| title = Project, Revision to Unit 1 and Unit 2 Emergency Action Levels, Evaluation of the Proposed Changes License Amendment Request (LAR) for Revision of EAL Scheme to NEI 99-01 Revision 6. Part 5 of 7

{{#Wiki_filter:OPOP03-ZG-0007 I Rev. 71 Page 197 of216 Plant Cooldown I Addendum 19 Controlling RCS Inventory at or above Elv 39 ft. 4.9 in. Page 3 of 10 INITIALS CAUTION" Do NOT Reduce RCS level Below Ely 39 ft. 4.9 in. using this Addendum.* As pressurizer level lowers to 10% AND before the PZR level goes off scale low, COMPARE Pressurizer level with RC-LG-3662 "RCS LEVEL SIGHTGLASS (SLINKY)" level indication.

 

===3.0 PERFORM===

the following to lower RCS inventory:

3.1 The following instrumentation SHALL be operable prior to RCS Draindown to 39' 4.9": 3.1.1 RHR heat exchanger inlet and outlet temperature with indication on QDPS OR chart recorder for all operable trains.3.1.2 RHR pump flow with indication on QDPS for all operable trains.3.1.3 RHR pump motor current indication (amps) for all operable trains.3.1.4 "RHR PUMP CURRENT LO" Annunciators on Lampbox I M02 for the operable RHR pumps is NOT removed from service.3.1.5 RCS level sightglass has been walked down in last twelve hours and satisfies requirements.

3.1.6 Both trains of RVWL are operable with at least two QDPS displays available.

3.1.7 Core Exit Thermocouples, five per train, two trains.3.2 ENSURE Adequate capacity is available in radwaste to receive volume drained from RCS. REFER TO Addendum 3, Determination of RCS Volume to be Drained.3.3 A dedicated, reliable communication line, headphones being the preferred method, is established between Control Room personnel and RCB sightglass watch.This procedure, when completed, SHALL be retained.

I OPOP03-ZG-0007 Rev. 71 Page 198 of216 j Plant Cooldown Addendum 19 Controlling RCS Inventory at or above Ely 39 ft. 4.9 in. Pa-e 4 of 10 j INITIALS NOTE* Venting and draining operations should be coordinated with the Radwaste Operator and Health Physics." RCS level changes SHALL be made slowly in a controlled manner to minimize effects on reactor vessel level indications.

The RCS level sightglass SHALL be continuously monitored during all draining and refill operations." One of the following pressurizer vent paths SHALL be established prior to draining the pressurizer:

* The Pressurizer spray line vent valves RC-0502 and RC-0503 OPEN to atmosphere.(Preferred Method)" A minimum of one Pressurizer Code Safety Valve REMOVED.* In addition to the specified temperature limits, the intent is to maintain RCS temperature as low as allowed by existing plant conditions, core cooling capabilities or other limiting criteria to maximize margin to core boiling:* (Mode 5) MAINTAIN RCS core exit temperature (RHR HX inlet temp when CETs NOT available) less than 140'F.3.4 IF PZR level wil be lowered below 10% Cold Calibrated level, THEN ENSURE RCS level sightglass is in service.This procedure, when completed, SHALL be retained.

OPOP03-ZG-0007 Rev. 71 Page 199 of 216 Plant Cooldown I Addendum 19 Controlling RCS Inventory at or above Ely 39 ft. 4.9 in. Page 5 of 10 INITIALS NOTE WHEN RC-LG-3662 "RCS LEVEL SIGHTGLASS (SLINKY)" is in service, THEN ENSURE "0POP07-RC-0001, RC Vent Rig/Sightglass Installation and Removal", LINEUP 1,"RC-LG-3662 "RCS LEVEL SIGHTGLASS (SLINKY)" in Service Lineup" PERFORMED daily and DOCUMENTED in a temporary log.3.5 COMMENCE temporary logging of LG-3662 sightglass valves once per shift (Ref. Procedure Step 3.37).CAUTION Prior to draining the pressurizer, a vent path SHALL be established to prevent drawing a vacuum.3.6 IF lowering pressurizer level to below 10% Cold Calibrated level (55 ft 6 inch elevation), THEN PERFORM the following:

 

====3.6.1 ENSURE====

RCS level sightglass is being monitored.

 

====3.6.2 ENSURE====

pressurizer vent path established.

 

====3.6.3 DOCUMENT====

Vent Path.3.6.4 OPEN PZR Spray Valves RC-PCV-655B and RC-PCV-655C.

 

====3.6.5 DETERMINE====

 

RCS volume to be drained using Addendum 3, Detennination of RCS Volume to be Drained.3.6.6 VERIFY "DIVERT LCV-01 12A" in the AUTO position.  

{CP004}3.6.7 Manually RAISE letdown flow using "PRESS CONT PCV-0 135".{CP004}3.6.8 COMPARE Pressurizer level with RCS level sightglass level indication (Should agree within 6 inches. 1% of Pressurizer Cold Calibrated level equals 4 inches).This procedure, when completed, SHALL be retained.

OPOP03-ZG-0007 Rev. 71 Page 200 of216 Plant Cooldown Addendum 19 Controlling RCS Inventory at or above Elv 39 ft. 4.9 in. Page 6 of 10 INITIALS CAUTION IF RVWL system indicates less than 100%, THEN the draindown SHALL be stopped and the level difference between RVWL and RCS level sightglass investigated.

3.6.9 IF pressurizer Cold Calibrated level AND RCS level sightglass do NOT agree within 6 inches, THEN STOP the drain and REFER TO Addendum 15, Rx Head Venting and RCS level Instruments Disagreements Evaluation Guideline.

3.6.10 IF pressurizer level will be maintained, THEN REFER TO Step 3.22 of this Addednum.CAUTION IF during any RCS draining process, fluctuations are observed in RHR pump flow, amps, OR discharge pressure, THEN any RCS drain in progress SHALL be stopped to allow RCS water level to stabilize and any RCS water level recovery SHALL be initiated as necessary to ensure RHR system operation.

 

===3.7 PLACE===

Reactor Vessel head temperature on trend display. (Plant Computer points IITE2040 and IITE3040)3.8 IF lowering of RCS level is to continue, THEN DRAIN to between 47 ft. 4 in.and 46 ft. 5 in. elevation as indicated on RC-LG-3662 "RCS LEVEL SIGHTGLASS (SLINKY)".

OPOP03-ZG-0007 Rev. 71 Page 201 of 216 Plant Cooldown E Addendum 19 Controlling RCS Inventory at or above Elv 39 ft. 4.9 in. Page 7 of 10 INITIALS NOTE WHEN RVWL Sensor Point I has been uncovered, THEN indicated temperature will rise to about 750'F due to heating from the heated junction thermocouple.

 

===3.9 VERIFY===

water in reactor vessel head less than 180'F as indicated by Plant Computer display RC12 (8112).3.10 PLACE the Reactor Vessel head to pressurizer equalizing line in service as follows: 3.10.1 ENSURE the reactor vessel head venting manifold is connected per OPOP02-RC-0003, Addendum 1, Filling and Venting the RCS.{RCB on RV Head)3.10.2 ENSURE the RV to PZR Equalizing Line is aligned lAW OPOP03-ZG-0009, Mid-Loop Operation.

OPOP03-ZG-0007 Rev. 71 Page 202 of 216 Plant Cooldown Addendum 19 Controlling RCS Inventory at or above Ely 39 ft. 4.9 in. Page 8 of 10 INITIALS 3.11 WHEN RCS level is between 47 ft. 4 in. and 46 ft. 5 in. as indicated on RC-LG-3662 "RCS LEVEL SIGHTGLASS (SLINKY)", THEN PERFORM the following:

3.11.1 OPEN the following valves to remove water plug (Loop Seal) from Head and Pressurizer vent manifold and Rx Head Vent line: "1(2)-RC-0509 RX VESSEL HEAD""VENTING MANIFOLD DRAIN"{RCB On RV Head}"1(2)-RC-0507 RX VESSEL HEAD-"VENTING MANIFOLD VENT VALVE"{RCB On RV Head}3.11.2 IF the reactor vessel head vent valves are operable, THEN OPEN the Reactor Vessel head vent valves. {CP005}* "ISOL HV-3657A"* "ISOL HV-365713"* "ISOL HV-3658A" 0 "ISOL HV-3658B"* "HEAD VENT THROT VLV HCV-0601"* "HEAD VENT THROT VLV HCV-0602" 3.11.3 IF desired, THEN OPEN PRT "1(2)-RC-0025 N2 SUPPLY ISOL".{RCB 6 ft E of PRT}3.11.4 IF RCS level will be maintained, THEN REFER TO Step 3.22.This procedure, when completed, SHALL be retained.

OPOP03-ZG-0007 Rev. 71 Page 203 of 216 Plant Cooldown I Addendum 19 Controlling RCS Inventory at or above Elv 39 ft. 4.9 in. Page 9 of 10 INITIALS 3.12 IF RCS level is to remain below 47 ft. 4 in, THEN PERFORM the following:

CLOSE "1(2)-RC-0507 RX VESSEL HEAD""VENTING MANIFOLD VENT VALVE"{RCB On RV Head}ENSURE "1(2)-RC-0509 RX VESSEL HEAD" "VENTING MANIFOLD DRAIN"{RCB On RV Head} remains OPEN to vent the HEAD.NOTE The temperature rise will occur when sensor is uncovered prior to RVWL point indicating dry.WHEN RVWL Sensor Point I has been uncovered, THEN indicated temperature will rise to about 7507F due to heating from the heated junction thermocouple.

WHEN RC-LG-3662 "RCS LEVEL SIGHTGLASS (SLINKY)" is in service, THEN ENSURE "OPOP07-RC-0001, RC Vent Rig/Sightglass Installation and Removal", LINEUP 1. "RC-LG-3662 "RCS LEVEL SIGHTGLASS (SLINKY)" in Service Lineup" PERFORMED daily and DOCUMENTED in a temporary log.CAUTION Inadequate head venting due to rapid draining can cause Reactor Vessel water level to remain higher than loop level.3.13 IF lowering of RCS level is to continue, THEN DRAIN RCS until RVWL Sensor Point 1 (45' 3.4") heated junction thermocouple temperature rises by 207F. (Plant Computer Points IITE2004, A-Train, IITE3004, C-Train)3.14 COMPARE RCS level sightglass indication with RVWL level.3.15 IF RVWL AND RCS level sightglass do NOT agree within 6 inches, THEN STOP the drain and REFER TO Addendum 15, Rx Head Venting and RCS level Instruments Disagreements Evaluation Guideline.

OPOP03-ZG-0007 Rev. 71 Page 204 of216 Plant Cooldown Addendum 19 Controlling RCS Inventory at or above Ely 39 ft. 4.9 in. Page 10 of 10 INITIALS 3.17 REFER TO Addendum 3, Determination of RCS Volume to be Drained, to determine draindown volume.NOTE* The temperature rise will occur when the sensor is uncovered prior to RVWL point indicating dry." WHEN RC-LG-3662 "RCS LEVEL SIGHTGLASS (SLINKY)" is in service, THEN ENSURE "OPOP07-RC-0001, RC Vent Rig/Sightglass Installation and Removal", LINEUP 1, "RC-LG-3662 "RCS LEVEL SIGHTGLASS (SLINKY)" in Service Lineup" PERFORMED daily and DOCUMENTED in a temporary log.* Do NOT Reduce RCS level Below Ely 39 ft. 4.9 in. using this Addendum.3.18 IF lowering of RCS level is to continue, THEN DRAIN RCS until RVWL Sensor Point 2 (39' 4.9") heated junction thermocouple temperature rises by 20'F. (Plant Computer Points IITE2007, A-Train, IITE3007, C-Train)3.19 COMPARE RCS level sightglass indication with RVWL level.3.20 IF RVWL AND RCS level sightglass do NOT agree within 6 inches, THEN STOP the drain and REFER TO Addendum 15, Rx Head Venting and RCS level Instruments Disagreements Evaluation Guideline.

3.21 ADJUST RHR HX flow as required to maintain RHR HX inlet temperature less than 140'F.3.22 MAINTAIN RCS level using any of the following:

* Raise RCS level as necessary using gravity drain from RWST through the LHSI pump cold leg injection valves in the idle RHR train* Raise RCS level as necessary using CCP normal charging or seal injection* Reduce RCS level as necessary using low pressure letdown 3.23 MAINTAIN temporary log OPOP07-RC-0001, LINEUP 1, "RC-LG-3662 RCS LEVEL SIGHTGLASS (SLINKY)" in Service Lineup as required. (Ref.Procedure Step 3.37)3.24 To raise RCS level, GO TO Step 2.0 of this addendum.3.25 RETURN TO Procedure Step in effect.This procedure, when completed, SHALL be retained.

OPOP03-ZG-0007 Rev. 71 Page 205 of216 Plant Cooldown Addendum 20 Venting Reactor Vessel Head Using Head Vent Throttle Page 1 of 2 Valve(s)INITIALS NOTE* This addendum vents a voided Reactor Vessel head when the RCS in Modes 5 or 6." HJTC Train "A" or Train "C" RVWL Sensor I indications are found at Computer Points IITE2004 and I1TE3004, respectively.

 

===1.0 CHECK===

the following indications for Reactor Vessel Head voiding:* Pressurizer level rising AND" VCT level constant OR rising AND* RVWL Sensor 1 temperature rising 2.0 IF Reactor Vessel Head voiding is indicated, THEN vent the Reactor Vessel Head to the PRT as follows: 2.1 OPEN Head Vent Isolation Valves:* ISOL HV-3657A and ISOL HV-3658A OR* ISOL HV 3657B and ISOL HV-3658B 2.2 OPEN Head Vent Throttle Valve(s):* HCV-0601* HCV-0602 This procedure, when completed, SHALL be retained.

OPOP03-ZG-0007 Rev. 71 Page 206 of 216 Plant Cooldown Addendum 20 Venting Reactor Vessel Head Using Head Vent Throttle Page 2 of 2 Valve(s)INITIALS 2.3 MONITOR for the following indications of the Reactor Vessel Head being vented: " Pressurizer level lowering AND* RVWL Sensor I temperature lowering AND* PRT pressure rising 2.4 WHEN the Reactor Vessel Head void is vented, THEN PERFORM the following:

 

====2.4.1 ENSURE====

CLOSED the Head Vent Throttle Valve:* HCV-0601* HCV-0602 2.4.2 ENSURE CLOSED the Head Vent Isolation Valves:* HV-3657A* HV-3657B* HV-3658A" HV-3658B This procedure, when completed, SHALL be retained.

OPOP03-ZG-0007 Rev. 71 Page 207 of 216 Plant Cooldown Addendum 21 Closure of Personnel Air Lock Doors Page 1 of 2 1.0 Purpose: 1.1 Provides instructions for closing Personnel Air Lock (PAL) doors to establish containment closure during work activities inside Reactor Containment Building (RCB) that require both PAL doors to be open.2.0 Instructions:

 

===2.1 PERFORM===

the following to close Personnel Air Lock doors (M-90): 2.1.1 ENSURE the following conditions at RCB PAL door:* Door-seating surfaces are clear of all obstructions.

* Handwheel position indication in "OPEN" position.* Both door latch pins fully retracted to ensure NO interference with door closure.2.1.2 PULL RCB PAL door CLOSED.2.1.3 WHEN RCB PAL door is flush with door jam, THEN ROTATE RCB PAL door hand wheel to "CLOSED" position to engage door latch pins.2.1.4 ENSURE the following conditions at MAB PAL door:* Door-seating surfaces are clear of all obstructions.

* Handwheel position indication in "OPEN" position.* Both door latch pins fully retracted to ensure NO interference with door closure.2.1.5 PULL MAB PAL door CLOSED.2.1.6 WHEN MAB PAL door is flush with door jam, THEN ROTATE MAB PAL door hand wheel to "CLOSED" position to engage door latch pins.This procedure, when completed, SHALL be retained.

I OPOP03-ZG-0007 Rev. 71 Page 208 of 216 Plant Cooldown Addendum 21 Closure of Personnel Air Lock Doors Page 2 of 2 NOTE An ECO Caution Tag will be hanging on 1 (2)-XC-0037 and MCB switch for PAL Seal OCIVs to prevent pressurizing door seals with the doors open.2.2 PERFORM the following to pressurize PAL door seals: 2.2.1 OPEN "1(2)-XC-0037 RCB PERSONNEL AIRLOCK SEAL AIR SUPPLY ISOLATION VALVE". (MAB 60', Room 326)2.2.2 NOTIFY Control Room (8614, 8610, 1111(7953, 8683, 2222)} that BOTH PAL doors are in the CLOSED position AND valve 1(2)-XC-0037 is OPEN.2.2.3 REQUEST Control Room to pressurize PAL door seals by taking"PERS AIR LOCK SEAL OCIVS" switch to OPEN. (CP005)This procedure, when completed, SHALL be retained.

