluatedinsupportofthe

NuScaleGDC33exemptionrequest.TheanalysisconcludesthatearlyECCSactuationonlowRCS

LO-0520-70261 Page 2 of 8



NuScale Nonproprietary pressurecanbeexpectedforallleakage,exceptinthecaseofverycoldinitialpooltemperature

conditions.ForthesecoldinitialpooltemperaturecasesitisexpectedthattheRCSpressurewilldrop

sufficientlyfortheECCSvalvestoopenthemselvespassivelywithinapproximately20hours.IfthisECCS

valvefunctionisignoredbyanalysis,therisermixturelevelisconservativelycalculatedtoprovide

sufficientflowthroughtheriserholestomaintainthedowncomerconcentrationabovethecritical

boronconcentrationforaperiodof24hours.At24hours,ECCSwouldbeactuatedforlossofACpower

scenarios.IfACpowerisavailable,avalidECCSactuationsignalwouldnotbeexpectedwithina72hour

periodduetothelackofcontainment(CNV)levelaccumulation.



Whileitisnotdeterministicallyconsidered,ifthepossibilityofECCSactuationwereassumedatany

pointafter24hoursandbefore72hours,thereisapossibilitythattherisermixturelevelcoulddrop

belowtheriserholeswhichcouldgenerateaborongradientbetweenthecoreanddowncomer.The

analysisforthecoreconcentrationwhenECCSisactuatedat24hoursindicatesthatalaterECCS

actuationwouldnotgenerateacoredilutionconcernevenifthedowncomerisdiluted.Thisisbecause

duringtheECCStransient,thereisanetmassflowoutofthecoreduetotheincreasedmixturelevel

duringthedepressurizationperiod.Eventually,pressuresandfluidlevelsstabilize,atwhichpointdiluted

coolantfromtheCNVentersthedowncomerthroughtheRRVs,whichisaconditionthatwasanalyzed

indetailinthefinalsupplementalresponsetoRAI8930(ML19332A120).



Fromariskperspective,RCSleakageevents,inwhichoperatorshypotheticallyfailtooperatetheplant

withinTechnicalSpecificationsthattransitionsafelytoECCS,areattributedafrequencyof6E7peryear

andwouldnotresultinacoredamage.Thelikelihoodofacommoncausefailureofall5ECCSvalvesto

passivelyopenonlowdifferentialpressureissignificantlylesslikely(5E12permodulecriticalyear)and

alsowouldnotresultinacoredamageevent.ThemoreprobablescenarioofasubsetoftheECCSvalves

notopeningcorrectlyisalreadycapturedintheprobabilisticriskassessment(PRA)asanincomplete

ECCSactuationwithafrequencyofapproximately7E12peryearandresultsinsubsequentcore

damage,asRCSmakeupwouldalsobenominallyavailable,butisassumedtofailinthisscenario.

Becausetheeventsofinterestincludeanisolatedcontainment,thereisnolargereleasefrequencyand

thusnosignificantradiologicalconsequences.Thisprovidesadditionalsupporttoconcludethatthe

eventspostulatedabovearenotrisksignificant.





RequirementforActionbythePlantOperatingStaff

TechnicalspecificationsareincorporatedintotheoperatinglicenseofnuclearpowerplantsasAppendix

A.Theydescriberequirementsthatmeetthecriteriain10CFR50.36thathelpensuretheplantwillbe

operatedinaccordancewiththesafetyanalysesthatprotectthehealthandsafetyofthepublic.

Thetechnicalspecificationsincluderequirementsregardingtheuseandapplicationoftherequirements

specifiedwithinthem.ThesearespecifiedinChapter1,UseandApplication,withadditional

requirementsforimplementingLimitingConditionsforOperationspecifiedinSectionLCO3.0,Limiting

ConditionforOperation(LCO)Applicability,andSR3.0,SurveillanceRequirements(SR)Applicability.

LO-0520-70261 Page 3 of 8



NuScale Nonproprietary Theformerapplytoallsectionsofthespecificationsanddefinetermsusedthroughoutthedocument

(andpresentedinALLCAPS),aswellasthemeaningofformattingelementsusedinthedocument.The

latter,sections3.0specifyrequirementsandrulesappliedtoactionsandsurveillancerequirements.For

example,LCO3.0.1statesthatLCOsshallbemetduringMODESorotherspecifiedconditions,and

LCO3.0.2states[u]pondiscoveryofafailuretomeetanLCO,theRequiredActionsoftheassociated

Conditionsshallbemet.1

Controlsandrequirementsarealsoprovidedbythesurveillancetestingrequiredbythetechnical

specifications.TheapplicabilityrulesinSR3.0providerequirementsforperformanceoftestingand

actionstobetakenifafailuretomeetasurveillanceoccurs.Specifically,SR3.0.1states

FailuretomeetaSurveillance,whethersuchfailureisexperiencedduringtheperformanceofthe

SurveillanceorbetweenperformancesoftheSurveillance,shallbeafailuretomeettheLCO.

