Response to NRC Staff Questions Technical Specification Proposed Change 250, Scram & Isolation Valve Closure Functions of Main Steam Line Radiation Monitors

ML022000089
Person / Time
Site:	Vermont Yankee
Issue date:	07/16/2002
From:	Wanczyk R Vermont Yankee
To:	Document Control Desk, Office of Nuclear Reactor Regulation
References
BVY 02-49
Download: ML022000089 (14)
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VERMONT YANKEE NUCLEAR POWER CORPORATION 185 Old Ferry Road, Brattleboro, VT 05301-7002 (802) 257-5271 July 16, 2002 BVY 02-49 U.S. Nuclear Regulatory Commission ATTN: Document Control Desk Washington, DC 20555

Reference:

(a) Letter, VYNPC to USNRC, "Technical Specification Proposed Change No. 250, Scram and Isolation Valve Closure Functions of the Main Steam Line Radiation Monitors," BVY 02-18, March 19, 2002.

(b) Letter, VYNPC to USNRC, "Technical Specification Proposed Change No. 250, Supplement No. 1, Scram and Isolation Valve Closure Functions of the Main Steam Line Radiation Monitors," BVY 02-4 1, June 4, 2002

Subject:

Vermont Yankee Nuclear Power Station License No. DPR-28 (Docket No. 50-271)

Technical Specification Proposed Change No. 250 Scram and Isolation Valve Closure Functions of the Main Steam Line Radiation Monitors Additional Information By letter dated March 19, 2002 [Reference (a)] and supplemented by letter dated June 4, 2002

[Reference (b)], Vermont Yankee (VY) proposed to amend its Facility Operating License, DPR-28 by eliminating the reactor scram and main steam isolation valve closure requirements associated with the main steam line radiation monitors (MSLRMs) and modifying other requirements related to MSLRM trip functions. The additional information provided herewith supplements References (a) and (b) and responds to questions posed by NRC staff during a telephone conference conducted on July 11, 2002.

The attachment to this letter contains responses to NRC staff questions. As explained during the telecon, the information necessary to fully respond to Question 2 will be provided under separate cover at a later date. VY anticipates being able to supply the response to Question 2 by July 25, 2002.

If you have any questions on this transmittal, please contact Mr. Gautam Sen at (802) 258-4111.

Sincerely, VERMONT YANKEE NUCLEAR POWER CORPORATION Robert J. nnzyk" /

Director o ety & Regulatory Affairs 0j

VERMONT YANKEE NUCLEAR POWER CORPORATION BVY 02-49 / Page 2 STATE OF VERMONT ))ss WINDHAM COUNTY )

Safety & Regulatory Then personally Affairs appeared before RobertYankee Vermont of me, Nuclear J. Wanczyk, Power who, duly sworn, tha beingCorporation, orized to

- "ttorof execute and file the foregoing document in the name and on the behalf of Vermont Yankee Nuclear Power Corporation, and that the statements therein are true to the best of his knowledge and belief.

S~ly A. Sandstrum, Notary Public My Commission Expires February 10, 2003 Attachment cc: USNRC Region I Administrator USNRC Resident Inspector - VYNPS USNRC Project Manager - VYNPS Vermont Department of Public Service

Docket No. 50-271 BVY 02-49 Attachment Vermont Yankee Nuclear Power Station Proposed Technical Specification Change No. 250 Scram and Isolation Valve Closure Functions of the Main Steam Line Radiation Monitors Additional Information

BVY 02-49 / Attachment / Page 1 of 11 RESPONSE TO NRC REQUEST FOR ADDITIONAL INFORMATION Concerning Vermont Yankee Proposed Change No. 250 Question 1 In your submittal you stated that you have an additional potential release pathway that was not included in the GE topical report NEDO-31400A. You have not documented the details of this site-specific analysis in the submittal. Please submit a description of the analysis and all calculation inputs and assumptions:

Response to Question 1 General The design-basis Control Rod Drop Accident (CRDA) at VY was re-analyzed in support of elimination of the following high-radiation trips initiated by the main steam line radiation monitor

[Reference I]:

I. Reactor scram,

2. Closure of the Main Steam Isolation Valves (MSIVs),

3. Closure of the main steam drain line, and

4. Closure of the Reactor Coolant System (RCS) recirculation sampling line.

The VY site-specific additional release pathway is a release from the RCS recirculation sampling lines in the Reactor Building (resulting from elimination of Trip 4 above).