OPOP03-ZG-0007 Rev. 71 Page 209 of216 Plant Cooldown Data Sheet 1 RCS and Pressurizer Cooldown Rates Page 1 of 4 Unit: Date: Initial Time: I. RECORD data at 15 minute intervals.

: 2. Pressurizer cooldown rate SHALL NOT exceed 200"F (160 0 F/hr ADMIN LIMIT) in any one hour. (TRM 3.4.9.2) Cooldown rate is the actual cooldown over the hour period.(i.e. :°FTemperature recorded 60 minutes prior to current time -°FTemperature current = A°F/hour)3. OBTAIN RCS pressure from QDPS Detail Data Menu Page 1 (PT403, PT404, PT405, PT406 or PT407)4. OBTAIN RCS temperature from QDPS Detail Menu Page 1 (TE414, TE424, TE434, or TE444)5. RCS cooldown rate SHALL NOT exceed 100°F (80'F/hr ADMIN LIMIT) in any one hour period during cooldown within the limits of Addendum 1. (Technical Specification 3.4.9.1) (Ref 2.70)Cooldown rate is the actual cooldown over the hour period. (i.e.: 0 FTemperatUre recorded 60 minutes prior to current time -0 FTeniperature current = A°F/hour)6. RECORD the differential temperature between the Pressurizer water space TI-0608 and RCS temperature (4). IF cooldown is due to an unisolable RCS leak, THEN differential temperature limit is less than or equal to 250'F. Differential temperature limit is less than or equal to 320'F for normal cooldowns. (Ref 2.62)7. INITIAL the appropriate column.8. 15 minute cooldown rate will be converted to an hourly rate.Calculation: (i.e.: (°FTemperature recorded 15 minutes prior to current time -°FTemperature current ) x 4 = A°F/hour)This procedure, when completed, SHALL be retained.

OPOP03-ZG-0007 Rev. 71 Page 210 of216 Data Sheet 1I RCS and Pressurizer Cooldown Rates Page 2 of 4 9. IF any readings obtained are outside the specified limits, THEN PERFORM the following: (Ref 2.7)9.1 Immediately NOTIFY the Shift Manager/Unit Supervisor of the out of specification reading.9.2 STOP the plant cooldown.9.3 ENSURE RCS temperature/pressure within the specified limits from the QDPS.9.4 MAINTAIN existing RCS temperature and pressure.NOTE The cooldown SHALL NOT be resumed until Engineering authorizes the cooldown to be restarted.

 

===9.5 NOTIFY===

Engineering to perform an Engineering Evaluation to determine the effects of the out-of-limit (NOT ADM1N LIMIT) condition on the structural integrity of the RCS or Pressurizer, as applicable.

[will provide higher indicated change for a given actual system change] and better represents actual metal temperature.

Use of the liquid temperature indication alone will provide assurance that cooldown limits will NOT be exceeded. (CREE 02-3367)Example:* Pressurizer vapor space temperature TI-0607 is non-functional, THEN substitute Pressurizer water space temperature TI-0608, for Pressurizer vapor space temperature TI-0607 in this procedure.

IOPOP03-ZG-0007 Rev. 71 Page 211 of 216 Plant Cooldown I Data Sheet I RCS and Pressurizer Cooldown Rates Page 3 of 4 Unit:- Date: Initial Time: Page -of TIME PRZR VAPOR SPACE PRZR WATER SPACE RCS PRESS RCS PRZR-RCS WTR INITIAL (I) QDPS (3) (7)TI-0607 0 F/HR (8) 0 F/HR (2) TI-0608 0 F/HR (8) °F/HR (2) QDPS (4) oF/HR (8) °F/HR (5) Delta T (6)15 minute Rolling Hourly 15 minute Rolling Hourly 15 minute Rolling Hourly rate rate rate rate rate rate_ _ _ _ _ _......_._ a ._ _ _ _ .._ _ _ _Personnel Participating in cooldown: Name Initials Date Initials Name Cooldown completed by: Data Sheet 1 Reviewed by: Operator Time Shift Manager/Unit Supervisor Date This procedure, when completed, SHALL be retained.

OPOP03-ZG-0007 I Rev. 71 Page 212 of216 Plant Cooldown E Data Sheet 1 RCS and Pressurizer Cooldown Rates. Page 4 of 4 Unit: Date: Initial Tirne:_ Page__ of-(CONTINUATION SHEET)TIME PRZR VAPOR SPACE PRZR WATER SPACE RCS PRESS RCS PRZR-RCS WTR INITIAL ((10) QDPS (3) (7)TI-0607 °F/HR (8) °F/HR (2) TI-0608 °F/HR (8) °F/HR (2) QDPS (4) °F/HR (8) °F/HR (5) Delta T (6)15 minute Rolling Hourly 15 minute Rolling Hourly 15 minute Rolling Hourly rate rate rate rate rate rate This procedure, when completed, SHALL be retained.

OPOP03-ZG-0007 f Rev. 71 Page 213 of 216 Plant Cooldown I Lineup 1 RV to PZR Equalizing Line Lineup Page 1 of 2 UNIT 1 (Circle Unit Performing Lineup) UNIT 2 EXCEPTIONS DEVICE COMPONENT NOUN REMARKS NUMBER DESCRIPTION Personnel participating in device manipulation:

Name Initials Device lineup completed by: Operator Date Time Lineup I Reviewed: Unit Supervisor Date This procedure, when completed., SHALL be retained.

OPOP03-ZG-0007 Rev. 71 Page 214 of216 Plant Cooldownj ineup 1 RV to PZR Equalizing Line Lineup Page 2 of'2 )DEVICE COMPONENT NOUN LOCATION POSITION ALIGNED VERIFIED NEW TAG NUMBER DESCRIPTION REQUIRED BY BY NEEDED RX VESSEL HEAD VENTING 1(2)-RC-0507 MANIFOLD VENT VALVE RCB On RV Head CLOSED 1(2)-RC-0509 RX VESSEL VENTING MANIFOLD RCB On RV Head ** OPEN/DRAIN CLOSED RV HEAD/PZR EQUALIZING LINE RCB 73' Outside On SG 1(2)-RC-0504 DRAIN VLV IA(2A) N Shield Wall CLOSED RX VESSEL HEAD ATMOSPHERIC 1(2)-RC-0132 VENT VALVE RCB On RV Head ** OPEN/CLOSED RX VESSEL HEAD VENTING 1(2)-RC-0508 MANIFOLD PZR EQUAL LINE ISOL RCB On RV head OPEN RV HEAD/PZR EQUALIZING LINE ISOL RCB 73' Outside On SG 1(2)-RC-0501 VLV IA(2A) N Shield Wall OPEN I(2)-RC-0163 PZR SPRAY LINE VENT VALVE RCB Top of PZR OPEN 1(2)-RC-0 103 PZR SPRAY LINE VENT VALVE RCB Top of PZR OPEN RX VESSEL HEAD VENTING

* OPEN/1(2)-RC-0506 MANIFOLD PI-3636 ]SOL RCB On Head CLOSED RCB 1(2)-RC-0070 RX VESSEL HEAD VENT ISOL RV LOCKED On RV Head inside OPEN shield wall* IF PI-3636 is installed, THEN OPEN "I(2)-RC-0506 RX VESSEL HEAD VENTING MANIFOLD P1-3636 ISOL".** OPEN IF RCS LEVEL below 47 ft. 4 in.This procedure, when completed, SHALL be retained.

I OPOP03-ZG-0007 Rev. 71 Page 215 of 216 Plant Cooldown Form 1 CVCS Line Boration Tracking Form Page 1 of 2 UNIT 1 (Circle Unit Performing Form)UNIT 2 INITIALS NOTE Any component and line NOT to be borated to 2800 ppm or greater requires Unit Operations Manager prior permission. (Form 1, Step 3.0)The volumes in Steps 2.0 and 3.0 of this form purge five dead leg volumes through the associated component and piping.With the RCS borated to greater than or equal to 2875 ppm, CVCS system design will mix the following lines ensuring the concentration will be 2800 ppm or greater prior to entering the RCS piping. (Reference 2.112)CVCS sections that do NOT Mixing volume require prior boration 1(2)-CV-FCV-0201, CCP IA(2A) recirc to VCT Volume Control Tank 1(2)-CV-FCV-0202, CCP 1B(2B) recirc to VCT Volume Control Tank 1(2)-CV-LCV-31 19, Aux Spray line Pressurizer 1(2)-CV-0255, CVCS charging discharge Charging pump discharge header to RCS FCV-0205 bypass including Regenerative Heat Exchanger 1(2)-CV-0206, CCP I B(2B) discharge bypass Charging pump discharge header to RCS including Regenerative Heat Exchanger 1.0 IF a component will NOT be borated, THEN PERMISSION from Unit Operations Manager is required, AND N/A components in Step 2.0 and 3.0 of this addendum NOT to be borated.2.0 ENSURE the following components borated to 2800 ppm or greater as follows: ENSURE CCP IA(2A) borated with 600 gallons of 2800 ppm or greater of borated water from VCT through CCP IA(2A) "DISCH ISOL MOV-8377A" per OPOP02-CV-0004.

ENSURE CCP IB(2B) borated with 600 gallons of 2800 ppm or greater of borated water from VCT through CCP I B(2B) "DISCH ISOL MOV-8377B" per OPOP02-CV-0004.

ENSURE 1(2)-CV-MOV-0003 and associated lines to RCS borated with 300 gallons of 2800 ppm or greater borated water per Step 7.12 of this procedure.

ENSURE 1(2)-CV-MOV-0006 and associated lines to RCS borated with 300 gallons of 2800 ppm or greater borated water per Step 7.12 of this procedure.

US/SM This procedure, when completed, SHALL be retained.

0POP03-ZG-0007 I Rev. 71 IPage216 of Q 216 Plant Cooldown Form I CVCS Line Boration Tracking Form Page 2 of 2 3.0 RECORD Time/Date when each component and associated lines were determined to be borated.CCP IA(2A) and associated lines have been inservice with 600 gallons of 2800 ppm or greater borated water flushed.CCP I B(2B) and associated lines have been inservice with 600 gallons of 2800 ppm or greater borated water flushed.1(2)-CV-MOV-0003 and associated lines to RCS have been inservice with 300 gallons of 2800 ppm or greater borated water flushed through it.1 (2)-CV-MOV-0006 and associated lines to RCS have been inservice with 300 gallons of 2800 ppm or greater borated water flushed through it.////This procedure, when completed, SHALL be retained.

RS1 CALC. NO.STPNOC013-CALC-002)E N E R C 0 N CALCULATION COVER SHEET REV. I ExrA)tence AEer-y wro.t Every dft PAGE NO. 1 of 49 Title: Radiological Release Thresholds for Emergency Client: South Texas Project Action Levels Project: STPNOC013 Item Cover Sheet Items Yes No 1 Does this calculation contain any open assumptions that require confinration? (If YES, Identify the assumptions)  

" 2 Does this calculation serve as an "Alternate Calculation"? (If YES, Identify the design verified Calculation.)

Design Verified Calculation No. /3 Does this calculation Supersede an existing Calculation? (If YES, identify the superseded Calculation.)

Superseded Calculation No. V Scope of Revision:

: 1. Change statement of no decay in the STAMPEDE runs.Revision Impact on Results: Values calculated in Attachment I decreased.

and have become the limiting values.J m"" m F ~tudr-alcaflati n-I--- R=imrl rleu irtIn=z F L1I Safety-Related E Non-Safety Related D (Print Name and Sign)Originator:

Chad Cramer Date: 3/21/14 Approver:

Marvin Morris Date: 3/21/14 CALC. NO. STPNOC013-CALC-002 ENERCON C CU TONREV. 1 REVISION STATUS -SHEET R, PAGE NO. 2 of 49 CALCULATION REVISION STATUS, REVISION DATE DESCRIPTION 0 03/0M3/2014 Initial Issue 1 3/21/2014 Resolve inconsistency in decay times for the two calculations PA'.GE REV1ISiON STATUS'PAGE NO. REVISION .REVISION AT'TACHMENT REVISION STATUS ATTACHMENT NO.PAGE NO. REVISION NO. ATTACiMENT NO,:. PAGE NO.REVISION NO.2 1" 2 12-24., 25-31 32-49.1 3.C, CALCULATION ON CALC. NO. STPNOC013-CALC-002 C ENE RCON DESIGN VERIFICATION REV. ICKLIST ..PAGE NO. 3 of 49 Item CHECKLIST ITEMS Yes No N/A 1 Design Inputs -Were the design inputs correctly selected, referenced (latest revision), consistent with the design basis and incorporated in the calculation?

-Were the applicable codes, standards and regulatory requirements, including issue and addenda, properly V" identified and their requirements satisfied?

......8 Design Outputs -Was the conclusion of the calculation clearly stated, did it correspond directly with the objectives and are the results reasonable compared to V/the inputs?9 Radiation Exposure -Has the calculation properly considered radiation exposure to the public and plant personnel?

10 Acceptance Criteria -Are the acceptance criteria incorporated in the calculation sufficient to allow verification that the design requirements have been V/satisfactorily accomplished?

11 Computer Software -Is a computer program or software used, and if so, are the requirements of CSP 3.02 met?COMMENTS: None-(PrintJVame and Sign)Design Verifier:

Chad Cramer Date: 3/21/14 Others: Date:

ENERCON Exce~femte-EwilypMfort Everyft CALCULATION.

DESIGN VERIFICATION PLAN AND  

 

==SUMMARY==

SHEET CALC. NO. STPNOC013-CALC-002 REV. 1 PAGE NO.4 of 49 Calculation Design Verification Plan: Calculation shall be verified by comparing the documented input with the references and checking the validity of the references for the intended use. As necessary, assumptio ns shall be evaluated ind verified to determine if they are based on sound engineering principles and practices.

Verify the applicable metoldology, inputs, results, and cbnclusions..(I (Print Name and Sign for Approval -mark "NIA if nhot reijUlred)

Appiove: Date: 8)21/1 Approver:

Marvin Mor'ris :.: Calculation Design Verification Siummary":  

... ....._.._ _- ._Design inputs, assumptions, methodology, results and conclusions .were evaluated/verified and found to be acceptable.

All comments have been incorporated.

Ci (Print Name and Sign)Design Verifier:

Chad Cramer Date: 3/21/14 Others: Date: C.

CALC. NO. STPNOC013-CALC.002 E 4 E R C 0 N Radiological Release Thresholds REV.I for Emergency Action Levels ExceiM,#-Eeiy ro veit. Ety dAy PAGE NO. 5 of 49 Table of Contents 1.0 OBJECTIVE/SCOPE  

6 2.0  

 

==SUMMARY==

OF RESULTS ..................................................................................................................

6 3.0 METHOD OF ANALYSIS ..........................................................................  

7 4.0 IN P U T S ................................................................................................................................................

==5.0 REFERENCES==

7 6.0 ASSUMPTIONS  

I ....... 8 7.0 STAMPEDE CALCULATIONS  

9 7.1 U nusual E vent -R U I ...................................................................................................................................

9 7.2 Alert, Site Area and General Emergencies  

10 Attachment 1 -Hand Calculations  

12 Attachment 2 -Calculations  

25 Attachment 3 -STAMPEDE OUTPUT ...........................................................................................................

32 CALC. NO. STPNOC013-CALC-002 0 E NE CO N Rdio ogil Releas oThesholds 6of4for Emergency Action Levels~PAGE NO. 6 of 49 1.0 OBJECTIVE/SCOPE The purpose of this calculation is to determine the Emergency Action Level (EAL) threshold values of a radiological release from the Unit Vent or Main Steam Lines for an Unusual Event, Alert, Site Areý'Bmergency,'

The calculated threshold values ae to be included in the STP EAL Technical Basis document, which implements the new NEI 99-01, Revision 6, Emergency Action Level Schetne and will be submitted to the NRC for approvýal.

pon NRC approval, the values will be Used in 0ERPO 1-ZV-INO 1, Revision 10, Emergency Classification.

Both a hand calculation and the South Texas Assessment Model Projecting Emergency Dose Evaluation (STAMPEDE)

Softwre program weere 'ised to generate the results. The hand calculation is included as Attachment 1.Revision I of this calculation incorporated decay for a release taking place one hour after reactor shutdown.

This 'was done to create continuity between the two methodologies pesent.2.0  

 

==SUMMARY==

OF RESULTS'The results of the calJulations for the radiation monitors specified in the STP EAL Basis Document and are listed in Table 2.1, below.Table 2.1: Summary of Calculation Results C Emergency Action Level RT-8010D, Unit Vent (pCilsec)RT-8046 th Main: Ste (PiC RU1 I Unusual Event I Alert.i rough 8049, am Lines f i/cc)tht- MC IýVxz Y I*STAMPEDE was not used to determine the threshold for RUI methodology should be used to determine the threshold value.This calculation will be used to establish the threshold values for abnormal radiation based emergencies in the STP EAL Technical Basis document.  