FailuretoperformaSurveillancewithinthespecifiedFrequencyshallbefailuretomeettheLCO

Ifsuchafailureoccurs,therequirementsofLCO3.0.2apply.

Technicalspecification5.2specifiestherequiredstafffortheplant,includingthemanagerresponsible

foroverallsafeoperationoftheplant,andthefacilitystaffrequiredtobeatthefacilitytoimplement

therequirementsoftheoperatinglicense,includingthetechnicalspecifications.

Plantoperationsarerequiredtobeconductedinaccordancewithwrittenproceduresasspecifiedin

technicalspecification5.4,Procedures.

Insummary,theCommissionhasissuedregulationsdescribingtherequiredcontentofthose

specificationsas10CFR50.36and10CFR50.36a.Thestaffandindustryhavedevelopedguidanceand

expectationsregardingtheformatanduseofthetechnicalspecifications.NuScalehasproposed

technicalspecificationsinconformancewiththeserequirementsandguidancedocuments.Andthe

technicalspecificationsincluderequirementsfortheplanttobeoperatedbyqualifiedstaffin

accordancewithwrittenproceduresthatwillrequireLCOstobemet,orupondiscoveryofafailureto

meetanLCOthespecifiedRequiredActionsmustbetaken.

Theserequirementsarethespecificbasisfortheoperatinglicenserequirementthattheoperatingstaff

takeactioninaccordancewithwrittenproceduresifanLCOorSRisnotmet.



RCSLeakageLimitsandRequiredActions

TechnicalspecificationsrequirethatRCSOperationalLEAKAGEbelimitedtolessthanthevalueslistedin

LCO3.4.5.AsnotedintheBasesforLCO3.4.5,





1 The LCO 3.0 and SR 3.0 sections include exceptions and allowances that address other, special, and limited circumstances that occur during implementation of the requirements. They have evolved over decades of use, however the discussion provided is the fundamental requirements of the subsections quoted. For additional details see the NuScale, or generic technical specifications (NUREG-1431, etc.)

LCO 3.0 and SR 3.0 sections and associated bases.

LO-0520-70261 Page 4 of 8



NuScale Nonproprietary ExceptforprimarytosecondaryLEAKAGE,thesafetyanalysesdonotaddressRCSOperational

LEAKAGE.However,otherformsofRCSOperationalLEAKAGEarerelatedtothesafetyanalyses

forLOCA.TheamountofLEAKAGEcanaffecttheprobabilityofsuchanevent.

LCO3.4.5includeslimitsonpressureboundary,unidentified,identifiedRCS,andprimarytosecondary

LEAKAGE.Theselimitsarestructuredsimilartothoseinlargepressurizedwaterreactors,howeverthe

NuScaledesignmakesidentificationofleakagechallengingandinmostconditionsthe0.5gpm

unidentifiedLEAKAGEmaximumislikelytobethelimitappliedduringtheconditionsofapplicability.

IftheidentifiedRCSorunidentifiedLEAKAGElimitsareexceeded,ConditionAofLCO3.4.5willapply

andtheRequiredActionisthattheLEAKAGEmustberestoredtowithinlimitswithin4hours,as

requiredbyLCO3.0.2.

IftheLEAKAGEcannotberestoredtowithinlimitswithinfourhours,orpressureboundaryorprimary tosecondaryLEAKAGElimitsarenotmet,thenConditionBmustbeenteredasrequiredbyLCO3.0.2.

RequiredActionsB.1andB.2requiretheoperatorstotakeactioninaccordancewithLCO3.0.2forthe

planttobeinMODE2(subcritical)within6hoursandtobeinMODE3withtheRCShottemperature

below200ºFwithin48hours.

TheseactionsarerequiredbyLCO3.0.2,anddesignedtoverifyleakageratesandeitheridentify

unidentifiedLEAKAGEorreduceRCSOperationalLEAKAGEtowithinlimitsbeforethereactormustbe

shutdown.ThecompletiontimesforConditionBaredesignedtoprovideareasonableopportunityto

reachtherequiredunitconditionsfromfullpowerconditionsinanorderlymanner.



