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| number = ML18304A330
| number = ML18304A330
| issue date = 10/25/2018
| issue date = 10/25/2018
| title = Surry Power Station Units 1 & 2 - Proposed License Amendment Request TSTF-490 & Update of Alternative Source Term Analyses Response to Request for Additional Information & Revised Proposed Technical Specifications
| title = Proposed License Amendment Request TSTF-490 & Update of Alternative Source Term Analyses Response to Request for Additional Information & Revised Proposed Technical Specifications
| author name = Bischof G T
| author name = Bischof G T
| author affiliation = Virginia Electric & Power Co (VEPCO)
| author affiliation = Virginia Electric & Power Co (VEPCO)

Revision as of 22:00, 30 January 2019

Proposed License Amendment Request TSTF-490 & Update of Alternative Source Term Analyses Response to Request for Additional Information & Revised Proposed Technical Specifications
ML18304A330
Person / Time
Site: Surry  Dominion icon.png
Issue date: 10/25/2018
From: Bischof G T
Virginia Electric & Power Co (VEPCO)
To:
Document Control Desk, Office of Nuclear Reactor Regulation
References
18-069A
Download: ML18304A330 (53)


Text

VIRGINIA ELECTRIC AND POWER COMPANY RICHMOND, VIRGINIA 23261 October 25, 20118 U. S. Nuclear Regulatory Commission Attention:

Document Control Desk Washington, DC 20555-0001 VIRGINIA ELECTRIC AND POWER COMPANY SURRY POWER STATION UNITS 1 AND 2 PROPOSED LICENSE AMENDMENT REQUEST Serial No.: NRA/GDM: Docket Nos.: License Nos.: 10CFR50.90 18-069A RO 50-280 50-281 DPR-32 DPR-37 TSTF-490 AND UPDATE OF ALTERNATIVE SOURCE TERM ANALYSES RESPONSE TO REQUEST FOR ADDITIONAL INFORMATION AND REVISED PROPOSED TECHNICAL SPECIFICATIONS PAGES By letter dated March 2, 2018 (Agencywide Documents Access and Management System (ADAMS) Accession Number ML 18075A021), Virginia Electric and Power Company (Dominion Energy Virginia) requested changes to the Technical Specifications (TS) for Surry Power Station Units 1 and 2 (SPS). The proposed changes would adopt TS Task Force (TSTF) Traveler, TSTF-490, Revision 0, "Deletion of E Bar Definition and Revision to RCS [reactor coolant system] Specific Activity Tech Spec," dated September 13, 2005 (ADAMS Accession No. ML052630462) and would update the Alternative Source Term (AST) analyses.

The proposed changes would replace the current limits on primary coolant gross specific activity, which is based on E-Bar (E) average disintegration energy, with a new limit for RCS noble gas specific activity.

The noble gas specific activity limit would be based on a new dose equivalent Xenon-133 definition that replaces the current E average disintegration energy. By email dated September 25, 2018, the Nuclear Regulatory Commission (NRG) staff provided a request for additional information (RAI) to complete their review. The NRG request and Dominion Energy Virginia's response are provided in Attachment 1 to this letter. In preparing this response, we determined the license amendment request (LAR) as originally proposed requires revision to address NRG RAI questions ARCB-RAl-1 and ARCB-RAl-2.

The required revision is discussed in Attachment 1, and the revised, marked-up and typed proposed TS and TS Bases pages are provided in Attachments 2 and 3, respectively.

The proposed marked-up and typed TS and TS Bases pages are being provided in their entirety with the revisions made as a result of the RAI responses indicated by double revision bars in the right hand margin of the revised pages. The associated TS Basis changes are included for information.

The information provided in this letter does not affect the conclusions of the significant hazards consideration or the environmental assessment included in the March 2, 2018 LAR.

Serial No. 18-069A Docket Nos. 50-280/281 Page 2 of 3 Should you have any questions or require additional information, please contact Mr. Gary D. Miller at (804) 273-2771.

Respectfully, t!!?.c~ Senior Vice President-Nuclear Operations

& Fleet Performance Commitments contained in this letter: None Attachments:

1. Response to NRC Request for Additional Information, Proposed Changes Associated with TSTF-490 and Updated Alternative Source Term Analyses 2. Revised Marked-up Technical Specifications and Bases Pages 3. Revised Proposed Technical Specifications and Bases Pages COMMONWEAL TH OF VIRGINIA ) ) COUNTY OF HENRICO ) The foregoing document was acknowledged before me, in and for the County and Commonwealth aforesaid, today by Mr. Gerald T. Bischof, who is Senior Vice President

-Nuclear Operations

& Fleet Performance of Virginia Electric and Power Company. He has affirmed before me that he is duly authorized to execute and file the foregoing document in behalf of that company, and that the statements in the document are true to the best of his knowledge and belief. Acknowledged before me this .2'5~ day of De;JoJ,e,: , 2018. My Commission Expires: Ja.n 3 \ 2.b 2 2 . CHERYLANN KELLY Notaiy Public Commonwealth of Virginia Registration No. 176425 My Commission Expires Jan 31. 2022

\ cc: U.S. Nuclear Regulatory Commission

-Region II Marquis One Tower 245 Peachtree Center Avenue, NE Suite 1200 Atlanta, GA 30303-1257 State Health Commissioner Virginia Department of Health James Madison Building -J1h floor 109 Governor Street Suite 730 Richmond, VA 23219 Ms. Alina Schiller NRC Project Manager -Surry U.S. Nuclear Regulatory Commission One White Flint North Mail Stop 07 E-5 11555 Rockville Pike Rockville, MD 20852-2738 Mr. James R. Hall NRC Senior Project Manager -North Anna U.S. Nuclear Regulatory Commission One White Flint North Mail Stop 08 G-9A 11555 Rockville Pike Rockville, MD 20852-2738 NRC Senior Resident Inspector Surry Power Station Serial No. 18-069A Docket Nos. 50-280/281 Page 3 of 3

\ Attachment 1 Serial No. 18-069A Docket Nos. 50-280/281 RESPONSE TO REQUEST FOR ADDITIONAL INFORMATION PROPOSED CHANGES ASSOCIATED WITH TSTF-490 AND UPDATED ALTERNATIVE SOURCE TERM ANALYSES Virginia Electric and Power Comp,any (Dominion Energy Virginia)

Surry Power Station Units 1 and 2 Serial No. 18-069A Docket Nos. 50-280/281 RESPONSE TO REQUEST FOR ADDITIONAL INFORMATION PROPOSED CHANGES ASSOCIATED WITH TSTF-490 AND UPDATED ALTERNATIVE SOURCE TERM ANALYSES SURRY POWER STATION UNITS 1 AND 2 NRC Comment: By letter dated March 2, 2018 (Agencywide Documents Access and Management System (ADAMS) Accession Number ML 18075A021), Virginia Electric and Power Company (Dominion Energy Virginia) the licensee, requested changes to the Technical Specifications (TS) for Surry Power Station Units 1 and 2 (SPS). The licensee requested to adopt Technical Specifications Task Force (TSTF) Traveler, TSTF-490, Revision 0, "Deletion of E Bar Definition and Revision to RCS [reactor coolant system] Specific Activity Tech Spec," dated September 13, 2005 (ADAMS Accession No. ML052630462) and update the Alternative Source Term (AST) analyses.

The proposed changes would replace the current limits on primary coolant gross specific activity which is based on E-Bar (E) average disintegration energy with a new limit for RCS noble gas specific activity.

The noble gas specific activity limit would be based on a new dose equivalent Xenon-133 definition that replaces the current E average disintegration energy. During the Nuclear Regulatory Commission (NRC) staff's review of the license amendment request the NRC staff determined that more information was needed to complete the review. Regulatory Analysis Basis 1. Title 10 of the Code of Federal Regulations (10 CFR) Part 50.67, "Accident Source Term," allows licensees seeking to revise their current accident source term in design basis radiological consequence analyses to apply for a license amendment under § 50.90. The application shall contain an evaluation of the consequences of applicable design basis accidents previously analyzed in the safety analysis report. Section 50.67(b)(2) requires . that the licensee's analysis demonstrates with reasonable assurance that: (i) An individual located at any point on the boundary of the exclusion area for any 2-hour period following the onset of the postulated fission product release, would not receive a radiation dose in excess of 0.25 Sv (25 rem) total effective dose equivalent (TEDE). (ii) An individual located at any point on the outer boundary of the low population zone, who is exposed to the radioactive cloud resulting from the postulated fission product release (during the entire period of its passage), would not receive* a radiation-dose in excess of 0.25 Sv (25 rem) TEDE. Page 1 of 12 Serial No. 18-069A Docket Nos. 50-280/281 (iii) Adequate radiation protection is provided to permit access to and occupancy of the control room under accident conditions without personnel receiving radiation exposures in excess of 0.05 Sv (5 rem) TEDE for the duration of the accident.

2. NUREG-0800, standard review plan (SRP) Section 15.0.1, "Radiological Consequences Analyses Using Alternative Source Terms," Revision 0, July 2000. 3. Regulatory Guide (RG) 1.183, "Alternative Radiological Source Terms for Evaluating Design Basis Accidents at Nuclear Power Reactors," July 2000 (ADAMS Accession No. ML003716792). . ARCB-RAl-1 In the license amendment request, the licensee proposed TS changes to revise TS 3.1.0 applicability requirements to specify that TS 3.1.0 is applicable whenever average reactor coolant system temperature exceeds 200°F. In addition, the licensee also proposed to revise Note (5) of TS Table 4.1-2B, "Minimum Frequencies for Sampling Tests," to state, "Only required when the unit is in POWER OPERATION," thus not requiring the surveillance requirements to be performed whenever TS 3.1.0 is required.

The proposed change revises the conditions for sampling, and may exclude sampling during the plant conditions where TS 3.1.D may be exceeded.

After transient conditions (i.e., reactor trip, plant depressurization, shutdown or startup) that end in REACTOR CRITICAL, HOT SHUTDOWN, or INTERMEOIA TE SHUTDOWN, the surveillance requirements are not required to be performed.

Isotopic spiking and fuel failures are more likely during transient conditions than during steady state plant operations.

Because TS 3. 1. D could potentially be exceeded after plant transient or power changes, please justify why sampling is no longer needed in the reactor operations that are proposed to be eliminated and justify how the TS 3. 1. D remains consistent with the design bases analysis from which the TS limits are derived (i.e., main steam line break, steam generator tube rupture, etc.). Furthermore, please justify why there is an apparent disparity between the TS applicability (average reactor coolant system temperature exceeds 200°) and the limited mode (POWER OPERATION) under which the surveillance is required.

Dominion Energy Virginia Response The proposed revision to Note (5) of TS Table 4.1-28; "Minimum Frequencies for Sampling Tests," to state, "Only required when the unit is in POWER OPERATION," is no longer being requested.

The intent of the proposed Note (5) revision was to permit unit startup to POWER OPERATION prior to performing the associated sampling tests since a main steam line break or steam generator tube rupture would not be expected to occur during startup conditions.

However, as noted in the RAI question, after Page 2 of 12 Serial No. 18-069A Docket Nos. 50-280/281 transient conditions that end in REACTOR CRITICAL, HOT SHUTDOWN, or INTERMEDIATE SHUTDOWN, isotopic spiking and fuel failures are more likely to occur than during steady state plant operations.

Consequently, a new Note (4) has been specified for the DOSE EQUIVALENT 1-131 and DOSE EQUIVALENT XE-133 sampling test frequencies and defined in the table as requiring the sampling test requirements to be performed "Whenever Tavg (average RCS temperature) exceeds 200°F," which is consistent with the TS 3.1.D applicability and addresses transient conditions.