ALC. NO. STPNOC013-CALC-002 0 E N E R C O N Radiological Release Thresholds REV. I for Emergency Action LevelsN b~ne-w PM W~y ftPGEN.7 f4 3.0 METHOD OF ANALYSIS Previously, STAMPEDE was used to calculate the Emergency Action Level threshold values for effluent releases.

The hand calculation is described in Attachment 1 of this document STAMPEDE conforms to the requirements of STP Procedure OPGP07-ZA-0014, Software Quality Assurance Program. STAMPEDE was run at STP on an STP computer and under the supervision of an ENERCON employee with access to the STP site as a critical worker.4.0 INPUTS 4.1 Per NEI 99-01, Revision 6, Initiating condition AU1, EAL 1, the Notice of Unusual Event initiating condition is a release of gaseous or liquid radioactivity greater than two times the ODCM limit for sixty minutes or longer (Reference 5.10).4.2 The ODCM .offsite dose limit is exceeded if the Xe-133 release concentration exceeds 7.41E-04 piCi/cc (Reference 5.6).4.3 The Unit Vent flow rate is 9.4E+07 cc/sec (Reference 5.1).4.4 The main steam line pressure and PORV choke flow rate are 1285 psig and I .05E+06 lbmlhr, respectively (Reference 5.2).-4-.5---The-spei-fic-volume-ofosaturated-stear-ar--V-285-psig i,0;3-38-ft -tlb-m=(R~

f 4.6 The concentration is varied to find the release concentration which correlates to each emergency action level. Emergency action levels are taken from NEI 99-01, Revision 6 (Reference 5.10) for initiating conditions AA1, AS 1 and AGI. EAL I is the EAL of interest in each initiating condition, The doses at the Site Boundary that correlate to the threshold concentrations are listed in Table 4.1.Table 4.1 EAL Offsite Dose Initiating Conditions Alert Site Area General  

5.2 Main Steam PORV Capacity Verification MC05591, Revision:

1 5.3 NIST Steam Tables, 2011 5.4 OERP01-ZV-INO1, Emergency Classification Draft Revision 10 5.5 OERPO 1 -ZV-TPO 1, Offsite Dose Calculations, Revision 21 5.6 STP Calculation NC-9012, CRMS Rad Monitor Setpoints, Revision 7 537 STP Calculation NC-901 1, Revision 2 5.8 STAMPEDE Computer Program, Revision 7.0.3.3 5.9 STAMPEDE User's Manual 5.10 NEI 99-01, Revision 6, Development of Emergency Action Levels for Non-Passive Reactors 5.11 OPGP07-ZA-0014 Quality Assurance Program :j 5.12 ITWMS Call Number 1000010987 Design Document, Revision 0 CALC. NO. STPNOCOI3-CALC-002 0 "E N E R C.O N Radiological Release Thresholds REV...: .. -for Emergency Action Levels r*Yf*t PAGE NO. 8 of 49 6.0 ASSUMPTIONS 6.1 Unit Vent Noble Gas Monitor To-be consistent'with the ODCM methodology, the.unit vent release is assumed t6be entirely Xe-133. The unit vent noble gas. monitor is calibrated to Xe-133 (Refere,*nc'5, 1) therefore; the monitor reading accurately reflects the Xe-133"release magnitiude.

To be consistent with ODCM methodology, the main steam line release is assumed to be entirely Xe-133. The noblegas monitor is calibrated to Xe- 13 3 (Reference 5.6).6.2 Release Duration Per Reference 5.10, S ections IC AAI.,. AS 1,and AGi developer notes, the release should be assumed to last on6 hour..6.3 Release folilowingReactor Shutdown The release initiates one hour after reactor shutdown.

While a release initiating at'reactor" shutdown is likely, signifiddrit decay of short lived nuclideg occurs during the mligration time. A release at reactor shuiitdown would have a significantly higher activity at the monitor location than

this- -.--. ---would a very high threshbid Which .would not bb-appropriate for releases which occur shortly after shtiidown.

One hour adr reactor shtýtaow is sufficfent time to decay short lived nuclides and createoa conservatie threshld..

 

===6.4 Source===

Term Per Reference 5'1, any' unit vent releaset itlfh increed RCS act ivity and no core melt should be calculated using tlhe-gap inventory.

Thedftore the gap in,ýentoiy is used for all.unit vent releases.Per Reference 5.1 for a main steam line release followirg a steam generator tube rupture it is appropriate to use an inventory of noble gases plus 0.2% iodine. A steam generator tube rupture is the only scenario which would create significant offsite doses through a main steam line release.6.5 Default STAMPEDE Input Values Keference D. I d pr tes rtiatig c P *A-l-.A-St-and-A-&l-suge st-using-he ODCM or the site's emergency dose assessment methodology.

STAMPEDE is Wsed for emergency dose assessment.

Per Reference 5.1, when actual meteorology is not available, the default STAMPEDE values should be used. Had the ODCM methiaddolog6y been* used, the 500 hour peak X/Q value would be used whichis less conservative than-the Xi/Q value produced by STAMPEDE using default meteorological c6ndition:

Therefore, the use of STAMPEDE default values provides a more conservative estimate than that of the altnriiative method outlined in Reference 5.10.6.6 Average Effluent Concentration (X/Q)The same X /Q is used for the unit vent and main steam line release. Reference

 

===5.1 applies===

the same unit vent X/Q to Units 1 and 2 which would also be applicable to the main steam line. All releases are considered to be ground level releases.

CAI.O. NO. STPNOCO1 3-CALC-002 EINNE R C 0 N Radiological Release Thresholds REV. I for Emergency Action Levels R'.ftolance-Evetvpfo Evamdox PAGE NO. 9 of 49 7.0 STAMPEDE CALCULATIONS

 

===7.1 Unusual===

Event -RU1 7.1.1 Unit Vent Monitor AUI recommends declaring an unusual event due to a release of gaseous or liquid radioactivity greater than 2 times the ODCM limits for 60 minutes or longer (Reference 5.10).STP sets the ODCM limit at 7.41E-04 j, Ci/cc (Reference 5.6, pg. 16). Two times the limit would be 1.48E-03 ýtCi/cc..

The threshold is listed in .iCi/sec so that variations in flow rate do not change the threshold.

The normal flow rate from the unit vent is 9.4E+07 cc/sec (Reference 5.1)., cc ~ ~Ci Concentration

* Flow Rate = Release Rate ccsec \ see/-(1.48E -03) (1 *,(9.4E + 07)(c)= 1.4E + 05 (!C§.. Equiatid-7.1.1:1.........71 7.1.2 Main Steam Line Monitor The ODCM does not calculate a release corresponding to allowable limits for the main steam line monitors.

Since the unit vent release calculated in the ODCM was assumed to be primarily Xe-133, the assumption is made in the ODCM that other noble gases and iodine may be ignored in the calculation.

This assumption is equally justifiable for the main steam line and the same limiting release will be used.The magnitude of the release calculated for the unit vent Unusual Event applies to the main steam lines as well. The main steam line PORV's will create a dose exceeding two times the ODCM limit by releasing 1.4E+05 p.Ci/sec of activity which is equivalent to the release from the unit vent.The steam lines hold saturated steam at 1285 psig, per Reference 5.2, which has a specific volume of 0.338 fl 3/lbm (Reference 5.3). The PORVs will release the steam at 1.05E+06 lbm/hr per Reference 5.2. This creates a set flow rate of steam from the main steam lines of 2.79E+06 cc/sec as shown below.flbm (ft 3\ CC ( sec~ cc F D Density.

+ 3600* *= 279 + 6)lbm (t 3 (cc' (sec\ cc 1.OSE +06 hr*) 0.338 28316.846  

+ 3600 -)= 2.79E + 06-Ehr aionbm 7.. sec Equation 7.1.2.1 O " " .CALC. NO. STPNOC013-CALC-002 Radiologic.al Release Thresholds CL. N.SMO03CL-

'E-NER.CO.N REV. I.d .. -for Emergency Action Levels PAGENO. 10 of 49 Since the flow rate is set, the concentration will determine the limit. Equation 7.1.1.1 solves for the limiting concentration of 5.OOE-02 1 , Ci/cc as shown below.Limiting Release (Jr!) _ ., sec = Limiting Concentration (Release Rate ccC/-* .oo 06 02 ( : 2.79* 106 cc (\cc Equation 7.1.2.2 7.2 Alert. Site Area andGeneral Emergencies  

-"RAl, RS1, RGI.7.2.1 Unit Vent Monitor C Input The Alelr EAL is set to 10 mrem TEDE and 50 mrem Thyroid CDE per Reference 5.10._- The-emergency-offsite-dose.

cdlculation-softwae STA -EDE. was _wdJQ kuja~te the-release which corresponds to this dose. A release concentration correlating to the EAL threshold value was calculated by varying the input. The foll6wing assu.mptions and inputs were -used forthe calculation as described in Sections 4.0 and 6.0..Release begins at reactor triP..* Release lasti for qie hour:.G Gap surce te" .* Defauklt STAMPEDEVinput.values.

13.2 mph o StabilityW class D.Results'C Given a monitored unit vent release of 2.50E-i+06 PICi/sec, the.Thyroid CDE is 51 andt-he-EATInitiatingCondition i.exceeded., Threshold values for the Site A.rea Emergency ay d General Emergenclis are multiples of 1 0 and 100 of the AIeit. Sincethe correlatioinbetween release cojncentration and dose is linear, threshold values for the steam line monitors are 2.50E+07 and 2.50E+08 [LCi/sec for the SAE and GE:respectively.

Both. are also limited by Thyroid CDE. Additional STAMPEDE iterationis Were performed to confirm this and aie attached.The input and output files can be found at the end of this document in Attachment 3.C CALC. NO. STPNOCOI3-CALC-002 EN E R CO N Radiological Release Thresholds for Emergency Action Levels REN. IAW, ydaX PAGE NO. I I of 49 7.2.2 Main Steam Line Monitor Input A release concentration correlating to the EAL threshold value was calculated by varying the input. The following assumptions and inputs were used for this calculation as described in Sections 4.0 and 6.0." Release begins at reactor trip* Release lasts for one hour* Noble gas + iodine with 0.2% iodine source term* Default STAMPEDE input values o Windspeed  

= 13.2 mph o Stability class D Results Given a monitored main steam line release of 4.5 ýiCi/cc, the Thyroid CDE is 50 mrem/hr and the EAL Initiating Condition is exceeded..-..... --Tie-inputtand-output-files-can be found-at-the end of-this documentin Attachment3;  

.- -.... -7.3 Threshold values for the Site Area Emergency and General Emergencies are multiples of 10 and 100 of the Alert. Since the correlation between release concentration and dose is linear, threshold values for the steam line monitors are 45 and 450 4tCilcc for the SAE and GE respectively.

Both are also limited by Thyroid CDE, Additional STAMPEDE iterations were performed to confirm this and are attached.

Radiological Release Thresholds ALC. NO. STPNOC013-CALC-002 0 E N E R C O N for Emergency Action Levels REV._Attachment 1 PAGE NO. 12 of 49 I Attachment 1 -Hand Calculations 1.0 OBJECTIVE/SCOPE Each release calculated using STAMPEDE in the main document is calculated by hand in this attachment and the results compared to STAMPEDE.2.0  

 

==SUMMARY==

OF RESULTS Table 2.1 is displayed again below showing the'results from all the calcuIations.

This also accounts for the change in the limiting dose being TEDE in the hand calculations and Thyroid CDE in the STAMPEDE calculations.

The accuracy of the hand calculation is considered sufficient and recommended for use in Emergency Action Levels.Table'2.1 Results Emergency Action RT-8010b, Unit Vent_- ___- _ .. .

--* (plci/cc)C HAI 1151 mI 6e Area E~mergencyI I uenerai Eimergency 1 3.0 METHOD OF ANALYSIS Using the limiting dose at the site boundary, the release is back calculated using atmospheric dispersion models. The X/Q value used is calculated from Regulatory Guide 1.145,.Atmospheric Dispersion Models for PotentialAccident Consequence Assessments at Nuclear Power Plants. Rather than using the most conservative meteorology, average meteorological conditions are used as inputs C Radiological Release Thresholds CALC. NO. STPNOC013-CALC-002 O NE RCO N "for Emergency Action Levels RV. 1 Attachment 1 PAGE NO. 13 of 49 to most closely agree with STP emergency dose assessment methodology per the ODCM and STAMPEDE.

Assumed nuclide inventories are taken from Reference 5.4. The dose conversion factors are taken from Reference 5.2. A release concentration is used to find an initial projected dose at the Site Boundary.

Using the projected dose at the Site Boundary, the release concentration is scaled to find the limiting dose for each EAL.4.0 INPUTS* The Unit Vent flow rate is taken from the Offsite Dose Calculation Manual; Revision 17, March 2011 and is 9.44E+07 cc/sec.* The main steam line pressure and PORV choke flow rate were taken from Reference 5.5 and are 1285 psig and 1.05E+06 lbm/hr respectively.

* The specific volume of saturated steam at this pressure is taken from the NIST steam tables and is 0.338 ft 3/Ibm.* The release concentration is varied to find the release concentration which correlates to each emergency action level dose. Emergency action level doses are taken from NEI 99-01 Revision 6 for initiating conditions AA 1, AS 1 and AG1. EAL 1 is the EAL of interest in each initiating condition.

The limiting doses are listed in Table 4.1. NEI 990-01 Revision 6 states that these values -bWA-tio--.  

----Guidelines (EPA PAGs) and the General Emergency represents the protective action values recommended by the EPA.Table 4.1 EAL Thresholds Alert Site Area General* A release lasting one hour is selected per NEI 99-01 Revision 6 developer notes.* Atmospheric dispersion factors are calculated per Regulatory Guide 1.145 (Reference 5.1). The reactor building dimensions used as inputs for this calculation are taken from Reference 513.* Nuclide inventories are taken from TGX/THX 3-1, (Reference 5.A) which is the source document for the nuclide inventories used in STAMPEDE.

The release inventories are a gap release and noble gases plus 0.2% iodine which are listed below. Each nuclide inventory was normalized to 1r,4ZV dULIVLUU5.

Radiological Release Thresholds CALC. NO. STPNOC013-CALC-002 I0 E N ER C O0 N for Emergency Action Levels IE .4 Attachment I PAGE NO. 14 of 49 Table 4.2 Gap InventoryActivity Normalized Nuclide' Actiifty (.wiClk Normalized 1-132 l.50E+/-+05 1.53E-03 Xe-137 ~1.00 +O7 1.747,75OI 1-134 2.4:0t+05 2.45E-03 Cs-'134 3,7'0E;ý+ý01 3.78E07 Kr-83mn 1.36F-+06 l.33E-ý021 Tel32., 4.0Ei 4 91E-108 Kr-85 370E+/-95 3.78E0 Ru ........3 9.00E-l11 IXr-88 7.g6tEý66  

:719EO PS9 1.10E-02' 1.12EM,'Xe-131 -l1OB.5 .ll~Q .T Ce44 A.O-3 75E Xe-133 2.tE+7 2ý25P,-Ol Sr9 AG-0 55-lo A,{-C C Table 4.3 Noble Gases+0.2%

Iodine Inventory Nuclide Inventory,-Nhrmlied 1-,13. .6E0 92P19E0 1-13 I861-oý2 6.9E05'"x in3 2.80E+OO 1jA.04E0 Xe-13n~ 770E+O 7 1776E02:.d~X.~J~i 1.JV.LU I .'t.L IU X6-138 5.80E'01 2.15E-03 Kj.r-85 7.60E+OG -2.82E-02 Kr-97 9.80E-01 3.63E-03 Kr-89 8.40E-02 3.12E-04 The dose conversion factors taken from EPA 400R92001 (Reference 5.2) are listed in Tables 4.4 and 4.5 below.C Radiological Release Thresholds CALC. NO. STPNOCO13-CALC-002 0 E NE R CON for Emergency Action Levels REV. I& ,,n -Attachment 1 PAGE NO. 15 of 49 Table 4.4 TEDE Dose Conversion Factors Dose Conversion Factor Nuclide (rem Der uCi*hr/cc)

Dose Conversion Factor (rem per uCi*hr/cc)

Nuclide 1-1324.90E+03 Xe-137 lE0 1-134 3. 1OE-I03 Cs-134 6.30E+04 Kr-85 1.30E+00 Ru1O3 13E0-88 1.30E+03 Zr95 32E0 Xe-l3tin--- -4.9----Ce144 -----4M.0E+05 3 I 2.OOE+O Sr89 5.00E+04 Table 4.5 Thyroid CDE Dose Conversion Factors Thyroid CDE DCF Nuclide (rem Cer uCl*hr/cc)

The unit vent noble gas monitor energy efficiency by nuclide is taken from Offsite Dose Calculation Manual (Reference 5.3). The values are relative to Xe-133 efficiency since the monitor is calibrated to Xe-133. Table 4.6 displays the energy efficiency by nuclide relative to Xe-133.