Design Input and Source Term The design input is summarized in Table 1.2, and the calculated (using ORIGEN-2) peak assembly total and gap inventories are presented in Table 1.3.

Assumptions (a) One hundred percent of the iodines released as a result of the postulated CRDA are assumed to be retained by the RCS liquid mass, and to mix uniformly therein. The fraction of halogens which get transported to the condenser is conservatively ignored in this release pathway.

(b) The RCS recirculation sampling line conservatively remains unisolated for 30 days, and results in the release of contaminated RCS coolant at the rate of 32 gph. The sampling line liquid is cooled (conservatively assumed to be at 70 'F).

(c) The RCS mass is assumed to remain constant (i.e., water is added to maintain the volume, thus leading to a decrease in the concentration with time, due to dilution).

(d) The noble gases produced by the decay of halogens retained by the RCS are conservatively assumed to remain within the liquid phase and form part of the source term for the dose analysis.

BVY 02-49 / Attachment / Page 2 of I1 RESPONSE TO NRC REQUEST FOR ADDITIONAL INFORMATION Concerning Vermont Yankee Proposed Change No. 250 (e) Ten percent of the released iodines are conservatively assumed to become airborne within the reactor building, and to get released to the atmosphere via the main stack without holdup, mixing in the reactor building, or filtration.

RadiologicalImpact The radiological impact associated with this pathway (RCS sampling line releases at 32 gph for 30 days) is summarized in Table 1.1, which follows.

Table 1.1 Radiological Impact Location Dose (rem)

Thyroid Whole Body/DDE Skin Inhalation Pathway External Radiation Beta Gamma

+

(ICRP-30 DCFs) (FGR 12 DCFs) (FGR 12 DCFs)

EAB 3.OE+00 1.5E-02 2.3E-02 LPZ 1.8E+00 7.4E-03 1.2E-02

BVY 02-49 / Attachment / Page 3 of 11 RESPONSE TO NRC REQUEST FOR ADDITIONAL INFORMATION Concerning Vermont Yankee Proposed Change No. 250 Table 1.2 VY CRDA Design Input RELEASE VIA THE RCS RECIRCULATION SAMPLING LINES Seq. DESCRIPTION VALUE A - SOURCE TERM Al Licensed power level 1593 MWt A2 Power uprate 20 %

Calorimetric uncertainty 2%

Power Level

_ for Design-Basis Calculation (1593*1.2*1.02) 1950 MWt A3 Number of assemblies in core 368 A4 Average assembly power level (1950/368) 5.299 MWt A5 Radial peaking factor 1.5 A6 Peak assembly power level (5.299

• 1.5) 7.949 MWt A7 Assembly uranium loading (GEI4 fuel) 0.18 MTU A8 Assembly-average fuel enrichment (selected to bound all peak assemblies in 4.0 and 5.0 wt %

the core) U-235 A9 Peak-assembly average burnup (for nuclide-specific bounding value selection) 5 - 60 GWD/MTU Al 0 Peak-assembly total and gap inventories See Table 1.3 B - CRDA FUEL DAMAGE AND ASSOCIATED RELEASE FRACTIONS BI Fuel clad failures (8x8 60-rod assemblies, bounding the 9x9s and 10xl0s) 850 rods (14.17 assemblies)

B2 Fuel melt None B3 Fraction of assembly inventories released from damaged fuel rods into the reactor vessel:

All noble-gas and halogen isotopes 10 %

C - RELEASE VIA THE RCS RECIRCULATION SAMPLING LINES Cl Fraction of released iodines retained by the RCS water 100%

C2 Primary coolant mixing mass 393,197 Ibm C3 Total liquid flow to chemistry sink in Reactor Building from the RCS 32 gal/hr recirculation sampling line (cooled)

C4 Density of liquid flow to chemistry sink (at 70 OF) 62.3 ibm/ft3 C5 Flashing fraction (upon exiting sampling line) 10 %

C6 Duration of sampling line releases 30 days C7 Release point to atmosphere Main stack

BVY 02-49 / Attachment / Page 4 of 11 RESPONSE TO NRC REQUEST FOR ADDITIONAL INFORMATION Concerning Vermont Yankee Proposed Change No. 250 Table 1.2 (Continued)

VY CRDA Design Input RELEASE VIA THE RCS RECIRCULATION SAMPLING LINES Seq. DESCRIPTION VALUE D - ATMOSPHERIC DISPERSION FACTORS (X/Q sec m 3)

DI Stack to worst-case offsite receptor 0 - 0.5 hr 2.03E-04 (fumig.)