RCSLeakageInstrumentationRequirements

GDC30ofAppendixAto10CFR50requiresmeansfordetectingand,totheextentpractical,identifying

thesourceofRCSLEAKAGE.RegulatoryGuide1.45describesacceptablemethodsforselectingLEAKAGE

detectionsystems.

LEAKAGEdetectionsystemsmusthavethecapabilitytodetectsignificantreactorcoolantpressure

boundarydegradationassoonafteroccurrenceaspracticaltominimizethepotentialforpropagationto

agrossfailure.Thus,anearlyindicationorwarningsignalisnecessarytopermitproperevaluationofall

unidentifiedLEAKAGE.AsnotedintheBasesofLCO3.4.5RCSLEAKAGEisrelatedtothesafetyanalyses

forLOCA.TheamountofLEAKAGEcanaffecttheprobabilityofsuchanevent.

TheNuScaledesignincludesthreedistinctmethodsfordetectionandmonitoringofRCSleakageas

describedinFSARsection5.2.5.1.

x ContainmentEvacuationSystem(CES)CollectedCondensate

x ContainmentPressure

x RadioactivityMonitoring

AllthreemethodsutilizefeaturesoftheCESthatisusedtomaintainthecontainmentvesselatavery

lowpressureduringoperations.



LO-0520-70261 Page 5 of 8



NuScale Nonproprietary AllthreemethodsarerequiredtobeOPERABLEasspecifiedinLCO3.4.7,RCSLeakageDetection

Instrumentation.TheLCOprescribestherequirementsthateachoftheinstrumentationmethodsbe

availablewhenthereactorcoolantsystem(RCS)isabove200ºF,withtheECCSvalvesclosedandthe

containmentnotflooded.

Thefirsttwoofthethreemethodsdescribedaboveincludetwochannelseachofinstrumentationused

tomeasuretherelevantparameters,i.e.,therearetwochannelsformeasuringcondensatecollection,

andtwochannelsformeasuringcontainmentpressure.Onechannelofradioactivitymonitoringis

availableinadditiontotheothertwomethods.Eachofthemethodsandchannelsaresubjectedto

CHANNELCHECKS,CHANNELOPERATIONALTESTS,andCALIBRATIONSinaccordancewiththe

surveillancerequirementsinLCO3.4.7.

PlantproceduresdescribedinFSARchapter13,andrequiredbytechnicalspecification5.4,willdescribe

themeansandmethodstheoperatingstaffwillusetodetectandrespondtoleakagefromtheRCS.

Thesewillincludealarms,indications,andsurveillancetestingresults.Eachofthethreemethods

provideindicationtotheplantoperatorsoftheplantcompliancewiththespecifiedlimits.Detailed

descriptionsofthefunctions,instrumentation,capability,andrequiredconditionstoensure

OPERABILITYaredescribedinFSAR5.2.5.1.

LCO3.4.7includesRequiredActionsthatmustbetakeniftheLCOcannotbemetinaccordancewith

LCO3.0.1andLCO3.0.2.TheConditionsaremorecomplexthantypicalPWRspecificationsbecauseof

thedesignoftheNuScaleleakagedetectioninstrumentation.

InaccordancewiththerequirementsofLCO3.0.2,ifonlyonechannelofthefirsttworequiredmethods

isinoperable,operationsareallowedtocontinueforupto14daysifasurveillancerequirementofthe

RCSleakageLCOisperformedevery24hours.ThisisacceptablebecausethreemethodsofRCSleakage

remainOPERABLE,albeitwithasinglechannelOPERABLEfortheaffectedmethod.Therequired

surveillanceperformsanRCSwaterinventorybalanceprovidingfurtherassuranceofleakagedetection

withaninoperablechannel.

Ifbothchannelsofamethodwithtwochannels,orthesinglechannelradioactivitymonitormethod,are

inoperablethenatleastonechannelmustberestoredforfunctionswithtwochannels,orthe

radioactivitymonitormustberestoredtoOPERABLEwithin72hours,asrequiredbyLCO3.0.2.Ifthe

inoperablefunctionisnotrestored,thenConditionCisrequiredtobeimplementedandtheplantmust

beplacedinMODE2(subcritical)within6hours,andbeinMODE3withtheRCShottemperaturebelow

200ºFwithin48hours.Thecompletiontimesaredesignedtoprovideareasonableopportunitytoreach

therequiredunitconditionsfromfullpowerconditionsinanorderlymanner.