Radiological Release Thresholds CALC. NO. STPNOCOI 3-CALC.002 0 E N E R C O N for Emergency Action Levels REV. I Attachment 1 PAGE NO. 16 of 49 Table 4.6 Energy Efficiency Relative to Xe-133 Efficiency Relative to X9-133., e133m 0.1* " xv- ... '."0042 *There ish, .o relative efficiency available for Ass umption 6A4 fiurther justifies th omission.Table 4.7 Nuclide Half Lives Nuclide Half Life Nuclide Half Life (b~r)(hr)C-T-ý3 Mý =639PI-02 1-132 8Eý001 Xe-137 1-134 8.77E-01 Cs-134.1.80E÷04 1.83E+OO Te132 7.79E+01 Kr-85 9.40E+04 Ru103 9.44E+02 Kr-88 2.84E0O Zr-95 1,55E+03 Xe-131m 2.83E+02 Ce144 6.92E+03 Xe-133 1.27E+02 Sr89 1.21E+03 ci* The half-lives are taken from Reference 5.15 which lists the input data used by STAMPEDE.

Radiological Release Thresholds CALC. NO. STPNOC013-CALC-002 E N E R C 0 N for Emergency Action Levels REV. I FX6flc.c&U>'prqjCd ,iwydax Attachment 1 PAGE NO. 17 of 49

==5.0 REFERENCES==

 

 

===6.1 Release===

lasts for one hour Per NEI 99-01 (Reference  

.5.14), IC AA1, ASI, AG1 developer notes, the release should be assumed to last one hour.For this to be true for the main steam line, it is assumed that the PORV is open for one hour. To calculate the most limiting case, it is assumed that the maximum flow possible is being released from the PORV.6.2 Nuclide mix Per OERPO1-ZV-TPO1, Offsite Dose Calculations (Reference 5.8) any unit vent release with increased RCS activity and no core melt should be calculated using a gap inventory.

It is conservative to assume an increased RCS activity and not within the intended scope of the relevant initiating conditions to assume core melt. Therefore, a gap inventory is used for all unit vent releases.Per OERPOI-ZV-TP01, Offsite Dose Calculations (Reference 5.8) for a main steam line release following a steam generator tube rupture it is appropriate to use an inventory of 100 percent noble gases plus 0.2 percent iodine. Since a steam generator tube rupture releasing through the PORVs is the only steam generator tube rupture scenario which would create offsite doses large enough to meet or exceed the EALs, this assumption is made.

Radiological Release Thresholds CALC. NO. STPNOCO13-CALC002 E N E. R C O :N for Emergency Action Levels REV.1* Attachment 1 PAGE NO. 18 of 49 6.3 Atmospheric Dispersion NEI 99.01 (Reference 5.14) developer notes for initiating conditions AA 1, AS I and AGl suggest using the ODCM or the site's emergency dose assessnient methodology.

1-ZV-TP01, offsite Dose Calctilations (Reference 5.8), whien actoal-.neteorologyisnot available, the default.STAMPEDE values should be used. The default STAMPEDE valuesassume s stability class D for atmospheric dispersion and a windtpeed of 1.3.2 mph. These"Value$

were used as inputs for the atmosphe:ic dispersionrcaliulation..-...:

It is clear that STAMPEDE uses the same method for calculating atmospheric dispersion factor (X/Q) outlined in section 7.1. 1. of this Attachjment.

However, STAMPEDE, does not follow the same logic in selecting the .e."rstilt-from..

The.ST EDE value printed in the"results found in attachm fit 3 is',consistent with the lag.get of the three hand calculated X/Q values. This gsts that STAMPEDE simiply seleets ihe laigest of the three X/Q values resulting in a much more consefVativ estimate, This calculatio.n wii deyiate from the recommendations of Regulatoi:yGuid.

1.145 and.donfdrm to the methodology STAMPEDE uses.The. close'proximity of all re dde points allows ftora single atmospheric dispersion coefficient to be used. This assustmption is also , .... ...-: (6.4 Exposure Pathways The dose conversion factors used in table 4.4 and 4.5 represent a summation of d'se conversion factors for external plume exposure, inhalation from theplume, and external exposure from deposition, Because the dose estimarlatos are used for implementing early phaseprotective actions, conv ersion .factors using limited pathliwys:

..The EPA does not provide a dose conversion factor for kr-83m. Becausethe PAGs are based on-. EPA dos. calculations, it is appropriate to only us.-e th e nuclideg for which dose conversion factors areprvidbed.:-

Additionally, Kr-83m. represents only 1.33 -o of tie niclide inventory activity and its exclusion would not significantly affect the final dose.6.5 The release initiates one hour after reactor shutdown.

While a release initiating at reactor shutdown is likely, significant decay of short lived nuclides occurs during the migration time. A-!r~ o Oi gl  

.ruterr-1 o *ation-thm-i-a at the re:eption Site. It isimpotit fotthethreshold to not be calculated at shutdown as this wo0uld create a very high t h res h old which w oul.d not be api ropriate for releages which occur sotyaer shutdown.i on'ehýur:

after reactor shutdown is shfiý n ie.od~i hr ie shortly after std n.OehuaferecosudonIs sufficie'nt tim~e to doe: 4y short lived nudides and createa conservativethresliold..." Decay is incorporated forone hour from reactor shutdown as well as migration time. Half-lives are taken:from Reference 5.15. Migration time is assuimed to be the reciprocal of the wind speed..

Radiological Release Thresholds CALC. NO. STPNOCO13-CALC-002 3 E E E R C 0 N for Emergency Action Levels REV. I imd Attachment I PAGE NO. 19 of 49 7.0 HAND CALCULATIONS 7.1 Unit Vent Monitor 7.1.1 X/Q The atmospheric dispersion factor, X/Q, determines the change in concentration between the unit vent discharge and the dose reception site. This value is based on meteorological conditions and will vary with wind speed and stability class. The ODCM uses the highest annual average X/Q value at the site boundary which is 5.3E-06 sec/m 3.However, for an accident related release STAMPEDE is used rather than the ODCM. STAMPEDE uses real time, user entered, or default meteorological conditions to calculate the X/Q for a specific accident.

Default values will be used as inputs into the Regulatory Guide 1.145 method for calculating X/Q as described below. Default values are identified in section 6.0, Atmospheric Dispersion.

For a neutral atmospheric stability class, which is the default in STAMPEDE, X/Q values can be determined through the following set of equations.

Q U 1 0 (ryr 2 Equation 7.1.1.1 X 1 QUio(3iwyo.)

Equation 7.1.1.2 X 1 Equation 7.1.1.3 Where X/Q = relative concentration (sec/m^3)it = 3.14159 U 1 0 = windspeed at 10 meters above plant grade (m/s)y = a er p me prea imn, a unc ion of atmosphTinc stabi ity and distance, determined from Regulatory Guide 1.145 Figure 1 Oz = vertical plume spread (in), a function of atmospheric stability and distance, determined from Regulatory Guide 1.145 Figure 2 y =(M -1)uy8oom + ouy = lateral plume spread with meander and building wake effects (m), a function of atmospheric stability, windspeed U 1 0 , and distance; M is determined from Regulatory Guide 1.145 Figure 3 A = the smallest vertical-plane cross-sectional area of the reactor building (mA2), taken from Reference 5.13 and shown below Radiological Release Thresholds tALC. NO. STPNOC013-CALC-002 E N EW R C O :N for Emergency Action Levels .REV. I Attachment 1 PAGE NO. 20 of 49 Figure 7.1.1.1: Reactor Building Dimensions C EL 241*'0 C Assuming the reactor building cross section to be a perfect rectangle and half sphere, the variables are defined as follows;U 1 0= 13.2 mph 5.9 m/s-z =4.2 m Fy (M -1)oy m + cy ;M=I -+ y =1200m A (135'* 158') + (L72) =-31128.37 The three equations become;x 1 2 5.9 7r120 *4.2

* 31128.37 C Radiological Release Thresholds CALC. NO. STPNOC013-CALC-002 ENERCO N for Emergency Action Levels R 1xle ,,-vv Attachment 1 PAGE NO. 21 of 49 X 1= 3.568

* 10-6 Q 5.9(37r

* 10-s Q 5.9

* ir * [(1 -1)ayaoom + 1200]

* 4,2 To select the appropriate X/Q value, the first two X/Q values should be compared and the higher value selected.

This value is then compared with the third X/Q value and the lower of those two is the appropriate X/Q value. The appropriate X/Q is 5.3 9E-06 sec/mr 3 for default meteorological conditions by the methodology recommended in Regulatory Guide 1.145.This calculated value is very similar to the ODCM highest average value of 5.3E-06 sec/n 3 which was not selected for use. Additionally, the value shown in the STAMPEDE output file at one mile is 1.032E-05 sec/m 3.This suggests that STAMPEDE uses the same methodology and simply selects the largest atmospheric dispersion value to remain conservative.

..As previously stated, a gap inventory is appropriate for this problem. The gap inventory is taken from TGX/THX 3-1 (Reference 5.4) which is used as the source term for STAMPEDE inventories.

The concentrations were then normalized so they could be scaled to the varying emergency classifications.

The values for the normalized inventory can be found in Table 4.2.7.1.3 Dose Conversion Factors As stated in NEI99-01 (Reference 5.14) developer notes, the purpose of dose projections is to check if the Environmental Protection Agencies Protective Action Guidelines (EPA PAGs) have been exceeded.

The dose conversion factors provided by the EPA in EPA 400R92001 are used. These dose conversion factors account for external plume exposure, inhalation -from the plume, and external exposure from deposition and are listed Tables-+.,- WIiU '.J3,' LW IW1 )1J~11 LU 1 -J.- ,-, 3-. HI nu"-k r'VU1\.YeUU f

The lack of this nuclide's contribution to the final dose will not significantly affect the outcome.7.1.4 Decay Time One hour of decay is incorporated to the monitor response due to the release initiating one hour after reactor shutdown.

Decay is also incorporated for the duration of the migration time. The total decay time is one hour plus the reciprocal of wind speed, or 1.07575 hours.

Radiological Release Thresholds CALC. NO. STPNOC013-CALC-002 EN ER CO N for Emergency Action Levels "RV.I fta ,i-Ey P dyAttachment 1 PAGE NO. 22 of 49 (7.1.5 Dose Calculations The dose rate at the site boundary is calculated using Equation 7.1.5.1.X .. .n1.07575.D = Ci

* 0..5 'DCF Equation 7.1.5.1 Where' dose rate per hour at the site ounidary x atmospheric dispersion coefficient as calculated in section 7.1.1'.F u"nit vent flow iate ..C., conc-"d eetration of nuclidi iat the time of shuitdow t 0575" the total decay time of interest from section 7.1.4-Tti.=- the half-life.

of ri.uclide I'DCFt.t the dpse. 6nversion factor for nuclide i listeed-in tables 4.4 and.."4.5 1: The total iaiiclides is varied to find the.dose rate of interest.Beginming with an arbitrary release concentration of 4Ci/cd."the dose rate is calculated.

Since the dose is linearly correlated t0o coicentrat ion, thejrelea, econcentration may be scaled to find the dos erate ofinterest.

The Alert EAL[s 10mrf" i TEDE or 50 mrnm Thyroid CDE. Using the above method to calculate TEDE with the appropriate conversion factors, a timiflng release rate of.:.2.33,E+-06 the unit ventresultsin 5.7.mrrm TEni .,.Ui ng the calculated release rate tofmdyd T D iththe propriat ecnversion factors, the same release resulý iin a 50 m.rem Lhyroid .CDE at the site boundar.;

Thus, 2.33E+06 gCi/sec is the limiting rlease rate based on the.50 mirem Thyroid C1'l EAL" fiitiating condition.

The limiting release fate threshold values for the Site Area Emergency and General Emergencies are multiples of 10 and 100 of the Alert release rate threshold value.These calculations can be found in Attachment 2.7.1.6 Monitor Response.The unit vent noble gas monitor is: calibrated tO Xe-133. Monitor efficiencies relative to Xe133 by nuclide are listed in ODCM TableB3-2.

To findthe monitor reading associated with each limiting release, the noble gas concentrationsmust be multiplied by the monitor response and sumned. Table 4.6 shows the indicated response of the unit C>

Radiological Release Thresholds CALC. NO. STPNOC013-CALC-002 E N E R C O N for Emergency Action Levels REV. I ,xcefie-Ewvy ptofta Fy, day Attachment I PAGE NO. 23 of 49 vent noble gas monitor by nuclide and Equation 7.1.5.1 shows how the monitor response was calculated.

n Monitor Response = C 1

* Re 1 Equation 7.1.5.1 Where C 1 = concentration of nuclide i Re 1 = monitor response to nuclide i (GCi/cc)x.

1 3 3 equivalent In the case of an Alert, the 2.33E+06 iCi/sec release rate will read as 1.57E+06[LCi/sec on the monitor. Kr-83rn does not have an indicated monitor response coefficient.

Because Kr-83m is only 1.34% of the noble gases and does not contribute to the dose calculation, its exclusion is acceptable.

This again is a linear correlation and the SAE and GE scale by factors of 10 and 100 respectively.

These calculations can be found in Attachment 2.7.2 Main Steam Line Monitors 7.2.1 X/Q Since the atmospheric dispersion is independent of nuclide inventory or release rate and the close proximity of the releases, the X/Q value will be the same for a main steam line release as it is for a unit vent release. This assumption is also taken by STAMPEDE and outline in Assumption 6.3.7.2.2 Nuclide Inventory Per- UEKRPk1 ZVT, POTif the release path is Me main steam line with a steam generator tube rupture, the nuclide inventory should be 100% noble gas and 0.2% of the iodine from the reactor coolant.The secondary steam concentration for noble gases and iodine after a steam generator.tube rupture are taken from TGX/THX 3-1 (Reference 5.4). Values for the reactor coolant inventory are listed in table 4.3. All of the noble gases are used and the iodine concentration from the coolant inventory is scaled to total 0.2% of iodine in the total coolant inventory.

These inventories are then normalized to one. These values are listed in Table 4.3.7.2.3 Dose Conversion Factors The dose conversion factors used are found in Tables 4.4 and 4.5, taken from tables 5-1, 5-2 in EPA 400R92001.

Radiological Release Thresholds CALC. NO. STPNOC013-CALC-002 E N E R C .N for Emergency Action Levels m 7.2.4DecaS'Time Attachment 1 PAGE NO. 24 of 49 1J 7.2.4 Djecay Time.One hour of decay is incorporated to the monitor response due to the release initiating one hour after reactor shutdown.

Decay is also incorporated for the duration of the migration time. The total decay time is one hour plus the reciprocal of wind speed, or 1.07575 hours.7.2.5 Dose Calculations Equatfio 7.1.5.1 applies to the release from the main steam lines. The main steamn line oflw rate is used instead of the unit vent flow rate for the value: F. The main steam line flow rate was calculated in Equation 7.1.2.2 of the STAMPEDE CALCULATIONS section of this document as 2.79E+06 cce/e.The Alert EAL threshold is 10 m'rei TEDE or 50 mrem Thyroid CDE at the site bounda'ry (Table 42); Using the .ethod in Equation 7.1 .5 to' calculate TEDE with the ,apropriate conyrsiOn facqors, a c6ncentratio'n'aat time of shutdown of 4.10 .tCi/cc would' egulti i0.89 mrei TD"E 4a1he iteiboidaim y if the §team line PORV was open for an' hour. ,Usig tihesae steam line concentration to5ca:6iclate.'Thr~id CDE results in 50 mrem Thyroid CDE at the site bobndaryi.

Both are also( limited by Thyroid CDE" ..These calculations can be found in Attachmiient  

;Becauis the main steam line monitoris adjacent to the tain stearA line, significant shielding takes place between th-o Sce'andmonitor.STP calculation NC-9011 Revision 2 calculates a conversion factor for the'mai steam lines~for a noble gas inventory which is incorporated into'the monitor readout. No monitor response needs to be calculated.

The corncentration of the main steam line one hour after shutdown given a concentration of4.i10 Cicc atttie of"shutdown isi3 .0 pCi/ccTfhis calculdiioniis also foufid in Attachment

: 2. Addition y, t hit6r feAdings fo6 the SAE and GE one hour after shutdown are 39.0 and 390 pCi/cc respectively.