ARCB-RAl-2 In the license amendment request, the licensee proposes to revise Note (5) of TS Table 4.1-28 to state, "Only required when the unit is in POWER OPERATION," as discussed above in ARCB-RAl-2.

However, Note (5) applies to more than the proposed DEi and DEX surveillance requirements, it also applies to the Radio-Chemical Analysis ahd the Tritium Activity tests. TSTF-490 only changed the surveillance requirements associated with DEi and DEX, it did not include any other surveillance requirement changes and it did not provide a technical basis for other surveillance changes. Therefore, provide a technical justification that explains why the surveillance . requirements for the Radio-Chemical Analysis and the Tritium Activity tests should be reduced from "When reactor is critical and average primary coolant temperature 350°F," to "Only required when the .unit is in POWER OPERATION." Dominion Energy Virginia Response It was not recognized during the development of the License Amendment Request (LAR) that revised Note (5) was also applicable to the Radio-Chemical Analysis and Tritium Activity sampling tests. As noted in the response to ARCB-RAl-1 above, the proposed revision to Note (5) of TS Table 4.1-28 is no longer being requested.

As such, Note (5) will remain as currently written; therefore, the Radio-Chemical Analysis and the Tritium Activity sampling tests are no longer affected by the proposed LAR. ARCB-RAl-3 In the license amendm_ent request, the licensee states in the TS bases for the dose equivalent Xe-133 surveillance requirement that the measurement is the sum of the degassed gamma activities and-gaseous gamma activities in the sample taken or equivalent sampling method. Equivalent sampling methods were not discussed in TSTF-490 and were not reviewed or approved by the NRG staff. The addition of this wording is ,P variation from TSTF-490.

Therefore, provide in detail the sampling methods that will be used at SPS and explain how they are equivalent to those discussed in TSTF-490.

Page 3 of 12 Dominion Energy Virginia Response Serial No. 18-069A Docket Nos. 50-280/281 RCS radioactive gas analysis can be performed using a stripped gas testing rig that physically strips the gas from the liquid phase by pumping air through the sample in a closed loop. However, this method of analyzing stripped gas is cumbersome and time consuming and results in higher dose exposure for the chemistry technicians testing the samples. Consequently, the SPS Chemistry Department uses a simpler yet equally effective method of analyzing radioactive RCS gases. Specifically, SPS uses a pressurized U-tube sample rig for obtaining optimum radioactive gas test results. The pressurized gas rig consists of thirty centimeters of 3/8" stainless steel tubing with a Swagelok valve installed at each end. The tubing is rated for 6,500 psig and is therefore suitable for withstanding full RCS pressure.

The tubing is bent into a U shape for optimal placement on the Canberra multichannel analyzer.

The total volume of the U-tube is 11.3 milliliters (ml) including*

the valves. The samples are delayed by 45 minutes prior to counting to effect lower background radiation.

The samples are also counted for 30 minutes, as opposed to the 10-minute counting time used in the gas stripping method, to increase the sensitivity of the U-tube method. The U-tube rig was evaluated to ensure reliable and accurate results could be obtained.

A comparison of the results between the stripped gas method and the pressurized U-tube method of analysis was performed to ensure consistent results were obtained between the two methods. As stated in the EPRI Fuel Reliability Monitoring and Evaluation Handbook, Revision 2 (2010), page 6-2, "A few sites count the pressurized sample directly.

This has the advantage of both simplicity and a short decay period for short-lived nuclides.

The disadvantages are a complex spectrum and reduced sensitivity for lower energy gamma rays due to gamma ray adsorption in the water and wall of the sample cylinder.

This is particularly true for the 81 keV gamma energy of Xe-133. (The 0.093 inch wall of a 1800 psig rated D.O.T cylinder will absorb 67% of the incident 81 keV photons.)" Consequently, one of the primary concerns noted in the EPRI guidance associated with using a pressurized sample method, such as the U-tube test rig, is the attenuation of Xe-133 due to its low energy gamma (81 KeV). Since Xe-133 has the lowest energy gamma of the gas isotopes of concern, it was used for the primary comparison between the two analysis methods for sensitivity and measurement accuracy.

One item that was examined was the minimum detectable amount (MDA) value of the stripped gas analysis method versus the U-tube analysis method. The results of a Unit 2 sample comparison of the MDA of Xe-133 using the stripped gas analysis and the U-tube analysis methods was 4.13E-4 versus 3.46E-4 µCi/ml, respectively.

Therefore, the U-tube analysis MDA was lower than the stripped gas analysis MDA, which indicates the U-tube analysis method is more sensitive to Xe-133 than the stripped gas method. Page 4 of 12 Serial No. 18-069A Docket Nos. 50-280/281 A Unit 1 sample was also taken using each analysis method and the results compared to ensure Xe-133 was being accurately measured when above MDA values. The result using the stripped gas method _was 1.86E-3 µ/ml and the U-tube method was 1.31 E-3 µ/ml. This difference between the two values was determined to be an acceptable variation in the sample results between the two methods as it was consistent with the variations seen between sample results that were run on a weekly basis using just the stripped gas analysis method. A comparison of the other remaining radioactive gas isotopes was also performed and, while there were small differences noted in the samples, they were likewise determined to be acceptable and consistent with variations between samples run on a weekly basis using only the stripped gas analysis method. In summary, the pressurized gas U-tube analysis method is simpler to perform, results in reduced dose to the sampling technicians, and provides sample results that are consistent with those obtained using the stripped gas method and is therefore an acceptable and equivalent sampling method. ARCB-RAl-4 In the license amendment request, the proposed change deletes the current gross activity, E determination, and radio iodine analysis tests and replaces them with a new surveillance to verify DEX is less than the new limit.

Therefore, discuss in detail the gross activity, E determination, and radio iodine analysis surveillance tests at SPS. Provide a comparison to the SRs in TSTF-490 and explain any differences.

In addition, provide the technical basis for the deletion of the radio iodine analysis test at SPS. Dominion Energy Virginia Response See the Table below for a comparison of the RCS sample analysis Surveillance Requirements in the NUREG-1431 Westinghouse STS to the SPS custom TS and the basis for elimination of the SPS TS SRs being subsumed by the proposed TS changes. Page 5 of 12 Sampling Test Gross Activity Serial No. 18-069A Docket Nos. 50-280/281 TABLE: COMPARISON OF ANALYSIS SURVEILLANCE REQUIREMENTS NUREG-1431 SPSTS Difference Basis for Elimination Westinghouse ISTS As discussed in the SR TS Table 4.1-28/SFCP, Item The Westinghouse SR measurement of total specific 3.4.16.1 Bases, the 1, includes:

ISTS require a activity (100/ E) and gross degassed surveillance requirement

1. The requirement to quantitative measure of activity at SPS is being performed for requires "performing a degassed and gaseous the same purpose and in only a slightly gamma isotopic analysis perform a Gross Degassed activities every 7 days. different manner than the -as a measure of the gross Activity test 5 days per The SPS TS require Westinghouse ISTS. Furthermore, the specific activity of the week. Associated Table the quantitative measurement of gross activity in both reactor coolant. While Note 2 states, "A gross beta measure of the cases is directly tied to E basically a quantitative gamma degassed activity degassed and gaseous determination, and the requirement for measure of radionuclides analysis shall consist of the activities semiannually performing E determination is being with half-lives longer than quantitative measurement of and additionally require removed from the TS for the reasons 15 minutes, excluding the total radioactivity of the a Gross Degassed noted in TSTF-490, which includes the iodines, the measurement primary coolant in units of Activity 5 days per implementation of the DOSE is the sum of the degassed µCi/cc". week. EQUIVALENT (DE) XE-133 SR. gamma activities and the 2. The requirement to Therefore, the Gross Activity sample gaseous gamma activities perform E Determination test is no longer required and can be in the sample taken. The semiannually which would eliminated consistent with the Surveillance provides an include calculating E and reasoning provided in TSTF-490.

indication of any increase 100/ E. in gross specific activity.

Current TS 3.1.D.1 requires The surveillance the total specific activity of requirement specifically the reactor coolant due to half-lives of more than 15 requires verification that minutes shall not exceed the reactor coolant gross 100/E µCi/cc. specific activity 100/E µCi/gm on a 7 Day frequency or in accordance with the SFCP. Page 6 of 12 Sampling Test NUREG-1431 Westinghouse ISTS The Westinghouse ISTS defines the "E -AVERAGE DISINTE-GRATION ENERGY" in Section 1.1, Definitions, as follows: "E shall be the average (weighted in proportion to the concentration of each radionuclide in the reactor coolant at the time of sampling) of the sum of the average beta and gamma energies per E-Bar disintegration (in MeV) Determination for isotopes, other than iodines, with half lives greater than [15] minutes, making up at least 95% of the total non-iodine activity in the coolant." SR 3.4.16.3 requires determination of E from a sample taken in Mode 1 after a minimum of 2 effective full power days and 20 days of Mode 1 operation have elapsed since the reactor was last subcritical for~ 48 hours5.555556e-4 days <br />0.0133 hours <br />7.936508e-5 weeks <br />1.8264e-5 months <br />. SPSTS The same definition for E contained in the Westinghouse ISTS is contained in the SPS TS 3.1 Bases, page 3.1-17. TS Table 4.1-2B, Item 1, includes the requirement to perform an E determination.

Associated Table Note 3 states, "E determination will be started when the gross gamma degassed activity of radionuclides with half-lives greater than 15 minutes analysis indicates~

10 µCi/cc. Routine sample(s) for E analysis shall only be taken after a minimum of 2 EFPD and 20 days of power operation have elapsed since reactor was last subcritical for 48 hours5.555556e-4 days <br />0.0133 hours <br />7.936508e-5 weeks <br />1.8264e-5 months <br /> or longer. Page 7 of 12 Difference None Serial No. 18-069A Docket Nos. 50-280/281 Basis for Elimination The E determination surveillance requirement in the SPS TS uses the same definition and is being performed for the same purpose as the Westinghouse ISTS. The requirement for performing E determination is being removed from the SPS TS for the reasons noted in TSTF-490, which includes the implementation of the DE XE-133 surveillance requirement.

Therefore, the E determination surveillance requirement is no longer required and can be eliminated consistent with the reasoning provided in TSTF-490.

Sampling Test NUREG-1431 SPSTS Westinghouse ISTS SR 3.4.16.2 requires the Table 4.1 :.2B/SFCP requires verification of reactor the following:

coolant DEl-131 specific 1. The DEl-131 specific activity .:s_ 1.0 µCi/gm every 14 days and between 2 activity be performed and 6 hours6.944444e-5 days <br />0.00167 hours <br />9.920635e-6 weeks <br />2.283e-6 months <br /> after Once/2 weeks, and THERMAL POWER 2. Radio-iodine Analysis change of >=15% RTP (including 1-131, 1-133 & I-within a 1 hour1.157407e-5 days <br />2.777778e-4 hours <br />1.653439e-6 weeks <br />3.805e-7 months <br /> period. 135) once every 4 hours4.62963e-5 days <br />0.00111 hours <br />6.613757e-6 weeks <br />1.522e-6 months <br /> whenever the specific activity exceeds 1.0 µCi/cc Radio-iodine DEl-131 or 100/E µCi/cc and Analysis until the specific activity of the Reactor Coolant System is restored within its limits AND one sample between 2 & 6 hours6.944444e-5 days <br />0.00167 hours <br />9.920635e-6 weeks <br />2.283e-6 months <br /> following a THERMAL POWER change exceeding 15 percent of RATED POWER within a one hour period provided the average primary coolant temperature

>350°F. Page 8 of 12 Difference SPS TS separate DEi-131 and Radio-iodine analysis as two different line items whereas the Westinghouse ISTS combines the requirements under DEl-131. Serial No. 18-069A Docket Nos. 50-280/281 Basis for Elimination When performing DEl-131 analysis, 1-131 thru 1-135 are used in the calculation.