OperationalImplementationofLeakageRequirements

TheoperationsstaffinthecontrolroomareprovidedwithextensivecapabilitytomonitortheRCS

leakageandassuretherequirementsofLCO3.4.5and3.4.7aremet.Technicalspecification5.2requires

minimumstaffingintheplantcontrolroom.



LO-0520-70261 Page 6 of 8



NuScale Nonproprietary Plantproceduresrequiredbytechnicalspecification5.4willensurethatappropriateoperational

awarenessoftheplantconditionsismaintainedbytherequiredoperators.

x COLItem13.51requiresaCOLapplicanttodescribethesitespecificproceduresthatprovide

administrativecontrolforactivitiesthatareimportantforthesafeoperationofthefacility

consistentwiththeguidanceprovidedinRegulatoryGuide1.33,Revision3.

x COLItem13.52requiresaCOLapplicanttodescribethesitespecificproceduresthatoperators

useinthemaincontrolroomandlocallyintheplant,includingnormaloperatingprocedures,

abnormaloperatingprocedures,andemergencyoperatingprocedures.

x COLItem13.53requiresaCOLapplicanttodescribethesitespecificmaintenanceand

operatingprocedures,includingcalibrationandtestprocedures,andmaintenanceprocedures.

TheseCOLitemsandtheprogramsandproceduresrequiredtobepreparedbyaCOLapplicantwill

ensuretheoperatingstaffinthecontrolroommaintainscontinuousawarenessoftheplantstatus.The

designofthesystemsensurethatoperatorsarenotifiedifparametersaretrendingtowardorexceed

limits,andresponseproceduresthatimplementthetechnicalspecificationrequirementswillensure

operatorstakeaction.

TheavailableleakagemonitoringcapabilitiesaredescribedindetailinFSAR5.2.5.1andinclude:

CondensateCollection

x Collectionvessellevelinstrumentationincludesquantificationandtrendingofleakratechanges.

x Indicationandalarminthecontrolroomtomonitorandtrendliquidleakageintothe

containmentatmosphere.

x Controlroomalarmbeforereachingthemaximumallowablepressuretemperaturetoensure

methodfunctionality.

x CapabilitytodetectanRCSleakrateoflessthan1gpmwithinonehour.

x Minimumdetectableleakrateoflessthan0.05gpm.

ContainmentPressure

x Theinlettothecontainmentevacuationsystemincludespressuresensorsthatmonitors

containmentpressure.

x Controlroomindicationofpressureandcapabilitytoalarmandtrendchangesinpressure.

x Controlroomalarmbeforereachingthemaximumallowablepressuretemperaturetoensure

methodfunctionality.

x Capableofdetectinganincreaseof0.1psiinlessthanoneminuteofa1gpmleakfromtheRCS.

x CapableofdetectingaminimumleakratefromtheRCSof0.007gpm.

RadioactivityMonitor

x Monitorsbothgaseousandliquideffluentremovedfromthecontainmentatmosphere.

x Capabilitytoevaluateisotopicmakeup(includingtracergasesifused)toidentifyleakagesource.

x Indication,alarm,andcapabilitytotrendradioactivitylevelsinthecontrolroom.

TheNuScaledesignisinherentlymoresensitivetodetectingRCSleakagethanotherdesigns.The

containmentvesselisoperatedatanactivelymaintainedlowpressurethatminimizesthepresenceof

LO-0520-70261 Page 7 of 8



NuScale Nonproprietary anygasorliquid.Thissensitivitymakesanychangecausedbypostulatedleakagemoreapparentand

readilyquantifiablethanpreviousdesigns.

Additionally,theOPERABILITYoftwoleakdetectionfunctionsthatdependonthecontainment

evacuationsystemrequiresthatthepressureinthecontainmentbemaintainedbelowthesaturation

pressureofthesurroundingpoolwaterasdescribedinFSARsection5.2.5.1.Thispressureisalarmed

andcanbecontinuouslymonitoredinthecontrolroomifthepressureapproachesthatwhichwould

renderthedetectionfunctionsinoperable.AsshowninFSARFigure5.23,thenominalUHSpool

temperatureof100ºFwillresultinanalarmbeforethecontainmentpressureapproachesabout

0.8psia.