These values are the thresholds for the main steam line monitor.-.I CALO. NO. STPNOCO I 3-CALC-002 Radiological Release Thresholds foErN EREthgency Action Levels$rcehnc--S'r/$t4t "Attachment 3 PAGE NO. 32 of 49 DRILL' 'L7 ~ ~:r luomi D LL air .ME .A; ..Afr.t L~nrd~dDunr I mtaas'Ed~nS**IDSmSS 120117W3MUM Nq m 34a3 .War" (u& D I Et-t 105B04 n 31UUB tll: 25EMS fl-S .: pmi 4I..*d:' : i-lid ImR Ce-Ut : :. ZASWi: ,': : Xe-n- GE400h KuU:2f Im ,1?AOI 3-M.46 FM R2ological Relese Thresholds CALC.NO.STPNOCO13-CAL-002 0 E NE CO N for Emergency Action Levels REV. I Attachment 2 PAGE NO. 25 of 49 Table A2-1: Unusual Event Emergency Calculations

..,I 1 .40E,+05 I 2.79E+06 1. 5.OOE-02 Table A2-2: Input Values for Calculations Radiological Release Thresholds CALC NO. STPNOC013-CALC-002 OM m. for Emergency Action Levels REV-.Attachment 2 PAGE NO. 26 of 49 Table A2-3: Ca.culations for Boundary Concentrations and TEDE dose due to Unit Vent Release 1-132 1-133 1-134 1-135 Kr-83m Kr-85m Kr-85 Kr-87 Kr-88 Kr-89 Xe-13 lm Xe-133m Xe-133 Xe-135m Xe-135 Xe-137 Xe-138 1.50,E+0.5 2.20E+05 2..40E+05 2-OOE+05 1 .30E+06 2.90E+06 3 .70E+05 5.504,06 7.80E+06, 9.50E+06 1.1OE+05 6.80E+05 2.20E+07 4.20E+06 5.50E+06 1 .90E+07 1 .80E4+/-07 1.53E-03, 2.125H-03.

2.05E-03 1 .33E-02 2.97E-02 3.78E-03 5.62E-02 7.90E-02 9.72E-02 1. 12E-'03 6.95E-03a 2.25E-61.4.30E-02 5.62E-02~1 .94E-01 1 .84&-01 3.9 I 1 2 I2 5, 1: 1..* .4, E-5$5F-05 64E-05 6&-05 0E-04, 533E-04 33E-05 39E-63 97E-03 40E70' ..76E-05 71F,04, 5-5E-03 06E-03 39E-03 79E. 03, s4E-03 1.OIE-03 1.QIE-03'1-0 1B-03 1.0 E- .03 1.0 IE-03, 1 .01E-03 1.01B-031 I .O1E703 1.01E-03ý1.O1E-03 1.OIE-03 1.0 1E-0ý3 3,84-&-08, 2.38E+00 5.61E.-08 2.03E*10-6.1 IR-0 9 -.77E-0 1-5.II-T& 6.6 IE40.0 3.3 1E-07 11.83E+tO0

.7.40EM7 ý4.48 .E+00 9.42E-09.

9.4oE+04 1.40E-06 1 .27E+00O 1.99t-06 2.-84E+00 2.42E-06 5.1OE.-02.ý

-2.79E-Q08 2.83E+02--1.73E-07 5.42E4-01.

5S61E-06 1.27E+02 1.07E-ý06  

-2.66E-01 I AOBE-06 9.09E+00~4].5ER-06 638E-02 4.59E-06 .23E 2.79E-08.S.40E-08-2.f61R08 2.21F-07 6.27]E-07 9.42E-08 7.79E-07 1.53E-06 2.78B409 1.711E 07 6.09E-08 1L29E-06 4.06F,,11 1 .95E-07, I.50E+034-3.1QE+03.

8"10E+03 9.30E+0 1 1.30E-I00 5.10E+02 1 .30E+03 1.20E+03 2.50F,+02 1.40E+02 1.104E+02 7.20E-I02 5.30E+I04 4-90E+03 1 .50E+04.1.37E-04 8.11E-04 ,09E-05 3.70E-04 0.OOE+0-0 5.83E-05 1.22E-07 3.97E-04 1.99E-03 1.30E-09 1.36E-07 2.90E-06 1.11 E-04 1.52E-05 1.81E-04 4.47E-09 1.40E-04 10 E E O for Emergency Action REV. I Attachment 2 , PAGE NO. 27 of 49 GS-134 3.70E+01 3.78E-07 93 -09 L.O1E-03 9.42E-12 i.80E+04 9.42E-12 6.30E+04 5.93E-07 Cs-137 2.90E+01 2.97E-07 7.3 E-09 1.01P-03 7.40E-12 2.60E+05 7.40E-12 4.10E+04 3.03E-07 Te132 4.80E+00 4.91E-08 1.2 E-09 1.OIE-03 1.22E-12 7.79E+01 1.21F-12 1.20E+04 1.45E-08 Mo99 1.22E+01 1.25E-07 3.0 E-09 1.01E-03 3.11E-12 6.62E+01 3.08E-12 5-20E+03 1.60E-08 Rul03 8.80E-03 9.00E-11 2. E-12 1.O1E-03 2.24E-15 9.44E+02 2.24E-15 1.30E+04 2.91E-I I Ru106 2.90E-03 2.97E-1I 7.31-13 1.01E-03 7.40E-16 8.84E+03 7.40E-16 5.70E+05 4.22E-10 Zr95 Lal40 Ce144 Ce- 141 Sr89 Sr9o 1. 1 OF,-02 1.90E-02 7.40E-03 1.O0E-02 6.40E-02 3.20E-03 1.12E-10 1.94E-10 7.57E-1 1 1.02E-10 6.55E-10 3.27E,-1 1 2.7 4.7, 1.8'2.5S 1.6: 8.0" E-12 E-12 E-12 E-12 E-1 I E- 13 1.OIE-03 1.0IE-03 1.01E-03 1.01E-03 1.OIE-03 1.O1E-03 2.79E-15 4.83E-15 1.89E-15 2.54E-15 1.63E-14 8.15E-16'1 .55E+03 4.033E+0 1 ,6.82E+03 7.77E+02:1.21E+03 2.50E-405 2.79E- 15 4.75E-15 1.89E-15 2.54E-15 1.63E-14 8.15E-16 3.20E+04 l.10E+04 4.50E+-05 1.10OE+04 5.00E+04 1 .60E+06 8.93E-11 5.22E- I1 8.49E-10 2.79E-1 1 8.16E-10 1.30E-09 T6~d F~D~ Dose -, 5.~77E-O3  

-~Radiological Release Thresholds CALC. NO. S1Th~o13-CALCOO02 0 ENE C.O N for Emergency Action Levels REV.°I Attachment 2 PAGE NO. 28 of 49 Table A2-4: Thyroid Dose Calculation for Unit Vent Release 1-131 1-132 1-133 1-134 1-135 2378E-08 2.79E -08 5.40E-08 2.61E-09 4.56E-108 I '30E4,06 7.70E-f 7 3 220E+05 1.30E+0O3-2QvLn 3.6IE,-02 2.15E-04 1.19E-02 3.39E-05.1 '7)D n V27 Table A2 Unit Vent Monitor Response to Nuclide Inventory Kr-85m Kr-85 Kr-87 Kr-88 Kr-89 Xe-131m Xe-133m Xe-133 Xe-135m Xe-135 Xe-137 Xe-138 U.33E-04 P33E-05..39&-03 ,97B:03 ,;40E-03 ,.76Eý-05.71B-04.;.55F-03.06E-03.39E-03-.79&-03-.54E-03 4.48E4-00 9.0E+-04.1.2"E00 2.84E+01O 5.10F,02 2.93E+02'5.42E+01..

2.60E-0 1 9.08E-+00 6.38E-02 2.3 6E-0 1 2.25,F-04 6.28E-04, 1.9 9.33E-05 2.4 8.03E-04 2.8 1.54E-03 2:3 3.00E-09 Z.8 2.76E-05 0.015 1.69E-04 0.14 5.52E-03 1 7.38E-05 0.042.1.28E-03 2.5 9.15E-08 2.8 2.41E-04 2.8 Monitor Reading: 0.OOE+0O 1.1 9E-013, 2.24F,04.2.25E-03 3.55E-03 8AO0E-09 4.13E-07 2.37E-05 5:S2E-,03ý 3

* IE-06 3.21E-03 2.56E-07 6.74E-04 KUM~c) (uCi/sec)

Radiological Release Thresholds CL.NO. STPNOCO 13-CAL(>002 SE N ER CO0 N for Emergency Action Levels REV. I awo-mPt&~dard Attachment 2 PAGE NO. 29 of 49 Table A2-6: Input for Main Steam Line Release Calculation I 1-1-1 1-132 1-133 1-134 1-135 Xe-131m Xe-133 Xe-133m Xe-135 Xe-135m Xe-137 Xe-138 Kr-83m Kr-85 Kr-85m Kr-87 Kr-88 Kr-89 0. 1Url-UL 8.61IE-02 I .OOE-01 1 .86E-02 2.73E-0 1 2.80E+00 2.40E+02 4.20E+00 7.60E+00 4.OOE-Ol 1.60E-01 5.80E-01 3.70E-01 7.60E+00 1 .50E+00 9.80E-0l 2.80E+00 8.40E-02 3.19E-04 3 .72E-04 6.92E-05 1.01E-03 1.04E-02 8.90E-01 1.56E-02 2.82E-02 1.48E-03 5.93E-04 2.15E-03 1.37E-03 2.82E-02 5.56E-03 3.63E-03 1.04E-02 3.12E-04 Y.L I /-U't 1.31E-03 1.53E-0.3 2.84E-04 4.14E-03 4.26E-02 3.65E+00 6.40E-02 1.16E-01 6.07E-03 2.43E-03 8.82E-03 5.62E-03 1.16E-01 2-28E-02 1.49E-02 4.26E-02 i .28E-03 1L.Y035f-1rJV 2-9853E-05 2.9853E-05 2.9853E-05 2.9853E-05 2.9853E,05 2.9853E-05 2.9853E-05 2.9853F,05 2.9853E-05 2.9853E-05 2.9853E-05 2.9853E-05 2.9853E-05 2.9853E-05 2-9853E-05 2.9853E,05 2.9853E-05

/1. / IrD-Uo 3 .90E-'08 4.55EI 08 8.47E-109 1 .24E-07 1 .27E!06 I .O9Eý.04 1 .91E-06 3.4513,06 1.8 1E-07 7.26E.-08 2.63E7-07 1.68E-rO7 3.45E-166 6.81E-07 4.44E-07 1 .27E,406 3.82E-08 I .Y.D"Jh., 2.3 8E+00 2.03E+01 8.77E-01 6.61E+00 2.83E+02 5.42E+01 1.27E+02 2.60E-01 9.08E+00 6.38E-02 236E-01 1.83E+00 4.48E+00 9.40E+04 1-27E+00 2.84E+00 5.1 OE-02 Z. /I OV--o 2.85E-08 4.39E-08 3.62E-09 1.1 OE-07 1.27E-06 1.07E-04 1.90E-06 1.96E-07 1.67E-07 6.10E-13 1.12E-08 1.12E-07 2.92E-06 6.81 E-07 2.47E-07 9.79F-07 1.71E-14 4.90E+03 1.50E+04 3.101E+03 8.10E+03 4.90E+00 2.00E+01 1.70E+01 1.40E+02 2.50E+02 IAOE+02 7.20E+02 I.L+OZ-UJ 1.401-04 6.58E-04 1.12E-05 8.95E-04 6.22E-06 2.15E-03 3.23E-05 2.75E-05 4.17E-05 8.53)E-11 8.04E-06 O.OOE+00 3.80E-06 6.33E-05 1.26E-04 2_OSE- I1 1.30E+00 9.30E+01 5.10E+02 1.30E+03 1.20E+03 1 .r I~ose, G. 03z-O ,*Release Constant = X/Q

* release rath 1-1311 1-J32 1! 133 11&5E-08-4.39E-08 3.6.2E-09'7.70E+ý0-3 2.20E+0.5 1 .30E+03.3.58E-02: 2.20E-04 9.66E-03~4.71F,06 4.20B-03 Radiological Release Thresholds CALC. NO. STPNOCOI 3-CALC-002 0 E N E R C O N for Emergency Action Levels REV. 1 Mx*-Y dyAttachment 2 PAGE NO, 31 of 49 Table A2-9: Main Steam Line Reading at Release 1-lij 1-132 1-133 1-134 1-135 Xe-131m Xe-133 Xe-133m Xe-135 Xe-135m Xe-137 Xe-138 Kr-83rp Kr-85 Kr-85m Kr-87 Kr-88 Y.Z /ts-U4 1.31E-03 1.53E-03 2.84E-04 4.14E-03 4.26E-02 3.65E+00 6.40E-02 1.16E-01 6.07E-03 2.43E-03 8.82E-03 5.62E-03 1.16E-01 2.28E-02 1.49E-02 4.26E-02 2.38E+00 2.03E+01 8.77E,01 6.61E+00 2.83E+02 5.42E+01 1.27E+02 2.60E-01 9.08E+00 6.38E-02 2.36E-01 1.83E+00 4.48E+00 9.40E+04 1.27E+00 2.84E+00 S.IOE-02 9.23E-04 9.77E-04 1,47E-03 1.29E-04 3.73E-03 4.25E-02 3.60E+00 6.36E-02 8.04E-03 5.62E-03 4.65E-08 4,67E-04 3.85E-03 9.90E-02 2.28E-02 8.62E-03 3.34E-02 Radiological Release Thresholds CALC. NO. STPNOC0I3-CALC-002 EM.. N for Emergency Action Levels-Attachment 3 PAGE NO. 32 of 49 rabisiftke Alii; 1ilIm3 Ni KE~S~ra~ 1I~4@~uG~ur vNOMZ4TO410 a .4f Kr43t 13E0"I Xe-33M UWm40OB Yw-uSB1 9-B&IM 3120MII 3&3,W- 3.03-T -2 13E.X~Z[4-i .3im .tm (MMOUM33~AP?

C CALC. NO. STPNOCO13-CALC-002 Radiological Release Thresholds EN ER CO N for Emergency Action Levels I xce*-Erypr.

Ervyday. Attachment 3 PAGE NO. 33 of 49 DRILL-32=01 AV0 DRJLL Dubaime M7114OI 15:M Ukw MM~E UMMIk uAjat UiStWj (miles)05.7.5 10D 2.0 520 7.3 20D (mistu&s l.0 7.5 IA0D MaD 023 OL45 1:31 4~iQ Vabu~cJ~2.Ui~.O05 im~3.IS1R-007 U~007 9.11l.0'3.ISIE.O0 7.373H,07 3245ECO1 1441E-007 amo XmshuknloBody owl 0.003 0.001 Row0 0"0 rdzoeD in ruiv C Q'07~~0.04 (Sam) OflE 0M00 0.001 0M0 CamO 0237 0.002 am~amo 12=0t33142*28 CALC. NO, STPNOC013-CALC-002 Radiological Release Thresholds REV. I E N. ER C 0 N for Emergency Action Levels. W.t$icm-4n rymJed &#xfd;ily dV. Attachment 3 PAGE NO. 34 of49 C DRILL* ....STAMPLDMResuiltsIto--S -...RESMLTS... W InuI,. Aedti 132 ...Jh ..'.:: a ':+ " ....?P DRILL Re..a... .te: LL1 .* ..ui....IOffh&t3 neurajMane (reier CUE D .051i H0ICL O . Emjected durtionoafudezeet Kohour, A Gener~all Emergency eY1qnires a -Pro'tective Action Recommemilation EVACUATE ZONE() I SHELTER 19 kLAE ZONE<SI 2 AFFECTED DOWNWIND SECTO1I& Re&#xfd; A,B All Reauliag Zones Go fiidori And Monif or EAS mlic Station.Based outalDose Rote Pr'etaiearef 3 inamter/b (inxsiou Whole Blody No ble Gas Gamma) at the S ite B oimduzyQ( Mile) ftr 15 ine or longer &he Enwmeeny Ch1.9kfeelio I itatig C4ondition R.1I (ALERT.) has been met A REVIEWED BY: dMnsxerRmdoloAk-Dirnetor.... l2/20153:24&44PH DaitddTie 1211712013 3.:24:28PM CALO. NO.

Radiological Release Thresholds EN ERCO N for Emergency Action Levels UV. I, Attachment 3 PAGE NO. 35 of 49 DRILL STAMPEDEUser  

%~ppfied InformatiouDR L DRL sT ..&F-d' !Mn7M3. .... DRML Im~hfflm:  

=Sam W-%O54 Utk06=*m SwMzeSjItA~u Hamsfftwerflumu 12N13 W-ra 4 IftmmahWhte: -mf lJ51a R~gdm~h~zt&~f.  