0.5- 1 hr 1.54E-04 1 -_2 hr 9.17E-05 D2 Stack Releases to LPZ 0 - 0.5 hr 2.55E-05 0.5 - 1 hr 2.55E-05 1 -2 hr 1.87E-05 2 - 8 hr 1.01E-05 8 - 24 hr 1.09E-06 24 - 96 hr 6.90E-07 96 - 720 hr 4.61E-07 E - OTHER El EAB receptor breathing rate (2-hr interval) 3.47E-04 (m 3/sec)

E2 LPZ receptor breathing rate 0 - 8 hr 3.47E-04 (m 3/sec) 8 - 24 hr 1.75E-04 (m 3/sec) 24 - 720 hr 2.32E-04 (m 3/sec)

BVY 02-49 / Attachment / Page 5 of 11 RESPONSE TO NRC REQUEST FOR ADDITIONAL INFORMATION Concerning Vermont Yankee Proposed Change No. 250 Table 1.3 VY CRDA - Source Term - Peak Assembly Total and Gap Inventories (7.949 MWt)

[Bounding Values in the range 4 -5 weight % U-235, and burnups 5-60 GWD/MTU]

Radionuclide Total Assembly Gap Fraction Assembly Gap Inventory (Ci) Inventory (Ci)

BR 82 2.674E+03 0.1 2.674E+02 BR 82M 1.034E+03 0.1 1.034E+02 BR 83 3.379E+04 0.1 3.379E+03 BR 84 6.244E+04 0.1 6.244E+03 BR 84M 1.727E+03 0.1 1.727E+02 BR 85 7.681E+04 0.1 7.681E+03 BR 86 5.762E+04 0.1 5.762E+03 BR 87 1.312E+05 0.1 1.312E+04 BR 88 1.498E+05 0.1 1.498E+04 1128 7.313E+03 0.1 7.313E+02 1130 1.791E+04 0.1 1.791E+03 1130M 6.997E+03 0.1 6.997E+02 1131 2.224E+05 0.1 2.224E+04 1132 3.168E+05 0.1 3.168E+04 1133 4.470E+05 0.1 4.470E+04 1134 4.9931E+05 0.1 4.993E+04 1134M 5.308E+04 0.1 5.308E+03 1135 4.162E+05 0.1 4.162E+04 1136 2.021E+05 0.1 2.021E+04 1136M 1.237E+05 0.1 1.237E+04 KR 83M 3.378E+04 0.1 3.378E+03 KR 85 2.949E+03 0.1 2.949E+02 KR 85M 7.765E+04 0.1 7.765E+03 KR 87 1.555E+05 0.1 1.555E+04 KR 88 2.198E+05 0.1 2.198E+04 KR 89 2.775E+05 0.1 2.775E+04 KR 90 2.756E+05 0.1 2.756E+04 XE131M 2.297E+03 0.1 2.297E+02 XE133 4.457E+05 0.1 4.457E+04 XE133M 1.379E+04 0.1 1.379E+03 XE135 1.481E+05 0.1 1.481E+04 XE135M 8.927E+04 0.1 8.927E+03 XE137 3.932E+05 0.1 3.932E+04 XE138 3.980E+05 0.1 3.980E+04 XE139 3.215E+05 0.1 3.215E+04

BVY 02-49 / Attachment / Page 6 of 11 RESPONSE TO NRC REQUEST FOR ADDITIONAL INFORMATION Concerning Vermont Yankee Proposed Change No. 250 Question 2 The atmospheric dispersion factor (X/Q) values for the exclusion area boundary (EAB) you used in your evaluation are 1.7xl 0- 3 s/m3 for a turbine building release and 2.0x1 0 4 s/m 3 for a release from the stack. These values do not appear to be documented in the FSAR. Are these values the same as were used in the FSAR section 14.9 control rod drop accident (CRDA) dose analysis or are they newly calculated for this amendment request?

a. If these values have been previously approved by the NRC staff, please provide a reference to this approval.

b. If these 7/Qs are new values, please provide a description of the analysis, the calculation inputs and assumptions, and the meteorological data used to determine these values.

Response to Question 2 A response to this question will be provided separately.

BVY 02-49 / Attachment / Page 7 of I1 RESPONSE TO NRC REQUEST FOR ADDITIONAL INFORMATION Concerning Vermont Yankee Proposed Change No. 250 Question 3 You have not addressed the impact of the proposed changes on the design basis accident radiological consequences in the control room. Please provide an evaluation. If this evaluation includes a control room dose analysis, please provide a description of the analysis, the calculation inputs and assumptions, and the control room dose results from a CRDA.

Response to Question 3 The impact of the proposed change on the habitability of the VY Control Room was analyzed and documented in Reference 1. Pertinent details are summarized below.

General Habitability of the control room was analyzed for the following post-CRDA release pathways:

H1. Release from the RCS recirculation sampling lines in the Reactor Building,

1. 2. Leakage from the main condenser, based on the assumption of manual isolation of the Main Steam Lines and/or of the Advanced Off Gas (AOG), and

1. 3. Release from the AOG system, based on the assumption that the Main Steam Lines remain open.

Release Pathways #2 and #3 are mutually exclusive, and Pathway #1 is additive to the other two.

Design-Input The design input associated with the source term, fuel damage following a postulated design basis CRDA, the release fractions from the damaged fuel, and the releases via Pathway #1 (RCS recirculation sampling lines in the reactor building) are presented in Table 1.2 (see Response to Question 1). The design input for release Pathways #2 and #3, and the control room characteristics are summarized in Table 3.2. The source term is given in Table 1.3.

Assumptions Release Pathway #2 - Condenser Leakage (a) Manual isolation of the Main Steam Lines and/or of the AOG system takes place prior to any release of activity to the atmosphere via the AOG. As a result, the activity released from the damaged fuel rods which reaches the turbine and condensers is retained within these systems and the AOG lines. Retention by the AOG charcoal beds, if any, is neglected, and release to the environment is due to condenser leakage.

(b) 100% of the noble gases released from the damaged fuel rods into the pressure vessel, and 10% of the iodines, are assumed to reach the turbine and condenser.

BVY 02-49 / Attachment / Page 8 of 11 RESPONSE TO NRC REQUEST FOR ADDITIONAL INFORMATION Concerning Vermont Yankee Proposed Change No. 250 (c) Halogen plateout and partitioning in the turbine, condenser and other internal surfaces is conservatively assumed to be equal to 50%. This value is consistent with the UFSAR (Sec.

14.9.2), and is conservative in comparison to the 90% value recommended in the SRP [Sec.

15.4.9, Sec. 111. 11].

(d) The condenser is assumed to leak at 0.5 %Iday. This value is consistent with the UFSAR (Sec.

14.9.2) and the SER.

(e) Condenser leakage is instantly released to the atmosphere (at ground level) without holdup in the turbine building.

(f) The exposure interval for control room operators was assumed to be 24 hrs. The accident scenario assumes that condenser leakage terminates in 24 hrs.

Release Pathway #3 - AOG Releases (a) For this scenario, the Main Steam Lines remain open after the postulated CRDA, and the AOG remains operational.

(b) The source term consists of the halogens and noble gases which reach the condenser, and is the same as for Release Pathway #2 (for condenser leakage). All releases to the atmosphere are via the AOG and main stack (elevated releases), and include only kryptons and xenons.

(c) The AOG was assumed to be operating with 6 charcoal beds in series, and a condenser inleakage of 30 scfm. The associated holdup times are 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> for the kryptons and 16.6 days for the xenons. No credit was taken for the fact that the AOG is normally operated with 7 charcoal beds in series, and that the condenser inleakage rate is usually below 20 scfm, i.e., that the hold up times are longer than assumed in the calculation. Sensitivity studies indicate that significantly higher condenser inleakage rates would still not result in unacceptable doses.

(d) Portions of the released halogens plate out in the condenser and AOG lines, and the remainder are retained by the AOG charcoal beds. The noble gases produced by the decay of these halogens are accounted for in the dose computations. To account for the transit times through the charcoal beds, the bromines are pre-decayed for 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> (same as the kryptons), and the iodines are pre decayed for 16.6 days (same as the xenons).

(e) The krypton and xenon holdup times were excluded from definition of the exposure intervals.

Indeed, kryptons and xenons were assumed to get released to the atmosphere simultaneously at the time of the accident, though properly corrected for their respective decays while in transit through the charcoal beds. Doses in the control room were calculated for a 30-day interval to account for the release of noble gases produced by the decay of halogens retained by the condenser and charcoal beds.

RadiologicalImpact The radiological impact to control room operators associated with the three release pathways following a design-basis CRDA are summarized in Table 3.1 which follows. All doses are within the acceptance criteria.

BVY 02-49 / Attachment / Page 9 of 11 RESPONSE TO NRC REQUEST FOR ADDITIONAL INFORMATION Concerning Vermont Yankee Proposed Change No. 250 Table 3.1 Radiological Impact Control Room Doses (rem)

Description Thyroid Whole Body/DDE Skin Inhalation Pathway External Radiation Beta + Gamma (ICRP-30 DCFs) (FGR 12 DCFs) (FGR 12 DCFs)

Condenser Leakage, with MS Lines and/or AOG 2.6E+01 9.5E-03 3.6E-01 isolation (24-hr Leakage)

AOG Releases (24 hr holdup for Kr, 16.6 days 1.1E-04 9.OE-03 3.7E-01 for Xe)

RCS Sampling Line Releases (32 gph for 30 1.5E+00 1.8E-04 2.7E-03 days)

Condenser Leakage +

RCS Sampling Line 2.8E+01 9.7E-03 3.7E-01 Releases AOG + RCS Sampling 1.5E+00 9.1E-03 3.7E-01 Line Releases Acceptance Criteria (remn) 30 5 30

BVY 02-49 / Attachment / Page 10 of 11 RESPONSE TO NRC REQUEST FOR ADDITIONAL INFORMATION Concerning Vermont Yankee Proposed Change No. 250 Table 3.2 VY CRDA - Design Input Condenser Leakage and Releases via the AOG Seq. I DESCRIPTION VALUE A PCflNDFN.ER LEAKA E FOT,IOWING MANUAL STEAM LINE AND/OR AOG ISOLATION Al Fraction of activities released into the rector vessel which reach condenser:

Noble gases 100 %

Halogens 10%

A2 Fraction of halogens (those reaching the turbine and condenser), as well as of 50%

particulates from the decay of noble gases, which plate out inside the condenser and are not available for release A3 Condenser leakage rate (into the turbine building and hence into the environment, without holdup):

0 - 24 hrs 0.5 %/day

> 24 hrs 0.0 %/day B - NO MAIN STEAM LINES ISOLATION - RELEASE VIA THE AOG BI See AI above B2 AOG system holdup times (based on 6 charcoal beds in operation and a 30 scfm condenser air inleakage rate):

Iodines Infinite Kryptons 24 hrs Xenons 16.6 days 3

C - ATMOSPHERIC DISPERSION FACTORS (X/Q sec m )

Cl Stack Releases to CR 0 - 0.5 hr 2.39E-04 (fumig.)

0.5 - 1 hr 1.05E-06 1 - 2 hr 8.70E-07 2 - 8 hr 4.79E-07 8 - 24 hr 2.34E-07 24 - 96 hr 1.23E-07 96 - 720 hr 6.90E-08 C2 Turbine Building Releases to CR 0 - 1 hr 3.665E-03 1 -2 hr 2.187E-03 2-8 hr 7.572E-04 8 - 24 hr 3.934E-04 24 - 96 hr 2.705E-04 96 - 720 hr 2.044E-04

BVY 02-49 / Attachment / Page 11 of 11 RESPONSE TO NRC REQUEST FOR ADDITIONAL INFORMATION Concerning Vermont Yankee Proposed Change No. 250 Table 3.2 (Continued)

VY CRDA - Design Input Condenser Leakage and Releases via the AOG Seq. DESCRIPTION VALUE D -OTHER D1 CR free air volume (area below ceiling, conservative) 41,534 ft3 D2 CR maximum outside air intake (normal operating mode without isolation) 3700 cfm D3 Control room occupancy factors:

0- 24 hrs: 100%

24 - 96 hrs: 60%

96- 720 hrs: 40%

D4 CR operator breathing rate (2-hr interval) 3.47E-04 (m3/sec)

Reference

1. Calculation VYC-221 1, Rev. 0, "Radiological Evaluation of a Control Rod Drop Accident", February 2002.