IntheNuScaledesignthecontainmentpressure,i.e.,vacuum,becomesakeyoperatingparameterbeing

maintainedandmonitoredbytheplantstaffusingthecontainmentevacuationsystemdescribedin

FSARsection9.3.6.2.1.WhileexistinglargePWRsmonitorcontainmentpressureandincorporatealarms

andactuations,thelargevolumeofthosecontainmentstructurestypicallyresultinslowerpressure

variationsandnosensitivitytoliquidleaksintothecontainmentvolume.

Basedontheabove,theNuScaledesignensuresthatanyleakageintothecontainmentwillberapidly

detected,evaluated,andacteduponinaccordancewiththerequirementsofthetechnicalspecifications

limitsandactionsrequiredtobeimplementedbytheunitoperatinglicense.



RiskInformedSummary



AlthoughinthiscaseNuScaleisabletodemonstratetheeventsaddressedinthisattachmentwere

acceptableusingChapter15assumptionsandmethods,anopportunitywaslosttotakeariskinformed

approachinlieuoftheseanalyses,whichwouldhaveresultedinlesstimeandcost,whilestillproviding

reasonableassuranceofadequateprotectionofpublichealthandsafety.Specifically,assummarized

below,implementationofCommissiondirectioninStaffRequirementsSECY190036-Applicationof

theSingleFailureCriteriontoNuScalePowerLLCsInadvertentActuationBlockValves,datedJuly2,

2019wouldseemtohaveresolvedthisissue.Inthatstaffrequirementsmemorandum(SRM),the

Commissionrequiredthat,theStaffshouldapplyriskinformedprincipleswhenstrict,prescriptive

applicationofdeterministiccriteriaisunnecessarytoprovideforreasonableassuranceofadequate

protectionofpublichealthandsafety.



Thestrict,prescriptiveapplicationofdeterministiccriteriaimposedinthiscasewerethat,forthe

durationoftheanalyses:

x ACandDCpowerwereassumedavailable,and

x Operatorswereassumedtonottakeanyactions,includingthoserequiredbytheoperating

licenseviatechnicalspecifications.



UndertheseassumptionsandusingChapter15methods,ECCSactuationwouldbeindefinitelydelayed

forverysmall(612gpm)reactorcoolantsystemleaks.Thus,Staffquestionedwhetherthishypothetical

scenariowouldleadtoananalyzedplantconditionoutsidetheNuScalelicensingbasis.Becauseitis

LO-0520-70261 Page 8 of 8



NuScale Nonproprietary plausiblethattheNuScaleplantmaybelesssafewithelectricpoweravailableincertainrare

circumstances,performinganalysisassumingelectricpowerisavailableisnormallyanappropriate

approachforChapter15.However,couplingthatassumptionwithanassumptionthatoperatorsviolate

technicalspecificationrequiredactions(whichinallcaseswouldhavemitigatedtheeventswithin10

hours)wasunnecessaryinthiscase.



TheNuScaleplantisdesignedtoremainsafeindefinitely,withacompletelossofallACandDCpower,a

situationthatiscatastrophicformostdesignswhetheranalyzedunderChapter15ormorerealistically

underChapter19methods.WhiletheNuScaledesignissafewithoutACandDCpower,itshouldbe

obviousthattheplantwillbeevensaferwhenACandDCpowerareavailable,regardlessofconclusions

fromChapter15.ThisisevidentfromtheProbabilisticRiskAnalysisdocumentedinthisattachmentand

inChapter19.ForthesmallRCSleaksequencepostulatedhere,theriskofcoredamageisseveralorders

ofmagnitudebelowtheNRCscoredamagefrequency(CDF)goal,andalargereleaseisprecludedbyan

intactcontainment.Therefore,applyingriskinformedprincipleswouldhaveshownthatstrict,

prescriptiveapplicationofdeterministiccriteriawasunnecessaryinthiscasetoprovideforreasonable

assuranceofadequateprotectionofpublichealthandsafety.PursuanttotheCommissionsdirectionin

SRMSECY190036,thedeterministicanalysisdescribedinthisattachmentwasunnecessary.

AlthoughtheopportunitytoapplytheSRMwasmissedinthiscase,itisanimportantlessonlearnedto

carryforwardtotheSDAapplication.Goingforward,NuScalerecommendsthatpreapplication

engagementwiththeNRConourplannedStandardDesignApproval(SDA)applicationfocuson

identifyingareaswheretheSRMmaybeimplementedtoyieldamoresafetyfocusedapplicationand

review.WelookforwardtoworkingwiththeNRCstafftoimplementtheCommissionsSRMinthemost

effectivemannerforthescopeandcontentoftheapplication,andtheNRCstaffreview.