.~~1~ .. .. ...... .TAU* ats i1DHafanu:-M D21f111 O5 C~kuedNMae)MXCAou:

1AL.0 lIMM uke NOWEG~AS!Mudift RUMi~C roniw NOWdid ucitsr.PMRCUXA7 xUuxb ucihec la-M3 1.14E*WO4 3,43E+M S729+004 422WOX7 12M+M3 I27E-0OM IMAM0G~-131: 1-1~2: 1-133: 3am*iM 32Za+QoP-14.La-MO: RusfkM Ru-Mll Sr-IS AC+000 O.MB40 OcMB00l4I0 0AXiEWCO I2/t&=13 PS55:L9 Al CALC. NO. STPNOCOI3-CALC-002 Radiological Release Tlhesholds CALC. NO. _TPNOC013-CALC--002 E.N E. R CO. N for Emergency Action Levels rEV,.FoenWee-E*r Y&ol .Nyd Attachment 3 PAGE NO. 36 of 49~1.:

'DRILL" Dat VThus IPAMCJI 0754 flklbtm: Stattita ShaMs C"":".i :'i":". ...L' : .. ' ".'"" 2" Vwtflfe tmilfue)10D 50: 7.5 1102 MD.Is Ii flaw trveln.CULQ  

*ami. CSIQDpa&.34 343~011 11-0 R=Xwt ama CS 0.0%0 0A00 0130 um3-(z lsm.rwhalflalm body anti. gflpifls deii pan fl ADO 0-000 0.000 ,0000 eznt&#xfd;mes IodieCD r6ELM CLOW LB 1211n=137:54AAM C

CALC. NO. STPNOCO I3-CALC-002 Radiological Release Thresholds ENE R CO N for Emergency Action Levels REV. I Attachment 3 PAGE NO. 37 of 49 DRILL ssTAMPwE03 Weut IngformIofi2 D.NRILL-alcuadIiens CID ylefed RESULTS.V~uDireetizma ISO Methodd bPmrfrial STA1M2D Rdewaaa Ih .19H+Dwu0&C~M I me ml~es ~ ml~es 10miles TEDE 0407 D.003 M.00 DAD0 CDE 0.050 0.017 0.004 1.001 Prouc4inmn fr~a~e~1.0 bour A General Emergency Requmires a Protective Action Recommendation EVACUATE~

ZO?4EMS: 1 SHELTER IN PLACE ZONE(S): 2 AFFECTIDDEOWNWTND SEC-TORSt  

-, A. B .....-.All IPernining Zones Go. Indoors And Manitur EAS Radio Station 13 ased on a Dose Rate Projection of > 3 mremuhr (Immersion.

Whole Body Noble Gas Gaumn) at the Site Bowrdary (I Mile) fci 15 mimites or longer flit Emergency C aificfimi~n Initiating ConditiouRAI (ALERT).Itusbeeumnet.

PRFGMRD BY.121l180137355:4AM DatelThne R --- ----- ---- H w i -IT2I EW213 7:54-42AM CALC. NO. STPNOCO 13-CALC-002 Radiological Release Thresholds E E-R C0 N for Emergency Action Levels"fn-t&#xfd; ..qf1Wt PyOyd.. Attachment 3 PAGE NO. 38 of49 DRI2___L " " .2_tnm_' ~f.. _DRILL ihwflum 12t1~X2Ot3 1525 , twlknr 1frk~$atSihAao Coals Ike'. It L MatwdwatnllhtYnwtz,*atfru1~utdaUr.

U2ndMw~kund1advAdiexr 120 &grou Uw-sekctei5biNhtyGlas SbtiIiyaus:

C C lileomlist D~eflbw 12/fl?2013132 woticAs Wus1~ aWsec la-nv as*oos ia4t L0Si~rn-isv 7~0ntu)5 fl47: PAIIEfOS 1fr4& U3&*0M~8t 3Ws0c~n-flizt nz~ua~4323It ISlEI4XhI Nefl& iAS&tCOE Xi-130&t tiffifilOt n-Sm t7'NI4Efl ia-ut 2(00*4KW ifl7/2~3 325'flfltI Wrn1i~ uCitsa flit.1-132: 1-133: 1-134 112 311 I'M 5.12 ti-lit ti-Isv 000'r-ICt SaCK V.443: 5*009 La-IS: 2W islEb-I9&Es-lit k/lIlt Irt Ye-aSk k-St IMS 31MN.k '. .ndT /ec C CALC. NO. STPNOC013-CALC-002 Radiological Release Thresholds SN E R CO N for Emergency Action Levels .

Emwyday Attachment 3 PAGE NO. 39 of 49 DRILL StLUh N DRILL Birti~m" wiflaxa 0.5 2.0 75 1Loa0 djtur-cm.i.tk~u).

0M.0.1m 0.23 054 IAS Z1EMO0M cm~mr 1.436WAs 9110500 7.371300 3.1459M0 2.4413-07 OLMMMSU (miles)0.5 1.0 210 5.0 75 10D0 260 1&nrne Sass .a famrauyda WTId Body soble Mmmt r=oas W.12 Tam :~aWaeRd CLOM acm rP DonRate aMO 134 acIM 0510 clmi OL76 MMB a014 001 0.00 5 a drumt n+.karlam Tyri Cns) ire_$(,,ZnCA 1.0 20 520 75 nao 10.0 0.160 0.0m Omli 01101 1364 0.510 0.176 0.14 0.005 12/1t7110332521 IM CALC. NO. STPNOC013-CALC-002 Radiological Release Thresholds E NER C for Emergency Action Levels , O. 0o4 f~drm&#xfd;EverywAct gv"yr Attachment 3 PAGE NO. 40 of' 492 C DLII STAMM Stm, P~RESULTS Y*Inavduif~.+/-

13..2m=ifir M~e MSe I 0.060 O0201 0.005WIO 4D5 10 0.176 0.041 OLD14 R....I.. ....g~j I.J9B4o011,ar~

A ee~ mrency Requires at Prateletive A~tio Reomndatio EVACUATE ZONW(). 1 SHBLTER IN PLACE ZMIE(S). 2 AFFE.CTED-DOWNWJNI RET1S , A, H All Rem "ft Z w hs x~ In t A nd MwidtoeEMS Ib dia '&#xfd;Ati M: R~em&Becy CJsi[.fcatwn IitfialngConiitwicnS1 (SIlE.AIEA EMERGENCY) batbeenm aet Al-PERFO0AIDUY DN~mt I -~QO1325:23 FM 12FI712013 3:25.11 FM GALC. NO. STPNOCO I3-CALC-002 Radiological Release Thresholds RAEV. IO. SPNO __3-CA _-00 E N E R C O N for Emergency Action Levels REV. I cehn-Mq t Attachment 3 PAGE NO. 41 of 49 DRILL STAMPEDE User Suppled lorsato DRIL PaWaLme 1217f0 1523 CMnunfic lkW~aMsc StsmmbaSfleAmn Qa~dlwmtuubtr31 ni&rs Gmdcrkuivi=dhrw 12 &gM1ree Mam-sMIkctuifbm-LODltun Nrbdae: ltllf 3.&#xf7;1 NovdiakW tfnAre ride:o: 1* 4as Cumlclte&OMZC4llSrdmsrte:

1201*08!8 u--Cztsog I NDHLEQIS Nurdule udhoc NWdi& VAsec PATA7CATE Nadub .xtksec Mr-am rz]85-X1-am X-nv: n-w ra-naut Xke-lit a-nas 14*410M 2519*006 9911*4D5 39M=&134E+004 I-Ift I-ll: Mat34 4323E004 L249*00 Cs-lit: Ceahz4M: Ce4Ul: La-MU bb-",.: d.uf Re-IN:OI 0039+"10 GO.WE44OOD orns*Uo...... J I Sr-W3: Te-0l: Zr-I: 0.Z*400 0.0240 IWS2MM33 299WWL CALC. NO. STPNoC013-CALC-002 N E RC O Radiological Release Thresholds

__002 E N E RC for Emergency Action Levels R,."nl ,rnu-4Wivne gAttachment 3 PAGE NO. 42 of 49 DRILL DRLL IddhWmF 121711n013 nor1 flwmnt Semmuz wsb Ar-m,: I.,.  

., *. : .. ..: *, ,, ..> ..2b 75 mw*005 in, ,023 a l. .045 ' ::'= ...'.ao.k..l.'.  

....noh nszr (rea .. M .?: ai.. ..05,4- 2,3 ..* .05 * .0LO.001... .00 ... ... .: Sisbim 05 10 1.0 so 7.5 took 2DJO L h , Idfl, 3..7st0 .-s ..MOE- u; ii :* **aim 1354 aim 0305 ChMm ODES*. '(l's, 0.1 "1.35 El .".' 05* ~~a ... :... ... ' BE..... .0.10.02 a.cm on: '11'"Ji " .: AM m.,.= &#xf7;=,' .:.. * .... ,: = ..... ..:. .k, m MO U 13, .i :*OM...': '(F Urn anr 1.'171.203 2t-3 Ud C CALC. NO. STPNOCOI3-CALC-002 Radiological Release Thresholds REV._I E14E N E R C 0 N for Emergency Action Levels REV. I c.-tNypio

_ay. Attachment 3 PAGE NO. 43 of 49 DRILL STAWIEDEResults Infonntftrn DRILL CuiazCIDMn.

1-tetd RESULTS Wffiad: ot~rajecdca WAxd~kI*-4 132=Ulx Reeene 12EO STAMPI1DE idretm19 Off ft Do" roiectiou (r'em)i, I nol 1 MILOS Bmfles 1 Mil"s IEDE 0.02 25 0,006 ~ 0M CM 0.506 WI5 0.0)41 0.013 Pnwjected dumfiofreleasr.

1.0houni A General Emergency Requiires a Protective Action Recarmvnudatioin EVACUATE ZONE(S) I SHELTER IN PLACE ZONE(S: 2*AFFECTED DOAVMVIN~D SECTORS. R, A, B -All Remmining Zowe Go Mdoone And MornitorEAS Radio Station fse~Based on a Site floandazy (I M~'ile) Dose Prjec~tion  

> 0. 1 rem TEDE imdlor DJ5 xm Thiyroid CD-E the Emergency Cisanifration Iuitiatin-CondtioniRSI (SITE AREA EMERGENCIV) bni been met.I PEKTORME B~r REVIMVD BY, 1IMi7013 519-10D PM DatsThoe a.1201/2013 3:203pM CALC. NO. STPNOC013-CALC-002 Radiological Release Thresholds REV. I 0 EN ERCO for Emergency Action Levels V.

yptrjda: Attachment 3 PAGE NO. 44 of 49 (nun y STAMVEDE User Supj1Ii~I Tatformation ThD b~tsnral Dat Inf Tka-sdactuS61flifika Mubmd~3it:ad~r

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CALC. NO. STPNOCOI 3-CALC-002 Radiological Release Thresholds aa'E NE RC0 N for Emergency Action Levels REV. I Evry doX Attachment 3 PAGE NO. 45 of 49 DRILL STAMEDE Lobs ImIormahoa DR]LL DIzdrumt IYIfW 1.5- UffNam: Tht Wok,-nd 4 4 DhlnMcu (VaiIes)aks 1.0 2.0 5.0 73 10.20)Pluma lkzd !Mao 0zuunMiwaleul U2 ams ODD 0:23 05"4 OAS 151 CULQ Vain&(ssrM'3 2069M 1OMM?7373EM0 2.44IB00 93107300.0 io 5.0.7.5 DiIun~ca 05 ID 10 510 7-3 MD 20)nM~ris. Val& OMITf 0,3322 tin 0M01 0.010 0IM73 Yam~rnla W&At Body nobsb go, grms (raw)till?0"01 0.000 0.0Mz MW CM.xeerwi+ ftrww. 2vIdyr.. umt" hrlY -.""15 0)01 0(210 0)5 ami CW17 OW(1 Snm 1,762 4131 U314 0135 10M0 WE baie CURI 0M60 am" C.M7I3M" Szo 1.762 0.411 0-214 0-135 ame 12(ilflflh3flt23PM

... ...Attachment 3 PAGE NO. 46 of 49 C DRILL STAMUME Result Intmtiion DRIL* ......,e.' C o ma '. .STAIQPfDE TEDE I0 1(LS1U4S W~nd~L~d .232mib WDW~ok~ a0s'02. M411 ~ nie lOg.~1IleB 0.017 DM5 A Geuerai iia&#xfd;xgency Ac.eauires a Pratertive'Actwin R. e. ommiednition EVAICUATEZONE(Sy-li1 SHELTER W PLACE ZON'E(S>.

:LRa& Satsi=Based onl a Site Boundaty(1 Mile) tDosp ftolictiow-I rem TEpt suftlr 5 mThyxoidI ODE the E~gucyCl ifiatin~n ngCndiiouR~i(GENERAL EMERdEXCV) bag been met I C F1EFDRMEDB~

REV~hNam 12MM1113 31033M 12Il71201332rK25PM

CALO. NO. 5TPNOCO1I3-CALC-002 Radiological Release Thresholds CAL_, NO. STPNOC013-CALC-002 I E IN E R C O N for Emergency Action Levels Rv 1 frcefr,-rwryn Evet Fryda Attachment 3 PAGE NO. 47 of 49 DRILL 'TZD Ur fd ormatio DRILL Da c12T 1530 Cm-M& I U", M n. StnMaUSUGMe" ThrchM ilnfmint Mtewardnu~d*Fht rapt: --- -- --a"----a---td sb~ry*" m" Shempbycist  

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M102-MD .0sav NOBIEGAS Macida uCIuw N 123Wme PAMKUEATE Macdi* .01/n 3t-S: ia-sw Kr-S.K8r-iD: Xfl-MmXT-Ut Xe-Ut 114940W6 3AM&+00 SAMMf~l Z n+C 413E41M1 1MMhw7 rLW:.-13M 1.-135: 424B01 IMMOM0 Ce-IC1: lnk D.0.3.M0 DOXff4 SrJY-5t Sr-W: oa0,+12n7.20133:).:SOwt CALC. NO. STPNOC013-CALC-002 Radiological Release Thresholds REV. I E N E R C 0 N for Emergency Action Levels. 1.7&n- A* Mrydao Attachment 3 PAGE NO. 48 of 49 C STA.. rlm.onn.iC DRILL DsWIr 32fl7D013 1510 Uflmet Klamhmn..... ......, ....* * ., , ........I .i d &#xfd;j &#xfd; d &#xfd;Ip PM -I., -., -b- , -, .:1. .. .j :, I ;p IM-&#xfd; 3 M jT-v,7 -7 :' &#xfd;' , ' , ! --&#xfd; : --&#xfd;, &#xfd; I I : -, -d ; -, ::;Ehhmm 75 20D 05 10.0 062 1434F5 045 1725524 24MM01 44236I~e~

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STAMIPEDE RdesI~anFrrt 1.0E+009uQihc 0ffEZIeCD ePrqjeLtiwi(rLL=)i 7M DJA 0154 CLO63 am2 CUE &#xb6;1.47 M0(7 0.134 Pwjedad Jti~aofr4e~ame:

1.0 hour A General Emergency Re quires a Prote~ctive Actiou Recainmendation EVACUATE ZWNE(): 1, 2 SHELTER IN PLACE ZONE(S: 6, 11 AffECTED DOWNWIN SECTORS: -R, A, B All Remainiing Zeone Go bn$oms And Monitor EAS Radio Statcoa Based ani a Site Boandary (I Wie) Dose P oection &#xfd; I remn TEDE andior. rtem Thyroid CDE the Emergeur Clasifrsienfi nitintin 5 Condition RGI (GENEAL EMERGENCT) has been met pmwnIU~IE By: REVIEW BY, 12012f013 130:V48 PM Thitetrhn______________________________________________

1~12417#2013 3:.313PM STPEGS UFSAR The particulate channel is used as part of the Reactor Coolant Pressure Boundary (RCPB) leakage detection system. The sensitivity and, response time of this pare of the leakage detection system, which is used for monitoring unidentified leakage to the Containment, are sufficient to detect an increase in leakage rate of the equivalent of one .gal/nin withfi one hour. Elements of this monitor, Including -he indicator mounted in the RMS CR cabinot, are designed and qualified to remain finotional following.

a Safe Shutdown Earthquake (SSE),. in -omplianoe with RO 1,45.. Further' i information on the RCPB leakage detection system is presented in Section 5.2.5, 11.5.2.3.3 Unit Vent Monitor: The unit vent monitor samples the plant vent stack prier {o discharge t6 'he environment and monitor for particulates, iodine, and noble gases.The unit vent particulate.

and iodine monitor draws representative air samples from the plant vent stack. via isoldnetic nozzles in the stack, and -directs them through a moving filter paper monitored by a shielded beta-sensitive scin' illation detector.

The sample stream then passes through a charcoal collector; where collected iodine is monitored by a shielded gamma-sensitive sointiilatibn detector, The sample is then returned to the vent s.tack.A separate wide-range gas monitor is p'rovided for the unit vent. The monitor, has two isokdnetic nozzles for sampling.during both nonmal and accident conditions.

The stack samples pass first through a sample conditioning unit which filters particulates and Iodine and may' be used to. take grab, samples, The samples then pass through the shielded detector assembly,, which uses throe detectors to cover the complete range required.

