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200 200 Exelon Way Exelon Way                                                                                       NNuclear uci ear Kennett Square, Square, PA PA 19348 19348 10 10 CFR CFR 50.90 50.90 RA-10-065 RA- 10-065 August 31, 2010 u.s.

U.S. Nuclear Regulatory Commission ATTN: Document Control Desk Washington, D.C. 20555-0001 Oyster Creek Nuclear Generating Station Renewed Facility Operating License No. DPR-16 NRC Docket No. 50-219

: 1. Letter from P. B. Cowan, Exelon Generation Company, LLC, to U.S. Nuclear Regulatory Application for Technical Specifications Change Regarding Risk-Informed Commission, "Application Justification for the Relocation of Specific Surveillance Frequency Requirements to a Licensee Controlled Program (Adoption of TSTF-425, Revision 3),"          3), dated October 30, 2009.

: 2. Electronic transmission from G. Edward Miller, U.S. Nuclear Regulatory Commission, to Glenn Stewart, Exelon Generation Company, LLC, "0            Oyster yster Creek Nuclear Generating Station     - Electronic Transmission, Draft Request for Additional Information Regarding Station - Electronic License Amendment Request to Relocate Surveillance Frequencies to a Licensee License Controlled Document Controlled                              ME2494), dated August 18, 2010.

Document (TAC No. ME2494),"

In Reference In  Reference 1,         Exelon Generation Company, LLC (Exelon) submitted a request for an 1, Exelon amendment to amendment         to the Technical Specifications (TS), Appendix A of Renewed Facility Operating License No.

License      No. DPR-16                 Creek Nuclear Generating Station (OCNGS). The proposed Oyster Creek DPR-1 6 for Oyster amendment would amendment         would modify   OCNGS TS by relocating selected Surveillance Requirement modify OCNGS frequencies to frequencies              licensee-controlled document in accordance with TSTF-425, Revision 3, to aa licensee-controlled Relocate Surveillance "Relocate                      Frequencies to Licensee Control - RITSTF [Risk-Informed Technical Surveillance Frequencies                              -

Specifications Task Specifications                      Initiative 5b,"

Force] Initiative Task Force]                    dated March 5b, dated        18, 2009. The NRC reviewed the license March 18,2009.

amendment request amendment                   and identified request and               the need identified the   need for additional information in order to complete their

Response to Draft Request for Additional Information Information LAR Regarding Relocation of Selected TS Surveillance Frequencies to a Licensee Controlled Document Docket No. 50-219 August 31, 2010 Page 2 evaluation of the amendment request. A draft request for additional additional information (RAI)

(RAI) was was electronically transmitted to Exelon on August 18,                            2). Attachment 11 to 18, 2010 (Reference 2).                 to this letter provides a restatement of the RAI along with Exelons                     Attachment 22 provides Exelon's response. Attachment       provides revised TS/Bases markups in response to the RAI.

The Surveillance Frequency is based on operating experience, equipment reliability, and liThe Program. 1I plant risk and is controlled under the Surveillance Frequency Control Program.

Also, relative to the Bases insert, Exelon proposes to replace the TSTF-425 Bases insert specified above with a revised insert that reads 'The    The Surveillance Frequency(ies) is(are) controlled under the Surveillance Frequency Control Program,1IProgram, or otherwise modify the TS Bases, as appropriate, as indicated on revised proposed TS/Bases pages provided in .

Additionally, during the review of the TSTF-425 TS Bases issue, Exelon identified two additional proposed changes to the Bases for TS Sections 4.5 and 4.9, as indicated on TS pages 4.5-15 proposed and 4.9-2, respectively, which are provided in Attachment 2 to this letter. These proposed changes are consistent with other proposed Bases changes in the original submittal (Reference

Also, the proposed notes specified on TS pages 4.1-10, 4.2-2, 4.4-2, 4.12-2, and 4.15-2 were revised for consistency with each other and with similar notes added to other TS pages included revised the TS markups.

in the in           markups. The revised proposed TS pages are provided in Attachment 2 to this letter.

should be ItIt should      noted that be noted  that the revised proposed TS/Bases pages provided in Attachment 2 to this the revised are specific letter are letter        specific to to the issues identified in this RAI response, and supersede only the the issues corresponding TS/Bases pages provided in the original submittal (Reference 1). As a result, the corresponding pages provided pages                are a subset of the total TS/Bases pages provided in the original submittal and provided are are not are        meant to not meant to be be a complete replacement set of proposed TS/Bases pages. Therefore, the

Response to Draft Request for Additional Information Information LAR Regarding Relocation of Selected TS Surveillance Frequencies to a Licensee Controlled Document Docket No. 50-219 August 31, 2010 Page 3 included in TS/Bases pages provided in the Reference 11 submittal that are not included       Attachment 22 to in Attachment     to this letter are still valid and remain part of the requested license amendment.

amendment.

Exelon has concluded that the information provided in this response does not impact the conclusions provided in the original submittal (Reference 1). 1).

st I declare under penalty of perjury that the foregoing is true and correct. Executed on the 31 st day of August 2010.

Respectfully, d~aJ1I Pamela Pamela B. Cowan Director, Licensing and Regulatory Affairs Exelon Generation Company, LLC :       Response to Draft Request for Additional Information :        Revised Proposed Technical Specifications/Bases Pages cc:     Regional Administrator - NRC Region II Regional                  -                                                  w/attachments NRC Senior Resident Inspector - OCNGS NRC Project Manager, NRR - OCNGS Director, Bureau of Nuclear Engineering, New Jersey Department of Director, Environmental Protection Mayor of Lacey Township, Forked River, New Jersey

ATTACHMENT 11 License Amendment Request Oyster Creek Nuclear Generating Station Docket No.

No.. 50-219 License Amendment Request Regarding Relocation of Selected Technical Specification Surveillance Frequencies to a Licensee Controlled Document Response to Draft Request for Additional Information

Docket No.

Docket  No. 50-219 50-219                                                                                               Attachment 11 Attachment Page 11of Page      of 11 RESPONSE TO RESPONSE           TO REQUEST REQUEST FOR     FOR ADDITIONA ADDITIONAL         INFORMATION L INFORMAT          ION LICENSE AMENDME LICENSE        AMENDMENT           REQUEST REGARDIN NT REQUEST           REGARDING           RELOCATION G RELOCATIO            N OF SELECTED OF   SELECTED TECHNICA TECHNICAL         SPECIFICATION L SPECIFICA                  SURVEILLANCE TION SURVEILLA              NCE FREQUENCIES FREQUENC          IES TO TO A A LICENSEE LICENSEE CONTROLLCONTROLLED      ED DOCUMEN DOCUMENT         T In Reference In  Reference 1, 1, Exelon Exelon Generation Generation Company, Company, LLC    LLC (Exelon)

(Exelon) submitted           request for submitted aa request           for an an amendment to amendment      to the the Technical Technical Specification Specifications     (TS), Appendix s (TS),    Appendix AA of     Renewed Facility of Renewed          Facility Operating Operating License No.

License   No. DPR-16 DPR-16 for  for Oyster Oyster Creek Creek Nuclear Nuclear Generating Generating Station        (OCNGS). The Station (OCNGS).           The proposed proposed amendment amendment      would would    modify modify    OCNGS OCNGS        TS TS  by by  relocating relocating     selected selected     Surveillance Surveillance        Requirement Requirement frequencies to frequencies    to aa licensee-cont licensee-controlled       document in rolled document            accordance with in accordance            TSTF-425, Revision with TSTF-425,          Revision 3, 3, "Relocate  Surveillance        Frequencies Relocate Surveillance Frequencies to Licensee   to  Licensee      Control Control  --  RITSTF RITSTF    [ Risk-Informe

[Risk-Informed     d  Technical Technical Specifications Specification      Task Force]

s Task     Force] Initiative Initiative 5b, 5b," dated dated March March 18,    2009. The 18,2009.       The NRC         reviewed the NRC reviewed          the license license amendment request and      and identified identified the the need need for for additional   information in additional information            order to in order        complete their to complete      their evaluation of the amendment request. A evaluation                                          A draft draft request request for for additional     information (RAI) additional information          (RAI) was was electronically transmitted to Exelon on electronically                                  on August August 18,  18, 2010   (Reference 2).