This meets the requirements for radio-iodine analysis as currently stated in the SPS TS. The requirements currently in the SPS TS for radio-iodine analysis are incorporated into the proposed DEi-131 surveillance requirement in the proposed SPS TS revision, and can therefore be deleted as a separate test.

ARCB-RAl-5 Serial No. 18-069A Docket Nos. 50-280/281 10 CFR 50.67(b)(2) requires that the licensee's analyses demonstrate with reasonable assurance that adequate radiation protection is provided to permit access to and occupancy of the control room under accident conditions without personnel receiving radiation exposures in excess of 5 rem total effective dose equivalent for the duration of the accident.

In the license amendment request, the resultant radiation dose associated with occupancy of the control room has been provided.

However, the license amendment request is missing a discussion and/or calculation that accounts for the control room personnel radiation exposure received, for the duration of the accidents, upon ingress/egress from the site boundary to the control room. In order to meet 10 CFR 50. 67 the radiation dose for accessing the control room must be evaluated from the site boundary to the control room for both ingress and egress for the duration of the accidents.

Provide an analysis of the radiation dose received from ingress and egress to the control room in enough detail that will enable the NRG staff to be able to perform an independent calculation.

Dominion Energy Virginia Response Control room occupancy is modeled as 100% of the time during the first 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> of a LOCA event. Therefore, transit to and from the control room is only expected after the first 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> following an accident.

During the 30-day event, a total of 30 round trips between the site boundary and the control room were modeled with a conservative way transit time of 30 minutes. This leads to a conservative total of 30 hours3.472222e-4 days <br />0.00833 hours <br />4.960317e-5 weeks <br />1.1415e-5 months <br /> of ingress/egress transit time per individual during the event. The containment building returns to a subatmospheric condition in the first 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br />, preventing any containment airborne release contribution to ingress/egress dose. Additionally, NUREG-0737, Item 11.B.2, "Plant Shielding," states that leakage of systems outside containment need not be considered as potential sources. The only remaining contributor to personnel dose during ingress/egress is the direct radiation exposure from the sources within the containment building.

Direct radiation exposure from the containment was modeled using the RADTRAD radioisotope inventories in the sprayed and unsprayed regions of the containment building at 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br />. The MicroShield shielding package was used to determine the resulting dose rate. The containment building was modeled as a right circular cylinder of air with a diameter of 126 feet and a height of 65.5 feet. The height of the cylinder represents the distance from ground level to the top bf the cylindrical portion of the containment building.

The air cylinder is surrounded by a radial concrete shield with a thickness of 4.5 feet and the concrete shield is surrounded by air. The default Page9of12 Serial No. 18-069A Docket Nos. 50-280/281 MicroShield densities of 2.35 glee for concrete and 0.0122 glee for air were used. The radioisotope inventories were uniformly distributed within the cylinder of air representing the containment building.

The dose rate for ingress/egress was determined at a point coplanar with the bottom surface of the cylindrical source and at a radial distance of 183.6 feet from the centerline of the containment building, representing an estimate of the closest point of approach during ingress/egress.

The resulting dose rate, with buildup, at the closest point of approach to the containment building was 0.3 mrem/hr, resulting in a conservative accumulated dose of 9 mrem during 30 hours3.472222e-4 days <br />0.00833 hours <br />4.960317e-5 weeks <br />1.1415e-5 months <br /> of ingress/egress transit. Given the calculated control room dose of 4.4 rem during the LOCA, the accumulated ingress/egress dose is a negligible contribution.

ARCB-RAl-6 The license amendment request proposes to increase the iodine speciation above the water in the fuel handling accident from 57 percent elemental and 43 percent organic iodide to 70 percent elemental and 30 percent organic iodide to align with draft regulatory guide 1.183 revision 1 (DG-1199).

OG-1199 states that the difference in decontamination factors for elemental and organic iodine species results in the iodine above the water being composed of 70 percent elemental and 30 percent organic species for release pressures that remain less than 1,200 pounds per square inch gauge. However, the release pressure was not discussed in -the license amendment request. Discuss if SPS release pressures remain less than 1,200 pounds per square inch gauge for the fuel handling accident.

Dominion Energy Virginia Response Refueling can begin 100 hours0.00116 days <br />0.0278 hours <br />1.653439e-4 weeks <br />3.805e-5 months <br /> after shutdown (Technical Specification 3.1 O.A.9) with the RCS < 140°F (REFUELING SHUTDOWN Technical Specification 1.C.1 ). Dominion Energy Virginia's fuel vendors have verified that rod internal pressure will be <1200 psig under the conditions of the fuel handling accident (:5100 hours after shutdown, water temperature 2:: 140°F, and fuel rod burnup of 62,000 MWD/MTU).

ARCB-RAl-7 The current licensing basis at SPS assumes that the control room is manually isolated at time O based on identification that a fuel handling accident (FHA) has occurred and a 2 minute time critical operator action which accomplishes manual isolation of the control room. Page 10 of 12 Serial No. 18-069A Docket Nos. 50-280/281 The licensee proposes to extend the time critical operator action to isolate the control room after initiation of the FHA from 2 minutes to 12 minutes. The proposed change also includes 20 seconds for the control room dampers to close after the time critical operator action. The licensee states that in order to accommodate the increase in time critical operator action and damper closure, the control room isolation is modeled as occurring at 10 minutes and 20 seconds or 0. 1722 hours0.0199 days <br />0.478 hours <br />0.00285 weeks <br />6.55221e-4 months <br /> and therefore, the control room isolation is changing from O hours to 0. 1722 hours0.0199 days <br />0.478 hours <br />0.00285 weeks <br />6.55221e-4 months <br />. However, there seems to be a disconnect between the modeling which assumes isolation of the control room at 10 minutes and 20 seconds and the operator actions which would isolate the control room at 12 minutes. This appears to be non-conservative in that the radiological dose received by the control room operators would be higher than that calculated by the model. From the information supplied in the application, it appears that the modeling should isolate the control room at 12 minutes and 20 seconds to be consistent with the proposed time critical operator action or the proposed time critical operator action should be limited to 10 minutes to be consistent with the modeling.

Explain how the control room isolation modeling and the time critical operator action are consistent with each other. Dominion Energy Virginia Response The current design and licensing basis for the FHA is the control room is isolated prior to the plume reaching the control room normal ventilation intake. This is modeled as isolation at t=O hours in the RADTRAD code. Isolation timing is currently based on a 2-minute time critical operator action and a calculation that determined that plume travel is 2 minutes from the release location to the control room normal intake. The RADTRAD model does not include the 2 minute plume travel time. The proposed design and licensing basis for the FHA models isolation at 10 minutes and 20 seconds, as described above, which includes 20 seconds for damper operation after the operator action is completed.

However, the sequence of events still includes the 2 minute time for plume travel. Therefore the operator action is accomplished in 12 minutes from the drop of the fuel assembly and 10 minutes after the plume reaches the normal intake. The modeling of control room isolation and the time critical operator action are therefore consistent and correct. ARCB-RAl-8 The current Steam Generator Tube Rupture (SGTR) licensing basis at SPS assumes that the control room in leakage is either 10 cubic feet per minute (cfm) or 500 cfm. In the license amendment request the licensee proposes to change the SGTR control room in leakage to O cfm or 250 cfm and the stated reason for the change is maximum ASTM E741 tracer gas test equals 147 +/- 6 cfm. An assumed control room in leakage of Page 11 of 12 Serial No. 18-069A Docket Nos. 50-280/281 O cfm does not appear to be consistent with the tracer gas test result. Explain how the most recent tracer gas test supports a control room in leakage of O cfm and explain why two different control room in leakages are used in the SGTR analysis.

Dominion Energy Virginia Response The limiting SGTR control room dose consequences were determined for the accident iodine spike with offsite power available.

Under these conditions the normal ventilation system keeps operating and control room isolation is delayed until the Safety Injection (SI) signal plus 20 seconds for damper operation.

As a result of the normal ventilation system high flow rate, delayed isolation, and the early availability for release of the pre-accident spike, the control room dose results increase with decreasing unfiltered inleakage as shown below. Assumed Unfiltered SGTR Control Room Dose In leakage Pre-accident Spike Power Available cfm Rem TEDE 500 0.538 250 0.582 10 0.647 0 0.650 Therefore, as long as measured unfiltered inleakage is =:: 0 cfm, the pre-accident spike remains bounded. The trend does not occur in the concurrent iodine spike cases or the pre-accident spike case with loss of offsite power. These cases were analyzed with up to 250 cfm of unfiltered inleakage and demonstrated an increase in dose with increasing unfiltered inleakage.

Therefore, as long as measured unfiltered inleakage is ::5 250 cfm the concurrent iodine spike and pre-accident spike with loss of offsite power remain bounded. Page 12 of 12 Attachment 2 Serial No. 18-069A Docket Nos. 50-280/281 REVISED MARKED-UP TECHNICAL SPECIFICATIONS PAGES Virginia Electric and Power Company (Dominion Energy Virginia)

Surry_Station Units 1 and 2 Replace with Insert M TS 1.0-5 01 25 94 K. FIRE SUPPRESSION WATER SYSTEM A fire suppression water system shall consist of: a water source(s), gravity tank(s) or pump(s), and distribution piping with associated sectionalizing control or isolation valves. Such valves shall include yard hydrant curb valves, and the first valve ahead of the water flow alarm device on each sprinkler, hose standpipe, or spray system riser. L. OFFSITE DOSE CALCULATION MANUAL (ODCM) M. An Offsite Dose Calculation Manual (ODCM) shall contain the methodology and parameters used in the calculation of offsite doses resulting from radioactive gaseous and liquid effluents, in the calculation of gaseous and liquid effluent monitoring Alarm/Trip Setpoints , and in the conduct of the Radiological Environmental Monitoring Program. The ODCM shall also contain (I) the Radioactive Effluent Controls and Radiological Environmental Monitoring Programs required by Section 6.4 and (2) descriptions of the information that should be included in the Annual Radiological Environmental Operating and Annual Radioactive Effluent Release Reports required by Specifications 6.6.B.2 and 6.6.B.3. v1hieh ttloHe wottld prodttee the sttffle thyroid dose tt s the qttttHtity ttHd isotopie HHxtttre ofl 131 , I 132 , I 133 , I 134 , ttHd I 135 ttetttttlly preseHt. The thyroid dose eoHversioH fttetor s ttsed for this ettlettltttioH shttll l:le those listed iH Tul:lle III of TID 14844 , " CttlettltttioH of DistttHee Fttetors for Po*uer ttHd Test Rettetor Sites" or iH P.tRC Regttltttory Gttide 1.109 , RevisioH 1 , Oetoeer 1977. N. GASEOUS RADWASTE TREATMENT SYSTEM A gaseous radwaste treatment system is any system designed and installed to reduce radioactive gaseous effluents by collecting primary coolant system offgases from the primary system and providing for delay or holdup for the purpose of reducing the total radioactivity prior to release to the environment.

Amendment Nos. 185 ttHd 185 INSERT M DOSE EQUIV AL ENT 1-131 shall be that concentration of 1-131 (microcuries per gram) that alone would produce the same dose when inhaled as the combined activities of iodine isotopes 1-131 , 1-132 , 1-133 , 1-134 , and 1-135 actually present. The determination of DOSE EQUIVALENT 1-131 shall be performed using Committed Effective Dose Equivalent (CEDE) dose conversion factors from Table 2.1 of EPA Federal Guidance Report No. 11.

W. STAGGERED TEST BASIS A staggered test basis shall consist of: TS 1.0-8 03 29 07 a. A test schedule for n systems, subsystems, trains or other designated components obtained by dividing the specified test interval into n equal subintervals, and b. The testing of one system, subsystem, train, or other designated component at the beginning of each subinterval.

X. LEAKAGE LEAKAGE shall be: a. Identified LEAKAGE 1. LEAKAGE, such as that from pump seals or valve packing ( except reactor coolant pump (RCP) seal water injection or leakoff), that is captured and conducted to collection systems or a sump or collecting tank, 2. LEAKAGE into the containment atmosphere from sources that are both specifically located and known either not to interfere with the operation of leakage detection systems or not to be pressure boundary LEAKAGE, or 3. Reactor Coolant System (RCS) LEAKAGE through a steam generator to the Secondary System (primary to secondary LEAKAGE);

b. Unidentified LEAKAGE All LEAKAGE (except RCP seal water injection or leakoff) that is not identified LEAKAGE, and c. Pressure Boundary LEAKAGE LEAKAGE (except primary to secondary LEAKAGE) through a nonisolable fault in an RCS component body , pipe wall, or vessel wall. Amendment Nos. 251 aRd 250 INSERT Y Y. DOSE EQUIVALENT XE-133 DOSE EQUIVALENT XE-133 shall be that concentration of Xe-133 (microcuries per gram) that alone would produce the same acute dose to the whole body as the combined activities of noble gas nuclides Kr-85m , Kr-85 , Kr-87 , Kr-88 , Xe-131m , Xe-133m , Xe-133 , Xe-135m , Xe-135 , and Xe-138 actually present. If a specif i c noble gas nuclide i s not detected , i t should be assumed to be present at the minimum detectab l e act i vity. The determ i nat i on of DOSE EQUIVALENT XE-133 sha ll be perfo r med using effective dose conversion factors for a i r subme r sion l i sted i n Table 111.1 of EPA Federal Guidance Report No. 12 , 1993 , "External Exposure to Radionuclides in A i r , Water , and Soil."

D 8):)eeifieatioHs TS 3.l-15a 03 29 0 7 -h The total speeifie aetivity of t!te reaetor eoolaHt dHe to HHelides with half li,*es of fflore th1m 15 HHHHtes shall Hot exeeed 100/E µCi/ee wheHever t!te reaetor is eritieal or the average teIHperamre i s greater t!taH 500°F , where E i s the average S liffl of t!te aeta aHd glifflffla eHergie s , iH Mev , per di s iHtegratioH. If thi s liffl:it i s Hot s ati s fied , the reactor shall ae shHt dowH aHd eooled to 500°F or less ,vithiH 6 hoHr s after detectioH. 8h0t1ld t!tis liffl:it ae exceeded ay 25%, the reactor shall ae IHade sHaeritical aHd eoo}ed to 500°F Or Jess withiH 2 hottr S after deteetiOH. The s peeifie activity of the reactor eoolaHt s hall ae liffl:ited to 5 1.0 ~Ci,'ee D08E EQUIVALENT I 131 wheHever the reaetor is eritieal or the average teIHperatHre i s greater thaH 500°F. The reqHireffleHt s of D 2 aao*ve IHay ae modified to allo,v ilie specific activity of ilie reactor eoolaHt > 1.0 µCifee D08E EQUIVALEP.H I 131 aHt less thaH 10.0 t,tCilee D08E EQUIVALENT I 131. FollowiHg s htttdowH , the ttHit may ae re s tarted aHdfor operatioH ffltty eoHtiHtte for ttp to 48 hottr s provided that operatioH ttHder these eirettfflstaHees s hall Hot exeeed 10 pereeHt of the ttHit's total yearly operatiHg tiffle. With the specific activity of the reactor eoolaHt > 1.0 ~Ci/ee D08E EQUIVALENT I 131 for FHore thaH 48 hottr s dttriHg oHe eoHtiHttotts tiffle iHtenal or exeeediHg 10.0 ~Ci/ee D08E EQUIVALEP.H I 131 , t!te reactor shall ae s httt dowH aHd eooled to 500°F Of le s s withiH 6 hottrS after deteetiOH. 4-: If the speeifie aetiYity 6f the reactor eoolaHt exceed s 1.0 ~Ci,'ee B8SE EQUIVALEP.H I 131 or 100/ E µCi/ee , a report shall ae prepared aHd sttaffl:itted to the CoFHffli ss ioH pttrsttaHt to 8peeifieatioH 6.6.A.2. Thi s report shall eoHtaiH the re s ttlt s of ilie s pecific activity aH!tly s i s together *.viili the followiHg iHforfflatioH:

tt:-Reactor power history s tartiHg 48 hottr s prior to the fir s t s ftffl:ple iH which ilie liffl:it wa s exceeded , b:-CleaH ttp s y s teffl flow hi s tory s tartiHg 48 hottr s prior to the first s afflf)le iH whieh Replace with Insert 3.1.D Amendment Nos. 251 aHd 250 History of clegassiRg OJ:leratioRs , if aRy , startiRg 4 8 hot1rs f)rior to the first saffl:ele iR whieh the Hffl:it was e~,eeeaecl , th The tiffl:e cltlfatioR 1.vheR the SJ:leeifie aetiYity of the J:lriffl:ary eoolaRt eKeeeclecl 4-:G ttCifee D O§E: E:O U I VALE:NT I 131. . . 1 . is for racl10101Re fl . . 6. erfefffl:ecl flrior to Resttlts of the last isotof)te lifta ys . ...i=I *1 the liffl:it was eKeeeclecl , aRa rest1lts . . Its of liftalysts w H e . . eKeeecliRg the hHHt , rest1 . . cl cl to less thaR the hffitt. . cl. oiocliRe aettv1tv was re t1ee . of oRe aRa l vsts after the ra t . 1

  • g aRcl the raclioiocltRe E:aeh restt l t shot1lcl iRe l t1cle date aRcl ttffle of SBfflJ:l tfl P.AFIP.P.Flff'A~iAR/<

ARA f. GrliJ:lh of the I 131 eoReeRtratioR aRa oRe other raclioiocliRe isotof)e eoHeeHtrtttiOH iR tt:Ci/ee ttS ft fttRCtiOH of ttffle for the clttrtttioH of the SJ:leeifie aeti*,itv abtwe the 11teaav 11tate level. Amendment Nos.160 ttRcl 159 INSERT 3.1.D D. RCS Specific Activity Applicability The following specifications are applicable whenever Tavg (average RCS temperature) exceeds 200°F. Specification

1. The specific activity of the primary coolant shall be limited to ~1 µCi/gm DOSE EQUIVALENT 1-131. a. With the specific activity of the primary coolant> 1 µCi/gm DOSE EQUIVALENT 1-131 , verify DOSE EQUIVALENT 1-131 10 µCi/gm once per4 hours. b. With the specific activity of the primary coolant> 1 ~tCi/gm DOSE EQUIVALENT 1-131 , but~ 10 µCi/gm, unit startup or POWER OPERATION may continue for up to 48 hours5.555556e-4 days <br />0.0133 hours <br />7.936508e-5 weeks <br />1.8264e-5 months <br /> while efforts are made to restore DOSE EQUIVALENT 1-131 to~ 1 ~tCi/gm limit. c. With the specific activity of the primary coolant >1 ~tCi/gm DOSE EQUIVALENT 1-131 for more than 48 hours5.555556e-4 days <br />0.0133 hours <br />7.936508e-5 weeks <br />1.8264e-5 months <br /> during one continuous time interval or DOSE EQUIVALENT 1-131 is> 10 ~tCi/gm, place the reactor in HOT SHUTDOWN within 6 hours6.944444e-5 days <br />0.00167 hours <br />9.920635e-6 weeks <br />2.283e-6 months <br /> and COLD SHUTDOWN within the following 30 hours3.472222e-4 days <br />0.00833 hours <br />4.960317e-5 weeks <br />1.1415e-5 months <br />. 2. The specific activity of the primary coolant shall be limited to~ 234 µCi/gm DOSE EQUIVALENT XE-133. a. With the specific activity of the primary coolant >234 ~tCi/gm DOSE EQUIVALENT XE-133 , unit startup or POWER OPERATION may continue for up to 48 hours5.555556e-4 days <br />0.0133 hours <br />7.936508e-5 weeks <br />1.8264e-5 months <br /> while efforts are made to restore DOSE EQUIVALENT XE-133 to 234 µCi/gm limit. b. With the specific activity of the primary coolant> 234 µCi/gm DOSE EQUIVALENT XE-133 for more than 48 hours5.555556e-4 days <br />0.0133 hours <br />7.936508e-5 weeks <br />1.8264e-5 months <br /> during one continuous time interval , place the reactor in HOT SHUTDOWN within 6 hours6.944444e-5 days <br />0.00167 hours <br />9.920635e-6 weeks <br />2.283e-6 months <br /> and COLD SHUTDOWN within the following 30 hours3.472222e-4 days <br />0.00833 hours <br />4.960317e-5 weeks <br />1.1415e-5 months <br />. Amendments Nos. and Basi s TS 3.1-16 08 03 95 The speeifieEl lifflit pFe v iEle s prnteetieH te the pt10lie agaiH s t the peteHtial Felea s e ef FeaeteF eeelaHt aetivity te the atffl.e s pheFe , a s Eleffl.eH s tFateEl ay the fellevtiHg aHaly s i s ef a s te!lffl geHeFateF tt10e rnptt1Fe aeciEleHt iH UPS AR Chat3teF 14 .3 .1. Rt1ptt1Fe ef a s teaffl. geHeFateF tl:lse v 1 0t1lcl alle w FaEli0Ht1eliEle s iH the FeaeteF eeelaHt te eHteF the s eeeHEl!lf)'

s y s teffl. The liffl:itiHg ea s e iH v el v e s a cl0t10le eHEleEl tt10e mptt1Fe eeiHeiEleHt with le ss ef the eettclettser attEl release ef ste!lffl freffl the seeettEl!lf)'

sicle te the atfflespheFe via the fflaitt steaffl s afety v al v e s er atffl.e s pheFie relief v alve s. Thi s is a ss t1ffleEl te e0tttittt1e for 30 ffliHt1te s itt the attaly s i s. Th e epe F ateF w ill take aetieH te reElt1 e e the prifflltt'Y s iEle tefflperatt1re te a valt1e selew that ceffe s pettclittg te the relief er s afety *1 alve s etpeittt.

Ottee thi s i s a e eefflpli s heEl the v al v e s e att se eleseEl attcl the Felease terffl:ittateEl. Amendment Nos. 203 attEl 203 TS 3.1-17 11 08 04 PermittiHg stftrtttp aHcltor REACTOR OPBRATION to eoHtiHt1e for limited tiffle periods *.vith the reaetor eoolaHt's specific activity>

1.0 µCi/cc Btlt < 10.0 µCi/cc DOSB EQUIVALBNT I 131 accofflfflodates possiBlc iodiHe spikiHg pheHoffleHa which fflay occt1r followiHg chaHges iH THERMAL POWER. Althot1gh the aHalysis of a steaffl geHerator tt1Be rnpt1:1re iHitiated with priffl!H)'

coolaHt activity at the 10.0 ,=tCifce traHsieHt limit shows offsite doses less thaH or eq1:1al to the Regttlatory Gttide (RC) 1.183 limits , operatioH at the traHsieHt lifflit is restricted to HO FHore thaH 10 perceHt of the ttHit's yearly operatiHg tifl'le to liFHit the risk of appreciaBle release followiHg a postttlated steaFH geHerator tttBe rttpttlre. The Basis for the 500°P tefflperatttre coHtaiHed iH the SpecificatioH is that the sattlratioH pressttre correspoHdiHg to 500°P , i.e., 680.8 psia , is *.veH Below the pressttre at whieh the atfl'l.ospheric relief valves OH the sccoHdltfy side eottld Be aetttated. The accideHt 1tH1tlysis exaffliHes h';O cases of iodiHe spikiHg. Por the ease *.vith a pre existiHg iodiHe spike , the traHsieHt eoolaHt activity limit of 10.0 µCi/ec is assttFHed. Por the case of a coHcttrreHt spike , the iHitial aetivit)'

is assttmed to eorrespoHd to the steady state lifflit of +:-e µCi/ee. The eoHettrreHt iodiHe spike is modeled with a eoHservative iodiHe ltf)pearaHce rate. Both eases shov, doses at the exclttsioH lifCli 1tHd low popt1l1ttioH

!lOHC BOt1Hd1tries whieh are less thaH or eqttal to the RC 1.183 limits 1tHd coHtfol room doses which life withiH the CeHernl DesigH CriterioH (CDC) 19 gttideliHes. MeasttremeHt of E will Be performed at least h.vice 1tHHt11tlly. CalettlatioHs reqttired to determiHe E *.vill coHsist of the follo*wiHg:

E shall Be the average (weighed iH proportioH to the eoHeeHtratioH of eaeh radioHttelide iH the reaetor eoolaHt at the time of sampliHg) of the sttm of the average Beta 1tHd gamma eHergies per disiHtegratioH (iH MeV) for isotopes , other thaH iodiHes , with half lives greater thaH 15 FHiHtttes , makiHg ttp at least 95% of the total HOH iodiHe aetivity iH the eoolaHt. A determiHatioH of the Beta 1tHd g1tffiffi1t deeay eHergy per disiHtegratioH of eaeh Httclide determiHed iH (1) 1tB0*1e BY applyiHg knowH deeay eHergies 1tHd scheFHes. 3-:-A ealcttlatioH of E By ltf)propriate weighiHg of each Httelide's Beta 1tHd g1tfflffl:1t eHergy with its COHCeHtratioH liS deterFHiHed iH ( 1) liBOVC. Amendment No s. BttsetT TS3.1-17a 08 03 95 DOSH HQUIVALHN"T I 131 shall ae that coF1ccF1tratioF1 of I 131 {t:t Ci/cc) 1#hich aloRe wo1:1lcl prncl1:1ce the same thyroid close as the q1:1aF1tity aFtcl isotopic HH:JEtl:tre ofl 131 , I 132 , I 133 , I 13 4 aFtcl I 135 aet1:1ally preseHt. The thyroid close coFtversioH factors 1:1secl for this calc1:1latioF1 shall ae either: a) those listecl ifl Tuale HI of TID l 4844 , " Calc1:1latioF1 of DistaHce Factors for Po*uer aFtcl Test Reactor Sites", or a) Reg1:1latory G1:1icle 1.109 , " Cale1:1latioF1 of AF1F11:1al Doses to MaH from Ro1:1tiF1e Releases of Reactor Effl1:1eF1ts for the P1:1rpose of CompliaHee r,.vith 10 CPR Part 50 , AppeHcliJt I." Amendment Nos. 203 aFtcl 203 INSERT BASIS 3.1.D BASES BACKGROUND

-The maximum dose that an individual at the exclusion area boundary can receive for 2 hours2.314815e-5 days <br />5.555556e-4 hours <br />3.306878e-6 weeks <br />7.61e-7 months <br /> following an accident, or at the low population zone outer boundary for the radiological release duration, is specified in 10 CFR 50.67 (Ref. 1 ). Doses to control room operators must be limited per GDC 19. The limits on specific activity ensure that the offsite and control room doses are appropriately limited during analyzed transients and accidents.

The Reactor Coolant System (RCS) specific activity Limiting Condition for Operation (LCO) limits the allowable concentration level of radionuclides in the reactor coolant. The LCO limits are established to minimize the dose consequences in the event of a steam line break (SLB) or steam generator tube rupture (SGTR) accident.

The LCO contains specific activity limits for both DOSE EQUIVALENT 1-131 and DOSE EQUIVALENT XE-133. The allowable levels are intended to ensure that offsite and control room doses meet the appropriate acceptance criteria in the Standard Review Plan (Ref. 2). APPLICABLE SAFETY ANALYSES -The LCO limits on the specific activity of the reactor coolant ensure that the resulting offsite and control room doses meet the appropriate Standard Review Plan acceptance criteria following a SLB or SGTR accident.

The safety analyses (Refs. 3 and 4) assume the specific activity of the reactor coolant is at the LCO limits, and an existing reactor coolant steam generator (SG) tube leakage rate of 1 gpm exists. The safety analyses assume the specific activity of the secondary coolant is at its limit of 0.1 µCi/gm DOSE EQUIVALENT 1-131 from LCO 3.6.H, Secondary Specific Activity.

The analyses for the SLB and SGTR accidents establish the acceptance limits for RCS specific activity.

Reference to these analyses is used to assess changes to the unit that could affect RCS specific activity, as they relate to the acceptance limits. The safety analyses consider two cases of reactor coolant iodine specific activity.

One case assumes specific activity at 1.0 µCi/gm DOSE EQUIVALENT 1-131 with a concurrent large iodine spike that increases the rate of release of iodine from the fuel rods containing cladding defects to the primary coolant immediately after a SLB (by a factor of 500), or SGTR (by a factor of 335), respectively.

The second case assumes the initial reactor coolant iodine activity is at 10.0 µCi/gm DOSE EQUIVALENT 1-131 due to an iodine spike caused by a reactor or RCS transient prior to the accident.

In both cases, the noble gas specific activity is assumed to be 234 µCi/gm DOSE EQUIVALENT XE-133. The SGTR analysis assumes *a coincident loss of offsite power. The SGTR causes a reduction in reactor coolant inventory.

The reduction initiates a reactor trip from a low pressurizer pressure signal or an RCS overtemperature Ll T signal. Amendments Nos. and The loss of offsite power causes the steam dump valves to close to protect the condenser.

The rise in pressure in the ruptured SG discharges radioactively contaminated steam to the atmosphere through the SG power operated relief valves and the main steam safety valves. The unaffected SGs remove core decay heat by venting steam to the atmosphere until the cooldown ends and the Residual Heat Removal (RHR) system is placed in service. The SLB radiological analysis assumes that offsite power is lost at the same time as the pipe break occurs outside containment.

Reactor trip occurs after the generation of an SI signal on low steam line pressure.

The affected SG blows down completely and steam is vented directly to the Turbine Building to maximize control room dose. The unaffected SGs remove core decay heat by venting steam to the atmosphere until the cooldown ends and the RHR system is placed in service. Operation with iodine specific activity levels greater than the LCO limit is permissible , if the activity levels do not exceed 10.0 µCi/gm for more than 48 hours5.555556e-4 days <br />0.0133 hours <br />7.936508e-5 weeks <br />1.8264e-5 months <br />. The limits on RCS specific activity are also used for establishing standardization in radiation shielding and plant personnel radiation protection practices.

RCS specific activity satisfies Criterion 2 of 10 CFR 50.36(c)(2)(ii).

LCO -The iodine specific activity in the reactor coolant is limited to 1.0 µCi/gm DOSE EQUIVALENT 1-131, and the noble gas specific activity in the reactor coolant is limited to 234 µCi/gm DOSE EQUIVALENT XE-133. The limits on specific activity ensure that offsite and control room doses will meet the appropriate SRP acceptance

    • criteria (Ref. 2). The SLB and SGTR accident analyses (Refs. 3 and 4) show that the calculated doses are within acceptable limits. Violation of the LCO may result in reactor coolant radioactivity levels that could, in the event of a SLB or SGTR, lead to doses that exceed the SRP acceptance criteria (Ref. 2). APPLICABILITY

-In REACTOR OPERATION conditions where Tavg exceeds 200°F, operation within the LCO limits for DOSE EQUIVALENT 1-131 and DOSE EQUIVALENT XE-133 is necessary to limit the potential consequences of a SLB or SGTR to within the SRP acceptance criteria (Ref. 2). In COLD SHUTDOWN and REFUELING SHUTDOWN the steam generators are not being used for decay heat removal, the RCS and steam generators are depressurized, and primary to secondary leakage is minimal. Therefore, the monitoring of RCS specific activity is not required.

Amendments Nos. and ACTIONS 3.1.D.1.a With the DOSE EQUIVALENT 1-131 greater than the LCO limit, samples at intervals of 4 hours4.62963e-5 days <br />0.00111 hours <br />6.613757e-6 weeks <br />1.522e-6 months <br /> must be taken to demonstrate that the specific activity is =:: 10.0 µCi/gm. The completion time of 4 hours4.62963e-5 days <br />0.00111 hours <br />6.613757e-6 weeks <br />1.522e-6 months <br /> is required to obtain and analyze a sample. Sampling is continued every 4 hours4.62963e-5 days <br />0.00111 hours <br />6.613757e-6 weeks <br />1.522e-6 months <br /> to provide a trend. 3.1.D.1.b The DOSE EQUIVALENT 1-131 must be restored to within limit within 48 hours5.555556e-4 days <br />0.0133 hours <br />7.936508e-5 weeks <br />1.8264e-5 months <br />. The completion time of 48 hours5.555556e-4 days <br />0.0133 hours <br />7.936508e-5 weeks <br />1.8264e-5 months <br /> is acceptable since it is expected that, if there were an iodine spike, the normal coolant iodine concentration would be restored within this time period. Also, there is a low probability of a SLB or SGTR occurring during this time period. A unit startup and/or continued plant operation is permitted relying on required actions 3.1.D.1.a and b while the DOSE EQUIVALENT 1-131 LCO limit is not met. This allowance is acceptable due to the significant conservatism incorporated into the specific activity limit, the low probability of an event which is limiting due to exceeding this limit, and the ability to restore transient-specific activity excursions while the plant remains at, or proceeds to, POWER OPERATION.

3.1.D.1.c If the required action of Condition 3.1.D.1.a or 3.1.D.1.b is not met, or if the DOSE EQUIVALENT 1-131 is > 10.0 µCi/gm, the reactor must be brought to HOT SHUTDOWN within 6 hours6.944444e-5 days <br />0.00167 hours <br />9.920635e-6 weeks <br />2.283e-6 months <br /> and COLD SHUTDOWN within the following 30 hours3.472222e-4 days <br />0.00833 hours <br />4.960317e-5 weeks <br />1.1415e-5 months <br />. The required completion times are_ reasonable, based on operating experience, to reach the required plant conditions from full power conditions in an orderly manner and without challenging plant systems. 3.1.D.2.a With the DOSE EQUIVALENT XE-133 greater than the LCO limit, DOSE EQUIVALENT XE-133 must be restored to within the limit within 48 hours5.555556e-4 days <br />0.0133 hours <br />7.936508e-5 weeks <br />1.8264e-5 months <br />. The completion time of 48 hours5.555556e-4 days <br />0.0133 hours <br />7.936508e-5 weeks <br />1.8264e-5 months <br /> is acceptable since it is expected that, if there were a noble gas spike, the normal coolant noble gas concentration would be restored within this time period. Also, there is a low probability of a SLB or SGTR occurring during this time period. A unit startup and/or continued plant operation is permitted relying on required action 3.1.D.2.a while the DOSE EQUIVALENT XE-133 _LCO limit is not met. This allowance is acceptable due to the significant conservatism incorporated into the specific activity limit, the low probability of an event which is limiting due to exceeding this limit, and the ability to restore transient-specific activity excursions while the plant remains at, or proceeds to, POWER OPERATION.

Amendments Nos. and j 3.1.D.2.b If the required action or associated Allowed Outage Time of Condition 3.1.D.2.a is not met, or if the DOSE EQUIVALENT XE-133 is > 234 µCi/gm, the reactor must be brought to HOT SHUTDOWN within 6 hours6.944444e-5 days <br />0.00167 hours <br />9.920635e-6 weeks <br />2.283e-6 months <br /> and COLD SHUTDOWN within the following 30 hours3.472222e-4 days <br />0.00833 hours <br />4.960317e-5 weeks <br />1.1415e-5 months <br />. The required action and completion time are reasonable, based on operating experience, to reach the required plant conditions from full power conditions in an orderly manner and without challenging plant systems. REFERENCES

1. 10 CFR 50.67 2. Standard Review Plan (SRP) Section 15.0.1 "Radiological Consequence Analyses Using Alternative Source Terms" , 3. UFSAR, Section 14.3.1 Steam Generator Tube Rupture 4. UFSAR, Section 14.3.2 Steam Line Break Amendments Nos. and TS 3.6-4 02 23 06 3. With three auxiliary feedwater pumps inoperable, immediately initiate action to restore one inoperable pump to OPERABLE status. Specification 3.0.1 and all other required actions directing mode changes are suspended until one inoperable pump is restored to OPERABLE status. G. The following actions shall be taken with inoperability of a component or instrumentation other than the flow instrumentation in one or both redundant auxiliary feedwater flowpaths required by Specification 3.6.C.3 on the affected unit: (See Specification 3.7 and TS Table 3.7-6 for auxiliary feedwater flow in s trumentation requirements.)
1. With component or instrumentation inoperability in one redundant flowpath, restore the inoperable component or instrumentation to OPERABLE s tatu s within 72 hour8.333333e-4 days <br />0.02 hours <br />1.190476e-4 weeks <br />2.7396e-5 months <br /> s or be in HOT SHUTDOWN within the next 6 hours6.944444e-5 days <br />0.00167 hours <br />9.920635e-6 weeks <br />2.283e-6 months <br /> and be less than 350°F and 450 psig within the following 12 hours1.388889e-4 days <br />0.00333 hours <br />1.984127e-5 weeks <br />4.566e-6 months <br />. 2. With component or instrumentation inoperability affecting both redundant flowpaths, immediately initiate action to restore the inoperable component or instrumentation in one flowpath to OPERABLE status. Specification 3.0.1 and all other required actions directing mode changes are suspended until the inoperable component or instrumentation in one flowpath is restored to OPERABLE status. EQUIVALENT I 131. If the speeifie ttetivity ef the seeeHclftfy eeelttHt system exeeecls G-:-le µCi}ee DOSE EQUIVALENT I 131 , the FettetoF shttll ee shttt clewH ttHcl eoelecl to 500°F OF less v,ithiH 6 hottFs ttfteF cleteetioH ttHcl iH COLD SIIUTDOWP'i
  • withiH the Replace with Insert 3.6.H Amendment Nos. 246 ttHcl 245 I I J INSERT 3.6.H H. The specific activity of the secondary coolant system shall be :5 0.10 µCi/gm DOSE EQUIV AL ENT 1-131. If the specific activity of the secondary coolant system exceeds 0.10 µCi/gm DOSE EQUIVALENT 1-131 , the reactor shall be placed in HOT SHUTDOWN within 6 hours6.944444e-5 days <br />0.00167 hours <br />9.920635e-6 weeks <br />2.283e-6 months <br /> after detection and in COLD SHUTDOWN within the following 30 hours3.472222e-4 days <br />0.00833 hours <br />4.960317e-5 weeks <br />1.1415e-5 months <br />.

RCS Flow TS4.1-5a 08 10 16 This surveillance requirement in Table 4.1-2A is modified by a note that allows entry into POWER OPERATION, without having performed the surveillance, and placement of the unit in the best condition for performing the surveillance.

The note states that the surveillance requirement is not required to be performed until 7 days after reaching a THERMAL POWER of~ 90% of RATED POWER (i.e., shall be performed within 7 days after reaching 90% of RATED POWER). [

Reference:

NRC Safety Evaluation for License Amendments 270/269, issued October 19, 2010] The 7 day period after reaching 90% of RATED POWER is reasonable to establish stable operating conditions, install the test equipment, perform the test, and analyze the results. If reactor power is reduced below 90% of RATED POWER before completion of the RCS flow surveillance, the 7 day period shall be exited, and a separate 7 day period shall be entered when the required condition of reaching 90% of RATED POWER is subsequently achieved. The Surveillance Frequency is controlled under the Surveillance Frequency Control Program. ---)~ INSERT Table 4.1-2B Basis Section Amendment Nos. Bases-INSERT -BASIS TS Table 4.1-28 SURVEILLANCE REQUIREMENTS Table 4.1-2B Item 1 -RCS Coolant Liquid Samples DOSE EQUIVALENT 1-131 -This surveillance is performed to ensure iodine specific activity remains within the LCO limit during normal operation and following fast power changes when iodine spiking is more apt to occur. The SFCP 14 day Frequency is adequate to trend changes in the iodine activity level, considering noble gas activity is monitored every 7 days. The Frequency, between 2 and 6 hours6.944444e-5 days <br />0.00167 hours <br />9.920635e-6 weeks <br />2.283e-6 months <br /> after a power change _::: 15% RTP within a 1 hour1.157407e-5 days <br />2.777778e-4 hours <br />1.653439e-6 weeks <br />3.805e-7 months <br /> period , is established because the iodine levels peak during this time following iodine spike initiation; samples at other times would provide inaccurate results. DOSE EQUIVALENT XE-133 -This surveillance requires performing a gamma isotopic analysis as a measure of the noble gas specific activity of the reactor coolant at least once every 7 days per the SFCP. This measurement is the sum of the degassed gamma activities and the gaseous gamma activities in the sample taken or equivalent sampling method. This surveillance provides an indication of any increase in the noble gas specific activity. Trending the results of this surveillance allows proper remedial action to be taken before reaching the LCO limit under normal operating conditions.

The SFCP 7 day Frequency considers the low probability of a gross fuel failure during this time. Due to the inherent difficulty in detecting Kr-85 in a reactor coolant sample due to masking from radioisotopes with similar decay energies, such as F-18 and 1-134 , it is acceptable to include the minimum detectable activity for Kr-85 in this calculation.

If a specific noble gas nuclide listed in the definition of DOSE EQUIVALENT XE-133 is not detected , it should be assumed to be present at the minimum detectable activity.

TS 4.1-10 04 29 11 TABLE 4.1-2B MINIMUM FREQUENCIES FOR SAMPLING TESTS UFSAR SECTION DESCRIPTION TEST FREQUENCY REFERENCE

1. Reactor Coolant Radio-Chemical SFCP (5) Liquid Samples Analysis (]) Crass Aeti v ity (2) S F C P (5) 9,+ Tritium Activity SFCP (5) 9.1
  • Chemistry (CL , F & 02) SFCP (9) 4
  • Boron Concentration SFCP 9.1 E BetefffliHtttiaH S FC P (3) DOSE EQUN ALENT 1-131 SFCP~ffi3 2. Refueling Water Storage Chemistry (Cl & F) SFCP 6 3. Boric Acid Tanks
  • Boron Concentration SFCP 9.1 4. Chemical Additive Tank NaOH Concentration SFCP 6 5. Spent Fuel Pit
  • Boron Concentration SFCP 9.5 6. Secondary Coolant DOSE EQUIVALENT 1-131 SFCP 7. Stack Ga s Iodine and
  • 1-131 and particulate SFCP Particulate Samples radioactive releases

Cr-51, Fe-59, Mn-54, Co-58, and Co-60. (2~!lft"'"'" Oego,,ed seov;1y onoly,;, ,ha ll eon,;,t of the q u.,,.;,.,;

v e ...... ...,.,. of the tatal fft6iaaefrf'ity af the prifflary eaalftflt iH ttHits af i:tCi.J.ee. Deleted Amendment Nos. 273 aHd 272 A" % ,{ A' ,{ )' A" y % .,r ..( %

(3) ( 4) Deleted. (5) When reactor is critical and average primary coolant temperature

> 350°F. TS4.l-10a 08 15 03 (6) WlieHe v eF the speeifie aetiYity exeeeds 1.0 ,:t Cil-ee DOSE EQUIVALENT I 131 SF 100/E J:t Citee RRd 1:tRtil the speeifie aeti v iey of the ReaetoF CoslaHt System is restofed withiH its limits. (7) One sample between 2 change 15 pe hours following a THERMAL POWER nt of RA TED POWER within a one hour period ffl'EWt aet Hfte-1tw~~Mtfflff:t=v-e6'~flt-feflfffltffit!Etffl~

--:+:~'t" (8) Deleted. (9) Sampling for chloride and fluoride concentration s is not required when fuel is removed from the reactor ves s el and the reactor coolant inventory i s drained below the reactor ve s sel flange, whether the upper internals and/or the vessel head are in place or not. Sampling for oxygen concentration is not required when the reactor coolant temperature is below 250 degrees F. Amendment No s. 234 IHld 233 TS 6.6-3 01 28 13 b. The res1:1lts ef speeifie aetivity aHalysis iH wk-ieh the primffi)'

eeelaHt exeeeded the limits ef SpeeifieatieH 3 .1.D.4. IH additieH , the iHfermatieH itemjzed iH Speeifiealiee 3.1.D.4 shall he ieeluEled io t!Hs report~ 3. Steam Generator Tube Inspection Report A report shall be submitted within 180 days after Tavg exceeds 200°F following completion of an inspection performed in accordance with the Specification 6.4.Q, Steam Generator (SG) Program. The report shall include: a. The scope of inspections performed on each SG, b. Degradation mechanisms found, c. Nondestructive examination techniques utilized for each degradation mechanism, d. Location, orientation (if linear), and measured sizes (if available) of service induced indications, e. Number of tubes plugged during the inspection outage for each degradation

..{' mechanism, f. The number and percentage of tubes plugged to date , and the effective 1' plugging percentage in each steam generator.

1-' g. The results of condition monitoring, including the results of tube pulls and in-situ testing, h. The primary to secondary LEAKAGE rate observed in each SG (if it is not practical to assign the LEAKAGE to an individual SG, the entire primary to secondary LEAKAGE should be conservatively assumed to be from one SG) t during the cycle preceding the inspection which is the subject of the report, ,t' Amendment Nos. 278 aHd 278 Attachment 3 Serial No. 18-069A Docket Nos. 50-280/281 REVISED PROPOSED TECHNICAL SPECIFICATIONS PAGES Virginia Electric and Power Company (Dominion Energy Virginia)

Surry Station Units 1 and 2 TS 1.0-5 K. FIRE SUPPRESSION WATER SYSTEM A fire suppression water system shall consist of: a water source(s), gravity tank(s) or pump(s), and distribution piping with associated sectionalizing control or isolation valves. Such valves shall include yard hydrant curb valves, and the first valve ahead of the water flow alarm device on each sprinkler, hose standpipe, or spray system riser. L. OFFSITE DOSE CALCULATION MANUAL (ODCM) An Offsite Dose Calculation Manual (ODCM) shall contain the methodology and parameters used in the calculation of offsite doses resulting from radioactive gaseous and liquid effluents, in the calculation of gaseous and liquid effluent monitoring Alarm/Trip Setpoints, and in the conduct of the Radiological Environmental Monitoring Program. The ODCM shall also contain (1) the Radioactive Effluent Controls and Radiological Environmental Monitoring Programs required by Section 6.4 and (2) descriptions of the information that should be included in the Annual Radiological Environmental Operating and Annual Radioactive Effluent Release Reports required by Specifications 6.6.B.2 and 6.6.B.3. M. DOSE EQUIVALENT I-131 DOSE EQUIVALENT I-131 shall be that concentration of I-131 (microcuries per gram) that alone would produce the same dose when inhaled as the combined activities of iodine isotopes I-131, I-132, I-133, I-134, and I-135 actually present. The determination of DOSE EQUIVALENT I-131 shall be performed using Committed Effective Dose Equivalent (CEDE) dose conversion factors from Table 2.1 of EPA Federal Guidance Report No. 11. N. GASEOUS RADWASTE TREATMENT SYSTEM A gaseous radwaste treatment system is any system designed and installed to reduce radioactive gaseous effluents by collecting primary coolant system offgases from the primary system and providing for delay or holdup for the purpose of reducing the total radioactivity prior to release to the environment.

Amendment Nos.

W. STAGGERED TEST BASIS A staggered test basis shall consist of: TS 1.0-8 03-29-07 a. A test schedule for n systems, subsystems, trains or other designated components obtained by dividing the specified test interval into n equal subintervals, and b. The testing of one system, subsystem, train, or other designated component at the beginning of each subinterval.

X. LEAKAGE LEAKAGE shall be: a. Identified LEAKAGE 1. LEAKAGE, such as that from pump seals or valve packing (except reactor coolant pump (RCP) seal water injection or leakoff), that is captured and conducted to collection systems or a sump or collecting tank, 2. LEAKAGE into the containment atmosphere from sources that are both specifically located and known either not to interfere with the operation of leakage detection systems or not to be pressure boundary LEAKAGE, or 3. Reactor Coolant System (RCS) LEAKAGE through a steam generator to the Secondary System (primary to secondary LEAKAGE);

b. Unidentified LEAKAGE All LEAKAGE (except RCP seal water injection or leakoff) that is not identified LEAKAGE, and c. Pressure Boundary LEAKAGE LEAKAGE (except primary to secondary LEAKAGE) through a nonisolable fault in an RCS component body, pipe wall, or vessel wall. Amendment Nos. 251 and 250 TS l.0-8a Y. DOSE EQUIVALENT XE-133 DOSE EQUIVALENT XE-133 shall be that concentration of Xe-133 (microcuries per gram) that alone would produce the same acute dose to the whole body as the combined activities of noble gas nuclides Kr-85m, Kr-85, Kr-87, Kr-88, Xe-131m, Xe-133m, Xe-133, Xe-135m, Xe-135, and Xe-138 actually present. If a specific noble gas nuclide is not detected, it should be assumed to be present at the minimum detectable activity.

The determination of DOSE EQUIVALENT XE-133 shall be performed using effective dose conversion factors for air submersion listed in Table III.1 of EPA Federal Guidance Report No. 12, 1993, "External Exposure to Radionuclides in Air, Water, and Soil." Amendment Nos.

D. RCS Specific Activity Applicability TS 3.1-15a The following specifications are applicable whenever T avg (average RCS temperature) exceeds 200°F. Specification

1. The specific activity of the primary coolant shall be limited to$ 1 µCi/gm DOSE EQUIVALENT I-131. a. With the specific activity of the primary coolant> 1 µCi/gm DOSE EQUIVALENT I-131, verify DOSE EQUIVALENT I-131 $ 10 µCi/gm once per 4 hour4.62963e-5 days <br />0.00111 hours <br />6.613757e-6 weeks <br />1.522e-6 months <br />s: b. With the specific activity of the primary coolant> 1 µCi/gm DOSE EQUIVALENT I-131, but$ 10 µCi/gm, unit startup or POWER OPERATION may continue for up to 48 hours5.555556e-4 days <br />0.0133 hours <br />7.936508e-5 weeks <br />1.8264e-5 months <br /> while efforts are made to restore DOSE EQUIVALENT I-131 to$ 1 µCi/gm limit. c. With the specific activity of the primary coolant> 1 µCi/gm DOSE EQUIVALENT I-131 for more than 48 hours5.555556e-4 days <br />0.0133 hours <br />7.936508e-5 weeks <br />1.8264e-5 months <br /> during one continuous time interval or DOSE EQUIVALENT I-131 is> 10 µCi/gm, place the reactor in HOT SHUTDOWN within 6 hours6.944444e-5 days <br />0.00167 hours <br />9.920635e-6 weeks <br />2.283e-6 months <br /> and COLD SHUTDOWN within the following 30 hours3.472222e-4 days <br />0.00833 hours <br />4.960317e-5 weeks <br />1.1415e-5 months <br />. 2. The specific activity of the primary coolant shall be limited to$ 234 µCi/gm DOSE EQUIVALENT XE-133. a. With the specific activity of the primary coolant> 234 µCi/gm DOSE EQUIVALENT XE-133, unit startup or POWER OPERATION may continue for up to 48 hours5.555556e-4 days <br />0.0133 hours <br />7.936508e-5 weeks <br />1.8264e-5 months <br /> while efforts are made to restore DOSE EQUIVALENT XE-133 to$ 234 µCi/gm limit. b. With the specific activity of the primary coolant> 234 µCi/gm DOSE EQUIVALENT XE-133 for more than 48 hours5.555556e-4 days <br />0.0133 hours <br />7.936508e-5 weeks <br />1.8264e-5 months <br /> during one continuous time interval, place the reactor in HOT SHUTDOWN within 6 hours6.944444e-5 days <br />0.00167 hours <br />9.920635e-6 weeks <br />2.283e-6 months <br /> and COLD SHUTDOWN within the following 30 hours3.472222e-4 days <br />0.00833 hours <br />4.960317e-5 weeks <br />1.1415e-5 months <br />. Amendment Nos.

TS 3.l-15b BASES BACKGROUND

-The maximum dose that an individual at the exclusion area boundary can receive for 2 hours2.314815e-5 days <br />5.555556e-4 hours <br />3.306878e-6 weeks <br />7.61e-7 months <br /> following an accident, or at the low population zone outer boundary for the radiological release duration, is specified in 10 CFR 50.67 (Ref. 1). Doses to control room operators must be limited per GDC 19. The limits on specific activity ensure that the offsite and control room doses are appropriately limited during analyzed transients and accidents.

The Reactor Coolant System (RCS) specific activity Limiting Condition for Operation (LCO) limits the allowable concentration level of radionuclides in the reactor coolant. The LCO limits are established to minimize the dose consequences in the event of a steam line break (SLB) or steam generator tube rupture (SGTR) accident.

The LCO c.ontains specific activity limits for both DOSE EQUIVALENT 1-131 and DOSE EQUIVALENT XE-133. The allowable levels are intended to ensure that offsite and control room doses meet the appropriate acceptance criteria in the Standard Review Plan (Ref. 2). APPLICABLE SAFETY ANALYSES -The LCO limits on the specific activity of the reactor coolant ensure that the resulting offsite and control room doses meet the appropriate Standard Review Plan acceptance criteria following a SLB or SGTR accident.

The safety analyses (Refs. 3 and 4) assume the specific activity of the reactor coolant is at the LCO limits, and an existing reactor coolant steam generator (SG) tube leakage rate of 1 gpm exists. The safety analyses assume the specific activity of the secondary coolant is at its limit of 0.1 µCi/gm DOSE EQUIVALENT 1-131 from LCO 3.6.H, Secondary Specific Activity.

The analyses for the SLB and SGTR accidents establish the acceptance limits for RCS specific activity.

Reference to these analyses is used to assess changes to the unit that could affect RCS specific activity, as they relate to the acceptance limits. The safety analyses consider two cases of reactor coolant iodine specific activity.

One case assumes specific activity at 1.0 µCi/gm DOSE EQUIVALENT 1-131 with a concurrent large iodine spike that increases the rate of release of iodine from the fuel rods containing cladding defects to the primary coolant immediately after a SLB (by a factor of 500), or SGTR (by a factor of 335), respectively.

The second case assumes the initial reactor coolant iodine activity is at 10.0 µCi/gm DOSE EQUIVALENT 1-131 due to an iodine spike caused by a reactor or RCS transient prior to the accident.

In both cases, the noble gas specific activity is assumed to be 234 µCi/gm DOSE EQUIVALENT XE-133. The SGTR analysis assumes a coincident loss of offsite power. The SGTR causes a reduction in reactor coolant inventory.

The reduction initiates a reactor trip from a low pressurizer pressure signal or an RCS overtemperature fl T signal. Amendment Nos.

TS 3.1-16 The loss of off site power causes the steam dump valves to close to protect the condenser.

The rise in pressure in the ruptured SG discharges radioactively contaminated steam to the atmosphere through the SG power operated relief valves and the main steam safety valves. The unaffected SGs remove core decay heat by venting steam to the atmosphere until the cooldown ends and the Residual Heat Removal (RHR) system is placed in service. The SLB radiological analysis assumes that off site power is lost at the same time as the pipe break occurs outside containment.

Reactor trip occurs after the generation of an SI signal on low steam line pressure.

The affected SG blows down completely and steam is vented directly to the Turbine Building to maximize control room dose. The unaffected SGs remove core decay heat by venting steam to the atmosphere unti:l the cooldown ends and the RHR system is placed in service. Operation with iodine specific activity levels greater than the LCO limit is permissible if the activity levels do not exceed 10.0 µCi/gm for more than 48 hours5.555556e-4 days <br />0.0133 hours <br />7.936508e-5 weeks <br />1.8264e-5 months <br />. The limits on RCS specific activity are also used for establishing standardization in radiation shielding and plant personnel radiation protection practices.

RCS specific activity satisfies Criterion 2 of 10 CPR 50.36(c)(2)(ii).

LCO -The iodine specific activity in the reactor coolant is limited to 1.0 µCi/gm DOSE EQUIVALENT I-131, and the noble gas specific activity in the reactor coolant is limited to 234 µCi/gm DOSE EQUIVALENT XE-133. The limits on specific activity ensure that offsite and control room doses will meet the appropriate SRP acceptance criteria (Ref. 2). The SLB and SGTR accident analyses (Refs. 3 and 4) show that the calculated doses are within acceptable limits. Violation of the LCO may result in reactor coolant radioactivity levels that could, in the event of a SLB or SGTR, lead to doses that exceed the SRP acceptance criteria (Ref. 2). APPLICABILITY

-In REACTOR OPERATION conditions where Tavg exceeds 200°F, operation within the LCO limits for DOSE EQUIVALENT I-131 and DOSE EQUIVALENT XE-133 is necessary to limit the potential consequences of a SLB or SGTR to within the SRP acceptance criteria (Ref. 2). In COLD SHUTDOWN and REFUELING SHUTDOWN the steam generators are not being used for decay heat removal, the RCS and steam generators are depressurized, and primary to secondary leakage is minimal. Therefore, the monitoring of RCS specific activity is not required.

Amendment Nos.