The low range detector uses a beta-sensitive plastic sointillatorlsphotomultiplier (PM) tube. The mid-range and high-range detectors use cadmium*'.., ~elluride (CdTe), chlorine-doped, solldstate sensors, This wide-range gas monitor satisfies' the requirements of NUREO-0737, Item 11.F.,1 for provisions fbr sampling plant effluents for iodines and battioulates and f6r noble gas effluents from the plant vent.11.5.2.3.4 Contol Room Eiotrical Auxiliary Buildina Ventljation Monitors:

The CR/EAB ventilation monitors are Class 1B monitors which continuously assess the Intake air to the CR for indication of abnbrmal airborne radioactivity concentration.

Bach monitor assembly is powered from a seprate. electrical power source, In the event of high radiation CR emergency ventilation operation is. initiated .Seotion 7.3.2). Failure of a monitor Is alarmed in the CR.EB&ch monitor assembly Is oomp-rsed of a recfrculation-pump.,3etagSensi1itlv ,oiitifit idn "....fourMpi lead shielding, check source, stainiess stelo sample gas receiving' chamber, and associated electronics, 11.5.2.3.5 Condenser Vacuum Pump Monitor: Gaseous samples are drawn through an off--lne-system by-a-pump-from the-disoharge-of-the-vd6iuum-pump-exhaust-header-of-the-condenser.  

-_This ohamel monitoxs the.gaseous sample for radioactivity which would be indicative of an SO tube Jleak, allowing reactor ooolaut to enter the secondary side fluid; this monitor complements the SQBD'itonitors hi indication of a SO tubo leak.' The gasebus radioactivity levels are monitored.by a fingle detector in a manner similar to the unit vent wide range 'gas monitor.'1 11.5-2.3.6 Snent Fuel Pool Echaust Monitors:.

The SFPE monitors are Class lB and ', identical to the CRIEAB ventilation monitors described in Section 1.1.5.2.3,4 except that they sample the exhaust from the FHB, In the event of high radiation the monitors initiate emergency operation S1l.5-i.1 Revision 14 STPEGS UFSAR (" 11.5.215.1 Gaseous Waste Processing System Inlet Monitor: The GWPS inlet monitor I employs a gamma (Nal crystal) scontillator/photomntflplier tube combination to measure the radioactivity level of the waste gases entering the G(WPS-. The monitor is used In conjunction with the GWPS discharge monitor to measure overall effectiveness of the GWPS.11.5,.25.2 GWPS Discharge Monitor: This monitor is similar to the GWPS inlet monitor and is installed upstream of the OWPS discharge valve. Upon detection of high radioactivity or monitor failure, the GWPS discharge valve, FV-4671, is. automatically closed, 11.5.15.3 Main Steam Lihe Monitors:

Each.MS line is-monitoredby .anATL monitor consisting of a Geiger Mueller (OM) tube detector and an ionchamber detector with overlapping ranges. The detectorsare shielded by 3 fn, of lead.The monitors are designed to moziitor gross gamma activity in the steam line. and provide a basis for detentAning possible atmospheric releases from the MS power-operated relief valve (PORV), SO 04 safety valves, and/or auxiliary feedwater pump turbine, The monitors provide a dose rate range equivalent to 1.071 to 103 ikCYm 3 xenon-131.

Based upon core inventory,.

the ratio of xenon-133 to other nuclides in the fuel can be dotemined, In order to obtain the abov6concentrations of xenon. 133 in the main, steam line, a large primary-to-seoondary leak must be present coincident with a large amount of fael failure. The presence of xenon-133 (. indicates other radioactive isotopes ame pmesent.Using the relative ratios ofisotopes present in the MS line, -a computer model for determination of dose rates from these isotopes, detector response curves, the thiecness, of the MS line, and the geometry of the MS line relative to the detector, the dose rate equivalent to MS line ooncentration is obtained.

The quantity of radi6active effluents released is obtained by multiplying the xenoan 133 equivalent MS line concentrations by the isotope ratio times the steam release rate, These detectors are s'aety-related Class 1E and meet the requirements of RG 1.97 and NUREG-0737, nlne monitors and are adjacent.

to the linves jien tIoietlii -dhCuid(IVCl.fhM).  

.. -'he monitors are used as an aid In determining the' source of SO blowdown radioactivity due to SO tube mpture or a large' primaryto-secondary leak.T-hes~e-de~teors-are-sfety-relatedCass4E-and-flet-t~he-requhemtffts-Of-PRG--9-7..  

' z4 11.,52.5,5 Main Steam Lne High Bnergy. Gamm-a (N-16) Monitors:  

'Each main steatn line is monitored by an ATL Nat scintillatiori detector.

These detectors were installed to monitor the status of steam generator primary' to secondary tube leaks and to provide a diagnostic tool for all individuals concerned with steam generator condition.

These detectors are designed to detect high energy gamma ictlvlit in the 6 to 7,2 MEV energy range. High energy gamma activity in the main k( ' steam lines indicates the presence of N-16. The level of N-16 in the main steam lines is used to 11.5-14 Revision 14 RS2 STPEGS UFSAR The new fuel assemblies are transported to the new fuel storage pit or to the new fuel elevator by the 15/2-ton, dual-service FHB crane. The 2-ton hoist of this crane is designed to handle new fuel assemblies.

New fuel handling is discussed in detail in Section 9.1.4. Use of the 2-ton hoist of the 15/2-ton crane or of the fuel-handling machine to handle new fuel ensures that the design uplift of the racks will not be exceeded.The new fuel storage pit is situated in the approximate center of each FHB. The floor of the new fuel storage pit is at El. 50 ft-3 inches. The new fuel storage pit access hatch is provided with a three-section protective cover at El. 68 ft. The fuel assemblies are loaded into the new fuel storage racks through the top and stored vertically.

Units 1 and 2 of the STPEGS are each provided with separate and independent fuel handling facilities.

Flood protection of each FHB is discussed in Section 3.4.1. Flooding of the new fuel storage pit from fluid sources inside either FHB is not considered credible since all fluid systems components are located well below the elevation of the new fuel storage pit access hatch. A floor drain is provided in the new fuel storage pit to minimize collection of water.The applicable design codes and the ability of the FHB to withstand various external loads and forces are discussed in Section 3.8.4. Details of the seismic design and testing are presented in Section 3.7.Missile protection of the FHBs is discussed in Section 3.5. Failure of nonseismic systems or structures will not decrease the degree of subcriticality provided in the new fuel storage pit.In accordance with American National Standards Institute (ANSI) N 18.2, the design of the normally dry new fuel storage racks is such that the effective multiplication factor will not exceed 0.98 with fuel of the highest anticipated enrichment in place, assuming optimum moderation (under dry or fogged conditions).

For the unborated flooded condition, assuming new fuel of the highest anticipated enrichment in place, the effective multiplication factor does not exceed 0.95. Credit may be taken for the inherent neutron-absorbing effect of the materials of construction.

The new fuel assemblies are stored dry, the 21-in. spacing ensuring a safe geometric array. Under these conditions, a criticality accident during refueling and storage is not considered credible.Consideration of criticality safety analysis is discussed in Section 4.3.Design of the facility in accordance with RG 1.13 ensures adequate safety under both normal and postulated accident conditions.

The new fuel storage racks also meet the requirements of General Design Criterion (GDC) 62.9.1.2 Spent Fuel Storage 9.1.2.1 Design Bases. The spent fuel pool (SFP) is a stainless steel-lined reinforced concrete pool and is an integral part of each FHB. All spent fuel racks are classified as seismic Category 1, as defined by RG 1.29, and as ANS SC 3.The spent fuel storage facility provides storage capacity for 1,969 high density absorber spent fuel racks in a honeycomb array in each unit. Two storage regions are provided in the SFP. Two of the 9.1-2 Revision 16 STPEGS UFSAR Region 2 rack modules on the southend of the pool (modules #12 and #16) have not been installed.

It has no adverse effect on the fuel assemblies that are selected for cleaning; nor does it have an adverse effect on the design function of the spent fuel pool or its associated support systems. Figure 9.1.2-2 shows the pool layout for both Units 1 and 2. The six Region I rack modules are located in the northwest comer of the spent fuel pool.The Region 1 racks have 10.95-in.

nominal center-to-center spacing between the cells. This region is conservatively designed to accommodate unirradiated fuel at enrichments to 4.95 weight percent.Region 1 storage cells are each bounded on four sides by a water box except oil the periphery of the pool. The Region 1 spent fuel racks include a lead-in-guide to assist in depositing fuel assemblies into the fuel cell. Figure 9.1.2-3 shows a typical Region 1 spent fuel rack.The reactivity characteristics of fuel assemblies which are to be placed in the spent fuel storage racks are determined and the assemblies are categorized by reactivity.

Alternately, if necessary, all assemblies may be treated as if each assembly is of the highest reactivity class until the actual assembly reactivity classification is determined.

Section 5.6 of the Technical Specifications provides the definitions of the reactivity classifications and the allowed storage patterns.

Fuel assemblies are loaded into theracks in a geometrically safe configuration to ensure rack subcriticality.

Fuel assembly reactivity requirements for close packed storage and checkerboard storage are specified in the Technical Specifications.

The boron concentration of the water in the spent fuel pool is maintained at or above the minimum value needed to ensure that the rack Keff is less than or equal to 0.95 in the event of misplaced assemblies in the close packed storage .areas or in checkerboard storage areas. Consideration of criticality safety is discussed in Section 4.3.The Region 2 racks have a 9.15-in. nominal center-to-center spacing with fixed absorber material surrounding each cell. A sheet of neutron absorber material is captured between the side walls of all adjacent boxes. To provide space for the absorber sheet between boxes, a double row of matching flat round raised areas are coined into the side walls of all boxes. The raised dimension of these locally formed areas on each box wall is half the thickness of the absorber sheet. The boxes are fusion welded together at all these local areas. The absorber sheets are scalloped along their edges to clear these areas. Figure 9.1.2-4 shows a typical Region 2 spent fuel rack.The axial location of the absorber with respect to the active fuel region is provided and maintained by the structure of each box. At the outside periphery of each rack, a sheet of absorber material is captured under thin stainless sheets which are intermittently welded all around to the box.All rack surfaces that come into contact with fuel assemblies are made of annealed austenitic stainless steel. These materials are resistant to corrosion during normal and emergency water quality conditions.

The racks are designed to withstand normal operating loads as well as to remain functional with the occurrence of an SSE. The racks are designed with adequate energy absorption capabilities to withstand the impact of a dropped spent fuel assembly from the maximum lift height of the spent fuel pit bridge hoist. The racks are designed to withstand a maximum uplift force equal to the uplift force of the bridge hoist. The 14-in. and 16-in. racks also meet the requirements of ASME Code, Section III, Appendix XVII. The high-density spent fuel racks meet the criteria of Appendix D to Standard Review Plan (SRP) 3.8.4.9.1-3 Revision 16 STPEGS UFSAR Shielding for the SFP is adequate to protect plant personnel from exposure to radiation in excess of published guideline values as stated in Section 12.1. A minimum depth of approximately 13 ft of water over the top of an array of 193 (full core) assemblies with 42 hours of decay is required to limit radiation from the assemblies to 2.5 mR/hr. or less.The FHB Ventilation Exhaust System is designed to limit the offsite dose in the event of a significant release of radioactivity from the fuel, as discussed in Sections 12.3.3, 15.7.4, and 9.4.2. However, no credit for the FHB Ventilation Exhaust System is taken in the LOCA and Fuel Handling accident in Chapter 15.The FHB is designed to prevent missiles from contacting the fuel. A more detailed discussion on missile protection is given in Section 3.5.In addition, space is provided for storage of fuel during refueling inside the RCB for 64 fuel assemblies in four 4 x 4 modules having 16-in, center-to-center spacing (Figure 9.1.2-1A).

These modules are firmly bolted in the floor.9.1.2.2 Facilities Description.

The FHB abuts the south side of the RCB and is adjacent to the west side of the MEAB of each unit. The locations of the two FHBs are shown in the station plot plan on Figure 1.2-3. For general arrangement drawings of the spent fuel storage facilities, refer to Figures 1.2-39 through 1.2-48 as listed in Table 1.2-1.The spent fuel storage facilities are designed for the underwater storage of spent fuel assemblies and control rods after their removal from the reactor vessel. The spent fuel is transferred to the FHB and handled and stored in the spent fuel pool underwater.

The fuel is stored to permit some decay, then transferred offsite. For a detailed discussion of spent fuel handling, see Section 9.1.4.The SFP is located in the northwest quadrant of each FHB. The floor of the pool is at El. 21 ft-1 I in., with normal water level at El. 66 ft-6 inches. The top of a fuel assembly in a storage rack does not extend above the top of the storage rack which is El. 39 ft-10 in. maximum. The fuel assemblies are loaded into the spent fuel racks through the top and are stored vertically.

Units 1 and 2 of the STPEGS are each provided with separate and independent fuel handling facilities.

Flood protection of each FHB is discussed in Section 3.4.1.A detailed discussion of missile protection is provided in Section 3.5.The applicable design codes and the various external loads and forces considered in the design of the FHB are discussed in Section 3.8.4. Details of the seismic design and testing are presented in Section 3.7..Design of this storage facility in accordance with GDC 62 and RG 1.1 3 ensures a safe condition under normal and postulated accident conditions.

The Keff of the spent fuel storage racks is maintained less than or equal to 1.00, even if unborated water is used to fill the spent fuel storage pool, by both the designs of the fuel assemblies and the storage rack and the use of administrative procedures to control the placement of burned and fresh fuel and control rods.Under accident conditions, the Kefr is maintained well below 0.95 assuming 2200 ppm borated water.The boron concentration of the water in the spent fuel pool is maintained at or above the minimum 9.1-4 Revision 16  REQUIREMENTS FOR RELIABLE SPENT FUEL POOL LEVEL INSTRUMENTATION AT OPERATING REACTOR SITES AND CONSTRUCTION PERMIT HOLDERS All licensees identified in Attachment 1 to this Order shall have a reliable indication of the water level in associated spent fuel storage pools capable of supporting identification of the following pool water level conditions by trained personnel: (I) level that is adequate to support operation of the normal fuel pool cooling system, (2) level that is adequate to provide substantial radiation shielding for a person standing on the spent fuel pool operating deck, and (3) level where fuel remains covered and actions to implement make-up water addition should no longer be deferred.1 .The spent fuel pool level instrumentation shall include the following design features: 1..,1 Instruments:

The instrumentation shall consist of a permanent, fixed primary instrument channel and a backup instrument channel. The backup instrument channel may be fixed or portable.

Portable instruments shall have capabilities that enhance the ability of trained personnel to monitor spent fuel pool water level under conditions that restrict direct personnel access to the pool, such as partial structural damage, high radiation levels, or heat and humidity from a boiling pool.1.2 Arrangement:

The spent fuel pool level instrument channels shall be arranged in a manner that provides reasonable protection of the level indication function.-* against missiles that may result from damage to the structure over the spent fuel pool. This protection may be provided by locating the primary instrument channel and fixed portions of the backup instrument channel, if applicable, to maintain instrument channel separation within the spent fuel pool area, and to utilize inherent shielding from missiles provided by existing recesses and corners, in the spent fuel. pool structure.

 

===1.3 Mounting===

 

Installed instrument channel equipment within the spent fuel pool shall be mounted to retain its design configuration during and following the maximum seismic ground motion considered in the design of the spent fuel pool structure.

 

===1.4 Qualification===

 

The primary and backup instrument channels shall be reliable at temperature, humidity, and radiation levels consistent with the spent fuel pool water at saturation conditions for an extended period. This reliability shall be established through use of an augmented quality assurance process (e.g., a process similar to that applied to the site fire _p6tection program).1.5 Independence:

The primary instrument channel shall be independent of the backup instrument channel.1.6 Power supplies:

Permanently installed instrumentation channels shall each be powered by a separate power supply. Permanently installed and portable instrumentation channels shall provide for power connections from sources independent of the plant ac and dc power distribution systems, such as portable generators or replaceable batteries.

Onsite generators used as an alternate power source and replaceable batteries used for instrument channel power shall have sufficient capacity to maintain the level indication function until offsite Attachment 2  resource availability is reasonably assured.1.7 Accuracy:

The instrument channels shall maintain their designed accuracy following a power interruption or change in power source without recalibration.

 

===1.8 Testing===

The instrument channel design shall provide for routine testing and calibration.

 

===1.9 Display===

Trained personnel shall be able to monitor the spent fuel pool water level from the control room, alternate shutdown panel, or other appropriate and accessible location.

The display shall provide on-demand or continuous indication of spent fuel pool water level.2. The spent fuel pool instrumentation shall be maintained available and reliable through appropriate development and implementation of the following programs: 2.1 Training:

Personnel shall be trained in the use and the provision of alternate power to the primary and backup instrument channels.2.2 Procedures:

Procedures shall be established and maintained for the testing, calibration, and use of the primary and backup spent fuel pool instrument channels.2.3 Testing and Calibration:

Processes shall be established and maintained for scheduling and implementing necessary testing and calibration of the primary and backup spent fuel pool level instrument channels to maintain the instrument channels at the design accuracy.  