2010 (Reference        2). The      question is The question       is restated restated below below   along   with   Exelon's Exelons     response.

RAI RAI In a number of locations, the proposed wording would require that a SR [surveillance requirement] be performed in        "in accordance with the Surveillance Frequency control Program.               Program."

Provide additional justification that this wording will not allow aspects of performing the SR                          SR other other than the frequency of performance from being governed by the Surveillance Frequency Control                              Control Program. Alternately, propose revised wording that limits the control of the Surveillance Frequency Control Program to only the frequency of performing an SR.

To make it clear that the Surveillance Frequency Control Program only controls changes to the frequency       surveillances that are included in the program, the proposed wording "in frequency of surveillances                                                                                        in accordance with the Surveillance Frequency Control Program"            Program inserted in the TS and Bases markups markups has has been been replaced replaced with the wording "at        at the frequency specified in the Surveillance Frequency Frequency Control       Program as indicated the revised proposed TS/Bases pages provided in Control Program"                          in                                                                      in Attachment Attachment 2. 2.

: 1. Letter Letter from from P.P. B.

B. Cowan, Cowan, Exelon Exelon Generation         Company, LLC, Generation Company,                                Nuclear Regulatory U.S. Nuclear LLC, to U.S.

Commission,       "Application Commission, Application            for for Technical Technical      Specification Specifications   s  Change Change      Regarding Regarding        Risk-Informed Risk-Informed Justification Justification for for the the Relocation Relocation of                 Surveillance Frequency Requirementss to a Specific Surveillance of Specific                      Frequency        Requirement Licensee Licensee Controlled Controlled Program Program (Adoption (Adoption of                     Revision 3),

TSTF-425, Revision of TSTF-425,                    3),II dated October 30, 2009.

2009.

: 2. Electronic Electronic transmission transmission from  from G.               Miller, U.S.

Edward Miller, G. Edward                      Nuclear Regulatory U.S. Nuclear                         Commission, to Regulatory Commission,               to Glenn    Stewart, Glenn Stewart, Exelon Exelon    Generation Generation     Company, Company,        LLC, LLC,     Oyster "0  yster  Creek Creek     Nuclear Nuclear       Generating Generating Station Station - Electronic

                    -               Transmission, Draft Electronic Transmission,                 Request for Draft Request           Additional Information for Additional                       Regarding Information Regarding License License Amendment Amendment Request Request to     Relocate Surveillance to Relocate                                            to  a Frequencies to a Licensee Surveillance Frequencies                  Licensee Controlled Controlled Document Document (TAC  (TAC No.      ME2494), dated No. ME2494),"                 August 18, dated August           2010.

18, 2010.

ATTACHMENT 22 ATTACHMENT License Amendment Request Oyster Creek Nuclear Generating Station Docket No. 50-219 Draft Request for Additional Information License Amendment Request Regarding Relocation of Selected Technical Specification Surveillance Frequencies to a Licensee Controlled Document Specifications/Bases Pages Revised Proposed Technical Specifications/Bases 4.1-2 41-2         4.3-1       4.5-6         4.7-1       4.9-1 4.1-3         4.3-2       4.5-9         4.7-2       4.92*

4.9-2*

4.1-8         4.3-3       4.5-11         4.7-3       4.10-1 4.1-9         4.4-2       4.5-12         4.7-4       4.12-1 4.1-10         4.5-2       4.5-13         4.7-5       4.12-2 4.2-1         4.5-3       4.515*

4.5-15*        4.8-1       4.15-2 4.2-2         4.5-4       4.6-1         4.8-2       4.17-1 4.2-4 4.2-4         4.5-5

** New New proposed   Bases page proposed TS Bases

4.1       PROTECTIVE INSTRUMENTATION Bases:

Surveillance intervals are based on reliability analyses and have been determined in          in accordance accordance with General Electric Licensing Topical Reports given in References 11 through  through 5.Surveillance 5.Surveillance Frequencies are controlled under the Surveillance Frequency Control Program           Program (SFCP).

(SFCP).

: a.         On-off sensors that provide a scram function or some otherother equally equally important important function.

: b.         Analog devices coupled with aa bi-stable trip that provides aa scram function or or some some other vitally important function.

: c.         Devices which only serve a useful function during some restricted mode mode of operation, such as startup or shutdown, or for which the only practical test is is one one that can be performed only at shutdown.

Group (b) devices utilize an analog sensor followed by an amplifier and bi-stable trip circuit. The sensor and amplifier are active components and a failure would generally result in an        an upscale signal, a downscale signal, or no signal. These conditions are alarmed so aa failure would not go undetected. The bi-stable portion does need to be tested in order to prove that it will assume its tripped state when required.

Group (c) devices are active only during a given portion of the operational cycle. For example, the IRM is inactive during full-power operation and active during startup. Thus, the only test that is significant is the one performed just prior to shutdown and startup. The condenser Low Vacuum trip can only be tested during shutdown, and although it is connected into the reactor protection system, it is not required to protect the reactor. Testing at each REFUELING OUTAGEat the frequency specified in the Surveillance Frequency Control Program is QUTAGEat adequate. The switches for the high temperature main steamline tunnel are not accessible during normal operation because of their location above the main steam lines. Therefore, after initial calibration and in-place OPERABILITY checks, they will not be tested between refueling initial calibration shutdowns. Considering the physical arrangement of the piping which would allow a steam leak at any of the four sensing locations to affect the other locations, it is considered that the function is is not jeopardized by limiting calibration and testing to refueling outages.

The CHANNEL FUNCTIONAL TEST verifies instrument channel operability. A successful test of the required contact(s) of a channel relay may be performed by the verification of a change in state of a single required contact of the relay. This clarifies what is an acceptable CHANNEL FUNCTIONAL TEST or CHANNEL contact CALIBRATION of a relay. This is acceptable because all the other required contacts of the relay are verified by other Technical Specifications and non-Technical Specification tests.

instrument safety systems in Table 4.1.1 is such that testing the instrument The logic of the instrument The channels trips the trip system to verify that it is OPERABLE. The testing may be performed by channels means of means     of any series of sequential, overlapping, or total channel steps. However, certain systems require coincident require                  instrument channel trips to completely test their trip systems. Therefore, SFCP coincident instrument minimum trip system test frequency for these tripped systems. This Table 4.1.2 specifies the minimum Table that all assures that assures          all trip systems for protective instrumentation are adequately tested, from sensors trip systems through the through     the trip trip system.

system.

OYSTER CREEK OYSTER        CREEK                                          4.1-2 Amendment No.:

Amendment         No.: 171, 171, 208,  263 208, 26d

IRM calibration is to be performed during reactor startup. The calibration of the IRMs IRMs during during startup will be significant since the IRMs will be relied on for neutron monitoring andand reactor protection up to 38.4%

38.4% of rated power during a reactor startup.

To ensure that the APRMs are accurately indicating the true core average power, the APRM5     APRMs are are calibrated to the reactor power calculated from aa heat balance. Limiting Safety SystemSystem Settings Settings (LSSS) 2.3.A.1 allows the APRMs to be reading greater than actual THERMAL POWER to compensate for localized power peaking. When this adjustment is made, the requirement for the absolute difference between the APRM channels and the calculated power to indicate within 2%         2°,fo RTP is modified to include any gain adjustments required by LSSS 2.3.A.1.

LPRM gain settings are determined from the local flux profiles measured by the Traversing Incore    Incore Probe (TIP) System. This establishes the relative local flux profile for appropriate representative input to the APRM System. The 1000 MVVD/T  MWD/T Surveillance Frequency is controlled under the Surveillance Frequency Control Program is based on operating experience with         \\'ith LPRM sensitivity changes.

General Electric Licensing Topical Report NEDC-30851 NEDC-30851P-A                   1), Section 5.7 indicates P-A (Reference 1),

that the major contributor to reactor protection system unavailability is common cause failure of the automatic scram contactors. Analysis showed a weekly test interval to be optimum for Scram contactors are tested at the frequency specified in the Surveillance Frequency Control Program. The test of the automatic scram contactors can be performed as part of the CHANNEL CALIBRATION or CHANNEL FUNCTIONAL TEST of Scram Functions or by use of the subchannel test switches.

(1)                         Technical Specification Improvement Analyses NEDC-30851 P-A, "Technical System.

for BWR Reactor Protection System."

(2)     NEDC-30936P-A, "BWR       Owners Group Technical Specification BWR Owners' Improvement Methodology (With Demonstration for BWR ECCS Instrumentation), Parts 11 and 2.

(3)     NEDC-30851P-A, NEDC-30851    P-A, Supplement 1, "Technical Technical Specification Improvement Analysis   for BWR Control Rod     Block Instrumentation.

(4)     NEDC-30851P-A, NEDC-30851                          Technical Specification P-A, Supplement 2, "Technical Improvement Analysis for BWR Isolation Instrumentation Instrumentation.

Common to RPS and ECCS Instrumentation."

(5)     NEDC-31677P-A,     Technical Specification Improvement Analysis NEDC-31 677P-A, "Technical Instrumentation.

for BWR Isolation Actuation Instrumentation."

OYSTER CREEK                                         4.1-3 71,171, 208, 263, 266 AMENDMENT NO.: 71,171,208,263,266

TABLE 4.1.1 TABLE     4.1.1 Page 550f6 Page      of 6 MINIMUM CHECK, CALIBRATION AND TEST        TEST FREQUENCY FREQUENCY FOR              PROTECTIVE INSTRUMENTATION FOR PROTECTIVE         INSTRUMENTATION Instrument Channel                                                 (Note 5)

Check (Note      Calibrate (Note Calibrate     (Note 5)

: 5)    Test (Note Test (Note 5)

: 5)  Remarks     (Applies to Remarks (Applies        Test &&Calibration) to Test    Calibration)

: 32. LPRM Level a)   Electronics                                     N/A               ~

1/l2mo.                     ~

b)   Detectors                                       N/A               Note 44 Note                        N/A N/A

: 33. RWCU HELB High Temperature                                     N/A               Eash refuoling Each  refl::Jeling          ~

1/3 mo.           Perform           Tests using Channel Tests Perform Channel                  the test using the test

outage                                       switches.

switches.

                                                                              -+fs-and test Calibrate prior to startup and normal shutdown and thereafter check 4/s-and       test 4/wic at the 4fwk at      frequency specified the frequency  specified inin the Surveillance Frequency the Surveillance     Frequency Control Program until no longer required.

Legend:       N/A =  = Not Applicable 1/s       Gnse Once per shift 1/d Gnse Once per day 1/3d Gnse 1/dd      Once per d    3 days I Iwk Gnse 1/wk      Once per ner 'Neek week 1/A10.

II(IIU. Gnse LIlIl..e per pei A10nth IIIUIILII 1/d 1/3 A10.

mo. Gnse Once every three throo A10nths months 1/12 A10.mo. Gnse Once every 12 A10nthsmonths 1/24 A10.mo. Gnse Once every 24 A10nths months OYSTER CREEK                                                             4.1-8 Change: 7, Amendment No.: 171,208,259     171, 208, 259

TABLE 4.1.1 TABLE        4.1.1 Page 66 of Page        of6 6 MINIMUM CHECK, MINIMUM        CHECK, CALIBRATION CALIBRATION AND         AND TEST TEST FREQUENCY FREQUENCY FOR          FOR PROTECTIVE PROTECTIVE INSTRUMENTATION INSTRUMENTATION NOTE 1:1:            Each automatic Each   automatic scram scram contactor contactor isis required required toto be be tested tested at at least least once   fler week ease per  .. eel( at at the the frequency    specified in frequency specified       in the the Surveillance    Frequency Control Surveillance Frequency         Control Program. When Program.      When not not tested tested by by other other means, means, thethe weekly weelHy-test      can be test can   be performed performed by by using using the subchannel test the subchannel    test switches.

switches.

NOTE  2:            At least daily At        daily during dHriag reactor reaster PO\VER        OPERATION At PO\VER OPELTION               At the the frequency frequency specified specified in in the the Surveillance Surveillance Frequency Frequency Control       Program, the Control Program,      the reactor neutron flux reactor neutron  flux peaking factor shall peaking          shall be be estimated estimated and and flow-referenced flow-referenced APRMAPRM scram  scram and and rod rod block block settings settings shall be adjusted, shall be                necessary, as adjusted, ififnecessary,      specified in as specified in Section Section 2.3 2.3 Specifications A.l Specifications    A.I and A.2.

A.2.

NOTE 3:                                       bistable trips Calibrate electronic bistable     trips by by injection injection of of an  external test an external     test current current atat the the frequency     specified in frequency specified      in the the Surveillance    Frequency Control Surveillance Frequency       Control Programonee Progral11BRe-fJer 33 months.

per    m8atfls. Calibrate Calibrate transmitters transmitters by by application application ofof test test pressure pressure atat the the frequency       specified in frequency specified      in the the Surveillance     Frequency Control Surveillance Frequency                    Program8ase per Control Programonce        Ber 12 months.

12  m8atfls.

NOTE 4:               Perform LPRM detectors calibration at       at the the frequency specified specified in  in the the Surveillance       Frequency Control Surveillance Frequency                      Program.e.ef\ 1000 Control Program.every                MWD/MT Merage lQQQ MWD/MT        P"eraEe Core Cere Exposure EJ'fl8SHre NOTES:

NOTE   5:                                                 specified in Surveillance Frequencies are specified           in the                     Frequency Control Surveillance Frequency the Surveillance                      Control Program         unless otherwise Program unless                    noted in otherwise noted      in the the table.

table.

The following notes are only for Item 15 of Table 4.1.1:  4.1.1:

A channel may be taken out of service for the purpose purpose of of aa check,  calibration, test check, calibration,     test or  maintenance without or maintenance                 declaring the without declaring     the channel channel to   be inoperable.

to be  inoperable.

: a.        The CHANNEL FUNCTIONAL TEST shall also demonstrate that                           control room alarm that control                    annunciation occurs alarm annunciation        occurs if any of ifany  of the the following   conditions exists:

: 1)     Instrument indicates measured levels above the alarm setpoint. setpoint.

: 2)     Instrument indicates a downscale failure.

: 3)     Instrument controls not set in operate mode.

: 4)     Instrument electrical power loss.

OYSTER CREEK                                                                           4.1-9 Change: 5,7, 5, 7, Amendment No.: 71,80,95,108,171,208,263,273 71, 80, 95, 108, 171, 208, 263, 273

TABLE 4.1.2 TABLE    4.1.2 MINIMUM TEST FREQUENCIES FOR TRIP SYSTEMS Trip System                                                             Frequency (Note 1)

Minimum Test Frequency            1)

: 1)    Dual Channel (Scram)                                           respective Instrumentation Same as for respective     Instrumentation in Table 4.1.1

: 2)     Rod Block                                       Same as for respective Instrumentation Instrumentation in Table 4.1.1

: 3)     DELETED                                         DELETED

: 4)     Automatic Depressurization                       Each refueling outage each trip system, one at a time

: 5)     MSIV Closure                                     Each refueling outage each closure logic circuit independently (1 valve at a time)

: 6)     Core Spray                                       1/3 mo and each refueling outago outage each trip system, one at a time

: 7)     Primary Containment Isolation                   Each refueling outage each trip circuit independently (1 valve at a time)

: 8)     Refueling Interlocks                             Prior to each refueling operation

: 9)     Isolation Condenser Actuation and Isolation     Each refueling outage each trip circuit independently (1 valve at a time) 10)

: 10) Reactor Building Isolation and SGTS               Same as for    rncnctive Instrumentation iui respective Initiation Initiation                                              in Table 1.1.1 4.1.1 11)

: 11)      DELETED DELETED                                        DELETED 12)

: 12)    Air Ejector Eiector Offgass Line Isolation             Each refueling outage 13)

: 13)      Containment Vent and Purge Isolation Containment                                    1/24 mo Note 1: Surveillance Frequencies are specified in the Surveillance Frequency Control Note 1:

Program unless otherwise noted in the table.

Program OYSTER OYSTER CREEK CREEK                               4.1-10 Amendment Amendment No.:       108,116,144,160,171,193, 208, 273 No.: 108,116,144,160,171,193,208,273

4.2 REACTIVITY CONTROL Applicability:                                                     reactivity control.

Applies to the surveillance requirements for reactivity     control.

Qbiective:      To verify the capability for controlling reactivity.

A.     80M SDM shall be verified:

: 1.       Prior to each CORE ALTERATION, and

: 2.       Once within 4 hours following the first criticality following any any CORE CORE ALTERATION.

B.     The control rod drive housing support system shall be inspected inspected after reassembly.

reassembly.

C.      The maximum scram insertion time of the control rods shall be demonstrated through measurement and, during single control rod scram time tests, the control    control rod drive pumps shall be isolated from the accumulators:

: 1.       For all control rods prior to THERMAL POWER exceeding 40%         40% power power with reactor coolant pressure greater than 800 psig, following core alterations or after a reactor shutdown that is greater than 120  120 days.

: 2.       For specifically affected individual control rods following maintenance maintenance on or modification to the control rod or control rod drive system which could affect the scram insertion time of those specific control rods in accordance with either "a"a or "b" b as follows:

a.1     Specifically affected individual control rods shall be scram time tested with the reactor depressurized and the scram insertion time from the fully withdrawn position to 90%90% insertion shall not exceed 2.2 seconds, and a.2     Specifically affected individual control rods shall be scram time tested at greater than 800 psig reactor coolant pressure prior to 40% power.

exceeding 400/0

: b.       Specifically affected individual control rods shall be scram time tested at greater than 800 psig reactor coolant pressure.

: 3.       On a frequency of less than or equal to once per 180 days of cumulative power operationAt the frequency specified in the Surveillance Frequency Control Program, for at least 20 control rods, on a rotating basis, with reactor coolant pressure greater than 800 psig.

o.

D.      Each withdrawn control rod shall be exercised at least Each                                                    Ioast once per 31 daysat the frequency specified in the Surveillance Frequency Control Program. This test shall be performed within 24 hours in the event power operation is continuing with two or more inoperable control rods or in the event power operation is continuing with one fully or partially withdrawn rod which cannot be moved and continuing for which control rod drive mechanism damage has not been ruled out. The surveillance need not be completed within 24 hours if the number of inoperable has been reduced to less than two and if it has been demonstrated that rods has rods rod drive mechanism collet housing failure is not the cause of an control rod immovable control rod.

immovable OYSTER  CREEK OYSTER CREEK                                   4.2-1            Amendment No: 178, 198, 249, 266, 275 249,266,275

E. Surveillance of the standby liquid control system shall be as follows:

: 1. Pump operability                         Note 1  Once/3 months lOnce/3  menths

: 2. Boron concentration                     Note 1  Once/month lOnce/month determination

: 3. Functional test                         Note 1  Once every 24 months lOnce

: 4. Solution volume and                     Note 1  Once/day lOnce/day temperature check

: 5. Solution Boron-10 Boron-lO                        Note 1 Once every 24 months.

lOnce Enrichment                                Enrichment analyses shall be received no later than 30 days after sampling. If not received within 30 days, notify NRC (within 77 days) of plans to obtain test results.

F. At specific power operation conditions, the actual control rod configuration will be compared with the expected configuration based upon appropriately corrected past data. This comparison shall be made every equivalent full power month. The initial rod inventory measurement performed with equilibrium conditions are established after a refueling or major core alteration will be used as base data for reactivity monitoring during subsequent power operation throughout the fuel cycle.

G. The scram discharge volume drain and vent valves shall be verified open at least once per 31 daysat the frequency specified in the Surveillance Frequency Control Program, except in shutdown mode*,    mode*, and shall be cycled at least one complete cycle of full travel at the frequency specified in the Surveillance Frequency Control Programat least quarterly.

H. All withdrawn control rods shall be determined OPERABLE by demonstrating the scram discharge volume drain and vent valves OPERABLE. This will be done at the frequency specified in the Surveillance Frequency Control Programat least once per refueling cycle by placing the mode switch in shutdown and by verifying that:

: a.       The drain and vent valves close within 30 seconds after receipt of a signal for control rods to scram, and

: b.       The scram signal can be reset and the drain and vent valves open when the scram discharge volume trip is bypassed.

Corrected: 12/24/84 OYSTER CREEK                    4.2-2 Amendment No.: 64, 74, 75,124,141,159,        172, 178 75,124,141,159,172,178 Change: 25 Change:~

The monthly control rod exercise test at the frequency specified in the Surveillance Frequency Control Program serves as a periodic check against deterioration of the control rod system. Experience with this control rod system and analysis performed for an industry       wide BVVR industry-wide BWR initiative that was approved by NRCf&1 NRC have indicated that monthly tests are adequate, and that rods 'Nhich which move by drive pressure will scram when required as the pressure applied is much higher.The Surveillance Frequency is controlled under the Surveillance Frequency Control Program. The requirement to exercise the control rods within 24 hours of a condition with two or more control rods which are valved out of service or one fully or partially withdrawn control rod which can not be moved provides assurance of the reliability of the remaining control rods.

Pump operability, boron concentration, solution temperature and volume of standby liquid control system(4) 4 are checked on a frequency system consistent with instrumentation checks described in Specification 4.1 at the frequency specified in the Surveillance Frequency Control Program.

Figure 3.2.1 was revised to reflect the minimum and maximum weight percent of sodium pentaborate solution, and the minimum atom percent of B-i 0 to meet 10 CFR 50.62(c)(4). Since the weight percent of sodium 8-10 pentaborate can change with water makeup or water evaporation, frequent surveillances are performed on the solution concentration, volume and temperature. The sodium pentaborate is enriched with B-b      8-10 at the vendors facility to meet the minimum atom percent.

chemical vendor's Preshipment samples of batches are analyzed for B-1     B-b 0 enrichment and verified by an independent laboratory prior to shipment to Oyster Creek. Since the 8-10B-b enrichment will not change while in storage or B-b enrichment is performed or in the SLCS tank, the surveillance for 8-10                               00 a 24 month intervalat the frequency specified in the Surveillance Frequency Control Program. An additional requirement has been added solutions capability to meet the original design shutdown to evaluate the solution's Boron-i 0 enrichment requirement is not met.

criteria whenever the 8oron-10 The functional test and other surveillance on components, along with the monitoring instrumentation, gives a high reliability for standby liquid control system operability.

OYSTER CREEK                         4.2-4           Amendment No.: 75, 124, 124, 159,  172, 178, 159, 172, 178, 275

4.3     REACTOR COOLANT Applicability:                                                           coolant system.

Applies to the surveillance requirements for the reactor coolant   system.

Oblective:    To determine the condition of the reactor coolant system and and the   operation of the operation    of the the safety devices related to it.

Specification: A.                                           neutron flux monitors shall Materials surveillance specimens and neutron                           be installed shall be installed midplane of in the reactor vessel adjacent to the wall at the midplane   of the active core.

the active  core.

Specimens and monitors shall be periodically removed, tested, and   and evaluated evaluated to determine the effects of neutron fluence on the fracture toughness of   of the the vessel shell materials. Pressure and temperature curves are contained in        in the Pressure and Temperature Limits Report (PTLR).

B. lnservice inspection of ASME Code Class 1, Inservice                                    1, Class 22 and Class 33 systems and components shall be performed in accordance with Section Xl      XI of the ASME Boiler and Pressure Vessel Code and applicable Addenda as required by 10 CFR, Section 50.55a, except where specific written relief has has been granted by the NRC pursuant to 10  10 CFR, Section 50.55a.

C. Inservice testing of ASME Code Class 1, Class 2 and Class 33 pumps and valves shall be performed in accordance with the ASME Code for Operation and Maintenance of Nuclear Power Plants (ASME OM Code) and applicable Addenda as required by 10 CFR, Section 50.55a,50.55a, except where specific written relief has been granted by the NRC pursuant to 10    10 CFR, Section 50.55a.

D. A visual examination for leaks shall be made with the reactor coolant system at pressure during each scheduled refueling outage or after major repairs have been made to the reactor coolant system in accordance with Article 5000, Section XI.Xl. The requirements of specification 3.3.A shall be met during the test.

E. Each replacement safety valve or valve that has been repaired shall be tested in accordance with Specification C above. Setpoints shall be as follows:

Number of Valves       Set Points (psig) 4                    1212+/-36 1212 +/- 36 5                    1221+/-36 1221 +/- 36 F. A sample of reactor coolant shall be analyzed at least every 72 hoursat the frequency specified in the Surveillance Frequency Control Program for the purpose of determining the content of chloride ion and to check the conductivity.

conductivity.

OYSTER CREEK OYSTER      CREEK                              4.3-1                 Amendment No.: 82, 90, 120, 150, 151, 164, 188, 195, 151,164,188,195, 261, 268, 269 261,268,269

* G.       Primary Coolant System Pressure Isolation  Isolation Valves Valves Srecification:

Specification:

: 1.         Periodic leakage testing(a)on testing(a) on each valve listed listed in in Table 4.3.1 4.3.1 shall shall exceeding 600 psig reactor be accomplished prior to exceeding                     reactor pressure everyevery shutdown condition for time the plant is placed in the cold shutdown refueling, each time the plant is placed in   in aa cold shutdown shutdown condition for 72 hours if testing has not been been accomplished accomplished in   in the the preceding 9 months, whenever the valve is moved     moved whether whether by by conditions, and manual actuation or due to flow conditions,         and after after returning returning the the valve to service after maintenance, repair or replacement work       work is is performed.

H.       Reactor Coolant System Leakage

: 1.         Unidentified leakage rate shall be calculated at the frequency specified in the Surveillance Frequency Control Programat      Programat-least once every Ihours.

4hours.

: 2.         Total leakage rate (identified and unidentified) shall be calculated at the frequency specified in the Surveillance Frequency Control Programat least once every 8 hours.

: 3.         A CHANNEL CALIBRATION of the primary containment sump flow integrator and the primary containment equipment drain tank flow integrator shall be conducted at the frequency specified in the Surveillance Frequency Control Programat least once per 24 months.

I.       An inservice inspection program for piping identified in NRC Generic Letter 88-01 shall be performed in accordance with the NRC staff positions on schedule, methods, personnel, and sample expansion included in the generic            generic letter or in accordance with alternate measures approved by the NRC staff.

Data is available relating neutron fluence (E>1.0MeV)  (E>1.OMeV) and the change in the Reference Nil-Ductility Transition Temperature (RT            NOT)' Pressure and temperature curves are contained in the Pressure (RTNDT).

and Temperature Limits Report (PTLR).

The inspection program will reveal problem areas should they occur, before a leak develops. In addition, extensive visual inspection for leaks will be made on critical systems. Oyster Creek was designed and constructed prior to designed (a)

(a)  To   satisfy ALARA requirements, leakage may be measured To satisfy indirectly (as from the performance of pressure indicators) if indirectly accomplished in accomplished      in accordance with approved procedures and supported by computations by  computations showing that the method is capable of demonstrating valve compliance valve                      the leakage with the compliance with        leakage criteria.

criteria.

** NRC NRC Order                         1981.

dated April 20, 1981.

Order dated OYSTER CREEK OYSTER          CREEK                                    4.3-2         Amendment No.: 97,118,120,151,154, 188, 193, 263, 269 19d,26d,269

the existence of ASME Section Xl. XI. For For this this reason, reason, the the degree degree of of access access required required by ASME Section Xl       is not XI is not generally generally available available andand will will be be addressed addressed as as requests "requests in accordance relief' in for relief    accordance with with 10 10 CFR CFR 50.55a(g).

50.55a(g).

Experience in safety valve operation showsshows testing testing in in accordance accordance withwith the the ASME ASME Code Code isis deterioration. The adequate to detect failures or deterioration.       The as-found as-found setpoint setpoint tolerance tolerance is is specified specified in the ASME CM  OM Code as the owner-defined tolerance tolerance oror +/-+/- 3%

3% of of valve valve nameplate nameplate setset pressure. An analysis has been performed which shows that with            with all all safety safety valves valves set set 1375 psig is 36 psig higher, the safety limit of 1375           is not exceeded.

monitor the reactor coolant.

Conductivity instruments continuously monitor                         coolant. Experience Experience indicates that a periodic check of the conductivity instrumentation at             least every at least  every 72 houreat hoursat the frequency specified in the Surveillance Frequency                   Control Program Frequency Control        Program is adequate to ensure accurate readings. The reactor water sample        sample will also be used to determine the chloride ion content to assure that      that the limits limits of 3.3.E are not exceeded. The chloride ion content will not change               rapidly over a period of several days; therefore, the sampling frequency is adequate.

OYSTER OYSTER CREEK CREEK                          4.3-3 4.3-3                                           82, 90, 261, 268 Amendment No.: 82,90,261,268

Item                           Freguency Frequency C. Containment Cooling System

: 2. Motor-operated valve operability               Note 1Evory lEvery 33 months

: 3. Pump compartment water-                       Note 1Onco/wook lOnce/week and after each entry tight doors closed D. Emergency Service Water System

: 1. Pump Operability                                     lOnce/3 months. Also after major Note 1Onco/3                        major maintenance and prior to startup following aa refueling outage.

: 1. Pump Operability                               Note 1Onco/month.

lOnce/month. Also after major maintenance and prior to startup following aa refueling outage.

: 1. Pump Operability                               Note 1Onco/month.

I Once/month. Also after major maintenance and prior to startup following aa refueling outage.

: 2. Isolation valve operability                     Note 1Once/3 IOnce/3 months. Also after major maintenance and prior to startup following aa refueling outage.

It is during major maintenance or repair that a systems system's design intent may be violated accidentally.

Motor operated pumps, valves and other active devices that are normally on standby should be exercised periodically to make sure that they are free to operate. Motors on pumps should operate long enough to approach equilibrium temperature to ensure there is no overheat problem. Whenever practical, valves should be stroked full length to ensure that nothing impedes their Inservice Testing Program in accordance with the ASME Code motion. Testing of components per OC lnservice every 3 months provides assurances of the availability of the system. The Control Rod Hydraulic pumps once ovory lnservice Test Program per the ASME and Fire Protection System pumps are not part of the Inservice monthat Code and will continue to be tested for operability once per month    at the frequency specified in the Surveillance Frequency Control Program. Engineering judgment                      m<perience and availability judgmont based on experience analyses of the type presented in Appendix L of the FDSAR indicates that testing these components more ofter      often than once a month ovorover a long period of time does not significantly improve the system reliability. Also, at this wearout should not be a problem through the life of the plant.

frequency of testing '..learout frequoncy OYSTER CREEK                               4.4-2                     Amendment No.: 109,160,       210, 268 109,160,210,268

: b.       If the airlock is opened during aa period when Primary Containment is not required, it need not be tested while Primary Containment is not required, but must be tested at a    Pa prior to returning the reactor to an operating mode requiring PRIMARY CONTAINMENT INTEGRITY.INTEGRITY.

D. Primary Containment Leakage Rates shall be limited to:

: 1.     The maximum allowable Primary Containment leakage rate is 1.0        1.0 La. The maximum allowable Primary Containment leakage rate to allow for plant startup following a type A test is 0.75 La. The leakage rate acceptance criteria for the Primary Containment Containment Leakage Rate Testing Program for Type B      B and Type C  C tests is

                  ~0.60 0.60 La at Pa,a, except as stated in Specification 4.5.D.2.

4.5.0.2.

: 2.      Verify leakage rate through each MSIV is     ~ 11.9 11.9 scfh when tested at   ~ 20 psig.

: 3.     The leakage rate acceptance criteria for the drywell airlock shall be

                  ~ 0.05 La when measured or adjusted to Pa. Pa.

E. Continuous Leak Rate Monitor

: 1.     When the primary containment is inerted, the containment shall be continuously monitored for gross leakage by review of the inerting system makeup requirements.

: 2.     This monitoring system may be taken out of service for the purpose of maintenance or testing but shall be returned to service as soon as practical.

F. Functional Test of Valves

: 1. All automatic primary containment isolation valves shall be tested for automatic closure by an isolation signal at the frequency specified in the Surveillance Frequency Control Programduring each REFUELING OUTAGE and the isolation time determined to be REFUELI~JG within its limit. The following valves are required to close in the time specified below:

Main steam line isolation valves:     ~ 3 seconds and   ~ 10 seconds

: 2. Each automatic primary containment isolation valve shall be demonstrated OPERABLE prior to returning the valve to service after maintenance, repair or replacement work is performed on OYSTER CREEK OYSTER                                  4.5-2                                                 196, 250 Amendment No.: 132, 186, 196,250

: 3. During each COLD SHUTDOWN, each main steam isolation valve shall be closed and its closure time verified to be within the limits of Specification 4.5.F.1 above unless this test has been performed within the last 92 days.

: 4. Reactor Building to Suppression Chamber Vacuum Breakers

: a. The reactor building to suppression chamber vacuum breakers and associated instrumentation, including setpoint, shall be checked for proper operation at the frequency specified in the Surveillance Frequency Control Programevery three months.

: b. At the frequency specified in the Surveillance Frequency Control ProgramDuring each REFUELING OUTAGE, each vacuum breaker shall be tested to determine that the force required to open the vacuum breaker from closed to fully open does not exceed the force specified in Specification 3.5.A.4.a. The air-operated vacuum breaker instrumentation shall be 3.5.AA.a.

calibrated at the frequency specified in the Surveillance Frequency Control Programduring each REFUELINGREFUELI~JG OUTAGE.

: 5. Pressure Suppression Chamber - Drywell Vacuum Breakers

: a. Periodic OPERABILITY Tests At the frequency specified in the Surveillance Frequency Control ProgramOnce every d      3 months and following any release of energy which would tend to increase pressure to the suppression chamber, each OPERABLE suppression chamber - drywell vacuum breaker shall be exercised.

Operation of position switches, indicators and alarms shall be verified at the frequency specified in the Surveillance Frequency Control Programevery Programe&#xa5;efY 3 months by operation of each OPERABLE vacuum breaker.

: b. REFUELING OUTAGE TestsThe REFUELI~JG                  TeetsThe following tests, with the exception of b(4),

(1)     All suppression chamber - drywell vacuum breakers shall be tested to determine the force required to open each valve from fully closed to fully open.

(2)     The suppression chamber - drywell vacuum breaker position indication and alarm systems shall be calibrated and functionally tested.

OYSTER CREEK                           4.5-3             Amendment No.: 144, 186, 196, 210, 221 18(3, 19(3,210,221

(3)                           suppression chamber - drywell At least four of the suppression              -  drywell vacuum vacuum breakers breakers shall shall inspected. If deficiencies are be inspected,                    are found, all vacuum vacuum breakers breakers shall shall be be inspected                      corrected such inspected and deficiencies corrected      such that Specification 3.5.A.5.a 3.5.A.5.a cancan be met.

(4)     A drywell to suppression chamber leak  leak rate test test shall shall be be performed performed once once every 24 months to demonstrate that with an    an initial  differential pressure initial differential  pressure of not less than 1.0          differential pressure 1.0 psi, the differential pressure decay decay rate shall shall not not exceed the equivalent of air flow through aa 2-inch 2-inch orifice.

orifice.

G. Reactor Building

: 1. Secondary containment capability tests shall be conducted after              isolating the after isolating reactor building and placing either Standby Gas Treatment System filter train          train in in operation.

: 2. The tests shall be performed at the frequency specified in the Surveillance Frequency Control Programat least once per operating cycle (interval not              not to exceed 20 months) and shall demonstrate the capability to maintain aa 1/4           1/4 inch of water vacuum under calm wind conditions with a Standby Gas Treatment System Filter train flow rate of not more than 4000cfm.

: 3. A secondary containment capability test shall be conducted at each refueling outage prior to refueling.

: 4. The results of the secondary containment capability tests shall be in the subject    subject of of a summary technical report which can be included in the reports specified in Section 6.

H. Standby Gas Treatment System

: 1. The capability of each Standby Gas Treatment System circuit shall be demonstrated by:

: a. At the frequency specified in the Surveillance Frequency Control ProgramAt least once per 18 months, after every 720 hours of operation, and following significant painting, fire, or chemical release in the reactor building during operation of the Standby Gas Treatment System by verifying that:

(1) The charcoal absorbers remove ~99%    99% of a halogenated hydrocarbon refrigerant test gas and the HEPA filters remove 99% of the DOP in a cold DOP test when tested in accordance

with ANSI N510-1975.

OYSTER CREEK OYSTER CREEK                                    4.5-4              Amendment No.: 144,186,193,219

(2)    Results of laboratory carbon sample analysis show 95% ;:::95%

radioactive methyl iodide removal efficiency when tested in accordance with ASTM 03803-1989 D 3803-1989 (30&deg;C, 95% relative humidity, at least 45.72 feet per minute charcoal bed face velocity).

: b. At the frequency specified in the Surveillance Frequency Control ProgramAt least once per 18 rnonths months by demonstrating:

(1)    That the pressure drop across a HEPA filter is equal to or less than the maximum allowable pressure drop indicated in Figure 4.5.1.

(2)    The inlet heater is capable of at least 10.9 KW input.

(3)    Operation with a total flow within 10% of design flow.

: c. At the frequency specified in the Surveillance Frequency Control ProgramAt least once per 30 days on a STAGGERED TEST BASIS by operating each circuit for a minimum of 10 hours.

: d. Anytime the HEPA filter bank or the charcoal absorbers have been partially or completely replaced, the test per 4.5.H.1.a (as applicable) will be performed prior to returning the system to OPERABLE STATUS.

: e. Automatic initiation of each circuit at the frequency specified in the Surveillance Frequency Control Programevery 18 months. rnonths.

I. Inerting Surveillance When an inert atmosphere is required in the primary containment, the oxygen concentration in the primary containment shall be checked at the frequency specified in the Surveillance Frequency Control Programat least weekly.

J. Drywell Coating Surveillance Carbon steel test panels coated with Firebar 0  D shall be placed inside the drywell near the mid plane level. They shall be removed for visual observation and weight reactor core midplane loss measurements during the first, second, fourth and eighth refueling outages.

K. Instrument Line Flow Check Valves Surveillance The capability of a representative sample of instrument line flow check valves to isolate shall be tested at the frequency specified in the Surveillance Frequency Control months. In addition, each time an instrument line is Programat least once per 24 rnonths.

returned to service after any condition which could have produced aa pressure flow disturbance in that line, the open position of the flow check valve in that line shall be verified. Such conditions include:

OYSTER CREEK                         4.5-5                    Amendment No.: 132,186,216,219 132,186,216,21Q Corrected by letter of 3/18/02

and valves Leakage at instrument fittings and  valves Venting an unisolated instrument or instrument instrument line line Flushing or draining an instrument Installation of a new instrument or instrument line L. Suppression Chamber Surveillance

: 1.                                        Surveillance Frequency At the frequency specified in the Surveillance                  Control ProgramAt Frequency Control  ProgramAt-least once per day the suppression chamber water level and and temperature temperature and and pressure suppression system pressure shall be checked.

: 2. A visual inspection of the suppression chamber interior, including water line line regions, shall be made at the frequency specified in the Surveillance Frequency Control Programat each major refueling outage.

: 3. Whenever heat from relief valve operation is being added to the suppression also observed pool, the pool temperature shall be continually monitored and also    observed until the heat addition is terminated.

: 4. Whenever operation of a relief valve is indicated and the suppression pool temperature reaches 160&deg;F or above while the reactor primary coolant system pressure is greater than 180 psig, an external visual examination of the suppression chamber shall be made before resuming normal power operation.

M. Shock Suppressors (Snubbers)

As used in this specification, "type    snubber shall mean snubbers of the same design type of snubber" and manufacturer, irrespective of capacity.

: 1. Each snubber shall be demonstrated OPERABLE by performance of the following inspection program:

: a. Visual Inspections Snubbers are categorized as inaccessible or accessible during reactor operation. Each of the categories (inaccessible and accessible) may be inspected independently according to the schedule determined by Table 4.5-1. The visual inspection interval for each type of snubber shall be determined based upon the criteria provided in Table 4.5-1.

CREEK OYSTER CREEK OYSTER                                4.5-6                                          186, 216 Amendment No.: 182, 186,216

: f.       Snubber Service Life Monitoring A record of the service life of each snubber, the date at which the designated service life commences and the installation and maintenance records on which the designated service life is based shall be maintained as required by Specification 6.10.2.1.

N. Secondary Containment Isolation Valves

: 1. Each secondary containment isolation valve shall be demonstrated operable prior to returning the valve to service after maintenance, repair or replacement work is performed on the valve or its associated actuator by cycling the valve through at least one complete cycle of full travel. Following maintenance, repair or replacement work on the control or power circuit for the valves, the affected component shall be tested to assure it will perform its intended function in the circuit.

: 2. At the frequency specified in the Surveillance Frequency Control Programl\t ProgramAt least     onGe per refueling outage, all valves shall be tested for lea6t once automatic closure by an isolation signal.

OYSTER CREEK                               4.5-9                   Amendment No.: 168,186,219 168,186,219

Guidance for implementation of Option B is contained in NRC Regulatory Guide 1.163,   1.163, "Performance Performance Based Containment Leak Test Program",Program, Revision 0, dated September 1995.

1995.

Additional guidance for NRC Regulatory Guide 1.163 is contained in Nuclear Energy Institute (NEI) 94-01, "Industry Industry Guideline for Implementing Performance Based Option of 10  10 CFR 50, Appendix J,"

J, Revision 0, dated July 26, 1995, and ANSI/ANS 56.8-1 56.8-1994, "Containment System 994, Containment Leakage Testing Requirements."

Requirements. The Primary Containment Leakage Rate Testing Program conforms with this guidance as modified by approved exemptions.

The maximum allowable leakage rate for the primary containment (La) is 1.0  1.0 percent by weight of the containment air per 24 hours at the design basis LOCA maximum peak containment pressure (Pa). As discussed below, Pa  Pa for the purpose of containment leak rate testing is 35 psig.

Automatic primary containment isolation valves are provided to maintain PRIMARY CONTAINMENT CONTAINMENT INTEGRITY following the design basis loss-of-coolant accident. Closure times for the automatic primary containment isolation valves are not critical because it is on the order of minutes before significant fission product release to the containment atmosphere for the design basis loss of coolant accident. These valves are highly reliable, see infrequent service and most of them are normally in the closed position. Therefore, a-testing at the frequency specified in the Surveillance Frequency Control Programduring each REFUELING OUTAGE is sufficient.

Closure times restrict coolant loss from the circumferential rupture of any of these lines outside primary containment to less than that for a main steam line break (the design basis accident for outside containment line breaks). The minimum time for main steam isolation valve (MS        IV)

(MSIV) closure of 3 seconds is based on the transient analysis that shows the pressure peak 76 psig below the lowest safety valve setting. The maximum time for MSIV closure of 10    10 seconds is based on the value assumed for the main steam line break dose calculations and restricts coolant loss to prevent uncovering the reactor core. Per the ASME Code, the full closure test of the MSIVs during COLD SHUTDOWNs will ensure OPERABILITY and provide assurance that the valves maintain the required closing time. The provision for a minimum of 92 days between the tests ensures that full closure testing is not too frequent. The MSIVs are partially stroked quarterly periodically as part of reactor protection system instrument surveillance testing.

OYSTER CREEK                             4.5-11           Amendment No.: 1J2,186,1Q6,21Q,221 132,186,196,219,221,250,

                                                                                                  ,250,

                                                                            ~

At the end of each refueling cycle, a leak rate test shall be performed to verify that significant leakage flow paths do not exist between the drywell and suppression chamber. The drywell pressure will be increased by at least 1  1 psi with respect to the suppression chamber pressure. The pressure transient (if any) will be monitored with a sensitive pressure gauge. If the drywell pressure cannot be increased by 1I psi over the suppression chamber pressure it would be because a significant leakage path exists: in this event, the leakage source will be identified and eliminated before POWER OPERATION is resumed. If the drywell pressure can be increased by 11 psi over the suppression chamber, the rate of change of the suppression chamber pressure must not exceed aa rate equivalent to the rate of air flow from the drywell to the suppression chamber through aa 2-inch orifice. In the event the rate of change of pressure exceeds this value, then the source of leakage will be identified and eliminated before POWER OPERATION is resumed.

The drywell suppression chamber vacuum breakers are exercised at the frequency specified in           I the Surveillance Frequency Control Programevery 3 months and immediately following termination of discharge of steam into the suppression chamber. This monitoring of valve operability is intended to assure that valve operability and position indication system performance does not degrade between refueling inspections. When a vacuum breaker valve is exercised through an opening-closing cycle, the position indicating lights are designed to function as follows:

Full Closed                     2 Green - On 0.10 open)

(Closed to 0.10"                1 Red - Off 1      -

Open 0.10" 0.10                    2 Green - Off (0.10" open to full open)

(0.10                          2 Red - On OYSTER CREEK                           4.5-12         Amendment No. 128,186,196,210,211,219 Corrected by letters of 3/18/02 and 4/5/02 4/5/02

At the frequency specified in      in the the Surveillance Surveillance Frequency Frequency Control Control ProgramDuring ProgramDuring each     eaoh refueling outage, four suppression chamber-drywell vacuum      vacuum breakers breakers will    be inspected will be   inspected to   to assure assure components have not deteriorated. Since    Since valve internals internals are are designed designed for for aa 40-year 40-year lifetime, lifetime, anan inspection program which cycles through through all all valves in in about about 1/10th 1/1 Oth of of the the design design lifetime lifetime is is extremely conservative. The alarm systems for the vacuum       vacuum breakers breakers will will be be calibrated calibrated at  at the the frequency specified in the Surveillance Frequency Frequency Control Control Programduring Programduring each   eaoh refueling refueling experienoe and frequenoy is based on experience outage. This frequency                                    and engineering judgement.

judgement.

Initiating reactor building isolation and operation of the standby gas      gas treatment treatment system system to  to maintain maintain a 1/4 inch of water vacuum, tests the operation of the reactor building isolation   isolation valves, valves, leakage leakage tightness of the reactor building and performance of the standby gas        gas treatment treatment system.

system. Checking Checking the initiating sensors and associated trip channels demonstrates the capability for              for automatic automatic actuation. Performing the reactor building in leakage test prior to refueling demonstrates demonstrates secondary secondary containment capability prior to extensive fuel handling operations associated with            with the outage.

outage.

Verifying the efficiency and operation of charcoal filters at the frequency specified     specified in  in the Surveillance Frequency Control Programonce Programonoe per 18                                      confidence of 18 months gives sufficient confidence             of standby gas treatment system performance capability. A charcoal filter efficiency of 99%                99% for halogen removal is adequate.

The in-place testing of charcoal filters is performed using halogenated hydrocarbon  hydrocarbon refrigerant which is injected into the system upstream of the charcoal filters. Measurement of the refrigerant concentration upstream and downstream of the charcoal filters is made using aa gas chromatograph. The ratio of the inlet and outlet concentrations gives an overall indication of the leak tightness of the system. Although this is basically aa leak test, since the filters have          have charcoal of known efficiency and holding capacity for elemental iodine and/or methyl iodide, the test also gives an indication of the relative efficiency of the installed system. The test procedure is an adaptation of test procedures developed at the Savannah River Laboratory which were described Conference.*

in the Ninth AEC Cleaning Conference.*

An efficiency of 99%99% is adequate to retain particulates that may be released to the reactor building building following   an accident. This will be demonstrated by testing with DOP at testing medium.

95% methyl iodide removal efficiency is based on the formula in GL 99-02 for allowable The 950/0 penetration [(100%         90% credited in DBA analysis) divided by a safety factor of 2]. If the

[(100% - 900/0 allowable penetration is ~5%, 5%, the required removal efficiency is ~95%. 95%. If laboratory tests for the adsorber material in one circuit of the Standby Gas the                                                                Treatment   System are unacceptable, all adsorber    material in adsorber material     in that circuit shall be replaced   with adsorbent   qualified   according to Regulatory Regulatory Guide 1.52.             HEPA filters found defective shall be 1.52. Any HEPA                                          replaced     with those qualified with with Regulatory   Position C.3.d of Regulatory Guide 1.52.

** D.R. Muhabier. "In D.R. Muhabier. In Place Place Nondestructive Nondestructive Leak                      Adsorbers. Proceedings of the Leak Test for Iodine Adsorbers."

Ninth AEC Ninth        Air Cleaning AEC Air    Cleaning Conference.       USAEC Report CONF-660904, 1966 Conference. USAEC OYSTER CREEK OYSTER       CREEK                                   4.5-13             Amendment No.: 186, 195,219      195, 219

The operability of the instrument line flow check valves are are demonstrated demonstrated to  to assure assure isolation isolation sensor when capability for excess flow and to assure the operability of the instrument sensor       when required.

The representative sample consists of an approximately equal number number of EFCVs EFCV's suchsuch that that each each EFCV is tested at least every 10 years (nominal). The nominal 10     10 year year interval interval isis based based onon other other performance-based testing programs, such as Inservice Testing (snubbers)

(snubbers) and OptionOption BB to to 10 10 CFR 50, Appendix J, EFCV test failures will be evaluated to determine                         testing in determine ifif additional testing   in that that test interval is warranted to ensure overall reliability is maintained. Operating experience experience has has Demonstrated that these components are highly reliable and that failures to isolate isolate are are very Infrequent. Therefore, testing of a representative sample was concluded to be acceptable from aa relaibility standpoint.

9 standpoint. (9)

Because of the large volume and thermal capacity of the suppression pool, the volume and temperature normally changes very slowly and monitoring these parameters GaUy-periodically daily periodically is is I temperature to sufficient to establish any temperature trends. By requiring the suppression pool temperature be continually monitored and also observed during periods of significant heat addition,addition, the temperature trends will be closely followed so that appropriate action can be taken. The requirement for an external visual examination following any event where potentially high      high loadings could occur provides assurance that no significant damage was encountered. Particular attention should be focused on structural discontinuities in the vicinity of the relief valve discharge since these are expected to be the points of highest stress.

References (1)       Licensing Application, Amendment 32, Question 3 (2)       FDSAR, Volume I, Section V-1.1 (3)       GE-NE 770-07-1090, 770-07-1 090, "Oyster                                  Response," February 1991 Oyster Creek LOCA Drywell Pressure Response,                         1991 (4)       Deleted (5)       FDSAR, Volume I, Sections V-1.5        V-i .6 v-I .5 and V-1.6 (6)                                   V-i .6 and XIII-3.4 FDSAR, Volume I, Sections V-1.6         Xlll-3.4 (7)                                 XIll-2 FDSAR, Volume I, Section XIII-2 (8)       Licensing Application, Amendment 11,ii, Question 111-18 (9)       GE BWROG B21-00658-01, B2i-00658-0l, "Excess                                  Relaxation, dated Excess Flow Check Valve Testing Relaxation,"

November 1998 OYSTER CREEK OYSTER      CREEK                              4.5-15                                 165,186, 216, 219 Amendment No.: 165,186,216,219 3/1 8/02 Corrected by letter 3/18/02

4.6 RADIOACTIVE EFFLUENT Applicability:                 monitoring of gaseous Applies to monitoring     gaseous and liquid liquid radioactive radioactive effluents effluents of of the the Station Station during during release release of of effluents via the monitored pathway(s). Each Surveillance Requirement applies   applies whenever whenever the the corresponding Specification is applicable unless otherwise statedstated in in an individual individual Surveillance Surveillance Requirement. Surveillance Requirements do not       have to be performed on not have                      on inoperable inoperable equipment.

equipment.

Obiective:        To measure radioactive effluents adequately to verify that radioactive effluents effluents are are as as low low as as is reasonable achievable and within the limit of 1010 CFR CFR Part Part 20.

20.

A.     Reactor Coolant Reactor coolant shall be sampled and analyzed at the frequency specified in            in the Surveillance Surveillance Frequency Control Programat least once every 72 hours for DOSE EQUIVALENT 1-131                 1-131 during during RUN RUN MODE, STARTUP MODE and SHUTDOWN CONDITION.

B.     NOT USED.

C.     Radioactive liqUid Liguid Storage

: 1. Liquids contained in the following tanks shall be sampled and analyzed for radioactivity at the frequency specified in the Surveillance Frequency Control Programat least          least once per 77 days days when radioactive liquid is being added to the tank:

: a. Waste Surge Tank, HP-T-3;

: b. Condensate Storage Tank.

D.     Main Condenser OffgasOffcias Treatment RELOCATED TO THE ODCM.

E.     Main Condenser OffgasOffcias Radioactivity 1.

: 1. The gross radioactivity in fission gases discharged from the main condenser air ejector shall be measured by sampling and analyzing the gases.

: a. At the frequency specified in the Surveillance Frequency Control Programat least once per month, and

: b. When the reactor is operating at more than 40 percent of rated power, within 4 hours after an increase in the fission gas release via the air ejector of more than 50 percent, as indicated by the Condenser Air Ejector Offgas Radioactivity Monitor after factoring out increase(s) due to change(s) in the THERMAL POWER level.

F.      Condenser Condenser Offgas Offqas Hydrogen Concentration The concentration of hydrogen in offgases downstream of the recombiner in the Offgas System shall be The monitored with hydrogen instrumentation as described in Table 3.15.2.

monitored G.

G.      NOT USED.

USED.

OYSTER CREEK OYSTER  CREEK                                      4.6-1                                         108,126,166,191, 2ii Amendment No.: 108,12i,1ii,191,       266

4.7     AUXILIARY ELECTRICAL ELECTRICAL POWER POWER Applicability: Applies to surveillance requirements of      of the the auxiliary auxiliary electrical electrical supply.

supply.

Objective:                                                     electrical supply.

To verify the availability of the auxiliary electrical     supply.

A.     Diesel Generator

: 1. Each diesel generator shall be started and     and loaded loaded to to not not less less than  80% rated than 80%   rated load at the frequency specified in the Surveillance              Frequency Control Surveillance Frequency         Control Programevery two weeks.

: d.                                                          77&deg; F, is greater than or equal to The pilot cell specific gravity, corrected to 77&deg;F, 1.190.

: 2.      Quarterly Surveillance will be performed at the frequency specified in the Quarterly Surveillance Frequency Control Program to verify the specific gravity for each Surveillance fourth cell is greater than or equal to 1.190 when corrected to 77&deg;F. The specific and electrolyte temperature of every fourth cell shall be recorded for gravity and gravity review.

surveillance review.

: 3. Annual Surveillance will be performed at the frequency specified in the Frequency Control Program to verify the specific gravity for each Surveillance Frequency Surveillance is greater cell is cell      greater than or equal than or equal to 1.190 1.190 when corrected to 77&deg;F.77&deg; F. The electrolyte temperature and temperature      and specific   gravity for every cell shall be recorded for surveillance specific gravity review.

review.

OYSTER CREEK OYSTER      CREEK                                  4.7-1 4.7-1                                   144,189,197, 227, 236,245 Amendment No.: 144,189,197,227,236,245 Corrected by letter of 10/15/2004 Cerrected

: 4. At the frequency specified in the Surveillance Frequency Control ProgramAt least once per 12 months, the diesel generator battery capacity shall be demonstrated to be able to supply the design duty loads (diesel start) during aa battery service test.

: 5.      At the frequency specified in the Surveillance Frequency Control ProgramAt least once per 24 months, the following tests will be performed-(perform during plant shutdowns or during 2l-month 24 month Diesel Generator inspections):