ACTIONS 3.1.D.l.a TS 3.1-17 With the DOSE EQUIVALENT I-131 greater than the LCO limit, samples at intervals of 4 hours4.62963e-5 days <br />0.00111 hours <br />6.613757e-6 weeks <br />1.522e-6 months <br /> must be taken to demonstrate that the specific activity is ::s_ 10.0 µCi/gm. The completion time of 4 hours4.62963e-5 days <br />0.00111 hours <br />6.613757e-6 weeks <br />1.522e-6 months <br /> is required to obtain and analyze a sample. Sampling is continued every 4 hours4.62963e-5 days <br />0.00111 hours <br />6.613757e-6 weeks <br />1.522e-6 months <br /> to provide a trend. 3.1.D.1.b The DOSE EQUIVALENT I-131 must be restored to within limit within 48 hours5.555556e-4 days <br />0.0133 hours <br />7.936508e-5 weeks <br />1.8264e-5 months <br />. The completion time of 48 hours5.555556e-4 days <br />0.0133 hours <br />7.936508e-5 weeks <br />1.8264e-5 months <br /> is acceptable since it is expected that, if there were an iodine spike, the normal coolant iodine concentration would be restored within this time period. Also, there is a low probability of a SLB or SGTR occurring during this time period. A unit startup and/or continued plant operation is permitted relying on required actions 3.1.D. l.a and b while the DOSE EQUIVALENT I-131 LCO limit is not met. This allowance is acceptable due to the significant conservatism incorporated into the specific activity limit, the low probability of an event which is limiting due to exceeding this limit, and the ability to restore transient-specific activity excursions while the plant remains at, or proceeds to, POWER OPERATION.

3.1.D.l.c If the required action of Condition 3.1.D.l.a or 3.1.D.l.b is not met, or if the DOSE EQUIVALENT I-131 is> 10.0 µCi/gm, the reactor must be brought to HOT SHUTDOWN within 6 hours6.944444e-5 days <br />0.00167 hours <br />9.920635e-6 weeks <br />2.283e-6 months <br /> and COLD SHUTDOWN within the following 30 hours3.472222e-4 days <br />0.00833 hours <br />4.960317e-5 weeks <br />1.1415e-5 months <br />. The required completion times are reasonable, based on operating experience, to reach the required plant conditions from full power conditions in an orderly manner and without challenging plant systems. 3.1.D.2.a With the DOSE EQUIVALENT XE-133 greater than the LCO limit, DOSE EQUIVALENT XE-133 must be restored to within the limit within 48 hours5.555556e-4 days <br />0.0133 hours <br />7.936508e-5 weeks <br />1.8264e-5 months <br />. The completion time of 48 hours5.555556e-4 days <br />0.0133 hours <br />7.936508e-5 weeks <br />1.8264e-5 months <br /> is acceptable since it is expected that, if there were a noble gas spike, the normal coolant noble gas concentration would be restored within this time period. Also, there is a low probability of a SLB or SGTR occurring during this time period. Amendment Nos.

TS 3.1-17a A unit startup and/or continued plant operation is permitted relying on required action 3. l.D.2.a while the DOSE EQUIVALENT XE-133 LCO limit is not met. This allowance is acceptable due to the significant conservatism incorporated into the specific activity limit, the low probability of an event which is limiting due to exceeding this limit, and the ability to restore transient-specific activity excursions while the plant remains at, or proceeds to, POWER OPERATION.

3.1.D.2.b If the required action or associated Allowed Outage Time of Condition

3. l .D.2.a is not met, or if the DOSE EQUIVALENT XE-133 is> 234 µCi/gm, the reactor must be brought to HOT SHUTDOWN within 6 hours6.944444e-5 days <br />0.00167 hours <br />9.920635e-6 weeks <br />2.283e-6 months <br /> and COLD SHUTDOWN within the following 30 hours3.472222e-4 days <br />0.00833 hours <br />4.960317e-5 weeks <br />1.1415e-5 months <br />. The required action and completion time are reasonable, based on operating experience, to reach the required plant conditions from full power conditions in an orderly manner and without challenging plant systems. REFERENCES
1. 10 CFR 50.67 2. Standard Review Plan (SRP) Section 15.0.1 "Radiological Consequence Analyses Using Alternative Source Terms" 3. UFSAR, Section 14.3.1 Steam Generator Tube Rupture 4. UFSAR, Section 14.3.2 Steam Line Break Amendment Nos.

TS 3.6-4 3. With three auxiliary feedwater pumps inoperable, immediately initiate action to restore one inoperable pump to OPERABLE status. Specification 3.0.1 and all other required actions directing mode changes are suspended until one inoperable pump is restored to OPERABLE status. G. The following actions shall be taken with inoperability of a component or instrumentation other than the flow instrumentation in one or both redundant auxiliary feedwater flowpaths required by Specification 3.6.C.3 on the affected unit: (See Specification 3.7 and TS Table 3.7-6 for auxiliary feedwater flow instrumentation requirements.)

1. With component or instrumentation inoperability in one redundant flowpath, restore the inoperable component or instrumentation to OPERABLE status within 72 hours8.333333e-4 days <br />0.02 hours <br />1.190476e-4 weeks <br />2.7396e-5 months <br /> or be in HOT SHUTDOWN within the next 6 hours6.944444e-5 days <br />0.00167 hours <br />9.920635e-6 weeks <br />2.283e-6 months <br /> and be less than 350~F and 450 psig within the following 12 hours1.388889e-4 days <br />0.00333 hours <br />1.984127e-5 weeks <br />4.566e-6 months <br />. 2. With component or instrumentation inoperability affecting both redundant flowpaths, immediately initiate action to restore the inoperable component or instrumentation in one flowpath to OPERABLE status. Specification 3 .0.1 and all other required actions directing mode changes are suspended until the inoperable component or instrumentation in one flowpath is restored to OPERABLE status. H. The specific activity of the secondary coolant system shall be '.:S_ 10 µCi/gm DOSE EQUIVALENT I-131. If th.e specific activity of the secondary coolant system exceeds 0.10 µCi/gm DOSE EQUIVALENT I-131, the reactor shall be placed in HOT SHUTDOWN within 6 hours6.944444e-5 days <br />0.00167 hours <br />9.920635e-6 weeks <br />2.283e-6 months <br /> after detection and in COLD SHUTDOWN within the following 30 hours3.472222e-4 days <br />0.00833 hours <br />4.960317e-5 weeks <br />1.1415e-5 months <br />. Amendment Nos.

TS 4.1-5a RCS Flow This surveillance requirement in Table 4.1-2A is modified by a note that allows entry into POWER OPERATION, without having performed the surveillance, and placement of the unit in the best condition for performing the surveillance.

The note states that the surveillance requirement is not required to be performed until 7 days after reaching a THERMAL POWER of 2: 90% of RATED POWER (i.e., shall be performed within 7 days after reaching 90% of RATED POWER). [

Reference:

NRC Safety Evaluation for License Amendments 270/269, issued October 19, 2010] The 7 day period after reaching 90% of RATED POWER is reasonable to establish stable operating conditions, install the test equipment, perform the test, and analyze the results. If reactor power is reduced below 90% of RATED POWER before completion of the RCS flow surveillance, the 7 day period shall be exited, and a separate 7 day period shall be entered when the required condition of reaching 90% of RATED POWER is subsequently achieved.

The Surveillance Frequency is controlled under the Surveillance Frequency Control Program. SURVEILLANCE REQUIREMENTS Table 4.1-2B Item 1 -RCS Coolant Liquid Samples DOSE EQUIVALENT 1-131 -This surveillance is performed to ensure iodine specific activity remains within the LCO limit during normal operation and following fast power changes when iodine spiking is more apt to occur. The SFCP 14 day Frequency is adequate to trend changes in the iodine activity level, considering noble gas activity is monitored every 7 days. The Frequency, between 2 and 6 hours6.944444e-5 days <br />0.00167 hours <br />9.920635e-6 weeks <br />2.283e-6 months <br /> after a power change 2: 15% RTP within a 1 hour1.157407e-5 days <br />2.777778e-4 hours <br />1.653439e-6 weeks <br />3.805e-7 months <br /> period, is established because the iodine levels peak during this time following iodine spike initiation; samples at other times would provide ina.ccurate results. DOSE EQUIVALENT XE-133 -This surveillance requires performing a gamma isotopic analysis as a measure of the noble gas specific activity of the reactor coolant at least once every 7 days per the SFCP. This measurement is the sum of the degassed gamma activities and the gaseous gamma activities in the sample taken or equivalent sampling method. This surveillance provides an indication of any increase in the noble gas specific activity.

Amendment Nos.

TS 4.l-5b Trending the results of this surveillance allows proper remedial action to be taken before reaching the LCO limit under normal operating conditions.

The SFCP 7 day Frequency considers the low probability of a gross fuel failure during this time. Due to the inherent difficulty in detecting Kr-85 in a reactor coolant sample due to masking from radioisotopes with similar decay energies, such as F-18 and 1-134, it is acceptable to include the minimum detectable activity for Kr-85 in this calculation.

If a specific noble gas nuclide listed in the definition of DOSE EQUIVALENT XE-133 is not detected, it should be assumed to be present at the minimum detectable activity.

Amendment Nos.

TS 4.1-10 TABLE 4.l-2B MINIMUM FREQUENCIES FOR SAMPLING TESTS DESCRIPTION

1. Reactor Coolant Liquid Samples 2. Refueling Water Storage 3. Boric Acid Tanks 4. Chemical Additive Tank 5. Spent Fuel Pit 6. Secondary Coolant 7. Stack Gas Iodine and Particulate Samples
  • See Specification 4.1.D TEST Radio-Chemical Analysis (1) Tritium Activity
  • Chemistry (CL, F & Oz)
  • Boron Concentration DOSE EQUIVALENT I-131 DOSE EQUIVALENT XE-133 Chemistry (Cl & F)
  • Boron Concentration NaOH Concentration

Cr-51, Fe-59, Mn-54, Co-58, and Co-60. (2) Deleted Amendment Nos.

(3) Deleted ( 4) Whenever T avg (average RCS temperature) exceeds 200°F. (5) When reactor is critical and average primary coolant temperature 2': 350°F. (6) Deleted (7) One sample between 2 and 6 hours6.944444e-5 days <br />0.00167 hours <br />9.920635e-6 weeks <br />2.283e-6 months <br /> following a THERMAL POWER change 2': 15 percent of RATED POWER within a one hour period. (8) Deleted. (9) Sampling for chloride and fluoride concentrations is not required when fuel is removed from the reactor vessel and the reactor coolant inventory is drained below the reactor vessel flange, whether the upper internals and/or the vessel head are in place or not. Sampling for oxygen concentration is not required when the reactor coolant temperature is below 250 degrees F. TS 4.1-lOa Amendment Nos.

L TS 6.6-3 b. Deleted 3. Steam Generator Tube Inspection Report A report shall be submitted within 180 days after Tavg exceeds 200°F following completion of an inspection performed in accordance with the Specification 6.4.Q, Steam Generator (SG) Program. The report shall include: a. The scope of inspections performed on each SG, b. Degradation mechanisms found, c. Nondestructive examination techniques utilized for each degradation mechanism, d. Location, orientation (if linear), and measured sizes (if available) of service induced indications, e. Number of tubes plugged during the inspection outage for each degradation mechanism, f. The number and percentage of tubes plugged to date, and the effective plugging percentage in each steam generator.

g. The results of condition monitoring, including the results of tube pulls and in-situ testing, h. The primary to secondary LEAKAGE rate observed in each SG (if it is not practical to assign the LEAKAGE to an individual SG, the entire primary to secondary LEAKAGE should be conservatively assumed to be from one SG) during the cycle preceding the inspection which is the subject of the report, Amendment Nos.