(NEI 12-02 (Revision 1)-.. Avust 2012 The three critical levels that must be monitored in a spent fuel pool are discussed below.It should be noted that continuous indication from a single instrument over the entire span from level 1 to level 3 is not required but could be used. If more than one instrument is used to monitor the entire span, that set of instruments constitutes a single channel satisfying either the primary or backup instrument channel requirement (refer to Figure 1 below).A visual representation of monitoring levels 1, 2 and 3 and the associated requirements for monitoring between the points are presented in Figure 1. The minimum requirements apply to the separation distance between level indications and support development of appropriate response procedures.

These requirements are separate firom the instrument channel design accuracy discussed in section 3, which apply to either discrete or to continuous instruments.

Figure 1 2.3.1. Level 1 -level that is adequate to support operation of the normal fuel pool cooling system A typical fuel pool cooling system design includes a combination of weirs and/or vacuum breakers that prevent siphoning of the pool water level, below a minimum level, in the event of a piping rupture that can affect the SFP level.Level 1 represents the HIGHER of the following two points: 3 NEI 12-02 (Revision 1)August 2012' The level at which reliable suction loss occurs due to uncovering of the coolant inlet pipe, weir or vacuum breaker (depending on the design), or The level at which the water height, assuming saturated conditions, above the centerline of the cooling pump suction provides the required net positive suction head specified by the pump manufacturer or engineering analysis.This level will vary from plant to plant and the instrument designer will need to consult plant-specific design information to determine the actual point that supports adequate cooling system performance.

 

====2.3.2. Level====

2 -level that is adequate to provide substantial radiation shielding for a person standing on the spent fuel pool operating deck Level 2 represents the range of water level where any necessary operations in the vicinity of the spent fuel pool can be completed without significant dose consequences from direct gamma radiation from the stored spent fuel. Level 2 is based on either of the following:

10 feet (+/- 1 foot) above the highest point of any fuel rack seated in the spent fuel pools, or a designated level that provides adequate radiation shielding to maintain personnel radiological dose levels within acceptable limits while performing local operations in the vicinity of the pool. This level shall be based on either plant-specific or appropriate generic shielding calculations, considering the emergency conditions that may apply at the time and the scope of necessary local operations, including installation of portable SFP instrument channel components.

Additional guidance can be found in EPA-400 (Reference 4), USNRC Regulatory Guide 1.13 (Reference  

: 5) and ANSI/ANS-57.2-1983 (Reference 6).Designation of this level should not be interpreted to imply that actions to initiate water make-up must be delayed'until SFP water levels have reached or are lower than this point.2.3.3. Level 3 -level where fuel remains covered and actions to implement make-up water addition should no longer be deferred.Level 3 corresponds nominally (i.e., +/- 1 foot) to the highest point of any fuel rack seated in the spent fuel pool. Level 3 is defined in this manner to provide the maximum range of information to operators, decision makers and emergency response personnel.

Designation of this level should not be interpreted to imply that actions to initiate water make-up must or should be delayed until this level is reached.4 Nuclear Operating Company South 7=zr FPro/cct Bfectr/c G&neMA/ng Statlon 10P Box 28,9 W1 qdsworth, r.as 774,63 February 28, 2013 NOC-AE-13002959 10 CFR 50.4 10 CFR 2.202 U, S. Nuclear Regulatory Commission Attention:

Document Control Desk Washington, DC 20555-0001 South Texas Project Units 1&2 Docket Nos. STN 50-498, STN 50-499 Overall Integrated Plan Regarding Commission Order Modifying Licenses with Regard to Reliable Spent Fuel Pool Instrumentation (Order Number EA-12-051)

: 1. Letter, Eric Leeds to E. D. Halpin, "Issuance of Order to Modify Licenses with Regard to Requirements for Reliable Spent Fuel Pool Instrumentation," March 12, 2012 (EA-12-051)

: 2. NRC Interim Staff Guidance JLD-ISG-2012-03, Compliance with Order EA-12-051, Reliable Spent Fuel Pool Instrumentation, Revision 0, August 29, 2012 3. Letter D. W. Rencurrel to NRC, "Initial Status Report in Response to March 12, 2012 Commission Order Modifying Licenses with Regard to Requirements for Reliable Spent Fuel Pool Instrumentation (Order Number EA-12-051)", dated October 24., 2012 On March 12, 2012, the Nuclear Regulatory.Commission (NRC) issued an order (Reference 1)to STP Nuclear Operating Company (STPNOC).

Reference 1 directs sTP Nuclear Operating Company to provide a reliable indication of the water level in associated spent fuel storage pools. Specific requirements are outlined in Attachment 2 of Reference 1.Reference 1 required submission of an overall integrated plan, including how compliance will be achieved.

: 2) was issued August 29, 2012 providing licensees an acceptable approach for complying with the order. The purpose of this letter is to provide the overall integrated, plan, Including a description of how compliance will be achieved pursuant to Section IV, Condition C.1.a, of Reference 1 in accordance with the guidance In Attachment 2 to Reference I and the guidance in Reference  

: 2. See the Enclosure for STPNOC's response to the requested information.

There are no new commitments in this letter.33650640 NOC-AE-1 3002959 Page 2 of 3 If there are any questions regarding this letter, please contact Robyn Savage at (361) 972-7438.I declare under penalty of perjury that the foregoing is true and correct.Executed on: Ocflcl' el/, Dennis L. Koehl President and CEO/CNO  

South Texas Project (STP) Overall Integrated Plan for Implementation of Unit 1 &Unit 2 Spent Fuel Pool Level Instrumentation to Meet NRC Order EA-12-051 33650640 NOC-AE-13002959 Page 3 of 3!i cc: (paper copy)(electronic copy)Regional Administrator, Region IV U. S. Nuclear Regulatory Commission 1600 East Lamar Boulevard Arlington, TX 76011-4511 Balwant K. Singal Senior Project Manager U.S. Nuclear Regulatory Commission.

One White Flint North (MS 8 B1)11555 Rockville Pike Rockville, MD 20852 NRC Resident Inspector U. S. Nuclear Regulatory Commission P. 0: Box 289, Mail Code: MNI 16 Wadsworth,-TX 77483 C. M. Canady City of Austin Electric Utility Department 721 Barton Springs Road Austin, TX 78704 U. S. Nuclear Regulatory Commission Director of Office of Nuclear Regulation One White Flint North (MS 13 H 16M)11555 Rockville Pike Rockville, MD 20852-2738 A. H. Gutterman, Esquire Morgan,. Lewis & Bockius LLP Balwant K. Singal U. S. Nuclear Regulatory Commission

*John Ragan Chris O'Hara Jim von Suskil NRG South Texas LP Kevin Polio Richard Pena City Public Service Peter Nemeth Crain Caton & James, P.C.C. Mele City of Austin Richard A. Ratliff Texas Department of State Health Services Alice Rogers Texas Department of State Health Services Q.9 33650640 ENCLOSURE NOC-AE-13002959 South Texas Project (STP)Overall Integrated Plan for Implementation of Unit 1 & Unit 2 Spent Fuel Pool Level Instrumentation to Meet NRC Order EA-12-051 (S Page 1 of 12 STP Overall Integrated Plan for Implementation of Unit 1 & Unit 2 Spent Fuel Pool Instrumentation to Meet NRC Order EA 12-051 Revision:

00 1.0 OVERALL INTEGRATED PLAN INTRODUCTION This document provides the overall Integrated Plan (the "Plan") which the STP Nuclear Operating Company ("STPNOC")

will implement for Units I and 2 to comply with the requirements of NRC Order EA-12-051, "Issuance of Order to Modify Licenses with Regard to Reliable Spent Fuel Pool Instrumentation" (Ref.2), (the "ORDER"), NRC Interim Staff Guidance JLD-ISG-2012-003  

[Rev.0] (Ref.3), (the "ISG"), and NEI Report 12-02[Rev.1] ("NEI 12-02").This Plan follows the format and provides all of the information on the STP 1 & 2 Integrated Plan that is required in NEI 12-02 [Rev.1] (Ref.1), Section A-2-2. Throughout this Plan, any reference to NEI 12-02 and the ISG will be based on the revisions above.Any reference to NEI 12-02 will include compliance to the clarifications and exceptions to NEI 12-02 required by the Interim Staff Guidance, Rev. 0.In response to the NRC requirements, STPNOC will provide two channels of independent, permanently-installed, wide-range spent fuel pool level instrumentation  

("SFPLI"), for the spent fuel pool ("SFP") of each unit. The spent fuel pool for each unit is independent and not interconnected in any way. For each SFP, the instrumentation provided for each channel will utilize the same technology, as permitted by the NEI 12-02 [Rev.1]. The spent fuel pool level instrumentation will provide continuous level indication for each SFP on both the Primary and Backup Channels.Both the Primary and Backup Channel/Instrument location and display of the SFP level will be independently mounted in each-unit's Radwaste Control Room in the Mechanical Electrical Auxiliary Building (MEAB), which is an accessible post-event location.

Other locations are still being considered.

Both the Primary and Backup Channel remote, non-safety related indication of the SFP level will also be provided in each unit's Control Room via input to the Plant Computer.The instrumentation systems will not be safety-related, but will meet the requirements for augmented quality in accordance with NEI 12-02 [Rev. 1] and the ISG as described below.Since all of the potential suppliers have not completed development, the information in this Plan is based on the overall .strategy and on information which, based on current information from potential suppliers, is thought to envelope the systems being developed for this application.

[Rev.0] and NEI 12-02 [Rev.1], relief from the requirements and schedule documented in this Plan may be required, in accordance with Section 12.0. Any required changes to this Plan will be defined in the periodic status reports submitted to the NRC.2.0 APPLICABILITY:

This Plan applies to the spent fuel pools for South Texas Project Unit 1 and Unit 2.Page 2 of 12 STP Overall Integrated Plan for Implementation of Unit 1 & Unit 2 Spent Fuel Pool Instrumentation to Meet NRC Order EA 12-051 Revision:

00 3.0 SCHEDULE: The installation of reliable spent fuel pool level instrumentation for the spent fuel pool associated with Unit 1 is scheduled for completion prior to 10/28/2015, which is the end of the second refueling outage (1 REI 9) following submittal of this Plan.The installation of reliable spent fuel pool level instrumentation for the spent fuel pool associated with Unit 2 is scheduled for completion prior to 4/29/2015, which is the end of the second refueling outage (2RE17) following submittal of this Plan.Unit 1 Milestones are as follows:* Design/Engineering  

& Functional Testing -October of 2015 Unit 2 Milestones are as follows:* Design/Engineering  

-December of 2013 ( .. ", Purchase of instruments  

& Functional Testing -April of 2015 Consistent with the requirements of the ORDER and the guidance from NEI 12-02 [Rev.1], status reports will be generated in six (6) month intervals from the submittal of this Plan.4.0 IDENTIFICATION OF SPENT FUEL POOL WATER LEVELS: The STP Unit I and 2 spent fuel pools are essentially identical.

The following SFP elevations are identified:

* The bottom of the pool is at Plant El. 21 ft. 11 in.* The top of the SFP racks is approximately at Plant El. 39 ft. 10 in.* The minimum Limiting Conditionfor Operation SFP level is Plant El. 62 ft.* Normal SFP water level is at Plant El. 66 ft. 6 in.* Non-safety related level switch alarms are activated at Plant El. 67 ft. on high level and Plant El. 66 ft. on low level.* The spent fuel pool deck is at Plant El. 68 ft.The required key SFP water levels, per guidance of NEI 12-02 [Rev.1] and ISG (with clarifications and exceptions), are as follows: Page 3 of 12 STP Overall Integrated Plan for Implementation of Unit 1 & Unit 2 Spent Fuel Pool Instrumentation to Meet NRC Order EA 12-051 Revision:

00 4.1 LEVEL 1: Level adequate to support operation of the normal fuel pool cooling system.LEVEL 1 represents the HIGHER of either the level at which reliable suction loss to the cooling pump occurs, or, the required NPSH (Nominal Pump Suction Head) of the cooling pump.*Loss of reliable suction to SFP cooling pumps. For the purposes of this Plan, this level will conservatively be placed at Plant El. 64 ft. 2 in. This. allows for just over 1 ft. of SFP water level above the top of the suction inlet flange (SFP Cooling Pump 14 in. suction line with centerline of suction inlet flange at Plant El. 62 ft. 6 in.)which will be sufficient for NPSH. (Ref. 9)Therefore, considering the top of SFP fuel storage rack is at Plant El. 39 ft. 10 in., the indicated level on either the Primary or Backup Instrument Channel of greater than 24 ft. 4 in, above the top of the SFP fuel storage racks based on the design accuracy for the instrument channel per NEI 12-02 [Rev.1], for both the Primary and Backup Instrument Channels, is adequate for normal SFP cooling system operation.

LEVEL 1 = Plant El. 64 ft. 2 in or 24 ft. 4 in. water level above the top of the SFP fuel storage rack 4.2 LEVEL 2: Level adequate to provide substantial radiation shielding for a person standing on the SFP operating deck.Indicated level on either the Primary or Backup Instrument Channel of greater than 10 ft, above the top of SFP stored fuel assemblies based on current guidance in NRC RG 1.13 [Rev.2] (Ref. 4) will achieve substantial radiation shielding.

Requirements on substantial SFP radiation shielding is also given in ANSI/ANS-57.2-1983 (Ref. 5), and states that radiation shall not exceed 2.5 mRem/hr, but the minimum water depth to achieve this is undefined.

NRC RG 1.13 [Rev.2] took exception to using dose rates as design input for minimum SFP water level, and instead defined the minimum level as 10 ft. above the stored fuel assemblies.

STPNOC elects to use the conservative approach of defining the top of the fuel rack as a basis for measurement.

Therefore, indicated level on either the Primary or Backup Instrument Channel of greater than 10 ft. above the top of the SFP fuel storage rack, based on the design accuracy of the instrument channel per NEI 12-02 [Rev.1], for both the Primary and Backup Instrument Channels, ensures there is adequate water level to provide substantial radiation shielding for a person standing on the spent fuel pool operating deck.Page 4 of 12 STP Overall Integrated Plan for Implementation of Unit I & Unit 2 Spent Fuel Pool Instrumentation to Meet NRC Order EA 12-051 Revision:

00 LEVEL 2 []Plant El 49 ft. 10 in. or 10 ft. water level above the top of the SFP fuel storage rack.4.3 LEVEL 3: Level where the fuel remains covered.As stated above, STPNOC elects to use the conservative approach of defining the top of the fuel rack as a basis for measurement.

The installation of the SFPLI sensor will be such that it will measure as close as possible to the top of the SFP fuel rack. Indicated level on either the Primary or Backup Instrument Channel of greater than 1 ft. above the top of SFP fuel storage racks based upon the design accuracy of the instrument channel per NEI 12-02 [Rev.1], for both the Primary and Backup Instrument Channels, satisfies the NEI 12-02 [Rev.2] requirement of +/- 1 ft.from the top of the fuel rack. This monitoring level ensures there is adequate water level above the stored fuel seated in the SFP fuel storage rack.LEVEL 3 = Plant El 40 ft. 4 in. or 6 in. water level above the top of the SFP fuel storage rack.5.0 INSTRUMENTS:

The design of the primary. and backup instruments will be consistent with the requirements by NEI 12-02 [Rev.1], the ISG, and this Plan.The current plan is for both channels to utilize Guided Wave Radar, which functions according to the principle of Time Domain Reflectometry (TDR). A generated pulse of electromagnetic energy travels down the probe. Upon reaching the liquid surface the pulse is reflected and based upon reflection times level is inferred.

The measured range will be continuous from the high pool level elevation (67') to the top of the spent fuel racks (Ref. 8). However, STP is still evaluating other designs for this application.

Any changes to the current plan will be reported in the 6 month update letter.The supplier for the SFP instrumentation will be chosen by a competitive bidding process completed after submittal of this Plan, so the information in this Plan is based on the overall strategy and on available information from potential supplier's information on systems being developed for this application.

 

===5.1 Primary===

(fixed) Instrument Channel The Primary Instrument Channel level sensing components will be located in the northeast corner of the Spent Fuel Pool, as shown in Attachment  

: 1. The primary instrument channel will provide continuous level indication over a range from Plant El. 40 ft. 4 in. (LEVEL 3) to Plant El. 67 ft. (SFP high level alarm) or a range of 26 ft.8 in. In addition, the capability for discrete level indications at LEVEL1, LEVEL 2 and LEVEL 3, as described in Section 4.0, will be available.

Page 5 of 12 Nuclear Operating Company South 7Xas PlotlectrE/ic Geei&#xfd;Iewiln Stjtioi RD , Box 2S.9 adsmoith, Tewos 77483 June 25, 2013 NOC-AE-1 3003008 File No.: G25 10 CFR 2.202 U. S. Nuclear Regulatory Commission Attention: