Revised Administrative Procedures,Including Rev 5 to AP-961, Earthquake, Rev 7 to AP-330, Loss of Nuclear Svc Water, Rev 19 to AP-770, EDG Actuation & Rev 5 to AP-1080, Refueling Canal Level Decrease

ML20069E465
Person / Time
Site:	Crystal River
Issue date:	05/31/1994
From:	FLORIDA POWER CORP.
To:
References
PROC-940531, NUDOCS 9406070203
Download: ML20069E465 (85)
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DATE:

Tue May 31 16:24:26 1994 CPY COPY TOTALS

- DOCUMENT REV COML:NTS INFO CNTL MSTR AP0330 07 7

1 0

0 AP0770 19 7

1 0

0 AP0961 05 7

1 0

0 AP1080 05 7

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INSTRUCTIONS TO THE ADDRESSEE:

IF YOU ARE A HOLDER OF A HARD CDPV,PLEASE VERIFY THE DOCUMENT (8) RECEIVfD AGREE 8 WITH THE ABOVE DESCRIPil0N.

CI SURE TO TsESTROY DOCUMENT (8) OR PORTIONS OF DOCUMENT (Si SUPERSEDED BY THE AB0VE.

THE SIGNATURE IMOICATES THAT YOU HAVE RE AD AND UNDERSTAND THESE IW8TRUCT10NS AND THE CHANGES TO THE DOCUMENTS.

RETURN SIGNEO AND DATED TRANSISTTAL TO DOCUMENT CONTROL WITHit 20 DAYS AT MAIL CODE:

NR2B WAIC

[ Flodde Power Carpersties Demmest Centrol Crystal River Energy Cumples 15780 W. Power Line St.

Crystal River, FL 34428 8708 SICNATURE Of ADDRESSEE DATE WDEPENDENT VERiflCAT10N icestret Reem Deeemeste 0mid DATE_

a nan 6 a s= n 9406070203 940531 h

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/~~ 'i EQ REV 5 AP-961 V

EARTHQUAKE 1.0 ENTRY CONDITIONS IE moderate to severe vibrations occur throughout the plant, OR seismic recorder indicates a seismic event has taken place, lHB use this procedure.

H 2.0 IMMEDIATE ACTIONS Note There are no immediate actions in this procedure.

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l This Procedure Addresses Safety Related Components r

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l Approved by MNP0 Date 4 -j-ly (S[GJ1 TE~0N' FILE)

AP-961 PAGE 1 of 9 EQ

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AP-961 REV 05 PAGE 2 of 9 EQ

3.0 FOLLOW-UP ACTIONS V

ACTIONS DETAILS 3.1 Notify personnel of plant o

Plant Operators conditions as required.

o S0TA o

SS0D to evaluate plant conditions for potential entry into the Emergency Plan.

' 3.2 Concurrently perform VP-540, Runback Verification Procedure.

3.3 E the entry conditions of Depress the Rx Trip pushbutton.

E0P-2, Vital System Status Verification are met, THEN trip the Rx, AND GO TO E0P-2.

e CONCURRENTLY PERFORM this procedure as resources become available.

3.4 Verify rod index is within o Refer to computer group 59.

limits.

o Refer to the COLR.

H NOT, THEN refer to ITS.

o Refer to ITS 3.1.5, Safety Rod Insertion Limits, o Refer to ITS 3.2.1, Regulating Rods Insertion Limits.

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AP-961 REV 05 PAGE 3 of 9 EQ

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AP-961 REV 05 PAGE 4 of 9 EQ m.

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3.0 FOLLOW-UP ACTIONS (CONT'D)

O ACTIONS DETAILS 3.5 Verify quadrant power tilt o Refer to computer group 59.

is within limits.

o Refer to the COLR.

H NOT, THEN refer to ITS 3.2.4, Quadrant Power Tilt.

3.6 Maintain imt,alance within o Observe SPDS imbalance display.

limits.

o Adjust APSRs to maintain H NOT, imbalance.

THEN refer to ITS 3.2.3, Axial Power Imbalance o Refer to the COLR for limits.

Operating Limits.

3.7 Verify rods are within 6.5% of their group O

average height.

E NOT, THEN refer to ITS 3.1.4, Control Rod Group Alignment Limits.

3.8 lE evaluation of the entry conditions indicate that plant equipment has caused vibrations, THEN exit this procedure.

3.9 Perform survey of plant for E injured personnel are found, injured personnel.

THEN notify EMT, OR notify a member of the Medical Emergency Team.

AV AP-961 REV 05 PAGE 5 of 9 EQ

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i AP-961 REV 05 PAGE 6 of 9 EQ l

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s-l l-3.0 FOLLOW-UP ACTIONS (CONT'0)

ACTIONS DETAILS 3.10 IE Rx is tripped, Refer to SP-421, Reactivity Balance THEN determine shutdown Calculations.

margin.

3.11 Observe indications for Refer to 0P-506, LPMS Data Handling l

loose parts in RCS.

Recording and Analysis.

3.12 Establish stable RCS Refer to SP-317, RCS Water conditions Inventory Balance.

AND determine RCS leak rate.

3.13 Notify Chemistry to sample RCS for fuel failure.

O 3.14 Perform EDG test.

o Refer to SP-354A, Monthly Functional Test of the Emergency Diesel Generator EGDG-1A.

o Refer to SP-354B, Monthly Functional Test of the Emergency Diesel Generator EGDG-18.

3.15 Perform comprehensive Observe:

physical inspection of entire plant.

o Sump levels, o Radiation monitors, o Tank levels, o H2 tank level.

O AP-961 REV 05 PAGE 7 of 9 EQ

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O BLANK PAGE O

AP-961 REV 05 PAGE 8 of 9 EQ

4 3.0 FOLLOW-UP ACTIONS (CONT'D)

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ACTIONS DETAILS 3.16 Notify I&C Tech to remove Obtain copy of tapes and give to tapes from Seismic recorders SS00.

and determine, from tapes, maximum vibration reading.

3.17 lE Seismic Recorder indicates 2 0.05g, THEN notify Computer and Controls Engineer to perform instrumentation tests.

3.18 IE fuel failure is detected, THEN refer to ITS 3.4.15, RCS Specific Activity.

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l 3.19 Notify department managers to determine any additional surveillance requirements.

3.20 Determine subsequent actions based on results of physical inspection.

i CN AP-961 REV 05 PAGE 9 of 9 (LAST PAGE)

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LSW REV 7 AP-330 LOSS OF NUCLEAR SERVICE WATER 1.0 ENTRY CONDITIONS 1E any of the following conditions exist:

o TEMPS of SW cooled components are high and rising, o SW surge tank is < 5 ft, o SW flow is lost, lHEN use this procedure.

'0 IMMEDIATE ACTIONS d.

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O There are no immediate actions in this procedure.

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This Procedure Addresse,s Safety Related Components I-7I -h l

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AP-330 PAGE 1 of 11 LSW

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AP-330 REV 7 PAGE 2 0F 11 L39

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j 3.0 FOLLOW-UP ACTIONS 3(G ACTIONS DETAILS 3.1 Notify personnel of plant

S0TA, conditions as required.

1 Plant Operators, l

SS00 to evaluate plant conditions for potential entry into the Emergency Plan.

l 3.2 E at any time while performing this procedure, any of the following conditions exist:

o SW surge tank is < 1 ft, and level can NOT be restored o SW flow is lost, and can NOT be restored o Multiple CRDM stator TEMPS are > 180*F, THEN trip the Rx.

Depress the Rx Trip pushbutton.

AND CONCURRENTLY PERFORM E0P-2, Vital System Status Verification, beginning with Step 2.1.

l 3.3 E SW flow is lost, Start 1 of the following:

AND SW surge tank is > 1 ft, THEN start 1 SW pump.

o SWP-1A, o SWP-1B, o SWP-10.

l 3.4 E SW surge tank is < 5 ft, o Start both DW transfer pumps THEN increase DW flow to SW WTP-6A and WTP-6B.

surge tank.

o Notify Building Operators to look for high DW usage.

s AP-330 REV 7 PAGE 3 0F 11 LSW

9 :

3.2 Jf any of the following conditions exist:

o SW surge tank is < 1 ft, and level can NOT be restored, o

SW flow is lost and can NOT be restored, o

Multiple CRDM stator TEMPS are 2180*F, THEN trip the Rx.

AND CONCURRENTLY PERFORM E0P-2, Vital System Status Verification, beginning with Step 2.1.

Table 1: SW Cooled Components.

RB Main fan assemblies Letdown coolers RCDT cooler CRDMs SF coolers and air handling units Sample coolers Seal return coolers Evaporators VG compressors EFP-1 SWP-1A, SWP-1B and SWP-lC RWP-2A, RWP-28 and RWP-1 IA and SA compressors, if aligned Water box ARPs, if aligned Control Complex chillers, if aligned RCPs MVPs if aligned AP-330 REV 7 PAGE 4 0F 11 LSW

' 3.0 FOLLOW-UP ACTIONS (CONT'D) f-g ACTIONS DETAILS b

l 3.5 1F DW makeup to the SW surge Notify AB Operator to.c.lign tank is 10T available, the FS header for SW surge THEN use water for makeup, tank makeup:

1 Connect pre-staged hose between FSV-186 and SWV-520.

2 Close SWV-298.

3 Open FSV-186.

4 Open SWV-520.

5 Maintain SW surge tank l

> 5 ft using the SW fill valve, SWV-277.

6 Notify TB Operator to place the Motor driven FS pump, FSP-1, on recirc.

l 3.6 IF SW surge tank is < 1 ft, TREN:

('s 1

Ensure operating MVP is tj DC cooled, s

2 Stop all SWPs, Stop SW cooled pumps by:

3 Stop all SW cooled RWPs.

1 Select SWP-2A and SWP-2B to "PdLL TO LOCK."

2 Ensure SWP-lC and RWP-1 in NORMAL AFT STOP.

3. Maintain pumps in stopped position:

SWP-1A SWP-1B RWP-2A RWP-2B.

4. Open DC knife switch at ES 4160V Bkr for:

SWP-1A SWP-1B RWP-2A RWP-28.

AP-330 REV 7 PAGE 5 0F 11 LSW

3.2 JE any of the following conditions exist:

N o

SW surge tank is < 1 ft, and level can NOT be restored, o

SW flow is lost and can HQI be restored, o

Multiple CRDM stator TEMPS are > 180*F, THEN trip the Rx.

AND CONCURRENTLY PERFORM E0P-2, Vital System Status Verification, beginning with Step 2.1.

Table 1: SW Cooled Components.

RB Main fan assemblies Letdown coolers RCDT cooler CRDMs SF coolers and air handling units Sample coolers Seal return coolers Evaporators

._ WG compressors EFP-1 SWP-1A, SWP-1B and SWP-1C RWP-2A, RWP-28 and RWP-1 IA and SA compressors, if aligned Water box ARPs, if aligned Control Complex chillers, if aligned RCPs MUPs if aligned

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PAGE 6 0F 11 AP-330 REV 7 LSW

i-3.0 FOLLOW-UP ACTIONS (CONT'D)

ACTIONS DETAILS

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3.7 IE SW flow is lost to the 1

Trip all RCPs RCPs for > 5 min, IHEN ensure Rx tripped and 2

Ensure oil lift pumps Auto trip all RCPs, start.

AND isolate SW to the RCPs.

3 Isolate SW to the RCPs, close the following:

SWV-80, RCP-1A SWV-79, RCP-18 SWV-82, RCP-1C SWV-81, RCP-1D l 3.8 If SW flow does NOT exist, See Table 1 for SW cooled THEN stop or isolate SW components.

cooled components.

l 3.9 If CRDM TEMPS are the only o Observe computer points X-211 TEMPS increasing, through X-279.

t THEN increase CRDM cooling.

o Ensure SWV-109 and SWV-110 are open.

o Increase CRDM cooling by:

Start Emergency Duty SW pump, SWP-1A or SWP-1B Start both CRDM booster pumps SWP-2A SWP-2B Place spare CRD filter in service Fail open SW-763:

Isolate and vent air to SW-224-TIC via filter regulator left of SW-224-TIC located 119, AB in RMA-6 Pen area Isolate TEMP control loop:

Close SW-766 and SW-767 (95' AB by CRDM booster pumps)

O AP-330 REV 7 PAGE 7 0F 11 LSW

3.2 If any of the following conditions exist:

o SW surge tank is < 1 ft,

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and level can NOT be restored, o

SW flow is lost and can NOT be restored, o

Multiple CRDM stator TEMPS are 2 180*F, THEN trip the Rx.

AND CONCURRENTLY PERFORM E0P-2, Vital System Status Verification, beginning with step 2.1.

Table 1: SW Cooled Components.

RB Main fan assemblies Letdown coolers RCDT cooler CRDMs SF coolers and air handling units

()

Sample coolers Seal return coolers Evaporators WG compressors EFP-1 SWP-1A, SWP-1B and SWP-lC RWP-2A, RWP-2B and RWP-1 IA and SA compressors, if aligned Water box ARPs, if aligned Control Complex chillers, if aligned RCPs MVPs if aligned O

AP-330 REV 7 PAGE 8 0F 11 LSW

' 3.0 FOLLOW-UP ACTIONS (CONT'D)

(3 ACTIONS DETAILS

\\J l 3.10 1F_ SW flow exists, Ensure:

AND SW cooled component l

TEMPS are increasing, Emergency Duty SW RW pump is THEN ensure maximum SW operating, RWP-2A or RWP-28, cooling to essential components.

Emergency Duty SW pump is operating, SWP-1A or SWP-1B, The "RW RECIRC CONTROL SURVEILLANCE SWITCH" is in the

" NORMAL" position.

Located on the Bkr cubicle for RWP-38 in the B ES 4160 V Switchgear

Room, The RW Recirc Control valve, RWV-150, is either closed or

isolated, All SW heat exchangers are in

service, Non-essential components are isolated, see Table 1 for list of SW cooled components, Proper intake canal conditions

exist, RB Fans are aligned to CI.

l 3.11 IE SW leak exists, o Observe Bldg sump levels.

THEN determine location of leak.

o Observe RCDT level, o Observe DC surge tank level.

l 3.12 1E SW le'k is in the RB, See Table 1 for SW cooled THEN isolate SW to components, non-essential loads in RB, AND notify Operator to perform SW walkdown in RB, if possible, f3

\\J AP-330 REV 7 PAGE 9 0F 11 LSW

3.2 lE any of the following conditions exist:

o SW surge tank is < 1 ft, and level can NOT be restored, o

SW flow is lost and can NOT be restored, o

Multiple CRDM stator TEMPS are 1180*F, 1

THEN trip the Rx.

AND CONCURRENTLY PERFORM E0P-2, Vital System Status Verification, beginning with Step 2.1.

Table 1: SW Cooled Components.

1 RB Main fan assemblies

__ Letdown coolers RCDT cooler CRDMs SF coolers and air handling units

__ Sample coolers Seal return coolers Evaporators WG compressors EFP-1 i

SWP-1A, SWP-1B and SWP-1C RWP-2A, RWP-2B and RWP-1 IA and SA compressors, if aligned Water box ARPs, if aligned Control Complex chillers, if aligned RCPs MUPs if aligned O

AP-330 REV 7 PAGE 10 0F 11 LSW

3.0 F0ll0W-UP ACTIONS (CONT'D)

O ACTIONS DETAILS V

l 3.13 E SW 1eak is in the AB, Notify AB Operator to:

THEN notify AB Operator to perform SW walkdown.

Observe local SW tank

level, Ensure proper SW valve alignment.

Refer to OP-408, Nuclear Services Cooling System.

Observe normal SW and SW RW Pump discharge pressures.

l 3.14 E SW leak exist and can 1.

Notify AB Operator to place NOT be found, standby SW heat exchanger THEN determine if SW heat in service and to isolate 1 exchangers are leaking.

inservice SW heat exchanger.

A 2.

Repeat the above process 1

(_)

at a time until all SW heat exchangers have been isolated.

l 3.15 E adequate SW cooling' can NOT be established, THEN GO TO OP-209, Plant Cooldown, beginning with appropriate Step, based on RCS TEMP and PRESS.

l 3.16 E adequate SW cooling has been restored, THEN EXIT this procedure.

GO T0 the appropriate procedure as determined by the SSOD.

(

AP-330 REV 7 PAGE 11 of 11 (LAST PAGE)

LSW

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EDGA REV 19 AP-770 l

EMERGENCY DIESEL GENERATOR ACTUATION 1.0 ENTRY CONDITIONS LF. 4160V ES Bus UV occurs, JJiElf use this procedure.

2.0 IMMEDIATE ACTIONS Note There are no immediate actions for this procedure.

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G AP-770 PAGE 1 ef 49 EDGA

O BLANK PAGE O

AP-770 REV 19 PAGE 2 of 49 EDGA

f-~g 3.0 FOLLOW-UP ACTIONS Y_]

ACTIONS DETAILS 3.1 Notify personnel of plant S0TA conditions as required.

Plant operators l

SSOD to evaluate plant conditions for potential entry into the Emergency Plan 3.2 lE both ES 4160V buses are energized, THEN GO T0 step 3.6 in this procedure.

3.3 If at any time, an EDG fails

1. Check overcurrent lockouts on the j

to energize its respective SSR section of the MCB for the

/

bus, affected bus.

(,

THEN check the bus overcurrent lockouts before ES 4160V Overcurrent Lockouts:

attempting to re-energize.

ES Bus 3A ES Bus 3B 86B-3205 868-3206 868-3207 86B-3208 868-3211 868-3217 2

If no overcurrent lockouts are actuated, THEN efforts should be made to energize the bus.

3 If any overcurrent lockout is found actuated, THEN do NOT attempt to energize the bus until the fault has been determined and corrected.

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AP-770 REV 19 PAGE 3 of 49 EDGA

(3 Applicable Carry-over steps:

3.3 JI at any time, an EDG fails...

O O

AP-770 REV 19 PAGE 4 of 49 EDGA

p LO F0liQW-UP ACTIONS (CONT'D1 V

ACTIONS DETAILS CAUTION Per stcp 3.3, do not attempt to energize a bus that has actuated overcurrtnt lockouts.

• • • • • • • 5**4**}******4*****************k********************w******************

3.4 If an EDG fails co energize its

1. Ensure all feeder Bkrs to respective bus, affected bus are open.

AND any of the following power sources are energized:

ES 4160V Bus Feeder Bkrs:

BEST Feeder A Bus B Bus Offsite Power Transformer BEST 3205 3206 Aux Transformer, Offsite 3211 3212 IHEH prepare the dead bus for Aux 3207 3208 re-energization.

EDG 3209 3210 2

Select MUPs on the dead bus to Normal After Stop.

3 If the "4160V ES BUS ES/UV BLOCK LOCK OUT" has

actuated, THEN defeat it for the affected bus:

o Notify available PPO to open knife switch "AY" in the " DUMMY" cubicle for the affected ES 4160V Bus o WHEN "AY" is open, IEEN reset UV lockout by depressing "4160 ES UV RESET" pushbutton for the affected bus.

AP-770 REV 19 PAGE 5 of 49 EDGA

1L d

Applicable Carry-over steps:

3.3 If at any time, an EDG fails...

l DO O

AP-770 REV 19 PAGE 6 of 49 EDGA

1 I

3.0 FOLLOW-UP ACTIONS (CONT'D) n

,q ACTIONS DETAILS CAUTION Per step 3.3, do not attempt to energize a bus that has actuated overcurrent lockouts.

• • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • i******

3.5 If an EDG fail: to energize

1. Close feeder Bkr from the its respective bus, available pov., source by holding AND power is available to in "CLOSE" position until the "4 re-energize the bus, KV ES BUS DEAD" annunciator alarm AND the bus has been clears (normally 110 seconds).

i prepared for re-energization, ES 4160V BUS Feeder Bkrs:

THEN energize the bus from the available power source.

Feeder A Bus B Bus BEST 320$

3206 Offsite 3211 3212

()

Aux 3207 3208 2

IE opened in step 3.4, THEN notify available PP0 to yclose knife switch "AY" in the " DUMMY" cubicle for the affected ES 4160V Bus.

O AP-770 REV 19 PAGE 7 of 49 EDGA

Applicable Carry-over steps:

O 3.3 If at any time, an EDG fails...

O O

AP-770 REV 19 PAGE 8 of 49 EDGA

3.0 FOLLOW-UP ACTIONS (CONT'D)

ACTIONS DETAILS 3.6 CONCURRENTLY PERFORM VP-580, Plant Safety Verification Procedure, beginning with Step 3.1.

3.7 IE letdown flow has been 1

Close MUV-49 "LETDN CLR IS0".

lost, THEN isolate letdown.

2 lE MUV-49 will not close, IHfH close:

o MUV-50 "BLK ORIFICE IS0" o MVV-51 " LETDOWN FLOW" control.

3.8 WHEN letdown flow g--

restoration is desired, IEEH Refer to Enclosure 1, RC Letdown Recovery.

Continue on in this procedure.

O AP-770 REV 19 PAGE 9 of 49 EDGA

Applicable Carry-over steps:

v 3.3 IE at any time, an EDG fails...

3.8 FE!!1 letdown flow restoration is desired, THEN Refer to...

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O AP-770 REV 19 PAGE 10 of 49 EDGA

l 3.0 FOLLOW-UP ACTIONS (CONT'D)

ACTIONS DETAILS i

CAUTION Per step 3.3, do not attempt to energize a bus that has actuated overcurrent lockouts.

I 3.9 If the affected bus has not Failed EDG recovery:

been energized, AND any of the following EDG 1

Notify PP0 to block the EDG failures have occurred:

start command by selecting the " NORMAL AT ENGINE" switch o

An EDG failed to start to "AT ENGINE" on the tripped EDG gauge board.

o An EDG tripped after

starting, 2

Ensure condition causing failure of the EDG is 1

THEN correct the cause of corrected.

the failure and energize the affected bus.

3 Select MVPs on the dead bus to Normal After Stop.

()

4 lE the knife switch "AY", in

" DUMMY" cubicle was opened per step 3.4, THEN notify available PP0 to close knife switch "AY" in the " DUMMY" cubicle for the affected ES 4160V bus.

5 Notify PP0 to depress the

" RESET" push button on the EDG gauge board.

6 Wait at least 2 minutes to allow the shutdown relays to reset.

7 Notify PP0 to select the

" NORMAL AT ENGINE"' switch to

" NORMAL" on the EDG gauge board.

The EDG should start and energize the bus if an UV condition exists.

O AP-770 REV 19 PAGE 11 of 49 EDGA

~

Q Applicable Carry-over steps:

b 3.3 IE at any time, an EDG fails...

3.8 !UiEN letdown flow restoration is desired, THEN Refer to Enclosure 1...

Table 1: EDG Rating

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load range in MW Maximum load 3.5

~

30 min

> 3.25 to 1 3.5

~

200 hr

> 3.0 to 1 3.25 2000 hr

> 2.85 to 1 3.0 Continuous 1 2.85 Table 2: EDG Loads to Shed Loads MW EFP-1 0.528 SWP-1A or 94P-1B 0.486 l

RWP-2A or RWP-2B 0.538

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AHF-1A or AHF-1B or AHF-lC 0.061 Table 3: ES 480V Load Ratings Loads MW ES MCC 3AB with AHF-1C 0.091 A or B heat tracing 0.041 AHF-54A or AHF-54B 0.013 AHF-17A or AHF-17B 0.050 AHF-18A or AHF-18B 0.050 AHF-19A or AHF-19B 0.017 CHP-1A or CHP-1B D " '. 7 CHHE-1A or CHHE-1B 0.193 SFP-1A or SFP-1B 0.041 O

AP-770 REV 19 PAGE 12 of 49 EDGA

3.0-FOLLOW-UP ACTIONS (CONT'D)

ACTIONS DETAILS 3.10 IE ES 480V UV lockout has 1

Bypass or reset ES actuation.

actuated, THEN reset ES 480V 2

Reset ES 480V lockouts lockout.

located behind the MCB.

ES 480V UV Lockouts:

A B

8627/ESA 8627/ESB 86X27/ESA 3.11 If only 1 ES 480V bus is 1

Ensure EDG capacity to supply energized, 0.1 MW additional load.

IHEN ensure ES MCC 3AB is aligned to the energized See Tables 1, 2, and 3.

ES 480V bus.

O 2

Depress transfer pushbuttons for the ES MCC 3AB to the energized ES.480V bus.

(

AP-770 REV 19 PAGE 13 of 49 EDGA

Applicable Carry-over steps:

-g s- /

3.3 If at any time, an EDG fails...

3.8 HEEH letdown flow restoration is desired, IHEN Refer to...

Table 1: EDG Rating

, ;g; 9%

Load range in MW Maximum load 3.5 30 min

> 3.25 to s 3.5 200 hr

> 3.0 to 1 3.25 2000 hr

> 2.85 to s 3.0 Continuous 5 1.85 Table 2: EDG Loads to Shed Loads MW EFP-1 0.528 SWP-1A or SWP-1B 0.486

()

RWP-2A or RWP-2B 0.538 AHF-1A or AHF-1B or AHF-lc 0.061 Table 3: ES 480V Load Ratings Loads MW ES MCC 3AB with AHF-1C 0.091 A or B heat tracing 0.041 AHF-54A or AHF-54B 0.013 AHF-17A or AHF-17B 0.050 AHF-18A or AHF-18B 0.050 AHF-19A or AHF-19B 0.017 CHP-1A or CHP-1B 0.017 CHHE-1A or CHHE-1B 0.193 SFP-1A or SFP-1B 0.041 AP-770 REV 19 PAGE 14 of 49 EDGA

l*

3.0 FOLLOW-UP ACTIONS (CONT'D)

,O V

ACTIONS DETAILS 3.12

.lf MVP restart is 1

Close MVV-16 "RC PUMP TOTAL

required, SEAL INLET FLOW VALVE" JJiG start MVP,

.AJfD establish RCP seal 2

Close MUV-31 "PZR LEVEL injection.

CONTROL".

Continue on in this 3

Establish MVP cooling.

procedure.

4 Establish MVP recirc flow path.

5 Start lube and gear oil pumps.

6 Start ES selected MVP.

7 Throttle open MVV-16 to obtain 3 gpm seal injection per RCP.

8 Note the time that RCP seal Os injection was established 9

Place MUV-31 in "AUT0" at desired setpoint.

10 2 10 min after the time noted in detail 8, throttle open MUV-16 to establish 6 gpm per RCP.

Note the time 11 2 10 min after the time noted in detail 10, throttle open MUV-16 to establish 10 gpm per RCP.

O AP-770 REV 19 PAGE 15 of 49 EDGA

f Applicable Carry-over steps:

3.3 1E at any time, an EDG fails...

3.8 WHEN letdown flow restoration is desired, THEN Refer to Enclosure 1...

j Table 1: EDG Rating W#8s.ain < id $

Load range in MW Maximum load 3.5 30 min

> 3.25 to 1 3.5 200 hr

> 3.0 to 1 3.25 2000 hr

> 2.85 to s 3.0 Continuous s 2.85 Table 2: EDG Loads to Shed Loads MW EFP-1 0.528 SWP-1A or SWP-1B 0.486 Os RWP-2A or RWP-28 0.538 AHF-1A or AHF-1B or AHF-lc 0.061 Table 3: ES 430V Load Ratings Loads MW ES MCC 3AB with AHF-1C 0.091 A or B heat tracing 0.041 AHF-54A or AHF-54B 0.013 AHF-17A or AHF-17B 0.050 AHF-18A or AHF-18B 0.050 AHF-19A or AHF-198 0.017 CHP-1A or CHP-1B 0.017 CHHE-1A or CHHE-1B 0.193 SFP-1A or SFP-1B 0.041 AP-770 REV 19 PAGE 16 of 49 EDGA

3.0 FOLLOW-UP ACTIONS (CONT'D)

ACTIONJ DETAILS 3.13 1E an additional MVP is See Tables 1 and 2.

required to be started, THEN ensure EDG capacity for 0.7 MW additional load exists prior to starting.

Note The MW load value provided in step 3.14, detail 1, is for 1 train of decay heat removal including the DCP and RWP.

3.14 IE RCS was on decay heat 1

Ensure EDG capacity for 0.55

removal, MW additional load exists AND decay heat removal prior to starting.

restart is required, THEN verify prerequisite See Tables 1 and 2.

conditions as directed by SS0D.

2 Refer to OP-404, Decay Heat

/"~5 Removal System, Section 4.7.

U 3.15 IE SW Raw Water PRESS has To restart a pur.p that was running not recovered, when power was interrupted:

THEN start RWP-2A or RWP-28.

1 Ensure EDG capacity for 0.55 MW additional load exists prior to starting.

See Tables 1 and 2.

2 Select the control switch to the "STOP" position to reset the anti-pump device.

3 Select the control switch to the " START" position.

P AP-770 REV 19 PAGE 17 of 49 EDGA

gs Applicable Carry-over steps:

3.3 1E at any time, an EDG fails...

3.8 MHEH letdown flow restoration is desired, IEEN Refer to...

Table 1: EDG Rating Load range in MW

^

en x

Maximum load 3.5 30 min

> 3.25 to 1 3.5 200 hr

> 3.0 to 1.^. 25 2000 hr

> 2.85 to s 2.0 Continuous s 2.85 Table 2: EDG Loads to Shed Loads MW EFP-1 0.528 SWP-1A or SWP-1B 0.486

()

RWP-2A or RWP-2B 0.538 AHF-1A or AHF-1B or AHF-lC 0.061 Table 3: ES 480V Load Ratings Loads MW ES MCC 3AB with AHF-lC 0.091 A or B heat tracing 0.041 AHF-54A or AHF-54B 0.013 i

AHF-17A or AHF-17B 0.050

)

AHF-18A or AHF-188 0.050 AHF-19A or AHF-198 0.017 CHP-1A or CHP-1B 0.017 CHHE-1A or CHHE-1B 0.193 SFP-1A or SFP-18 0.041

('~h

' s/

'ss REV 19 PAGE 18 of 49 EDGA AP-770 l

3.0 FOLLOW-UP ACTIONS (CONT'D)

ACTIONS DETAILS 3.16 1E SW PRESS has not To restart a pump that was running recovered, when power was interrupted:

IllEH start SWP-1A or SWP-18.

1 Ensure EDG capacity for 0.5 MW additional load exists prior to starting.

See Tables.1 and 2.

2 Select the control switch to the "STOP" position to reset the anti-pump device.

3 Select the control switch to the " START" position.

3.17 Ensure RB Cooling is in 1

Ensure EGDG capacity for service on SW cooling.

0.075 MW additional load exists prior to starting.

See Tables 1 and 2.

2. Ensurc ' RB cooling unit running in slow : peed:

___. AHF-1A slow speed AHF-IC slow speed AHF-1B slow speed.

3. Ensure SW is aligned to RB cooling units:

Close SWV-152 Close SWV-151 Close SWV-355 Open SWV-353 Open SWV-354.

OV AP-770 REV 19 PAGE 19 of 49 EDGA

O Applicable Carry-over steps:

V 3.3 If at any time, an EDG fails...

3.8 W11@ letdown flow restoration is desired, Ili@ Refer to Enclosure 1...

Table 1: EDG Rating

's*

Load range in MW Maximum load 3.5 30 min

> 3.25 to s 3.5 200 hr

> 3.0 to 1 3.25 2000 hr

> 2.85 to 1 3.0 Continuous 1 2.85 l

Table 2: EDG Loads to Shed Loads MW EFP-1 0.528 SWP-1A or SWP-1B 0.486 O

RWP-2A or RWP-2B 0.538 AHF-1A or AHF-1B or AHF-lC 0.061 Table 3: ES 480V Load ngs Loads MW ES MCC 3AB with AHF-lc 0.091 A or B heat tracing 0.041 AHF-54A or AHF-548 0.013 AHF-17A or AHF-178 0.050 AHF-18A or AHF-188 0.050 AHF-19A or AHF-198 0.017 1

CHP-1A or CHP-1B 0.017 i

CHHE-1A or CHHE-1B 0.193 SFP-1A or SFP-1B 0.041 O

AP-770 REV 19 PAGE 20 of 49 EDGA

3.0 F0ll0W-UP ACTIONS (CONT'D)

O ACTIONS DETAILS Note 2 PZR Htr groups are required to compensate for heat loss to ambient.

3.18 E all of the following See Tables 1 and 2.

conditions are met:

CONCURRENTLY PERFORM Enclosure PZR Htrs are required 2, Energizing PZR Htrs, IAP-1A, DPBC-lG and DPBC-ll from 4160V PZR Htr normal power ES A, to energize 2 PZR Htr supply is not available groups.

J ES 4160V Bus A is energized ES 480V Bus A is energized PZR Htr MCC 3A is available, IE G ensure EDG-1A capacity for 0.275 MW load AND energize 2 PZR Htr groups from 4160V ES Bus A.

I 3.19 E all of the following See Tables 1 and 2.

conditions are met:

CONCURRENTLY PERFORM Enclosure PZR Htrs are required 3, Energizing PZR Htrs, IAP-18, DPBC-lH and DPBC-ll from 4160V l

PZR Htr normal power ES B, to energize 2 PZR Htr supply is not available groups.

ES 4160V Bus B is energized ES 480V Bus B is energized PZR Htr MCC 3A is not available, THEN ensure EDG-1B capacity for

/.

0.275 MW load AND energize 2 PZR Htr groups from 4160V ES Bus B.,

AP-770 REV 19 PAGE 21 of 49 EDGA I

e Applicable Carry-over steps:

3.3 Jf at any time, an EDG fails...

3.8 WHEN letdown flow restoration is desired, THEN Refer to Enclosure 1...

Table 1: EDG Rating vgsy%g 3 Load range in MW Maximum load 3.5 30 min

> 3.25 to 1 3.5 200 hr

> 3.0 to 5 3.25 2000 hr

> 2.85 to s 3.0 Continuous 1 2.85 Table 2: EDG Loads to Shed Loads MW EFP-1 0.528 SWP-1A or SWP-1B 0.486 RWP-2A or RWP-2B 0.538 AHF-1A or AHF-!B or AHF-lc 0.061 Table 3: ES 480V Load Ratings loads MW ES MCC 3AB with AHF-lC 0.091 A or B heat tracing 0.041 AHF-54A or AHF-54B 0.013 AHF-17A or AHF-17B 0.050 AHF-18A or AHF-18B 0.050 AHF-19A or AHF-198 0.017 CHP-1A or CHP-1B 0.017 CHHE-1A or CHHE-1B 0.193 SFP-1A or SFP-1B 0.041 O

AP-770 REV 19 PAGE 22 of 49 EDGA

3.0 FOLLOW-UP ACTIONS (CONT'D)

,q V

ACTIONS DETAILS 3.20 lE an outside air compressor is available, THEN notify SP0 to start 1

SAP-lc or SAP-lD.

3.21 lE SAP-1C and SAP-1D are not available, I!iFJ notify SP0 to start diesel air compressor if available.

3.22 1E no outside air See Tables 1 and 2.

compressors are available, 1

AND EGDG capacity for CONCURRENTLY PERFORM Enclosure 0.075 MW additional load 2, Energizing PZR Htrs, IAP-1A, j

exists, OPBC-lG and DPBC-II from 4160V O

THEN energize and start ES A, to place IAP-1A in IAP-1A or IAP-18.

service.

CONCURRENTLY PERFORM Enclosure 3, Energizing PZR Htrs, IAP-1B, DPBC-lH and DPBC-II from 4160V ES B, to place IAP-1B in service.

O AP-770 REV 19 PAGE 23 of 49 EDGA

(- /s)

Applicable Carry-over steps:

3.3 1E at any time, an EDG fails...

3.8 WHfH letdown flow restoration is desired, IHsH Refer to Enclosure 1...

Table 1: EDG Rating

' j *M f~

Load range in MW Maximum load 3.5 30 min

> 3.25 to s 3.5 200 hr

> 3.0 to 1 3.25 2000 hr

> 2.85 to s 3.0 Continuous 1 2.85 Table 2: EDG Loads to Shed Loads MW EFP-1 0.528 SWP-1A or SWP-1B 0.486

()

RWP-2A or RWP-2B 0.538 AHF-1A or AHF-1B or AHF-lC 0.061 Table 3: ES 480V Load Ratings Loads MW ES MCC 3AB with AHF-lC 0.091 A or B heat tracing 0.041 AHF-54A or AHF-54B 0.013 AHF-17A or AHF-17B 0.050 AHF-18A or AHF-18B 0.050 AHF-19A or AHF-19B 0.017 CHP-1A or CHP-1B 0.017 CHHE-l'A or CHHE-1B 0.193 SFP-1A or SFP-1B 0.041 O

AP-770 REV 19 PAGE 24 of 49 EDGA

e 4

3.0 FOLLOW-UP ACTIONS (CONT'D1 ACTIONS DETAILS 3.23 Start CC ventilation.

1 Ensure EGDG capacity for 0.3 MW additional load exists prior to starting.

See Tables 1, 2, and 3.

2 Start normal CC ventilation.

Refer to OP-409, P1 ant Ventilation, Section 4.2.

3 Start CC chiller.

Refer to 0P-409, Plant Ventilation, Section 4,10.

E CC chillers are NOT available, THEN refer to OP-409, Plant Ventilation, Section 4.3 for Appendix R chillers, OR refer to MP-193, Temporary G

Cooling to Control ' Complex.

O 3.24 E DPBA-lC battery charge See Tables 1 and 2.

is desired, AND EGDG capacity for CONCURRENTLY PERFORM Enclosure 0.175 MW additional load 2, Energizing PZR Htrs, IAP-1A,

exists, DPBC-1G and DPBC-II from 4160V THEN energize and charge ES A, to charge DPBA-lc from ES DPBA-1C battery.

4160V A.

CONCURRENTLY PERFORM Enclosure 3, Energizing PZR Htrs, IAP-18, DPBC-lH and DPBC-ll from 4160V ES B, to charge DPBA-lc from ES 4160V B.

l

~.)

AP-770 REV 19 PAGE 25 of 49 EDGA i

~

Applicable Carry-over steps:

s 3.3 IF at any time, an EDG fails...

3.8 WHEN letdown flow restoration is desired, THEN Refer to Enclosure 1...

Table 1: EDG Rating awa ", ? + "

Load range in MW Maximum load 3.5 30 min

> 3.25 to 1 3.5 200 hr

> 3.0 to s 3.25 2000 hr

> 2.85 to 1 3.0 Continuous 1 2.85 Table 2: EDG Loads to Shed Loads MW EFP-1 0.528 SWP-1A or SWP-1B 0.486

,,s

's,)

RWP-2A or RWP-2B 0.538 AHF-1A or AHF-1B or AHF-lC 0.061 Table 3: ES 480V Load Ratings Loads MW ES MCC 3AB with AHF-1C 0.091 A or B heat tracing 0.041 AHF-54A or AHF-54B 0.013 AHF-17A or AHF-17B 0.050 AHF-18A or AHF-188 0.050 AHF-19A or AHF-19B 0.017 CHP-1A or CHP-18 0.017 CHHE-1A or CHHE-1B 0.193 SFP-1A or SFP-1B 0.041 O

AP-770 REV 19 PAGE 26 of 49 EDGA

4

~

3.0 FOLLOW-UP ACTIONS (CONT'D)

,gb ACTIONS DETAILS 3.25 IE heat tracing is See Tables 1, 2, and 3.

desired, AND EGDG capacity for 0.05 Reset heat tracing at:

j MW additional load exists, THEN restore heat tracing.

o HTCP-5, A heat trace pan 91 near ES MCC-3A2, 119 ft AB o HTCP-2, B heat trace panel near elevator, 95 ft AB.

3.26 If offsite power from the Refer to OP-703A, Establishing And 230 KV switchyard cannot Removing 500 KV-Electrical Power be restored in a timely Backfeed.

manner, AND the 500 KV switchyard is available, THEN establish backfeed to the Aux transformer.

Continue on in this procedure.

3.27 IE offsite power will not IE both EDGs are running, be available for THEN notify the SS00 to:

restoration within 2

hours, o Order diesel fuel oil for THEN verify EDG loading is emergency delivery within within fuel oil the next 10 hours1.157407e-4 days <br />0.00278 hours <br />1.653439e-5 weeks <br />3.805e-6 months <br /> consumption limits and that fuel oil reserves are o Reduce and maintain combined adequate.

EDG loads to 1 2.33 MW within the next 10 hours1.157407e-4 days <br />0.00278 hours <br />1.653439e-5 weeks <br />3.805e-6 months <br />.

(D LJ AP-770 REV 19 PAGE 27 of 49 EDGA

Applicable Carry-over steps:

3.3 If at any time, an EDG fails...

3.8 WHEN letdown flow restoration is desired, THEN Refer to...

Table 1: EDG Rating s'

/ kW >

Load range in MW Maximum load 3.5 30 min

> 3.25 to 1 3.5 200 hr

> 3.0 to s 3.25 2000 hr

> 2.85 to 5 3.0 Continuous 1 2.85 Table 2: EDG Loads to Shed Loads MW EFP-1 0.528 l

SWP-1A or SWP-1B 0.486 RWP-2A or RWP-2B 0.538 AHF-1A or AHF-1B or AHF-lc 0.061 Table 3: ES 480V Load Ratings Loads MW ES MCC 3AB with AHF-lC 0.091 A or B heat tracing 0.041 AHF-54A or AHF-548 0.013 AHF-17A or AHF-17B 0.050 AHF-18A or AHF-18B 0.050 AHF-19A or AHF-198 0.017 CHP-1A or CHP-1B 0.017 CHHE-1A or CHHE-1B 0.193 SFP-1A or SFP-1B 0.041 O

i AP-770 REV 19 PAGE 28 of 49 EDGA

i.

3.0 FOLLOW-UP ACTIONS (CONT'D)

ACTIONS DETAILS l

l CAUTION When operating an EDG in parallel with the Aux. Transformer, avoid starting or stopping major loads fed from the transformer in order to i

prevent voltage fluctuations which could cause tripping of the EDG output Bkr and loss oli bus voltage.

• • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • kk****************************

Note Plant should be in a stable condition prior to paralleling to EDG.

3.28 WHEN offsite power is 1

Ensure HPI is bypassed or available to ES 4160V reset.

busses, TlifE sync in offsite power 2

Depress the "4160V ES A or B supply and unload EDG, UV RESET" pushbutton.

3 Notify PP0 to select EDG 4

" SPEED DROOP" to 60 in O

increments of 10.

4 Notify PP0 to select EDG Unit Parallel switch to

" PARALLEL".

5 Select synchroscope for Bkr to be paralleled to "0N".

6 Select "EXC VOLT ADJ SELECT" switch to " CONT RM".

j 7

Match voltages using "EXC VOLT ADJ DIESEL GEN".

8 Adjust " GEN SPEED" to establish synchroscope moving slowly in the " SLOW" direction, counter-clockwise.

9 Close oncoming 8kr at = 1 o' clock.

10 Refer to OP-707, Operation of the ES Emergency Diesel O.

Generators, Section 4.13, for ES restoration.

AP-770 REV 19 PAGE 29 of 49 EDGA i

Applicable Carry-over steps:

3.8 WHEN letdown flow restoration is desired, IBfN Refer to Enclosure 1...

Table 1: EDG Rating

$$M: $l%W4 Load range in MW Maximum load 3.5 30 min

> 3,25 to 5 3.5 200 hr

> 3.0 to s 3.25 2000 hr

> 2.85 to s 3.0 Continuous 1 2.85 Table 2: EDG Loads to Shed Loads MW EFP-1 0.528 SWP-1A or SWP-1B 0.486 RWP-2A or RWP-2B 0.538 AHF-1A or AHF-1B or AHF-lC 0.061 Table 3: ES 480V Load Ratings Loads MW ES MCC 3AB with AHF-1C 0.091 A or B heat tracing 0.041 AHF-54A or AHF-54B 0.013 AHF-17A or AHF-17B 0.050 AHF-18A or AHF-18B 0.050 AHF-19A or AHF-198 0.017 CHP-1A or CHP-1B 0.017 CHHE-1A or CHHE-1B 0.193 SFP-1A or SFP-1B 0.041 OV AP-770 REV 19 PAGE 30 of 49 EDGA

3.0 FOLLOW-UP ACTIONS (CONT'D)

ACTIONS DETAILS CAVTION When operating an EDG in parallel with the Aux Transformer, avoid starting or stopping major loads fed from the transformer in order to

' prevent voltage fluctuations which could cause tripping of the EDG cutput Bkr and loss of bus voltage.

• • • • • • • • • • • • • • • • • • • • • • • • • • • • • wik**********************************************

3.29 WHEN offsite power is Refer to OP-703, Plant Distribution available to Jnit 4160V System, Section 4.1, to energize

buses, unit buses.

IB1H energize unit buses.

3.30 Exit this procedure.

Applicable operating procedures to GO T0 applicable operating be determined by plant conditions procedures.

and SS0D.

DO i

()

AP-770 REV 19 PAGE 31 of 49 EDGA

Table 1: EDG Rating O

sgy;/

.Je Load range in MW 4

Maximum load 3.5 30 min

> 3.25 to 1 3.5 200 hr

> 3.0 to 1 3.25 2000 hr

> 2.85 to s 3.0 Continuous s 2.85 Table 2: EDG Loads to Shed Loads MW EFP-1 0.528 SWP-1A or SWP-1B 0.486 RWP-2A or RWP-28 0.538 AHF-1A or AHF-1B or AHF-lC 0.061 Table 3: ES 480V Load Ratings Loads MW ES MCC 3AB with AHF-lC 0.091 A or B heat tracing 0.041 AHF-54A or AHF-54B 0.013 AHF-17A or AHF-178 0.050 AHF-18A or AHF-18B 0.050 AHF-19A or AHF-198 0.017 CHP-1A or CHP-1B 0.017 CHHE-1A or CHHE-1B 0.193 SFP-1A or SFP-1B 0.041

()

AP-770 REV 19 PAGE 32 of 49 EDGA

ENCLOSURE 1

1. q g

RC Letdown Recovery.

ACTIONS DETAILS 1

Ensure letdown is isolated.

Close MUV-49 "LETDN CLR IS0".

Close MUV-50 "BLK ORIFICE 150".

Close MVV-51 " LETDOWN FLOW".

2 Ensure SW and MU valves open o MUHE-1A:

for desired letdown coolers.

Open SWV-47 Open SWV-50 Open MUV-38 Open MUV-40.

o MUHE-18:

O V

Open SWV-48 Open SWV-49 Open MVV-39 Open MUV-41.

o MUHE-lC:

Open SWV-47 Open SWV-50 Open MVV-498 Open MUV-505.

Ensure 1 Pre-filter in service 3

Establish a flow path for

__ or bypassed.

letdown.

Ensure MU demins are bypassed.

Ensure 1 Post-filter in service or bypassed.

AP-770 REV 19 PAGE 33 of 49 EDGA

e Table 1: EDG Rating g-g 6

(,)

,aum4 Load range in MW Maximum load 3.5 30 min

> 3.25 to 1 3.5 200 hr

> 3.0 to s 3.25 2000 hr

> 2.85 to 1 3.0 Continuous 1 2.85 Table 2: EDG Loads to Shed Loads MW EFP-1 0.528 SWP-1A or SWP-1B 0.486 RWP-2A or RWP-2B 0.538 AHF-1A or AHF-1B or AHF-lc 0.061 Table 3: ES 480V Load Ratings Loads MW ES MCC 3AB with AHF-lC 0.091 A or B heat tracing 0.041 AHF-54A or AHF-548 0.013 AHF-17A or AHF-178 0.050 AHF-18A or AHF-188 0,050 AHF-19A or AHF-198 0.017 CHP-1A or CHP-1B 0.017 CHHE-1A or CHHE-1B 0.193 SFP-1A or SFP-1B 0.041 AP-770 REV 19 PAGE 34 of 49 EDGA

ENCLOSURE 1 (CONT'D) s

(

RC Letdown Recovery.

_ ACTIONS DETAILS 4

Start letdown flow.

1 Open MUV-49.

2 Throttle open MUV-51 to establish 2 to 3 gpm each minute for 20 minutes.

3 Allow letdown TEMP to stabilize for 210 minutes.

5 Open MUV-50.

6 Throttle MUV-51 to establish desired letdown flow.

O i

O AP-770 REV 19 PAGE 35 of 49 EDGA

Table 1: EDG Rating

~

g* + ~. JC; Load range in MW Maximum load 3.5 30 min

> 3.25 to 1 3.5 200 hr

> 3.0 to 1 3.25 2000 hr

> 2.85 to 1 3.0 Continuous 1 2.85 Table 2: EDG Loads to Shed Loads MW EFP-1 0.528 SWP-1A or SWP-1B 0.486 RWP-2A or RWP-2B 0.538 AHF-1A or AHF-1B or AHF-lC 0.061 Table 3: ES 480V Load Ratings Loads MW ES MCC 3AB with AHF-1C 0.091 A or B heat tracing 0.041 AHF-54A or AHF-54B 0.013 AHF-17A or AHF-17B 0.050 AHF-18A or AHF-188 0.050 AHF-19A or AHF-198 0.u17 CHP-1A or CHP-1B 0.017 CHHE-1A or ChHE-1B 0.193 SFP-1A or SFP-1B 0.041

-tS V

AP-770 REV 19 PAGE 36 of 49 EDGA

Energizing PZR Htrs, IAP-1A, DPBC-lG and DPBC-II from 4160V ES A ACTIONS DETAILS Note Action steps 1 through 5 establish power feeds for this Enclosure and only need to be performed once.

1 Ensure 480V Rx Aux Bus 3A Ensure open:

feeder Bkrs are open.

o Bkr 3305 o Bkr 3395.

2 Notify SP0 to ensure open All Bkrs open on:

all Bkrs on 480V Rx Aux Bus 3A and PZR Htr MCC 3A.

o 480V Rx Aux Bus 3A o PZR Htr MCC 3A.

O 3 __ Place IAP-1A control switch in " PULL TO LOCK".

4 Energize 480V Rx Aux Bus 3A.

Close the following Bkrs:

o Bkr 3321 o Bkr 3395.

5 _ _. Energize PZR Htr MCC 3A.

Notify SP0 to close Bkr 3355, Unit IC, on Rx Aux Bus 3A.

O AP-770 REV 19 PAGE 37 of 49 EDGA

Table 1: EDG Ratina O\\

F#4 p j@[

Load range in MW Maximum load 3.5 30 min

> 3.25 to 1 3.5 200 hr

> 3.0 to s 3.25 2000 hr

> 2.85 to s 3.0 Continuous s 2.85 Table 2: EDG Loads to Shed Loads MW EFP-1 0.528 SWP-1A or SWP-1B 0.486 RWP-2A or RWP-2B 0.538 AHF-1A or AHF-1B or AHF-lC 0.061 Table 3: ES 480V Load Ratings

()

Loads MW ES MCC 3AB with AHF-lc 0.091 A or B heat tracing 0.041 AHF-54A or AHF-54B 0.013 AHF-17A or AHF-178 0.050 AHF-18A or AHF-18B 0.050 AHF-19A or AHF-19B 0.017 CHP-1A or CHP-1B 0.017 CHHE-1A or CHHE-1B 0.193 SFP-1A or SFP-1B 0.041 n

v AP-770 REV 19 PAGE 38 of 49 EDGA

. (CONT'0)

Energizing PZR Htrs, IAP-1A, DPBC-lG and DPBC-ll from 4160V ES A ACTIONS DETAILS 6

If PZR Htrs are required, 1

Ensure EGDG-1A capacity is IEES energize PZR control available for 0.275 MW.

power and energize 2 groups of Htrs.

See Tables 1 and 2.

2 Notify SP0 to close the foJ10 wing Bkrs at PZR Htr MCC 3A:

o Unit lA " PRESS HTR CONTROL TRANSFORMER A-1" o Unit 2A " PRESS HTR CONTROL TRANSFORMER A-2".

3. Notify SP0 to close 2 of the following Bkrs at PZR Htr MCC 3A:

Unit 4A " PRESS. HEATERS S.C.R. GROUP 1"

(}

Unit 1C " PRESS. HEATERS GROUP 7" Unit 2C " PRESS. HEATERS GROUP 8" Unit 3C " PRESS. HEATERS GROUP 9".

7 If IAP-1A is required, 1

Ensure CGDG-1A capacity is THEN establish IAP-1A available for 0.075 MW.

cooling from SW system and start IAP-1A.

See Tables 1 and 2.

2 Notify SP0 to line up SW cooling for IAP-1A.

Refer to 0P-408, Nuclear Services Cooling System, Section 4.6.

3 Start IAP-1A.

f--(s AP-770 REV 19 PAGE 39 of 49 EDGA

Table 1: EDG Rating Os g/,pg,,

Load range in MW Maximum load 3.5 30 min

> 3.25 to s 3.5 200 hr

> 3.0 to s 3.25 2000 hr

> 2.85 to 1 3.0 Continuous s 2.85 Table 2: EDG Loads to Shed Loads MW EFP-1 0 528 SWP-1A or SWP-1B 0.486 RWP-2A or RWP-2B 0.538 AHF-1A or AHF-1B or AHF-1C 0.061 Table 3: ES 480V Load Ratings (u)%

Loads MW ES MCC 3AB wini AHF-lC 0.091 A or B heat tracing 0.041 AHF-54A or AHF-54B 0.013 AHF-17A or AHF-17B 0.050 AHF-18A or AHF-18B 0.050 AHF-19A or AHF-198 0.017 1

CHP-1A or CHP-1B 0.017 i

CHHE-1A or CHHE-1B 0.193 SFP-1A or SFP-1B 0.041 i

O l

AP-770 REV 19 PAGE 40 of 49 EDGA

)

]

. (CONT'D) p Energizing PZR Htrs, IAP-1A, DPBC-1G and DPBC-ll from 4160V ES A ACTIONS DETAILS 8

IE DPBA-1C recharge is 1

Ensure EGDG-1A capacity is

required, available for 0.175 MW.

EM place DPBA-lC on charge.

See Tables 1 and 2.

Notify SP0 to open DPDP-1C 2

switch 13.

~

3 Notify SP0 to close the following switches:

o DPDP-1C switch 4 o DPDP-lc switch 14.

4 Notify SP0 to select DPXS-1C to the " POWER FROM PZR HTR MCC 3A" "0N" position.

5 Notify SP0 to close PZR Htr MCC 3A Bkrs:

o Unit 3A " BATTERY CHGR DPBC-lG" o Unit 3B "BATT CHGR DPBC-11 VIA DPXS-1C".

o AP-770 REV 19 PAGE 41 of 49 EDGA

e

=

Table 1: EDG Rating d

gg; V4'sg Load range in MW Maximum load 3.5 30 min

> 3.25 to 1 3.5 200 hr

> 3.0 to 1 3.25 2000 hr

> 2.85 to < 3.0 Continuous 1 2.85 Table 2: EDG Loads to Shed Loads MW EFP-1 0.528 SWP-1A or SWP-1B 0.486 RWP-2A or RWP-28 0.538 AHF-1A or AHF-1B or AHF-IC 0.061

)

l Table 3: ES 480V Load Ratings fh loads MW s,J ES MCC 3AB with AHF-lc 0.091 A or B heat tracing 0.041 j

AHF-54A or AHF-54B 0.013 AHF-17A or AHF-17B 0.050 AHF-18A or AHF-18B 0.050 AHF-19A or AHF-198 0.017 CHP-1A or CHP-1B 0.017 CHHE-1A or CHHE-1B 0.193' SFP-1A or SFP-lb 0.041 l

O AP-770 REV 19 PAGE 42 of 49 EDGA

. q, e

f-~)

Energizing PZR Htrs, IAP-18, DPBC-lH and DPBC-II from 4160V ES B ACTIONS DETAILS Note Action steps 1 through 6 establish power feeds for this Enclosure and only need to be performed once.

1

- Ensure the listed 480V Ensure open:

feeder and tie Bkrs are open.

Bkr 3392 Plant Aux tie Bkr 3312 Plant Aux feeder Bkr 3306 Rx Aux 3B feeder Bkr 3396 Rx Aux 3B tie Bkr 3393 Turb Aux 3A tie Bkr 3394 Turb Aux 3B tie Bkr 3399 Heating Aux tie.

2 Notify SP0 to ensure open All Bkrs open on:

all Bkrs on 480V Plant Aux

)

Bus, 4POV Rx Aux Bus 3B, and 480V Plant Aux Bus i

PZR Htr MCC 3B.

480V Rx Aux Bus 3B PZR Htr MCC 38.

3 Place IAP-1B control s,sitch in " PULL TO LOCK".

l O

AP-770 REV 19 PAGE 43 of 49 EDGA

Table 1: EDG Rating

(

,M @@m' Load range in MW Maximum load 3.5 30 min

> 3.25 to s 3.5 200 hr

> 3.0 to s 3.25 2000 hr

> 2.85 to s 3.0 Continuous 1 2.85 Table 2: EDG Loads to Shed Loads MW EFP-1 0.528 SWP-1A or SWP-18 0.486 RWP-2A or RWP-2B 0.538 AHF-1A or AHF-1B or AHF-lc 0.061 Table 3: ES 480V Load Ratings Loads MW j

O ES MCC 3AB with AHF-lc 0.091 i

l A or B heat tracing 0.041 AHF-54A or AHF-54B 0.013 AHF-17A or AHF-17B 0.050 AHF-18A or AHF-188 0.050 AHF-19A or AHF-198 0.017 CHP-1A or CHP-18 0.017 CHHE-1A or CHHE-1B 0.193 SFP-1A or SFP-1B 0.041 i

O AP-770 REV 19 PAGE 44 of 49 EDGA 1

. (CONT'D)

Energizing PZR Htrs, IAP-1B, DPBC-lH and DPBC-11 from 4160V ES B ACTIONS DETAILS 4

Energize 480V Plant Aux Bus.

Close the following Bkrs:

o Bkr 3222 o Bkr 3312.

r 5

Energize 480V Rx Aux Bus 38.

Close the following Bkrs:

o Bkr 3392 o Bkr 3396.

6 Energize PZR Htr MCC 3B.

Notify SPO to close Bkr 3356, Unit IC, on Rx Aux Bus 38.

O O

AP-770 REV 19 PAGE 45 of 49 EDGA j

Table 1: EDG Rating

$pAj;)$$@4 Load range in MW Maximum load 3.5 30 min

> 3.25 to 1 3.5 l

200 hr

> 3.0 to 1 3.25 2000 hr

> 2.85 to 1 3.0 Continuous s 2.85 Table 2: EDG Loads to Shed Loads MW EFP-1 0.528 SWP-1A or SWP-1B 0.486 RWP-2A or RWP-2B 0.538 AHF-1A or AHF-1B or AHF-lc 0.061 Table 3: ES 480V Load Ratings Loads MW ES MCC 3AB with AHF-lC 0.091 A or B heat tracing 0.041 AHF-54A or AHF-54B 0.013 AHF-17A or AHF-17B 0.050 AHF-18A or AHF-188 0.050 AHF-19A or AHF-198 0.017 CHP-1A or CHP-1B 0.017 CHHE-1A or CHHE-1B 0.193 SFP-1A or SFP-1B 0.041

' O AP-770 REV 19 PAGE 46 of 49 EDGA

i

. (CONT'D) f

(

Energizing PZR Htrs, IAP-18, DPBC-lH and DPBC-ll from 4160V ES B ACTIONS DETAILS 7

If PZR Htrs are required, 1

Ensure EG0G-18 capacity is It!fti energize PZR control available for 0.275 MW.

power and energize 2 groups of Htrs.

See Tables 1 and 2.

2 Notify SP0 to close the following Bkrs at PZR Htr MCC 3B:

o Unit lA " PRESS HTR CONTROL TRANSFORMER B-1" o Unit 1B " PRESS HTR CONTROL TRANSFORMER B-2".

3. Notify SP0 to close 2 of the following Bkrs at PZR Htr MCC 3B:

Unit 2A " PRESS HTRS SCR GROUP 2" Unit 3A " PRESS HTRS SCR GROUP 5" Unit 4A " PRESS HTRS SCR GROUP 6" i

Unit 10 " PRESS HTRS GROUP 10" Unit 2C " PRESS HTRS GROUP 11" Unit 3C " PRESS HTRS GROUP 12" l

Unit 4C " PRESS HTRS GROUP 13".

AP-770 REV 19 PAGE 47 of 49 EDGA l

L

1 i

f-,g-Table 1: EDG Rating V

c "",, p p/ sh?

Load range in MW Maximum load 3.5 30 min

> 3.25 to s 3.5 i

200 hr

> 3.0 to 1 3.25 2000 hr

> 2.85 to s 3.0 Continuous s 2.85 Table 2: EDG Loads to Shed Loads MW EFP-1 0.528 SWP-1A or SWP-1B 0.486 RWP-2A or RWP-2B 0.538 AHF-1A or AHF-1B or AHF-1C 0.061 Table 3: ES 480V Load Ratings Loads MW

[}

ES MCC 3AB with AHF-lc 0.091 A or B heat tracing 0.041 AHF-54A or AHF-548 0.013 AHF-17A or AHF-17B 0.050 AHF-18A or AHF-188 0.050 AHF-19A or AHF-198 0.017 CHP-1A or CHP-1B 0.017 CHHE-1A or CHHE-1B 0.193 SFP-1A or SFP-1B 0.041 AP-770 REV 19 PAGE 48 of 49 EDGA

~.

\\

. (CONT'D) t Energizing PZR Htrs, IAP-1B, DPBC-lH and DPBC-II from 4160V ES B w/

ACTIONS DETAILS 8

E IAP-1B is required, 1

Ensure EGDG-1B capacity is lilB establish IAP-18 available for 0.075 MW.

cooling from SW system and start IAP-18.

See Tables 1 and 2.

2 Notify SP0 to line up SW cooling for IAP-18.

Refer to OP-408, Nuclear Services Cooling System, Section 4.6.

3 Start IAP-18.

9 E DP3A-1C recharge is 1

Ensure EGDG-1B capacity is requi rtiti, available for 0.160 MW.

THEN place DPBA-lC on charge.

See Tables 1 and 2.

O 2

Notify SPO to open DPDP-lc vg switch 14.

3 Notify SP0 to close the following switches:

o DPDP-lC switch 5 o DPDP-lC switch 13.

4 Notify SPO to select DPXS-1C to the " POWER FROM PZR HTR MCC 3B" "0N" position.

5 Notify SP0 to close PZR Htr MCC 3B Bkrs 1

o Unit 3BL " BATTERY CHGR DPBC-lH" o Unit 3BR "BATT CHGR DPBC-II VIA DPXS-lC".

AP-770 REV 19 PAGE 49 of 49 (LAST PAGE)

EDGA

h-RCLD REV' 5

.AP-1080 CJ REFUELING CANAL LEVEL DECREASE 1.0 ENTRY CONDITIONS J.E unexpected decrease in refueling canal water level occurs, THEN use this procedure.

2.0 IMMEDIATE ACTIONS U9tg There are no immediate actions in this procedure.

. _.r~

rematra. u;n=mrmrm7l}

Document Section r

E M F 0 R i.i A T I O M O N L

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.a..

ThisProcedureAddresseySafetyRelatedComponents Date N3/[6 /

Approved by MNP0 4

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1 AP-1080 PAGE 1 of 15 RCLD

N BLANK PAGE i

l i

i i

AP-1080 REV 5 PAGE 2 of 15 RCLD i

~

]

3.0 FOLLOW-UP ACTIONS ACTIONS DETAILS 3.1 Notify personnel of plant Plant operators conditions as required.

__ S0TA Health Physics to survey for high radiation levels SS00 to evaluate plant conditions for entry into the emergency plan.

3.2 E irradiated fuel is suspended from bridge, THEN notify bridge operator to place fuel in Rx vessel.

E fuel can NOT be placed in the Rx vessel, THEN place fuel in upender (w)

(

and lower.

l 3.3 E irradiated components are suspended from crane, AND in the canal, THEN notify crane operator to place component in deep end.

E component can NOT be placed in the deep end, THEN suspend component inside Rx vessel above fuel.

3.4 E irradiated fuel is suspended from spent fuel handling bridge, THEN notify bridge operator to place fuel in any available spent fuel rack location.

OO AP-1080 REV 5 PAGE 3 of 15 RCLD

_ _.. _.~.

O i

l BLANK PAGE O

AP-1080 REV 5 PAGE 4 of 15 RCLD

)

3.0 FOLLOW-UP ACTIONS (CONT'D)

A L

ACTIONS DETAILS 3.5 LF it becomes apparent that the water level is decreasing faster than the fuel can be

lowered, THEN leave the bridge, AND evacuate the area immediately.

H_ote IF fuel transfer tubes are open, TITEN RB PRESS can affect fuel transfer canal level.

3.6 Attempt to determine and Visually inspect if possible:

'orrect source of leak.

o RB sump area o Seal plate.

Observe levels in:

AB sump

(

_ RB sump Refueling canal level

_ BWST level SF pool levels RCS level trends SW surge tank level trends.

Ensure closed Fuel Transfer Canal deep end drains to the RB sump:

SFV-83 SFV-84 l 3.7 LF leak is in the RB, 1 - Depress "RB EVACUATION" DR leak cannot be stopped, pushbutton.

TREN evacuate the RB.

2 Notify personnel over PA.

3 Depress "RB EVACUATION" pushbutton.

4 Repeat PA announcement.

AP-1080 REV 5 PAGE 5 of 15 RCLD

O BLANK PAGE i

l O

AP-1080 REV 5 PAGE 6 of 15 RCLD

3.0 FOLLOW-UP ACTIONS (CONT'D_1 ACTIONS DETAILS 3.8 IF the leak is in the RB, o

WDP-2A AND cannot be isolated, TITEN place the RB sump".

o WDP-2B pumps in " PULL TO LOCK 3.9 IF RCS level is not known, Signs of cavitation are:

TREN observe DHPs for cavitation.

o Erratic DHP amperage o

Erratic DHP flow o

High DHP vibration.

l 3.10 IF DHP cavitation exists, TREN stop the DHP.

ANT CONCURRENTLY PERFORM UP-ll Removal}LossofDecayHeat beginning with Step 3.

3.11 Stop the Spent Fuel Pumps.

Stop the following pumps:

o SFP-1A o

SFP-1B o

SFP-2.

3.12 Stop the RB purge.

Close the following valves:

AHV-1A

_ AHV-1B AHV-lc

_ AHV-lD.

Stop the following fans:

AHF-6A AHF-6B AHF-7A l

_ AHF-78.

AP-1080 REV 5 PAGE 7 of 15 RCLD

O I

i BLANK PAGE O

O AP-1080 REV 5 PAGE 8 of 15 RCLD

i l

3.0 FOLLOW-UP ACTIONS (CONT'D) h (O

ACTIONS DETAILS Note Fuel transfer tube valves may not be able to be fully closed due to carriage cables, j 3.13 Notify AB operator to Close:

close fuel transfer tube

~

valves as far as possible.

o SFV-119 o

SFV-120.

3.14 Evacuate AB if required.

1.

Determine evacuation requirements based on the following:

Health Physics survey Local area radiation monitors AB atmospheric radiation monitors.

2.

IE evacuation is required, THEN:

Depress "AB EVACUATION" pushbutton Notify plant personnel over PA.

Depress "AB EVACUATION" pushbutton Repeat PA Announcement.

AP-1080 REV 5 PAGE 9 of 15 RCLD

l OV BLANK PAGE O

AP-1080 REV 5 PAGE 10 of 15 RCLD

=

e 3.0 FOLLOW-UP ACTIONS (CONT'D) t')

~

ACTIONS DETAILS j

l 3.15 Establish makeup to fuel o

BWST refer to OP-406 transfer canal from available l

barated water sources.

o RCBT refer to OP-402 Note Leakage from SF suction and discharge piping will stop when level decreases to approximately four feet below normal level.

j 3.16 E SF is determined to be o

H leakage is isolable, the source of the leakage, THEN isolate the leak.

THEN attempt to isolate the

leak, o

E leakage is from piping and is unisolable, l

THEN consider pumping the volume above affected piping to the BWST if space exists.

Refer to OP-406.

OU g%.]

AP-1080 REV 5 PAGE 11 of 15 RCLD

O i

BLANK PAGE i

l 1

O AP-1080 REV 5 PAGE 12 of 15 RCLD

=

-4 3.0 FOLLOW-UP ACTIONS (CONT'D)

O ACTIONS DETAILS 3.17 Check for SF Pool liner Check SF pool liner telltale leakage and Transfer Tube drains in MVP cubicles and leakage.

Transfer Tube telltale drains under stairs by SFP air handlers.

E any drains are flowing, IliFJi note the valve number,

.l AND close all telltale drain valves.

~

CAUTION If level is not restored to allow cooling, the SP pool may reach the boiling poiM. in as little as 8 hours9.259259e-5 days <br />0.00222 hours <br />1.322751e-5 weeks <br />3.044e-6 months <br /> and require up to 70 gpm water flow to the pool to maintair. level.

3.18

.LF SF was determined to be E the leak is unisolable, the source of the leakage, It[E!! maintain level just below f-THEN maintain SF water the affected SF piping elevation level.

until repairs are complete.

Consider using the following sources as make up to the SF pool:

o BWST refer to 0P-406 o

Batch add from BASTS refer to OP-403B o

Demin. water.

o Fire service hose.

O AP-1080 REV 5 PAGE 13 of 15 RCLD

j N

l 1

l 1

1 BLANK PAGE f

\\

AP-1080 REV 5 PAGE 14 of 15 RCLD

1

• 1

~

3.0 FOLLOW-UP ACTIONS (CONT'D) pd ACTIONS DETAILS 3.19 MM the leak has been isolated or repaired, Ilim restore SF pool level per OP-406.

l 3.20 lE leak can EI be Base course of action on:

isol ated, AND level continues to o

Availability of incores

lower, ILLW determine proper o

Location of leak course of action.

o Spent fuel location o

Availability of equipment.

Possible actions:

o Maintain DH removal

/~~N.

Cl o

Establish LPI cooling o

Establish LPI cooling from RB sump o

Establish HPI cooling o

Allow level to lower.

i i

l l

AP-1080 REV 5 PAGE 15 of 15 (LAST PAGE)

RCLD

DOUUMENT TRANSMITTAL 15141 FOR DOCUMENT NOTIFICATION AND/OR TRANSMITTAL TO: NRC (DC bESK)

MAC: NIA DESTINATION:

DESCRIPTION:

DATE:

Tue May 24 08:12:59 1994 CPY COPY TOTALS DOCUMENT REV COMMENTS INFO CNTL MSTR EM0307 21 12 1

0 0

f L

IN8TRUCTIONS TO THE ADDRESSEE:

If YOU ARE A HOLDER OF A HARD COPY.PLEASE VERIFY THE DOCUMENT (S) RECEIVED AGREE 8 WifH THE ABOVE DESCRIPil0E DE SURE TO DESTROV DOCUMENT (8) OR PORTIONS Of DOCUMENT ($180PERSEDED BY THE ABOVE.

THE SIGNATURE INDICATES THAT YOU HAVE READ ANO UNDERSTAND THESE IN51RUCT10NS AND THE CHANGE 8 TO THE 00CUMEN's.

CETURN 81CNED AND DATED TRANSMITTAL 10 DOCUMENT CONTROE WifMIN 10 OAYS AT MAIL CODE:

_ X_ hk28

~ SAIG NA1C Z Fledde Power Corporetles Desamest Centret -

Crystal River Energy Comples 15700 W. Power Lies St.

Crystal Nver. FL 34428 8708 SIGNATURE 0f ADLREltEE DATE CBEPENDENT VERIFICAfl0N (Cestrel Reem Dessneste 0 sly)

DATE 9406070198 940524

[l PDR ADOCK 05000302 y

PDR

Rev. 21 Effective Date S # # 1M

~

u i

c!

1

.1

>JNL i

EMERGENCY PLAN IMPLEMENTING PROCEDURE EM-307 FLORIDA POWER CORPORATION CRYSTAL RIVER UNIT 3 i

o SAMPLING AND ANALYSIS OF THE REACTOR COOLANT SYSTEM,

'(

THE REACTOR BUILDING SUMP, AND THE MISCELLANE0US WASTE STORAGE TANK UNDER ACCIDENT CONDITIONS THIS PROCEDURE ADDRESSES NON-SAFETY RELATED COMPONENTS l

1 APPROVED BY:

Interpretation Contact n!c pant L%Nb

'l DATE:

MIN INTERPRETATION CONTACT:

Nuclear Chemistry Manager

TABLE OF CONTENTS

/O V

SECTION PAGE J.0 PURPOSE............................

1

2.0 REFERENCES

1 2.1 IMPLEMENTING REFERENCES...............

1 2.2 DEVELOPMENTAL REFERENCES 1

3.0 PERSONNEL INDOCTRINATION 2

3.1 DESCRIPTION

2 3.2 DEFINITIONS.

3 3.3 RESPONSIBILITIES 3

3.4 LIMITS & PRECAUTIONS 3

3.5 PREREQUISITES...

4 4.0 INSTRUCTIONS 4

4.1 SAMPLING THE RCS WHILE STILL AT PRESSURE FOR BORON AND/0R GAMMA ISOTOPIC ANALYSES 4

4.2 SAMPLING THE RCS WHILE STILL AT PRESSURE FOR DISSOLVED HYDROGEN. oH. AND/0R CHLORIDE ANALYSES 8

4.3 SAMPLING THE RCS WHEN ON DFCAY HEAT OR LOW PRESSURE INJECTION FOR BORON AND/0R GAMMA IS0 TOPIC ANALYSES..................

12 O.s 4.4 SAMPLING THE REACTOR BUILDING SUMP FOR BORON AND/0R GAMMA ISOTOPIC ANALYSES 14 4.5 SAMPLING THE MISC. WASTE STORAGE TANK FOR BORON AND/0R GAMMA ISOTOPIC ANALYSIS 17 4.6 GAMMA ISOTOPIC ANALYSIS...............

20 4.7 CHLORIDE ANALYSIS..................

21 4.8 GRAB SAMPLING.

28 4.9 DEMINERALIZED WATER FLUSH AND SYSTEM SHUTDOWN AFTER SAMPLING RCS LETDOWN AT PRESSURE FOR GAMMA IS0 TOPIC. BORON. DISSOLVED HYDR 0 GEN. DH. 10N CHROMAT0 GRAPHIC ANALYSES. OR ACQUIRING A GRAB SAMPLE 31 4.10 DEMINERALIZED WATER FLUSH AND SYSTEM SHUTDOWN AFTER SAMPLING DECAY HEAT FOR BORON OR GAMMA ISOTOPIC ANALYSES..................

36 4.11 DEMIN WATER FLUSH AND SYSTEM SHUTDOWN AFTER SAMPLING MWST FOR BORON AND/0R GAMMA IS0 TOPIC ANALYSFS 39 4.12 DEMIN WATER FLUSH AND SYSTEM SHUTDOWN AFTER

)

SAMPLING THE RB SUMP FOR BORON AND/0R GAMMA IS0 TOPIC ANALYSES.

42 4.13 NOTIFICATION.S...

45

]

EM-307 Rev. 21 Page i

I 1

TABLE OF CONTENTS

(~

SECTION PAGE ENCLOSURES 1

Alternate Containment Isolation Sample Valves.....

...46 2

Reagents for Ion Chromatograph 47 3~

P.A.S.S. Data Sheet......................

48 4

P.A.S.S. and Analysis of RC, Emergency Coordinator

~~

Notification 49 5

Recommended Sample Flush Times 50 6

Priming Analytical Pump of the DIONEX 2010 I.C 51 7

Main Power Supplies for Pass System Components 52 8

T. S. C. Dat a Sheet.......................

54 9

SP4400 Integrator PASS Calibration File Example........

55 10 4270 Integrator PASS Calibration File Example.........

56 O

O EM-307 Rev. 21 Page ii

1 1.0 PURPOSE

,e 1.1 The purpose of this procedure is to describe the actions taken to sample and analyze the Reactor Coolant System (RCS) under accident conditions for radioisotopes up to 10 Ci/cc, dissolved hydrogen concentrations from 0 to 2000 cc/Kg, boron concentrations from 0 to 6000 ppm, chloride concentrations from 0.020 to 20.00 ppm (greater j

concentrations can be measured using appropriate calibration j

standards), and pH in the range of 1.0 to 14.0.

2.0 REFERENCES

i 2.1 IMPLEMENTING REFERENCES 2.1.1 EM-209, Re-Entry Procedure 2.1.2 Drawings FD-302-700.

2.1.3 CH-194, Chemical Analysis with the Dionex lon Chromatograph 2.1.4 Maintenance And Calibration Of The Orbisphere Post Accident Sampling System Hydrogen Analyzer, Section 1, Countroom Instrument Logbook.

(q 2.1.5 Maintenance And Calibration Of The Leeds And Northrup High Purity j

Water pH Analyzer, Section 2, Countroom Instrument Logbook.

2.1.6 Maintenance And Calibration Of The ABB/CE Boronometer, Section 3, Countroom Instrument Logbook.

2.2 DEVELOPMENTAL REFERENCES 2.2.1 NUREG 0737 2.2.2 PASS Users Manual, Crystal River Installation 2.2.3 FD-302-700, Post Accident Sampling System Flow Diagram 2.2.4 Pass Manuals, Volume One through Nine 2.2.5 APEX Technologies Post Accident Sample System Modules Manual, FPC controlled Manual #2034 2.2.6 6059-S-002, APEX Technologies PASS Process Flow Diagram O

O EM-307 Rev. 21 Page 1

3.0 PERSONNEL INDOCTRINATION O

3.1 DESCRIPTION

3.1.1 The Post Accident Sampling System is an on-line system designed to sample and analyze reactor coolant for radioisotopes, chloride concentration, dissolved hydrogen, boron, and pH during an accident.

It also allows for boron and radioisotopic analysis on the Decay Heat system, MWST, and RB Sump under accident situations.

3.1.2 The major components of the PASS include:

o The PASS Analyzer Panels with solenoid valve controls and position indicators, pressure indicators, and flow indicators.

o Modules including Liquid Calibration Module, Hydrogen Calibration Module, CAV-484 Module, Boron Analyzer Module, Dissolved Hydrogen and pH Module, Drain Tank Module, and The Waste Pumping Module. These modules contain tubing and valves used to direct samples and calibration solutions to the instrumentation used to perform the various analyses.

o The Hydrogen Analyzer, consists of two sensors capable of measuring dissolved hydrogen concentrations from 0 to 2000 cc/kg. The low range hydrogen sensor measures hydrogen

(

concentrations in the 0 to 200 cc/kg.

The high range hydrogen sensor measures hydrogen concentrations in the 200 to 2000 cc/kg range. These sensors are housed in The Dissolved Hydrogen and pH Module. Under normal and accident conditions, flow will be routed through both hydrogen sensors.

The Orbisphere computer automatically selects the proper sensor input based on sample fluid hydrogen levels.

o The high purity water pH sensor / analyzer is capable of measuring pH in the ranges from.01 to 14.0.

The pt sensor is located in The Dissolved Hydrogen and pH Module.

o Thr High Radiation Boronometer used for boron analysis, capable of detecting baron concentrations from 0 to 6000 ppm.

o Two remotely operated Sentry VREL pressure reducing elements, CAV-484 and CAV-631 provide pressure reduction and flow control of liquid samples through the Boronometer, Hydrogen sensors, and pH sensors respectively. Depending on system conditions, these valves can be used alone for flow control or in combination with a downstream pressure regulating valve and flow control valve, o

The Ion Chromatograph used for chloride analysis, is capable of measuring 0.005 ppm to 20.0 ppm. Greater concentrations can be measured using appropriate calibration standards.

GV EM-307 Rev. 21 Page 2

I e

o The VAX Workstation or MicroVax 3100 Computer and associated

()

terminal.

o The Automatic Isotopic Measurement System (AIMS) cabinet containing an Intrinsic High Purity Germanium Planar Detector, capable of measuring gross activity in liquid sample streams up to 10 Ci/cc.

All of these components are located in the Radiochemistry Count i

Room, the Primary Laboratory, the PASS Sampling Room, in the general area of the PASS Sampling Room in the northwest corner of the 95' elevation of the Aux. Building, or the CAV-2 valve alley located in the Intermediate Building.

3.2 DEFINITIONS 3.2.1 RANGE - Radioiodine And Noble Gas Effluents 3.2.2 PASS - Post Accident Sample System 3.2.3 AIMS - Automated Isotopic Measurement System 3.3 RESPONSIBILITIES The Nuclear Chemistry Manager is responsible for the content of this procedure, shall act as Interpretation Contact for any questions e

regarding intent, and has final authority regarding the procedure.

4 3.4 LIMITS & PRECAUTIONS 1

3.4.1 Performance of all or part of this procedure will be done on the instruction and authority of the Emergency Coordinator.

3.4.2 Entry into controlled access areas will be under the direction of the Radiation Monitoring Team as outlined in EM-209, Re-Entry Procedure.

3.4.3 For the on-line analysis essentially all operations may be conducted from the Counting Room, the Primary Laboratory and the Main Control j

Room, however, monitoring for radiological concerns should be j

provided.

3.4.4 An additional requirement of NUREG-0737 is the capability to remove grab samples of the reactor coolant should the in-line system fail or confirmations are requested.

(

I EM-307 Rev. 21 Page 3

e 3.4.5 During some post accident sampling, extremely high radiation dose

(,,T levels could be experienced.

The ability to perform all of this

\\- /

procedure will require pre-planning to stay within exposure limits and maintain doses as low as reasonably achievable.

3.4.6 As long as this procedure is being used, all samples are returned to the containment sump.

3.4.7 The VAX work station computer is the recommended system for performing Post Accident Sampling and Analysis.

It is the only system capable of providing Live Spectral Acquisition; all other systems will only display " snap shots" of Spectral Acquisition.

3.5 PREREQUISITES None 4.0 INSTRUCTIONS o

Ensure all breakers for required containment isolation valves are energized prior to leaving Sample Team Staging Area. lists these breakers, the valves they provide power

,s to, and their locations.

'~')

(

o Complete Enclosure 4 and forwarded to the Emergency Coordinator prior to leaving the Sample Team Staging Area.

o Utilize Enclosure 1 to determine alternate sample points if flush times are going to be a limiting factor due to staytime.

o See Enclosure 5 for recommended sample flush times.

4.1 SAMPLING THE RCS WHILE STILL AT PRESSURE FOR BORON AND/OR GAMMA ISOTOPIC ANALYSES NOTE: Dissolved hydrogen, pH and ion chromatographic analyses can be performed simultaneously with RCS gamma isotopic and boron analyses per section 4.2.

4.1.1 Place the following valves in the indicated position:

EM 307 Rev. 21 Page 4

NOTE: These valves are operated from the PASS Analyzer Panel in the

(

count room.

VALVE POSITION 4.1.1.1 CAV-484 Closed 4.1.1.2 CAV-519 Open

~

4.1.1.3 CAV-437 Open 4.1.1.4

.CAV-439 Closed

~

4.1.1.5 CAV-448 Open 4.1.1.6 CAV-447 Open j

4.1.1.7 CAV-623 Sample 4.1.1.8 CAV-624 Open 4.1.1.9 CAV-625 Sample 4.1.2 Place the following valves in the indicated position:

NOTE: These valves and pump controls are operated from the PASS Analyzer Panel in the count room.

VALVE POSITION 4.1.2.1 CAV-626 Drain Tank 4.1.2.2 CAV-636 Closed l

4.1.2.3 CAP-10 Auto 4.1.2.4 CAP-10 (Flow Control Switch)

FULL CLOCKWISE i

4.1.2.5 CAP-14 On i

N EM-307 Rev. 21 Page 5

F-The following breakers are normally in the locked open (Off)

NOTE:

position by Operations due to not having automatic ES closure d

functions.

4.1.3 Energize, or verify energized, the following breakers:

o DPDP5A (124' Control Complex, 480V Switchgear Rm.) Brk. No. 27 for CAV-434.

o DPDP5B (124' Control Complex, 480V Switchgear Rm.) Brk. No. 8

~

tor CAV-436.

NOTE: The following containment isolation valves are operated from the Main Control Board. Operations personnel will open when requested.

NOTE:

See Enclosure 1 for alternate valve list.

4.1.4 Request operations to OPEN the following valves:

s 4.1.4.1 Open CAV-436 (Return to RB Sump, Outside Containment Valve).

4.1.4.2 Open CAV-434 (Return to RB Sump, Inside Containment Valve).

4.1.4.3 Open CAV-431 (Sample Supply to PASS Outside Containment).

4.1.4.4 Open CAV-126 (RCS Letdown Sample Supply to Liquid PASS, Inside Containment).

NOTE: As the control knob for CAV-484 is turned towards the open position, it will slowly move the actuator towards the open position. When turned towards the closed position, it will slowly move the actuator towards the closed position.

Adjusting the valve control knob towards the open or closed position will vary the flow and pressure accordingly.

Additional flow adjustments may be required when flow to other instrumentation is initiated or secured.

4.

4.1.5 From CACP-1 in the Count Room, SLOWLY turn (open) the output adjustment control for CAV-484 until the pressure indicated on CA-89-PI is between 10-50 psig and the flow indicated on CA-74-FI is between 0.35-0.50 gpm.

4.1.6 IE a HI-HI level alarm occurs on CAT-8 (Drain tank) closing CAV-623 and stopping CAP-10, THEN perform 4.1.6.1 through 4.1.6.7 N

.AJtLD continue with 4.1.7.

[d EM-307 Rev. 21 Page 6

4.1.6.1 Place CAP-10 switch to "0FF" position.

4.1.6.2 Place CAV-623 to the " CLOSED" position.

4.1.6.3 Press and hold " RESET" button on Drain Tank level indicator (keep

" HELD IN").

4.1.6.4 Turn CAP-10 switch to the "0N" position.

4.1.6.5 Hold " RESET" button "IN" until CAP-10 lowers Drain Tank level below "HI" level indicator / switch and "HI" level alarm light clears.

4.1.6.6 Place CAV-623 to the "0 PEN" position.

4.1.6.7 Place CAP-10 switch to the "AUT0" position.

4.1.7 After sufficient sample flush per Enclosure 5, observe the indications of thermocouples CA-54 TE-1 (downstream of precooler CAHE-8) and CA-51-TE (downstream of cooler CAHE-5) by performing Steps 4.1.7.1 through 4.1.7.6.

4.1.7.1 Sign on the VAX computer as Username:

PASS.

4.1.7.2 Select PASS Menu.

4.1.7.3 Select Display ND68DC Input Values.

4.1.7.4 ND68DC Input Values will be displayed.

Note input number 11 for CA-54-TE-1 and input number 28 for CA-54-TE.

4.1.7.5 Temperatures of greater than 120 degrees F on CA-54-TE-1 and 100 degrees F on CA-51-TE indicate insufficient cooling.

4.1.7.6 lE these conditions exist, IBM consult Chemistry Supervision for instructions.

4.1.7.7 Enter "Q" to exit.

4.1.7.8 Enter "NO" for printout.

4.1.8 Go to section 4.6 to perform a Gamma Isotopic Analysis after appropriate sample flush time is met.

4.1.9 Allow sample to flush through the Boronometer for at least one hour.

4.1.10 The Boron concentration of the sample will be displayed at the readout (CA-56-CI) located on the PASS Analyzer Panel in the countroom.

4.1.11 Leave system in present lineup to allow continuous Boron monitoring 1

of the selected sample point.

AU EM-307 Rev. 21 Page 7

NOTE: The following Steps (4.1.12 through 4.1.12.3) will isolate O

flow only to the boronometer.

Flow to any of the other components lined up in Section 4.2 will be maintained.

4.1.12 IE required to isolate flow through the boronometer, IUEN:

4.1.12.1 Close CAV-484.

4.1.12.2 Close CAV-623.

4.1.12.3 Close CAV-626, 4.1.13 IE a demin water flush of system is required, leave system lineup as is, IHEN go to Section 4.9.

4.2 SAMPLING THE RCS WHILE STILL AT PRESSURE FOR DISSOLVED HYDROGEN. DH.

AND/0R CHLORIDE ANALJS.55 NOTE: Dissolved hydrogen, pH and ion chromatographic analyses can be performed simultaneously with RCS gamma isotopic and boron analyses.

4.2.1 1E flow is lined up to the boronometer, 08 a gamma isotopic is being performed, IEEN CAV-484 will be OPEN.

Leave CAV-484 open in this situation.

4.2.2 1E the boronometer is not lined up, 08 an isotopic is not being performed, IHEN verify that CAV-484 is closed.

4.2.3 Place the following valves in the indicated position:

NOTE: These valves are operated from the PASS Analyzer Panel in the count rcom.

VALVE POSITION 4.2.3.1 CAV-437 Open 4.2.3.2 CAV-439 Closed 4.2.3.3 CAV-448 Open 4.2.3.4 CAV-627 Sample

()

4.2.3.5 CAV-628 Sample EM-307 Rev. 21 Page 8

F l

VALVE POSITION

/U 4.2.3.6 CAV-629 Sample 4.2.3.7 CAV-630 Sample 4.2.3.8 CAV-633 pH/IC 4.2.3.9 CAV-634 Sample 4.2.3.10 CAV-636 Closed

~

4.2.3.11 CAP-10 Auto 4.2.~3.12 CAP-10 (Flow Control Switch)

FULL CLOCKWISE 4.2.3.13 CAP-14 On 1

NOTE:

The following breakers are normally in the locked open (Off) position by Operations due to not having automatic ES closure functions.

4.2.4 Energize, or verify energized, the following breakers:

o DPDP5A (124' Control Complex, 480V Switchgear Rm.) Brk. No. 27 for CAV-434.

o DPDP5B (124' Control Complex, 480V Switchgear Rm.) Brk. No. 8 i

for CAV-436.

NOTE: The following containment isolation valves are operated from the Main Control Board. Operations personnel will open when requested.

NOTE:

See Enclosure 1 for alternate valve list.

4.2.5 Request operations OPEN the following valves:

4.2.5.1 Open CAV-436 (Return to RB Sump, Outside Containment Valve).

4.2.5.2 Open CAV-434 (Return to RB Sump, Inside Containment Valve).

4.2.5.3 Open CAV-431 (Sample Supply to PASS Outside Containment).

4.2.5.4 IE RCS letdown is in service, THEN open CAV-126 (RCS Letdown Sample Supply to Liquid PASS, inside O

Containment).

v EM-307 Rev. 21 Page 9

4.2.5.5 E RCS letdown is not in service, O

ItifS determine the valid sample point, AND request operations open appropriate valve from Enclosure 1.

1 NOTE: As the control knob for CAV-631 is turned towards the open position, it will slowly move the actuator towards the open position. When turned towards the closed position, it will slowly move the actuator towards the closed position.

Adjusting the valve control knob towards the open or closed position will vary the flow and pressure accordingly.

Additional flow adjustments may be required when flow to other instrumentation is initiated or secured.

4.2.6 From CACP-1 in the Count Room, SLOWLY turn (open) the output i

adjustment control for CAV-631 until the pressure indicated on CA-77-PI is between 10-50 psig and the flow indicated on CA-78-FI AND CA-80-FI is as close to 0.067 gpm as possible.

4.2.7 E a HI-HI level alarm occurs on CAT-8 (Drain tank) closing CAV-627 and stopping CAP-10, THEN perform 4.2.7.1 through 4.2.7.7 NiQ continue with 4.2.8.

4.2.7.1 Place CAP-10 switch to "0FF" position.

4.2.7.2 Place CAV-627 to the " CLOSED" position.

4.2.7.3 Press and hold " RESET" button on Drain Tank level indicator (keep

" HELD IN").

4.2.7.4 Turn CAP-10 switch to the "0N" position.

4.2.7.5 Hold " RESET" button "IN" until CAP-10 lowers Drain Tenk level below "HI" level indicator / switch and "HI" level alarm light clears.

4.2.7.6 Place CAV-627 to the "0 PEN" position.

4.2.7.7 Place CAP-10 switch to the "AUT0" position.

4.2.8 After sufficient sample flush per Enclosure 5, observe the indications of thermocouples CA-54-TE-1 (downstream of precooler CAHE-8) and CA-51-TE (downstream of cooler CAHE-5).

4.2.8.1 Sign on the VAX computer as Username:

PASS.

4.2.8.2 Select PASS Menu.

4.2.8.3 Selact Display N068DC Input Values.

4.2.8.4 N068DC Input Values will be displayed. Note input number 11 f;r CA-54-TE-1 and input number 28 for CA-54-TE.

EM-307 Rev. 21 Page 10

4.2.8.5 Temperatures of greater than 120 degrees F on CA-54-TE-1 and 100 degrees F on CA-51-TE indicate insufficient cooling.

4.2.8.6 E these conditions exist, ItiH consult Chemistry Supervision for instructions.

4.2.8.7 Enter "Q" to exit.

4.2.8.8 Enter "N0" for printout.

4.2.9 E a chloride analysis is required, THEN go to section 4.7.

4.2.10 Allow the sample to purge through the dissolved hydrogen and pH sensors for at least 15 minutes to insure that a representative sample has been obtained.

4.2.11 The dissolved hydrogen concentration will be displayed on the electronics readout CA-55-CI located on the Pa.is Analyzer Panel in the countroom.

4.2.12 The sample pH will be displayed on the electronics readout CA-73-Cl also located on the PASS Analyzer Panel in the countroom.

NOTE: The following step will isolate flow only to the Dissolved Hydrogen, pH and I.C. analyzers.

Flow to any of the other

')

components lined up in Section 4.1 will be maintained.

4.2.13 E isolation is desired to the Dissolved Hydrogen, pH, or I.C.

analyzers, THEN:

4.2.13.1 Close CAV-627.

4.2.13.2 Close CAV-628.

4.2.13.3 Close CAV-629.

4.2.13.4 Close CAV-630.

4.2.13.5 Close CAV-633.

4.2.13.6 Close CAV-634.

4.2.14 E a demin water flush of system is required, leave system lineup as is, THEN go to Section 4.9.

O EM-307 Rev. 21 Page 11

4.3 SAMPLING THE RCS WHEN ON DECAY HEAT OR LOW PRESSURE INJECTION FOR BORON AND/0R GAMMA ISOTOPIC ANALYSES NOTE: These analyses can be performed simultaneously if desired.

NOTE: These valves are operated from the PASS Analyzer Panel in the count room.

4.3.1 Place the following valves in the indicated position:

VALVE POSITION 4.3.1.1 CAV-519 Open 4.3.1.2 CAV-447 Open 4.3.1.3 CAV-437 Open 4.3.1.4 CAV-439 Closed 4.3.1.5 CAV-448 Open 4.3.1.6 CAV-623 Sample 4.3.1.7 CAV-625 Sample 4.3.1.8 CAV-626 Drain Tank 4.3.1.9 CAV.-636 Closed 4.3.1.10 CAP-10 Auto 4.3.1.11 CAP-10 (Flow Control Switch)

FULL CLOCKWISE 4.3.1.12 CAP-14 On NOTE: The following breakers are normally in the locked open (Off) position by Operations due to not having automatic ES closure functions.

4.3.2 Energize, or verify energized, the following breakers:

l o

DPDPSA (124' Control Complex, 480V Switchgear Rm.) Brk No. 27 for CAV-434.

o DPDPSB (124' Control Complex, 480V Switchgear Rm.) Brk. No. 8 for CAV-436, EM-307 Rev. 21 Page 12

)

NOTE: The following containment isolation valves are operated from g

the Main Control Board.

Operations personnel will open when requested.

NOTE: See Enclosure 1 for alternate valve list.

4.3.3 Request operations OPEN the following valves:

4.3.3.1 Open CAV-436 (Return to RB Sump, Outside Containment Valve).

4.3.3.2 Open CAV-434 (Return to RB Sump, Inside Containment Valve).

l NOTE: The following valves are operated from the PASS Analyzer Panel in the Count Room.

4.3.4 IE the "A" DH train is to be sampled, THEN open CAV-441 (Isolation for Decay Heat Train "A"), OR lE the "B" DH train is to be sampled, THEN open CAV-442 (Isolation for Decay Heat Train "B").

4.3.5 Open CAV-440 (Inlet to Low Pressure AIMS Sample Loop).

p 4.3.6 SLOWLY move the actuator switch on CAV-624 towards the open V

position, while carefully monitorina the downstream flowrate on CA-74-FI, UNTil the flow rate indicated on CA-74-FI is 0.35 to 0.5 GPM.

4.3.7 IE a HI-HI level alarm occurs on CAT-8 (Drain tank) closing CAV-623 and stopping CAP-10, THEN perform 4.3.7.1 through 4.3.7.7 AND continue with 4.3.8.

4.3.7.1 Place CAP-10 switch to "0FF" position.

4.3.7.2 Place CAV-623 to the " CLOSED" position.

4.3.7.3 Press and hold " RESET" button on Drain Tank level indicator (keep

" HELD IN").

4.3.7.4 Turn CAP-10 switch to the "0N" position.

j 4.3.7.5 Hold " RESET" button "IN" until~ CAP-10 lowers Drain Tank level below "HI" level indicator / switch and "HI" level alarm light clears.

4.3.7.6 Place CAV-623 to the "0 PEN" position.

4.3.7.7 Place CAP-10 switch to the "AUT0" position.

O EM-307 Rev. 21 Page 13

'4.3.8 If a Gamma Isotopic Analysis is required,

~

JBfQi go to section 4.6.

4.3.9 Allow the sample to purge through the boronometer for one hour, 4.3.10 The Boron concentration of the sample will be displayed at the readout (CA-56-CI) located on the PASS Analyzer Panel in the countroom.

4.3.11 JE required to isolate flow through the boronometer, JBE[i:

4.3.11.1 Close CAV-623.

4.3.11.2 Close CAV-626.

4.3.12 If a demin water flush of system is required, leave system lineup as is, JJiEB go to Section 4.10.

4.4 SAMPLING THE REACTOR BUILDING SUMP FOR BORON AND/0R GAMMA ISOTOPIC ANALYSES NOTE: These analyses can be performed simultaneously if desired.

O NOTE:

These valves are operated from the PASS Analyzer Panel located in the count room.

4.4.1 Place the following valves in the indicated position:

VALVE ILOSITION 4.4.1.1 CAV-519 Open 4.4.1.2 CAV-447 Open 4.4.1.3 CAV-437 Open 4.4.1.4 CAV-439 Closed 4.4.1.5 CAV-448 Open 4.4.1.6 CAV-623 Sample 4.4.1.7 CAV-625 Sample 4.4.1.8 CAV-626 Drain Tank 4.4.1.9 CAV-636 Closed EM-307 Rev. 21 Page 14

VALVE POSITION 4.4.1.10 CAP-10 Auto 4.4.1.11 CAP-10 (Flow Control Switch) FULL CLOCKWISE-4.4.1.12 CAP-14 On NOTE: The following breakers are normally in the locked open (Off)

~

position by Operations due to not having automatic ES closure functions.

4.4.2 Energize, or verify energized, the following breakers:

o DPDP5A (124' Control Complex, 480V Switchgear Rm.) Brk. No. 27 for CAV-433, and CAV-434.

o DPDP58 (124' Control Complex, 480V Switchgear Rm.) Brk. No. 8 for CAV-435, and CAV-436.

NOTE: The following containment isolation valves are operated from the Main control Board. Operations personnel will open when requested.

NOTE:

See Enclosure 1 for alternate valve list.

4.4.3 Request operations OPEN the following valves:

4.4.3.1 Open CAV-436 (Return to RB Sump, Outside Containment Valve).

4.4.3.2 Open CAV-434 (Return to RB Sump, Inside Containment Valve).

NOTE:

Steps 4.4.4 and 4.4.6 are to utilize demineralized water to initially cool the RB Sump Sample until flow is established.

These steps will prevent possible flashing in the CAP-8 suction line.

4.4.4 Open DWV-337 (Demin Water Supply Valve).

4.4.5 Open CAV-521.

4.4.6 Open CAV-471 to prime CAP-8.

4.4.7 Start CAP-8 (RB Sump recirculation pump).

O EP-307 Rev. 21 Page 15

L..

1 4.4.8 :

SLOWLY move the actuator switch on CAV-624 towards the open position, while carefully monitorina the downstream flowrate on CA-74-FI, UNTIL the flow rate indicated on CA-74-FI is 0.35 to 0.5 GPM.

NOTE: The following containment isolation valves are operated from the Main Control Board. Operations personnel will open when requested.

NOTE: See Enclosure 1 for alternate valve list.

4.4.9 Request operations Df_W the following valves:

4.4.9.1 CAV-433 (RB Sump Suction, Inside Containment).

4.4.9.2 CAV-435 (RB Sump Suction, Outside Containment).

4.4.10 When sample flow has stabilized on CA-74-FI (approximately 5 minutes), close CAV-471.

NOTE: The following valves are operated from the PASS Analyzer Panel located in the Count Room.

O 4.4.11 SLOWLY move the actuator switch on CAV-624 towards the open position, while carefully monitorina the downstream flowrate on CA-74-FI, Ul!Ill the flow rate indicated on CA-74-FI is 0.35 to 0.5 GPM.

4.4.12 IE a HI-HI level alarm occurs on CAT-8 (Drain tank) closing CAV-623 and stopping CAP-10, THQ perform 4.4.12.1 through 4.4.12.7 AND continue with 4.4.13.

4.4.12.1 Place CAP-10 switch to "0FF" position.

4.4.12.2 Place CAV-623 to the " CLOSED" position.

4.4.12.3 Press and hold " RESET" button on Drain Tank level indicator (keep-

" HELD IN").

4.4.12.4 lurn CAP-10 switch to the "0N" position.

4.4.12.5 Hold " RESET" button "IN" until CAP-10 lowers Drain Tank level below "HI" level indicator / switch and "HI" level alarm light clears.

4.4.12,6 Place CAV-623 to the "0 PEN" position.

4.4.12.7 Place CAP-10 switch to the "AUT0" position.

EM-307 Rev. 21 Page 16

e 4.4.13 lE a Gamma Isotopic Analysis is required, JJi@ go to section 4.6.

4.4.14 Allow the sample to purge through the boronometer for one hour.

4.4.15 The Boron concentration of the sample will be displayed at the readout (CA-56-CI) located on the PASS Analyzer Panel in the countroom.

4.4.16 E required to isolate flow through the boronometer, THEN:

4.4.16.1 Close CAV-623.

4.4.16.2 Close CAV-626.

4.4.17 E a demin water flush of system is required, leave system lineup as is, THEN go to section 4.12.

4.5 SAMPLING THE MISC. WASTE STORAGE TANK FOR BORON AND/0R GAMMA IS0 TOPIC ANALYSIS NOTE: These analyses can be performed simultaneously, if desired.

3(V 4.5.1 Request Operations verify that WDP-6A and/or WDP-68 (MWST Recirculation Pumps) are running.

4.5.2 Place the following valves in the indicated position:

i NOTE: These valves are operated from the PASS Analyzer Panel located in the count room.

VALVE POSITION 4.5.2.1 CAV-519 Open 4.5.2.2 CAV-447 Open 4.5.2.3 CAV-437 Open 4.5.2.4 CAV-439 Closed 4.5.2.5 CAV-448 Open D

(V EM-307 Rev. 21 Page 17

val.VE POSITION 4.5.2.6 CAV-623 Sample 4.5.2.7 CAV-625 Sample 4.5.2.8 CAV-626 Drain Tank 4.5.2.9 CAV-636 Closed

~

4.5.2.10 CAP-10 Auto 4.5.2.11 CAP-10 (Flow Control Switch)

FULL CLOCKWISE 4.5.2.12 CAP-14 On NOTE: The following breakers are normally in the locked open (Off) position by Operations due to not having automatic ES closure functions.

4.5.3 Energize, or verify energized, the following breakers:

o DPDP5A (124' Control Complex, 480V Switchgear Rm.) Brk'. No. 27 for CAV-434.

o DPDP5B (124' Control Complex, 480V Switchgear Rm.) Brk. No. 8 for CAV-436.

NOTE: The following containment isolation valves are operated from the Main control Board.

Operations personnel will open when requested, i

NOTE:

See Enclosure 1 for alternate valve list.

4.5.4 Request operations OPEN the following valves:

4.5.4.1 Open CAV-436 (Return to RB Sump, Outside Containment Valve).

4.5.4.2 Open CAV-434 (Return to RB Sump, Inside Containment Valve).

4.5.5 Open CAV-444.

4.5.6 Open CAV-443, 4.5.7 SLOWLY move the actuator switch on CAV-624 towards the open position, carefully monitorina the downstream flowrate on CA-74-FI,

(

UNTil the flow rate indicated on CA-74-FI is 0.35 to 0.5 GPM.

l EM-307 Rev. 21 Page 18

4.5.8 IE a HI-HI level alarm occurs on CAT-8 (Drain tank) closing CAV-623 O

and stopping CAP-10, IBEM perform 4.5.8.1 through 4.5.8.7 AND continue with 4.5.9.

4.5.8.1 Place CAP-10 switch to "0FF" position.

4.5.8.2 Place CAV-623 to the " CLOSED" position.

4.5.8.3 Press and hold " RESET" button on Drain Tank level indicator (keep

" HELD IN").

4.5.8.4 Turn CAP-10 switch to the "0N" position.

4.5.8.5 Hold " RESET" button "IN" until CAP-10 lowers Drain Tank level below "HI" level indicator / switch and "HI" level alarm light clears.

4.5.8.6 Place CAV-623 to the "0 PEN" position.

4.5.8.7 Place CAP-10 switch to the "AUT0" position.

4.5.9 IE a Gamma Isotopic Analysis is required, TBfdl go to Section 4.6.

4.5.10 Allow the sample to purge through the boronometer for one hour.

4.5.11 The Baron concentration of the sample will be displayed at the O

readout (CA-56-CI) located on the PASS Analyzer Panel in the countroom.

4.5.12 IE required to isolate flow through the boronometer, IBEN 4.5.12.1 Close CAV-623.

4.5.12.2 Close CAV-626.

4.5.13 If a demin water flush of system is required, leave system lineup as is, THEN go to section 4.11.

1 l

O EM-307 Rev. 21 Page 19

4.6 GAMMA ISOTOPIC ANALYSIS G'

4.6.1 Prior to continuing with this section, insure the following concerns are met:

CAUTION: Never reset the Liquid Nitrogen Monitor until the High Voltage bias has been lowered to 0 volts.

o Detector should have an adequate supply of Liquid Nitrogen, o

High Voltage should be applied to the Liquid PASS detector and not disabled by the Liquid Nitrogen Monitor.

o A weekly detector calibration should have been performed within the past 7 days.

NOTE: Assure minimum flush times are met as per ENCLOSURE 5.

4.6.2 Sign on the VAX computer as Usernams:

PASS.

OV NOTE: The < SELECT > option is designated by the PFI key.

4.6.3

< SELECT > PASS Menu.

4.6.4 Answer "N0" to "Do you want a spectral display window?".(Def ault) 4.6.5

< SELECT > Liquid Sampling.

4.6.6

< SELECT > appropriate sample point.

Collimator will move to correct position.

4.6.7 The MUX values will be displayed. Enter "Q" to continue, or < RETURN >

to get an update to the values.

4.6.8 Enter "N0" to abort sample. (Default value).

4.6.9 Update sample parameters and Press < ACCEPT >.

4.6.10 The system will now perform a count rate check to establish the best counting geometry.

4.6.11 Once acquisition is complete, all reports will be output to a printing device.

EM-307 Rev. 21 Page 20

4.6.12

.lE a demin flush is required, JHW go to the appropriate section depending on sample flow lineup:

Section Samole Flow Lineuo l

4.9 RCS at pressure 4.10 Decay Heat 4.11 MWST 4.12 RB Sump 4.7 CHLORIDE ANALYSIS 4.7.1 Before starting up the Dionex IC check the following:

o IC plugged into the 120 VAC labeled " PASS chromatograph only".

o Red instrument air tubing secured to air bulkhead.

o Blue eluent tubing secured to analytical pump outlet, o

White eluent delivery tubing secured to the analytical pump inlet bulkhead (#1 position) for sodium tetraborate.

White demin water delivery tubing secured to the analytical pump o

inlet bulkhead (#6 position).

o Adequate volumes of eluent, regenerants, demin water, and calibration solution are in their containers.

For reagent preparation, see Enclosure 2.

o Adjust air pressure to regenerate container to insure proper

delivery, o

Thermal conductivity BNC leads are properly connected to the back of the conductivity detector module (Two cell leads and one Thermistor Lead).

o Insure that the integrator to be used is connected to the " Chart Recorder" output of the conductivity detector module.

4.7.2 Depress the POWER button.

Instrument LEDs will light.

O EM-307 Rev. 21 Page 21

i 4.7.3 Verify the following conductivity detector module LEDs are in their l

correct positions:

o Local / Remote is " Local".

o CELL is "0N".

o Auto 0FFSET is "0FF".

o Temperature Compensator is "1.7".

o ' Scale - the scale setting can be varied depending on the nature of the sample being analyzed. The scale automatically sets itself at 30 when the POWER button is depressed.

If, after obtaining the first printout, there is a peak (s) that is off-scale, increase the scale setting 1 increment and repeat the analysis.

The goal is to have the scale setting as low as cossibl_q while maintaining all oeaks of interest on scale.

4.7.4 Verify the following analytical pump module setpoints:

o Local / Remote is " Local".

o low Pressure Pump trip is 20#.

o High Pressure Pump trip to be set at 200 psi above operating pressure.

o Flow rate is 2.0 ml/ min.

NOTE:

Eluent #1 is for determination of chloride in a boron matrix

- this eluent will not elute sulfates.

4.7.5 Select the eluent solution to be used and depress its corresponding selector switch. A red LED lamp should light just to the right of the switch.

4.7.6 Depress the analytical pump Stop/ Start Switch. As the pump comes on the LED should move from the stop to the start position and the pressure indication (located just below the Stop/ Start Switch) should start to increase.

It is not uncommon to have to start the pump 2 or 3 times before it will stay on. The pump outlet pressure indication will stabilize momentarily and the pump " Ready" LED will light.

O EM-307 Rev. 21 Page 22

NOTE:

If the system pressure is indicated to be less than 20#, the

[]

low pressure trip point set in 4.7.4 will have to be lowered U

to 0 until after the pump is started and system pressure has risen to at least 30#.

NOTE:

If the pump will not sustain a stable pressure, one or both of the pump cylinders is airlocked. explains the l

procedure for priming the airlocked pump.

l

~

4.7.7 At the top of the Advanced Chromatography Module are two sets of valve controls labeled System 1 and System 2.

System 2 is reserved for PASS use.

Verify the following System 2 valve positions:

o

' Load / Inject is Load".

o "A" valve is "0FF".

9 "B" valve is "0N".

o local / Remote is " Local".

4.7.8 Allow the conductivity reading to stabilize before continuing.

It is considered stable when the reading is unchanged (to two decimal places) for 2 minutes.

O NOTE:

Insure that calibration solution does not run dry.

NOTE: The line from the IC calibration pump to the 'B' valve can be flushed at greater than 15Y. pump stroke if the 'B' valve is switched "0FF" before the pump stroke is raised.

Switching the 'B' valve "0FF" diverts the flow to waste allowing rapid line flushing.

Return the pump stroke to between 10% and 15%

before returning the 'B' valve to the "0N" position.

NOTE:

If the calibration pump is not operational, calibration solution may be loaded manually using a syringe with a block coupler in the PASS cabinet in the PASS Room, disconnect the sample inlet line from the load / inject valve and connect the syringe.

Slowly inject - 1 ml of calibration solution.

4.7.9 Align the Calibration Solution Select Valve to the " calibration" position and start the calibration pump (at the reagents cabinet outside the wall of the. PASS room).

OO EM-307 Rev. 21 Page 23 1

4.7.10 E the Chromjet SP4400 Integrator is to be used, O

J]iG GO TO Section 4.7.11 to setup integrator M :ontinue with Section 4.7.13.

4.7.10.1 '1E the 4270 Integrator is to be used, JJiG GO TO Section 4.7.12 to setup. integrator E continue with Section 4.7.13.

4.7.11 SP4400 INTEGRATOR SETUP 4.7.11.1 E a " PASS Calibration" file is known to be present in the SP4400 integrator's memory, THEN enter "FI-n"( where "n" is the number corresponding to the current PASS file from the most recent calibration data in the Instrument log book).

4.7.11.2 Review FILE printout.

4.7.11.3 To edit a function or sample parameter in the file, enter an equality statement between the function or parameter and the value you wish to enter.

EXAMPLE 1:

To set the first components' retention time to 1.91:

o Enter <RT(1)=1.91>

o Press < ENTER >

EXAMPLE 2:

To set the method peak threshold to 6000:

o Enter <PT=6000>

o Press < ENTER >

4.7.11.4 E a " PASS Calibration" file does not exist, THEN see Enclosure 9 for an example file to enter.

4.7.11.5 A file may be initially entered using the integrator " DIALOG" function.

4.7.12 4270 INTECRATOR SETUP 4.7.12.1 E a " PASS Calibration" file is known to be present in the 4270 Integrator's memory, THEN: press "USE FILE" button.

4.7.12.2 Enter the num er for the FILE.

4.7.12.3 Press " ENTER" button, 4.7.12.4 Press "PRFILE" button.

4.7.12.5 Review FILE printout.

t EM-307 Rev. 21 Page 24

9 4.7.12.6 If a " PASS Calibration" file does not exist,

()

IEEN see Enclosure 10:for an example file to enter.

4.7.13 As soon as the conductivity reading has stabilized the IC is ready to perform a calibration check. Utilize the AUTO 0FFSET switch on the Conductivity Detector module to better determine the rate of change in the conductivity reading.

Proceed when the reading has comoletely stabilized.

4.7.14 Switch the Auto Offset "0FF" and "0N".

Wait 10 seconds.

4.7.15 Simultaneously switch the System 2 Load / Inject valve to the." Inject" position aHQ depress the "INJA" buttcn on the integrator.

4.7.16 After 10 seconds return the Load / Inject valve to the " Load" position.

4.7.17 When the chromatographic separation is complete, "Stop" the integrator. Adjust the scale position as needed to place all peaks of interest on scale.

4.7.18 After allowing the conductivity reading to restabilize, repeat 4.7.14 thru 4.7.17 until you get 2 consecutive printouts in which the ion peaks of interest are of equal height or area (i 10%).

4.7.19 IE using the SP4400 integrator, IBEN GO TO Section 4.7.20 to edit the calibration table O

aHD continue with Section 4.7.22.

IE using the 4270 integrator, IHEN GO TO Section 4.7.21 to edit the calibration table AHD continue with Section 4.7.22.

4.7.20 Editina a calibration table in the SP4400 intearator 4.7.20.1 Take the " AREA" of the ion peak of interest from the last printout and divide the " AREA" by the concentration of the calibration standard.

This is the "RF" value.

4.7.20.2 Edit the "RF" value by pressing the following buttons:

R F

(

1

)

=

4.7.20.3 Enter the numerical value for "RF" and press the " ENTER" button.

Example.

To change the "RF" value to 11501 press:

1 1

5 0

1 ENTER R

F

(

1

)

O EM-307 Rev. 21 Page 25

i 4.7.20.4 Edit the retention time by pressing the following buttons:

R T

(

1

)

=

4.7.20.5 Enter the numerical value for the retention time and press the

" ENTER" button.

Exampl e.

To change to a retention time of 4.86 minutes press:

4 8

6 ENTER R

T

(

1

)

=

4.7.20.6 ~ Continue with Step 4.7.22.

4.7.21 Editino a calibration table in the 4270 4.7.21.1 Take the " AREA" of the ion peak of interest from the last printout and divide the " AREA' by the concentration of the calibration standard.

This is the "RF" value.

4.7.21.2 Edit the "RF" value by pressing the following buttons:

SHIFT SHIFT R

F SHIFT

(

1

)

=

4.7.21.3 Enter the numerical value for "RF" and press the " ENTER" button.

Example.

To change the "RF" value to 11501 press:

1 1

5 0

1 ENTER SHIFT SHIFT R

F SHIFT

(

1

)

=

4.7.21.4 Edit the retention time by pressing the following buttons:

SHIFT SHIFT R

T SHIFT

(

1

)

=

4.7.21.5 Enter the numerical value for the retention time and press the

" ENTER" button.

Example.

To change to a retention time of 4.86 minutes press:

4 8

6' ENTER SHIFT SHIFT R

T SHIFT

(

1

)

=

4.7.21.6 Continue with step 4.7.22.

l EM-307 Rev. 21 Page 26 1

4.7.22 Open CAV-525.

(T 4.7.23 Prior to beginning the sample analysis:

o Switch the 'B' valve "0FF".

o Turn "0FF" the calibration solution pump.

o Insure the conductivity reading is stabilized and zerced by cycling the Auto offret "0FF" and "0N".

o Insure the Load / Inject switch is in " Load" for at least I minute.

4.7.24 EMN, sample analysis by simultaneously depressing the integrator "INJA" button AND switching the Load / Inject valve to " Inject". This initiates chromatographic separation of the sample.

4.7.25 Allow the separation at least 10 minutes before stopping the integrator.

The integrator printout will compute the chloride and sulfate concentrations directly.

4.7.26 Repeat 4.7.23 and 4.7.25 until 2 consecutive analyses show equal (1 10%) amounts of anions of interest in the sample.

NOTE:

It may take 2 or 3 sample analysis to completely flush the calibration standards from the system.'

4.7.27 Upon finishing the sample analysis the column must be rinsed with demin water to prevent carbonate fouling.

4.7.27.1 Depress Eluent Switch #6 until its LED indicator lights.

4.7.27.2 Depress Eluent Switch #1, or 3, until its LED indicator goes out.

These 2 steps switch the pump suction from eluent to demin water.

E H the conductivity reading stabilizes, 4.7.28 W

THEN perform the following to secure the IC:

4.7.28.1 "A" valve "0FF".

I 4.7.28.2 "B" valve "0FF" l

1 4.7.28.3 Pump Stop/ Start to "Stop".

4.7.28.4 Power "0FF".

4.7.28.5 Secure air pressure to regenerant container.

D O

EM-307 Rev. 21 Page 27

4.8 GRAB SAMPLING b

NOTE:

Preplanning is required to address radiological concerns and Health Physics coverage should be supplied prior to continuing with this procedure as outlined in EM-209 Re-Entry Procedure.

4.8.1 E the required lineup is not established for the sanple point of

interest, THE!f GO TO Sections 4.1, 4.3, 4.4, or 4.5 to lineup sample and continue to Section 4.8.3.

~

4.8.2 E the required lineup is established for the sample point of

interest, THEN GO TO Step 4.8.3.

4.8.3 Prior to Grab Sampling:

o Insure engagement of cart by unlocking the cart from the station and moving the engagement handle back and forth.

If properly engaged, the cart will also move back and forth.

Re-lock the cart to the station.

o Check the 3-way valves in the open (counter-clockwise) position (Grab Sampler Inlet and Outlet Valves).

o Turn on the Grab Sampler exhaust fan.

The switch is located to the rignt of the Intermediate Building door (across from RM-A7).

o Install the Grab Sampler ramp.

o Insure the transit cover and a wrench a.e available.

The properly sized wrench is available in the Primary Chemistry Lab hanging on the key locker.

4.8.4 From the PASS Mimic Panel in the Counting Room perform the following lineup to put flow through the grab sampler:

4.8.4.1 Open CAV-445.

4.8.4.2 Open CAV-446.

4.8.4.3 Close CAV-447.

4.8.5 Allow 5 to 15 minutes for sample to purge through the sampler.

4.8.6 Using the T-handle, turn the Grab Sampler three-way valves fully clockwise to isolate the sample in the sample bomb.

()

V EM-307 Rev. 21 Page 28

---

a

l 4.8.7 From the PASS Mimic Panel in the Counting Room:

4.8.7.1 Close CAV-445.

i 4.8.7.2 Close CAV-446.

4.8.7.3 Open CAV-447.

4.8.8 Perform demin water flush per Sections 4.9, 4.10, 4.11, or 4.12 depending on sample flow lineup.

CAUTION:

Perform a demin water flush Before removing the grab sampler.

4.8.9 Removina the Grab Samoler 4.8.9.1 Disconnect the Grab Sampler from the sample station by squeezing the disengagement lever and by pushing the engagement handle to its rearmost position.

4.8.9.2 Pull up on the handle of the cart locking mechanism to release the cart.

4.8.9.3 Remove the Grab Sampler and cart to the Turbine Building crane well and install the transit cover over the quick-connects.

The grab sampler can be removed from the cart using a wrench and transported off-site.

4.8.10 Installina a new Grab Samoler 4.8'.10.1 Bolt the Grab Sampler onto the cart and remove the transit cover.

Attach the transit cover to the lifting ring.

4.8.10.2 Using the T-handle, position the Grab Sampler 3-way valves to the fully counter-clockwise position for sampling.

4.8.10.3 With one person guiding the sampler assembly, another person should push it up the ramp and onto the platform, halting several inches from the connection points.

O EM-307 Rev. 21 Page 29

• • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • o***********************************

CAUTION:

When connecting the sampler, force should NEVER be used.

s,,

Damage to the quick-connects will result from forcing the connection.

4.8.10.4 Very carefully, slowly push the sampler into the sample station.

If positioned correctly, the front of the sampler will make metal-to-metal contact with the curved face of the sample station.

4.8.10.5 If the sampler does not position correctly, THEN pull the cart back a short distance and realign'it.

~

4.8.10.6 Repeat Step 4.8.10.4 to position sampler.

Repeated attempts may be necessary for proper alignment.

4.8.10.7 Lock the cart to the station by pushing the handle of the locking mechanism completely down, driving the lock-bolt through the hole in the cart.

4.8.10.8 Gently pull the engagement handle forward until a distinct " click" is heard (the handle must NOT be forced). This signifies that the quick-connects have engaged.

NOTE:

Due to environmental conditions, the click may not be heard.

V 4.8.10.9 To insure engagement, unlock the cart from the station and move the engagement handle back and forth.

4.8.10.10 if properly engaged, THEN the cart will also move back and forth.

4.8.10.11 Re-lock the cart to the station.

The Grab Sampler is now ready for use.

i 4.8.11 Continue with Step 4.9.23 to secure valve lineup.

l l

l 1

()

EM-307 Rev. 21 Page 30

[.l-l

\\

4.9 DEMINERALIZEp WATER FLUSH AND SYSTEM SHUTDOWN AFTER SAMPLING RCS

/

LETDOWN AT PRESSURE FOR GAMMA IS0 TOPIC. BORON. DISSOLVED HYDROGEN.

(

DH. ION CHROMAT0 GRAPHIC ANALYSES. OR ACQUIRING A GRAB SAMPLE NOTE:

When securing sample lineup to flush any component and associated sample lines with demin water, sample flow will also be secured to any other analyzers that are on line.

Depending on system lineup, the following valves may already be positioned correctly for a demin water flush.

NOTE:

These valves are operated from the main control board located in the control room.

4.9.1 Request operations:

4.9.1.1 Close CAV-126 4.9.1.2 Close CAV-431 4.9.2 Place the following valves in the indicated position:

NOTE:

These valves are operated from the Pass Analyzer Panel in the count room.

O' VALVE POSITION 4.9.2.1 CAV-484 Closed 4.9.2.2 CAV-623 Closed 4.9.2.3 CAV-624 Open 4.9.2.4 CAV-626 Drain Tank 4.9.2.5 CAV-631 Closed 4.9.2.6 CAV-627 Closed 4.9.2.7 CAV-633 pH/IC 4.9.2.8 CAV-634 Sample 4.9.2.9 CAV-636 Closed 4.9.2.10 CAP-10 Auto 4.9.2.11 CAP-10 (Flow Control Switch)

FULL CLOCKWISE

()

4.9.2.12 CAP-14 On EM-307 Rev. 21 Page 31

\\

NOTE:

These valves are operated from the Pass Analyzer Panel in the N]J

/~

count room.

4.9.3 Open DWV-337.

4.9.4 Open CAV-470.

4.9.5 Place CAV-623 in the " SAMPLE" position.

4.9.6 Place CAV-627 in the " SAMPLE" position.

4.9.7 Adiustina demin water flowrate throuah the boronometer NOTE:

As the control knob for CAV-484 is turned towards the open position, it will slowly move the actuator towards the open position. When turned towards the closed position, it will slowly move the actuator towards the closed position.

Adjusting the valve control knob towards the open or closed i

position will vary the flow and pressure accordingly.

Additional flow adjustments may be required when flow to other instrumentation is initiated or secured.

doom, turn (open) the output adjustment 4.9.7.1 From CACP-1 in the

[']s control for CAV-484 unti'> the pressure indicated on CA-89-PI is between 10-50 psig ard the flow indicated on CA-74-FI is between 0.35 to 0.50 gpm.

4.9.7.2 Continue with Step 4.9.S 4.9.8 Adiustina demin water flowrate to the Dissolved Hydroaen sensors NOTE:

These valves are operated from the Pass Analyzer Panel in the count room.

4.9.8.1 Check closed:

0 CAV-627.

O CAV-633.

j 4.9.8.2 Place CAV-631 in the " CLOSED" position.

4.9.8.3 Place CAV-627 in the " SAMPLE" position.

4.9.8.4 Place CAV-628 in the " SAMPLE" position.

4.9.8.5 Place CAV-628 in the " SAMPLE" position.

EM-307 Rev. 21 Page 32 i

. =

d e

4.9.8.6 Place CAV-629 in the " SAMPLE" position.

4.9.8.7 Place CAV-630 in the " SAMPLE" position.

4.9.8.8 Place CAV-634 in the " SAMPLE" position.

4.9.8.9 Place CAV-633 in the "pH/IC" position.

NOTE:

As the control knob for CAV-631 is turned towards the open position, it will slowly move the actuator towards the open position. When turned towards the closed position, it will slowly move the actuator towards the closed position.

Adjusting the valve control knob towards the open or closed position will vary the flow and pressure accordingly.

Additional flow adjustments may be required when flow to other instrumentation is initiated or secured.

4.9.8.10 From CACP-1 in the Count Room, turn (open) the output adjustment control for CAV-631 until the pressure indicated on CA-77-PI is between 10 to 50 psig and the flow indicated on CA-78-FI AND CA-80-FI is as close to 0.067 gpm as possible.

4.9.9 Aliow the water to flush for 10 minutes.

4.9.10 lE a HI-HI level alarm occurs on CAT-8 (Drain tank) closing CAV-623, i

I CAV-627, and stopping CAP-10, THEN perform 4.9.10.1 through 4.9.10.9 AND continue with 4.9.11.

4.9.10.1 Place CAP-10 switch to "0FF" position.

l 4.9.10.2 Place CAV-623 to the " CLOSED" position.

4.9.10.3 Place CAV-627 to the " CLOSED" position.

4.9.10.4 Press and hold " RESET" button on Drain Tank level indicator (keep 1

" HELD IN").

l 1

4.9.10.5 Turn CAP-10 switch to the "0N" position.

4.9.10.6 Hold " RESET" button "IN" until CAP-10 lowers Drain Tank level below "HI" level' indicator / switch and "HI" level alarm light clears.

j 4.9.10.7 Place CAV-623 to the "0 PEN" position.

4.9.10.8 Place CAV-627 to the "0 PEN" position.

4.9.10.9 Place CAP-10 switch to the "AUT0" position.

O EM-307 Rev. 21 Page 33 i

m e

NOTE:

A low liquid nitrogen level will automatically secure the

-O high voltage supply to the detector. Always lower the high V

voltage to zero volts before resetting the liquid nitrogen monitor.

4.9.11 Ensure the A.I.M.S. is in an operable condition by:

o Checking the liquid nitrogen monitor

~

o Ensuring the high voltage supply to the detector is properly adjusted 4.9.12

_ Sign on the VAX computer as Username:

PASS.

NOTE:

The < SELECT > option is designated by the PF1 key.

4.9.13

< SELECT > PASS Menu.

4.9.14 Answer "N0" to "Do you want a spectral display window?".(Default) 4.9.15

< SELECT > Flush Sample Lines.

4.9.16

< SELECT > RCS Demin Flush.

O-4.9.17 The collimator will move to the correct. position and the system will begin to acquire a spectrum. Maximize MCA Display 1 and toggle thru ADC's until RCS configuration is shown.

NOTE:

Step 4.9.18 cannot be performed from a remote terminal.

4.9.18 Use " ERASE" function on MCA Display to re-acquire spectrum.

4.9.19 E a high countrate is still indicated, THE continue flushing.

4.9.20 LF_ a low stable countrate is indicated, THEN:

4.9.20.1 Minimize MCA Display 1.

4.9.20.2 Press < RETURN >.

4.9.20.3 Press < QUIT >.

4.9.20.4 Sign off VAX computer by entering "LO".

4.9.21 E a grab sample was not performed, THEN go to Step 4.9.23.

O EM-307 Rev. 21 Page 34

e 1

~

NOTE:

These valves are operate from the PASS Analyzer Panel in the Counting Room:

4.9.22 Jf a Grab Sample was performed, THEN:

4.9.22.1 Close CAV-447.

4.9.22.2 Open CAV-445.

l 4.9.22.3 Open CAV-446.

I 4.9.22.4 Continue flush for 5 minutes.

4.9.22.5 Close CAV-445.

4.9.22.6 Close CAV-446.

4.9.22.7 Go to Step' 4.8.9 to remove grab sampler.

4.9.23 Close/ Check closed CAV-470.

e 4.9.24 Close/ Check closed DWV-337.

4.9.25 Close/ check closed CAV-519.

4.9.26 Close/ check closed CAV-437.

4.9.27 Close/ check closed CAV-447, 4.9.28 Close/ check closed CAV-448.

4.9.29 Close/ check closed CAV-484.

4.9.30 Close/ check closed CAV-623.

4.9.31 Close/ check closed CAV-624.

4.9.32 Close/ check closed CAV-625.

4.9.33 Close/ check closed CAV-626.

4.9.34 Close/ check closed CAV-627.

l 4.9.35 Close/ check closed CAV-628.

4.9.36 Close/ check closed CAV-629, 4.9.37 Close/ check closed CAV-630.

l 4.9.38 Close/ check closed CAV-631.

l

[

EM-307 Rev. 21 Page 35

I l

4.9.39 Close/ check closed CAV-632.

4.9.40 Close/ check closed CAV-633, 4.9.41 Close/ check closed CAV-634.

4.9.42 Close/ check closed CAV-635.

4.9.43 Close/ check closed CAV-525.

NOTE:

The following containment isolation valves are operated from the Main Control Board.

4.9.44 Request operations CLOSE the following valves:

4.9.44.1 Close CAV-436 (Return to RB Sump, Outside Containment Valve).

4.9.44.2 Close CAV-434 (Return to RB Sump, Inside Containment Valve).

4.10 DEMINERALIZED WATER FLUSH AND SYSTEM SHUTDOWN AFTER SAMPLING DECAY HEAT FOR BORON OR GAMMA IS0 TOPIC ANALYSES 4.10.1 LE the "A" DH train was sampled, I!!EH close CAV-441 (Isolation for Decay Heat Train "A") OR, IE the "B" DH train was sampled, THEN close CAV-442 (Isolation for Decay Heat Train "B").

NOTE:

These valves are operated from the Pass Analyzer Panel in the count room.

4.10.2 Place the following valves in the indicated position:

VALVE POSITION 4.10.2.1 CAV-440 Closed 4.10.2.2 CAV-624 Closed 4.10.2.3 DWV-337 Open 4.10.2.4 CAV-471 Open 4.10.3 Start CAP-8.

O EM-307 Rev. 21 Page 36

4.10.4 H OVWLY move the actuator switch on CAV-624 towards the open

("3 position, while carefully monitorina the downstream flowrate on V

CA-74-FI, UNTIL the flow rate indicated on CA-74-FI is 0.35 to 0.5 GPM.

4.10.5 Allow the water to flush for 10 minutes.

4.10.6 lE a HI-HI level alarm occurs on CAT-8 (Drain tank) closing CAV-623 and stopping CAP-10, IliEH perform 4.10.6.1 through 4.10.6.7 At!Q continue with 4.10.7.

4.10.6.1 Place CAP-10 switch to "0FF" position.

i 4.10.6.2 Place CAV-623 to the " CLOSED" position.

4.10.6.3 Press and hold " RESET" button on Drain Tank level indicator (keep

" HELD IN").

4.10.6.4 Turn CAP-10 switch to the "0N" position.

4.10.6.5 Hold " RESET" button "IN" until CAP-10 lowers Drain Tank level below "HI" level indicator / switch and "HI" level alarm light clears.

4.10.6.6 Place CAV-623 to the."0 PEN" position.

4.10.6.7 Place CAP-10 switch to the "AUT0" position.

NOTE:

A low liquid nitrogen level will automatically secure the high voltage supply to toe detector. Always lower the high voltage to zero volts before resetting the liquid nitrogen monitor.

4.10.7 Ensure the A.I.M.S. is in an operable condition by:

o Checking the liquid nitrogen monitor o

Ensuring the high voltage supply to the detector is properly adjusted 4.10.8 Sign on the VAX computer as Username:

PASS.

NOTE:

The < SELECT > option is designated by the PF1 key.

4.10.9

< SELECT > PASS Menu.

4.10.10 Answer "N0" to "Do you want a spectral display window?".(Default) 4.10.11

< SELECT > Flush Sample Lines.

EM-307 Rev. 21 Page 37

4.10.12

< SELECT > Sump Demin Flush.

O V

4.10.13 The collimator will move to the correct position and the system will begin to acquire a spectrum.

Maximize MCA Display 1 and. toggle thru ADC's until desired configuration is shown.

NOTE:

Step 4.10.14 cannot be performed from a remote terminal.

4.10.14 Use " ERASE" function on MCA Display to re-acquire spectrum.

4.10.15 E a high countrate is still indicated, THEN continue flushing.

4.10.16 E a low stable countrate is indicated, THEN:

4.10.16.1 Minimize MCA Display 1.

4.10.16.2 Press < RETURN >.

4.10.16.3 Press < QUIT >.

4.10.16.4 Sign off VAX computer by entering "LO".

4.10.17 E a grab sample was not performed, O

THEN go to Step 4.10.19.

NOTE: These valves are operate from the PASS Analyzer Panel in the Counting Room:

4.10.18 E a Grab Sample was performed, THEN:

4.10.18.1 Close CAV-447.

4.10.18.2 Open CAV-445.

4.10.18.3 Open CAV-446.

4.10.18.4 Continue flush for 5 minutes.

4.10.18.5 Close CAV-445.

4.10.18.6 Close CAV-446.

4.10.18.7 Go to step 4.8.9 to remove grab sampler.

4.10.19 Close/ Check closed DWV-337.

O EM-307 Rev. 21 Page 38

4.10.20 Close/ check closed CAV-471.

4.10.21 Close/ check closed CAV-519.

4.10.22 Close/ check closed CAV-447.

4.10.23 Close/ check closed CAV-623.

4.10.24 Close/ check closed CAV-624.

~

4.10.25 Close/ check closed CAV-625.

4.10.26 Close/ check closed CAV-626.

4.10.27 Turn off CAP-8.

NOTE:

The following containment isolation valves are operated from the Main Control Board.

4.10.28 Request operations CLOSE the following valves:

4.10.28.1 CAV-436 (Return to RB Sump, Outside Containment Valve).

4.10.28.2 CAV-434 (Return to RB Sump, Inside Containment Valve).

4 11 DllilN WATER FLUSH AND SYSTEM SHUTDOWN AFTER SAMPLING MWST FOR BORON.

AND/0R GAMMA ISOTOPIC ANALYSES i

4.11.1 Close CAV-443.

4.11.2 Close CAV-444, 4.11.3 Place the following valves in the indicated position:

NOTE:

These valves are operated from the Pass Analyzer Panel in the count room.

VALVE POSITION 4.11.3.1 CAV-624 Closed 4.11.3.2 DWV-337 Open 4.11.3.3 CAV-471 Open 4.11.4 Start CAP-8.

O EM-307 Rev. 21 Page 39

4.11.5 SLOWLY move the actuator switch on CAV-624 towards the open

-~g

(' d position, while carefully monitorina the downstream flowrate on CA-74-FI, UNTIL the flow rate indicated on CA-74-FI is 0.35 to 0.5 GPM.

4.11.6 Allow the water to flush for 10 minutes.

4.11.7 lE a HI-HI level alarm occurs on CAT-8 (Drain tank) closing CAV-623 and stopping CAP-10, IREN perform 4.11.7.1 through 4.11.7.7 AND continue with 4.11.8.

4.11.7.1 Place CAP-10 switch to "0FF" position.

4.11.7.2 Place CAV-623 to the " CLOSED" position.

4.11.7.3 Press and hold " RESET" button on Drain Tank level indicator (keep

" HELD IN").

4.11.7.4 Turn CAP-10 switch to the "0N" position.

4.11.7.5 Hold " RESET" button "IN" until CAP-10 lowers Drain Tank level below "HI" level indicator / switch and "HI" level alarm light clears.

4.11.7.6 Place CAV-623 to the "0 PEN" position.

4.11.7.7 Place CAP-10 switch to the "AUT0" position.

NOTE:

A low liquid nitrogen level will automatically secure the high voltage supply to the detector. Always lower the high voltage to zero volts before resetting the liquid nitrogen monitor.

4.11.8 Ensure the k_1.M.S. is in an operable condition by:

o Checking the liquid nitrogen monitor.

o Ensuring the high voltage supply to the detector is properly adjusted.

4.11.9 Sign on the VAX computer as Username:

PASS.

NOTE:

The < SELECT > option is designated by the PF1 key.

4.11.10

< SELECT > PASS Menu.

4.11.11 Answer "N0" to "Do you want a spectral display window?".(Default)

()

4.11.12

< SELECT > Flush Sample Lines.

EM-307 Rev. 21 Page 40

4.11.13

< SELECT > Sump Demin Flush.

4.11.14 The collimator will move to the correct position and the system will begin to acquire a spectrum. Maximize MCA Display 1 and toggle thru l

ADC's until desired configuration is shown.

NOTE:

Step 4.11.15 cannot be performed from a remote terminal.

1 4.11.15 Use " ERASE" function on MCA Display to re-acquire spectrum.

4.11.16 IE a high countrate is still indicated, THEN continue flushing.

4.11.17 If a low stable countrate is indicated, IHEN:

4.11.17.1 Minimize MCA Display 1.

4.11.17.2 Press < RETURN >.

4.11.17.3 Press < QUIT >.

4.11.17.4 Sign off VAX computer by entering "LO".

l 4.11.18 IE a grab sample was not performed, THEN go to step 4.11.20.

NOTE:

These valves are operate from the PASS Analyzer Panel in the Counting Room.

4.11.19 IE a Grab Sample was performed, THEN:

4.11.19.1 Close CAV-447.

4.11.19.2 Open CAV-445.

4.11.19.3 Open CAV-446.

4.11.19.4 Continue flush for 5 minutes.

4.11.19.5 Close CAV-445.

4.11.19.6 Close CAV-446.

4.11.19.7 Go to step 4.8.9 to remove grab sampler.

4.11.20 Close/ Check closed DWV-337.

O EM-307 Rev. 21 Page 41

l 4.11.21 Close/ check closed CAV-471.

.O 4.11.22 Close/ check closed CAV-519, 4.11.23 Close/ check closed CAV-447.

4.11.24 Close/ check closed CAV-623.

4.11.25 Close/ check closed CAV-624.

1 4.11.26 Close/ check closed CAV-625.

4.11.27 Close/ check closed CAV-626.

4.11.28 Turn off CAP-8.

NOTE:

The following containment isolation valves are ' operated from the Main Control Board.

4.11.29 Request operations CLOSE the following valves:

4.11.29.1 CAV-436 (Return to RB Sump, Outside Containment Valve).

4.11.29.2 CAV-434 (Return to RB Sump, Inside Containment Valve).

O 4.12

.DEMIN WATER FLUSH AND SYSTEM SHUTDOWN AFTER SAMPLING THE RB SUMP FOR BORON AND/0R GAMMA ISOTOPIC ANALYSES 4.12.1 Close CAV-433.

4.12.2 Close CAV-435.

j 4.12.3 Place the following valve; in the indicated position:

NOTE:

These valves are operated from the Pass Analyzer Panel in the count room.

VALVE POSITION 4.'12.4 CAV-624 Closed 4.12.5 DWV-337 Open 4.12.6 CAV-471 Open 4.12.7 Start CAP-8.

EM-307 Rev. 21 Page 42

p 4.12.8 SLOWLY move the actuator switch on CAV-624 towards the open Q

position, while carefully monitorina the downstream flowrate on CA-74-FI, UNTIL the flow rate indicated on CA-74-FI is 0.35 to 0.5 GPM.

4.12.9 Allow the water to flush for 10 minutes.

4.12.10 IE a HI-HI level alarm occurs on CAT-8 (Drain tank) closing CAV-623 and stopping CAP-10, THEN perform 4.12.10.1 through 4.12.10.7 AND continue with 4.12.11.

4.12.10.1 Place CAP-10 switch to "0FF" position.

4.12.10.2 Place CAV-623 to the " CLOSED" position.

4.12.10.3 Press and hold " RESET" button on Drain Tank level indicator (keep

" HELD IN").

4.12.10.4 Turn CAP-10 switch to the "0N" position.

4.12.10.5 Hold " RESET" button "IN" until CAP-10 lowers Drain Tank level below "HI" level indicator / switch and "HI" level alarm light clears.

4.12.10.6 Place CAV-623 to the "0 PEN" position.

4.12.10.7 Place CAP-10 switch to the "AUT0" position.

NOTE:

A low liquid nitrogen level will automatically secure the high voltage supply to the detector.

Always lower the high voltage to zero volts before resetting the liquid nitrogen

monitor, l

4.12.11 Ensure the A.I.M.S. is in an operable condition by:

o Checking the liquid nitrogen monitor, o

Ensuring the high voltage supply to the detector is properly adjusted.

4.12.12 Sign on the VAX computer as Username:

PASS.

'l NOTE:

The < SELECT > option is designated by the PF1 key.

4.12.13

< SELECT > PASS Menu.

4.12.14 Answer "NO" to "Do you want a spectral display window?".(De;ault) 4.12.15

< SELECT > Flush Sample Lines.

EM-307 Rev. 21 Page 43

)

f-'s 4.12.16

< SELECT > Sump Demin Flush.

b 4.12.17 The collimator will move to the correct position and the system will begin to acquire a spectrum. Maximize MCA Display 1 and toggle thru ADC's until desired configuration is shown.

NOTE:

Step 4.12.18 cannot be performed from a remote terminal.

4.12.18 Use " ERASE" function on MCA Display to re-acquire spectrum.

4.12.19 If a high countrate is still indicated, JHEN continue flushing.

4.12.20 lE a low stable countrate is indicated, THEN:

4.12.20.1 Minimize MCA Display 1.

4.12.20.2 Press < RETURN >.

l 4.12.20.3 Press < QUIT >.

4.12.20.4 Sign off VAX computer by entering "LO".

/"')

4.12.21 If a grab sample was not performed, (m/

THEN go to step 4.12.23.

NOTE:

These valves are operate from the PASS Analyzer Panel in the Counting Room.

1 4.12.22 If a Grab Sample was performed, THEN:

4.12.22.1 Close CAV-447.

4.12.22.2 Open CAV-445.

4.12.22.3 Open CAV-446.

f 4.12.22.4 Continue flush for 5 minutes.

4.12.22.5 Close CAV-445.

4.12.22.6 Open CAV-446.

4.12.22.7 Go to step 4.8.9 to remove grab sampler.

7-~g 4.12.23 Close/ Check closed DWV-337.

\\s )

EM-307 Rev. 21 Page 44

a 4.12.24 Close/checkclosedCAV-471.

4.12.25 Close/ check closed CAV-519.

4.12.26 Close/ check closed CAV-447.

4.12.27 Close/ check closed CAV-623.

4.12.28 Close/ check closed CAV-624.

4.12.29 Close/ check closed CAV-625.

4.12.30 Close/ check closed CAV-626.

4.12.31 Turn off CAP-8.

NOTE:

The following containment isolation valves are operated from the Main Control Board.

4.12.32 Request operations CLOSE the following valves:

4.12.32.1 CAV-436 (Return to RB Sump, Outside Containment Valve).

4.12.32.2 CAV-434 (Return to RB Sump, Inside Containment Valve).

4.13 NOTIFICATIONS 4.13.1 All data accumulated per this procedure is to be summarized on and forwarded to the Emergency Coordinator via Chemistry Supervision on Enclosure 8.

4.13.2 All personnel leaving the general assembly area for the purpose of sampling the Reactor Coolant System per this procedure are to be listed on Enclosure 4 which is to be forwarded to the Emergency Coordinator.

O EM-307 Rev. 21 Page 45

m ALTERNATE CONTAINMENT ISOLATION SAMPLE VALVES Samole Alternate Valves CAV-434*

CAV-433*

~

~~

CAV-436*

CAV-435*

Note a crosstie valve CAV-500 (Intermediate Bldg. Elev. 95')

must be opened to utilize this crosstie.

CAV-431 CAV-432*

()CAV-126 CAV-429*

RCP 1A Disch.

CAV-430*

RCP 1C Disch.

CAV-126 CAV-001 PZR STM Space CAV-003 PZR Water Space

• NOTE:

Breaker is normally locked open.

O EM-307 Rev. 21 Page 46

I ION CHROMAT0 GRAPH REAGENTS ENCLOSURE 2 i

1.

0.025 N sulfuric acid (H SO ) Molecular weight 98.06g.

2 4 Pipet 700ul of concentrated H SO, into 500ml reagent grade water 2 4 and dilute to 1 liter, i

2.

Eluent #3 stock solution - [0.22 M sodium carbonate (Na,C0 )/0.075 M j

3 sodium bicarbonate (NaHCO )] Dissolve 6.30 g NaHCO and 23.3 g Na 00 3

3 2 3 in - 800 ml reagent grade water and dilute to the mark in a 1 liter volumetric flask.

3.

Eluent #3 - [0.0022 M sodium carbonate (Na HC0 )/0.00075 M sodium g

3 bicarbonate (NaHCO )] Pipet 10 ml of 0.22 M Na 00 /0.075 M NaHCO 1

3 2 3 3

eluent concentrate into a 1 liter volumetric flask and dilute to the mark with reagent grade water.

4.

Eluent #1 - [0.005 M sodium tetraborate (Na B 0fl0 H O)] For each 24 2

liter of eluent to be prepared dissolve 1.91 grams Na B 0/10 H 0 in 24 2

- 500 ml reagent grade water and dilute to the mark in a 1 liter volumetric flask.

5.

Calibration Standards (F~, Cl~, SO 2, etc.). All standards should 4

be prepared from commercially available aqueous stock solutions or s

from the sodium / salts of the anions of interest.

Some common stock solutions are prepared as follows:

Chloride - 0.165 g Nacl diluted to 11 is 100 ppm Cl.

)

Fluoride - 0.221 g NaF diluted to It is 100 ppm F~.

Sulfate - 0.148 g Na 50 diluted to 11 is 100 ppm S0 2 2 4 4

NOTE: Chloride & Fluoride standards should be prepared in glassware cleared in nitric acid and rinsed thoroughly in reagent grade water.

NOTE: Calibration Standard concentrations will be determined based on accident scenario.

l I

\\

(

EM-307 Rev. 21 Page 47

4 EM-307.

ENCLOSURE 3 P.A.S.S. DATA SHEET DATE:

TIME:

AIMS ANALYSIS O

O O

RCS, DH, RB Sump, MwS1 Samole Point:

Total Activity (uci/cc) from report above, if applicable Major Contributing Isotopes from report, if applicable:

uCi/cc, uCi/cc, uCi/ce, uCi/cc uCi/cc, uCi/cc, uCi/cc, uCi/cc 1

)

uCi/cc, uCi/cc, uCi/ce, uCi/cc Chemistry Analysis b

Baron ppm pH Chloride ppm 3 or fug O rotel cas cc/gg O

nyorogen cc C

0 0

0 0

0 0

0 SIGNATURE / TITLE l

EM-307 Rev. 21 Page 48

ENCLOSURE 4 U

POST-ACCIDENT SAMPLING 0F RCS. RB SUMP AND MWST.

EMERGENCY COORDINATOR NOTIFICATION

• List of Personnel Performing Entry For Sample Acquisition:

Name Title TLD#

Dose Marain 1.

2.

3.

4.

5.

Date/ Time of Entry (projection):

/

" Working Copy" of EM-307 available/ reviewed.

Initials i

Sample (s) to be collected (list) 1.

2.

3.

Applicable isolation valve breakers per Enclosure 7 energized.

Initials Sample Collection route discussed.

Initials Dose Limits / Radiological Conditions discussed.

Initials Communication Techniques discussed.

TSC Phone Number D

Radio check performed on Channel -

Initials

• To be completed prior to leaving the general assembly area.

For the purpose of sampling the Reactor Coolant System under EM-307.

To be completed by Nuclear Chemistry Supervisor or designee.

EM-307 Rev. 21 Page 49

ENCLOSVRE 5 RECOMMENDED SAMPLE FLUSH TIMES Samole Point

.25 aom Flow

.50 com Flow

• Reactor Coolant Letdown 2 hr, 56 min I hr, 28 min Reactor Coolant Loop A 8 min 4 min Reactor Coolant Loop B 12 min 6 min Reactor Building Sump 34 min 17 min Decay Heat 6 min 3 min Miscellaneous Waste Storage Tank 4 min 2 min Reactor Coolant Letdown 40 min 35 min PZR Water Space 10 min 5 min PZR STM Space 30 min 15 min AC)

• This sample flush time is based on zero letdown flow.

EM-307 Rev. 21 Page 50

ENCLOSURE 6 qO PRIMING THE ANALYTICAL PUMP OF THE DIONEX 2010 I.C.

1.

STOP the analytical pump.

2.

Insure the correct eluent selector switch has been energized.

3.

To the left of the analytical pump is a black block valve with a handle on top and a connector for a 50cc plastic syringe.

Connect a 50cc syringe to the block valve and align the valve handle to point down the length of the syringe.

l 4.

Slowly withdraw the syringe plunger. This should draw eluent from the eluent bottle into the syringe as well as air from the eluent supply line.

5.

Disconnect the syringe from the block valve and expel all air from the syringe.

Reconnect the syringe.

6.

Loosen the round black knob that covers the analytical pump outlet two full turns counterclockwise.

This opens the drain line from the pump.

7.

Depress the plunger on the syringe forcing the eluent into the pump.

It O

should flow thru the pump and to waste carrying the air from the pump with it.

8.

Tighten the cover knob to close the drain line and return the handle on the block valve to its normal position (perpendicular to the syringe).

Restart the pump.

If pressure will not stabilize repeat 7.8.1 through i

7.8.7 until all air is expelled from the pump.

l O

EM-307 Rev. 21 Page 51

ENCLOSURE 7 (Page 1 of 2) g,,/

MAIN POWER SUPP'LY'S FOR POST ACCIDENT SAMPLE / NOBLE GAS UPGRADE SYSTEMS Location Panel No.

Breaker No.

Power To 119' Aux Bldg.

MCC 3B1 8BR 37.5 KVA Transformer.

Elgar UPS & ACDP 59 119' Aux. Bldg.

ESMCC 3A2 6BR Pump WSP-1 95' Aux. Bldg.

ACDP-59 1

CMP RANGE Mimic Panel 95' Aux. Bldg.

ACDP-59 2

RMP PASS Mimic Panel 95' Aux. Bldg.

ACDP-59 3

AIMS PASS #1 Cabinet 95' Aux. Bldg.

ACDP-59 4

AIMS RANGE #2 Cabinet 95' Aux. Bldg.

ACDP-59 9

ABV Range Manifold 95' Aux. Bldg.

ACDP-59 10 RBV Range Manifold ACDP-59 11 Boron /pH/ Chloride O

95' Aux. Bldg.

Reagent Panel 95' Aux. Bldg.

ACDP-59 13 ISP Instrument Sensor Panel 95' Aux. Bldg.

ACDP-59 15 Sample Valve Relay Box 95' Aux. Bldg.

ACDP-59 16 Sample Room Exhaust Fan 95' Aux. Bldg.

ACDP-59 17 Main Junction Box (Computer AC TBI-7

& 8)

~

O EM-307 Rev. 21 Page 52

ENCLOSURE 7

()

(Page 2 of 2)

POST ACCIDENT SAMPLE / NOBLE GAS UPGRADE SYSTEMS Location Panel No.

Breaker No.

Power To 95' Aux. Bldg.

ACDP-59 18 Main Junction Box (TBI-7 & 8) 124-Control Complex DPDP-4B 11 0.C. power to non-Control Rod Drive Rm containment isolation valves operated by the PASS / Noble Gas MIMIC Panels 145' Main Control Rm ACDP-52 39 A.C. power to ABV, RBV (between Main Control Mid, High Range Panels)

Victooreen Monitors 124' Contrn' r.omplex DPDP-5A 27*

CAV-429, CAV-430, 480V Switc, 0 Rm.

CAV-433, CAV-434 124' Control Complex DPDP-5B 8*

CAV-435, CAV-436, 480V Switchgear Rm.

CAV-432 124' Control Complex DPDP-58 2

CAV-431 480V Switchgear Rm.

• NOTE:

These treakers are normally locked open.

O EM-307 Rev. 21 Page 53 i

i, e

EM-307 ENCLOSURE 8 T. S. C. DATA SHEET DATE:

TIME:

~

AIMS ANALYSIS RADIO CHECK: SAT UNSAT O

O on, O

O

RCS, Rs Sump, MwST Samole Point:

Total Activity (uCi/cc) from report above, if applicable Major Contributing Isotopes from report, if applicable:

uCi/cc, uCi/cc, uCi/cc, uCi/cc uCi/cc uCi/cc, uCi/cc, uCi/cc, uCi/cc, uCi/cc, uCi/cc, uCi/cc O

Chemistry Analysis O

goron O

O cnior3ee ppm pg ppm b

otal Gas cc/kg b b

Hydrogen

% or cc/kg T

O O

O O

O O

O O

O O

EM-307 Rev. 21 Page 54 J

o SP4400 INTEGRATOR PASS CALIBRATION FILE EXAMPLE MN = 5.

REM FE-2.

CH= "A" PS=

1.

NM

= " PASS "

PW

= 6.

PT

= 5000.

RN

= 1.

IX

= 12.

00

= 1.

PH

=1 TB

= 0.

CW

= 0.1 CZ

= 1.

EC

= 1.

LC

= 0.

LS

= 0.

NV

= 0.

SI

-0 RC

=0 CI

= 254 SP

8 TT(1)

0.01 TF(l)="PM" TV(1)=

1.

TT(2)=

0.01 TF(2)="II" TV(2)=

1.

TT(3)=

1.75 TF(3)="AZ" TV(3)=

1.

TT(4)=

4 TF(4)="II" TV(4)=

0.

TT(5)=

6 TF(5)="ER" TV(5)=

1.

(

RT(1)=

4.58 CN(1)=" CHLOR" CM(1)= "IDE RF(l)=8651.

CU(1)= " PPB CV

=

l 5

i EM-307 Rev. 21 Page 55 j

u

(s ENCLOSURE 10 t\\

4270 INTEGRATOR PASS CALIBRATION FILE EXAMPLE MN = 5.

REM FE-3.

CH "A"

PS-1.

" PASS "

NM(1)= "CALIB" NM(2)= " RATIO" NM NM(3)

"N PW

= 6.

PT

- 3000.

RN

= 1.

IX

- 2.

OD

- 1.

PH

- 0.

TB

- 0.

CW

- 0.1 CZ

- 1.

LS

- 0.

NV

- O.

SI

- 0.

RC

- 0.

TT(1)-

0.01 TF(1)="PM" TV(1)=

1.

TT(2)=

0.1 TF(2)="AZ" TV(2)-

1.

TT(3)=

6.

TF(3) "ER" TV(3)=

1.

RT(1)=

4.6 CN(1) " CHLOR" CM(1)

"IDE RF(l)=19960.

"CHEMI" AN(1)= "STRY "

AN(2)= " TECH AN

=

CU(1)

" PPB CU 1

O EM-307 Rev. 21 Page 56 (LAST PAGE)

1 Los Alamos WBS 1.2.e.1.1, 1.2.3.9.7 Los Alamos National Laboratory "QA N/A" 101 Convention Center Drive, Suite 820 Las Vegas, NV 89109 OmOMn Um LA-EES-13-LV-05-94-011 Page 1 of 5 May 9, 1994 702/794-7095 M/S 527 TO:

S.

B.

Jones, DOE /YMSCO W.

B.

Simecka, DOE /YMSCO FROM:

R.

D.

Oliver, LANL

SUBJECT:

EXPLORATORY STUDIES FACILITY TESTING ACTIVITIES -

5" APRIL 1994 - MONTHLY PROGRESS REPORT (SCPB: N/A) kN m

GUNERAL EXPLORATORY STUD.IES FACILITY ACTIVITILS

' M, TEST PROGRAM: EXECUTIVE

SUMMARY

Cleaning and logging activities continued in the long radial boreholes in Test Alcove #1.

The completion of drilling operations for the Large Block Tests and the continuation of construction at the Exploratory Studies Facility (ESF) North Portal Pad was alco conducted in April.

Other Job Package (JP) activities invo?.ved Sandia National Laboratories' (SNL) Field Team with Construction Monitoring.

The Test Planning Package (TPP), JP, and Work Package (WP) for the Radial Borehole Test are in review.

Comments have been received from the U.S. Geological Survey (USGS) which represent new test support requirements (instrument-grade power and 0.01 micron filtration on compressed air for testing).

Additional planning information will be required from the USGS in order to define implementation options and associated costs; this process may delay test implementation.

Scheduled progress consistent with the ESF Design is illustrated in Attachment 1.

INITIATIVES Preliminary results from the Core Packaging study are being analyzed to determine general trends.

Some problem areas have already been identified and addressed.

A visit to the Test Coordination Office (TCO) by Dr. Claude Degueldre was sponsored by Alan Mitchell.

Dr. Degueldre presented a discussion regarding

" Colloid Transport at Yucca Mountain."

FIELD ACTIVITIES Field Activities are detailed in appendices attached to this report..

Each of the appendices contains a description of the I

progress in milestones and deliverables, a summary of field n

activities, a brief description of the manner of data flow, 6

flh

'll l

d# j) tGutou t

9406070272 940509 PDR WASTE WM-11 PDR I

4 4

S.

Jones, W.

Simecka, DOE /YMSCO LA-EES-13-LV-05-94-011 MONTHLY PROGRESS REPORT Page 2 of 5 May 9, 1993 and a schedule.

When pertinent, additional graphic information is provided to illustrate progress or concerns.

JNTEGRATED DATA SYSTEM (IDS)

Work continues on identifying and evaluating the various possible approaches to meet the principal investigators' data acquisition needs in a timely and cost effective mannar.

The evaluation of the ramifications of the recent decision to combine the present IDS functions with the Control System (CS) functions in a new system called the Integrated Data / Control System (ID/CS) began this month.

The TCO continued to provide input and assistance to Civilian Radioactive Waste Management Syctem & Operating (CRWMS M&O) Contractor IDS Design team in their preparation of ID/CS Design requirements document this month.

ENVIRONMENTAL. SAF.ETL_AND HEALTH (ES&H) ACTIVITIES The ESF Safety Coordinator prepared the mid-year status and review of safety budget WBS 1.2.6 and 1.2.13, and it was submitted to the U.S.

Department of Energy (DOE).

The ESF Safety coordinator conducted the April general safety meeting.

A report on ' miles driven per accident' from Los Alamos National Laboratory (LANL) was submitted to DOE.

Tracer water used underground by Reynolds Electrical &

Engineering Company, Inc. (REECo) for April totaled 10.7 kiloliters (2,835 gallons), showing a total usage of 1,752.6 kiloliters (462,985 gallons).

SITE CONSTRUCTION JOB PACKAGE (JP) 92-20 ESF NORTH PORTAL PAD AND FACILITIES Construction at the ESF continued this month with REECo preparing the ESF for construction of the concrete invert and launch chamber.

The radon monitoring in Test Alcove #1 by Science Applications International Corporation (SAIC) was completed.

REECo and CRWMS M&O completed pull-tests of various types of rockbolts and grouts in the starter tunnel.

An inspection of the highwall and tunnel by representatives from the CRWMS M&O, LANL, SNL, and REECo found conditions consistent with previous inspections.

SNL installed an additional set of convergence pins in the Starter Tunnel, located approximately 11.6 meters (38 ft) from the entrance, to monitor some small cracks in the fibercrete.

4 9

S.

Jones, W.

Simecka, DOE /YMSCO LA-EES-13-LV-05-94-011 MONTHLY PROGRESS REPORT Page 3 of 5 May 9, 1993 Appendix I -

Geologic Mapping of the ESF (JP 92-20A)

Appendix II -

Perched Water Testing in the ESF (JP 92-20B)

Appendix III - Consolidated Sampling in the ESF (JP 92-20C)

Appendix IV -

Construction Monitoring in the ESF (JP 92-20D)

Appendix V -

Engineered Barrier - Fran Ridge Large Block Experiment (JP 93-10)

Appendix VI -

Hydrochemistry (JP 92-20E)

ADMINISTRATIVE SCHEDULE AND

SUMMARY

TABLE Table I identifies the field activities in progress at the ESF.

The Administrative Schedule (Attachment 1) is based on information provided by the ESF Design Team.

IABLE I ESF Testing Field Activity North Ramp Starter Tunnel Z Z (;

cs O -

SCP PfiGJRAM N AME SGPJTJDY NME SCP $3JDY TEST _NAME_(SGP WLIS LCO__ TEST _EVENI TPE!

JP.!

NZ mhh m

ELAN ACTWITY)

Et.EMENT N_A_ M E NUMBER pr Rock Characteristic Characterization of 8.3.1.4.2.2 underground Geologic 1.2.3.2.2.1.2 Geologic Mapping -

TPP JP MG Program Structural Features in the Mapping ESF 92-10 92-20A

[

[

Site Area wy Geohydrology Characterization of Yucca 8.3.1.2.2.4 Perched Water Testing 1.2.3.3.1.2.4 Perched Water -

TPP JP AO:

Program,

Mountain Unsaturated-in the ESF (Contingency) 92-11 92-208 O'

h (7 Zone in the ESF Hydrochemistry Tests 1.2.3.3.1.2.4 Hydrochemistry TPP JP u) >

In the ESF Testing 92-12 92 20E fn ?

n

$h Radial Borehole Tests 1.2.3.3.1.2.4 Radial Borehole TPP JP in the ESF Testing 92-13 92-20F tc Thermeiand in Situ Design Verification 8.3.1.15.1.8 Evaluation of Mining 1.2.4.2.1.1.4 Construction TPP JP Mechanical Rock Methods Monitoring - ESF T-93-2 92-200

,.3 t Propertt?s Program

(

Monitoring of Ground 1.2.4.2.1.1.4 P

Support Systems y

Geochemistry Water Movement Test 8.3.1.2.2.2 Chloride and Chlorine-36 1.2.3.3.1.2.2 Consolidated TPP JP Program Measurements of Sampling -

92-14 92-20C tf Percolation at Yucca ESF

[

Mountain Study Plan for History of 8.3.1.3.2.2 History of Mineralogic 1.2.3.2.1.1.2 l

Mineralogic Alteration of and Geochemical Yucca Mountain Alteration of Yucca Mountain Study Plan for Mineralogy, 8.3.1.3.2.1 Mineral Distributions 1.2.3.2.1.1.1 Petrology, and Chemistry of Between Host Rock Transport Pathways and Accessible

[h Environment m.

Study Plan for Mineralogy, 8.3.1.3.2.1 Fracture Mineralogy 1.2.3.2.1.1.1 01:

Petrology, and Chemistry of 3[

Transport Pathways I

i Reposikry Horizon Engineered Barrier System 8.3.4.2.4.4 Repository Horizon Rock-1.2.2.2.4

' Engineered Barrier-NA JP O&

Rock-Wa'er Field Tests Water Interaction Fran Ridge Large 93-10 Interaction Large Block Block Emperiment W t-LEnperiment r

3

(:

0

/

t

(

h I

S.

Jones, W.

Simecka, DOE /YMSCO LA-EES-13-LV-05-94-011 MONTFLY P ROGRESS REPORT Page 5 of 5 May 9, 3FS4 ISSUES: lione Attachm. ants " Limited value Material" RDO:MKL:dm14 Cy:

,W.

J.

Boyle, DOE /YMSCO, MS 523 R.

A.

Crawley, DOE /YMSCO, MS 523 J.

R.

Dyer, DOE /YMSCO, MS 523 V.

F.

Iorii, DOE /YMSCO, MS 523 E. H.

Petrie, DOE /YMSCO, MS 523 K.

J.

Skipper, DOE /YMSCO, MS 523 M.

W.

Smith, DOE /YMSCO, MS 523 D.

P.

Stucker, DOE /YMSCO, MS 523 R.

S.

Waters, DOE /YMSCO, MS 523 R.

J. White, DOE /YMSCO, MS 523 D. R. Williams, DOE /YMSCO, MS 523 W.

A. Girdley, DOE /FOC, MS 717 W. A.

Wilson, DOE /FOC, MS 717 W.

C.

Kopatich, RSN, MS 403 E.

L.

Wright, RSN, MS 403 B.

R. Gardella, REECo, MS 408 R.

C.

Mcdonald, CRWMS M&O, MS 423 R.

W.

Craig, USGS/LV, MS 509 D.

L.

Edwards, USGS/LV, MS 509 L.

R.

Hayes, USGS, Denver, CO M.

D. Voegele, SAIC, MS 517 D.

S.

Kessel, SNL/LV, MS 509 L.

E. Shephard, SNL, Dept. 6302, Albuquerque, NM J.

A.

Blink, LLNL/LV, MS 465 W.

L.

Clarke, LLNL, Livermore, CA J.

A.

Canepa, LANL, EES-13, MS J521 D.

M.

Boak, LANL, EES-13/LV, MS 527 N.

Z.

Elkins, LANL, EES-13/LV, MS 527 E.

F.

Homuth, LANL, EES-13/LV, MS 527 K.

L.

Kinter, LANL, EES-13/LV, MS 527 M.

L.

Lawson, LANL, EES-13/LV, MS 527 A.

J.

Mitchell, LANL, EES-13/LV, MS 527 D.

J.

Weaver, LANL, EES-13/LV, MS 527 l

J.

H.

Berry, LANL/FOC, MS 735 R.

G.

Kovach, LANL/FOC, MS 735 EES-13/LV, LANL, MS 527 l

8

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Appendix I Page 1 of 2 j

GEOLOGIC MAPPING OF THE ESF PROGRESS - MILESTONES AND DELIVERABLES The geologic mapping data collection activity started with starter tunnel. construction.

SUMMARY

OF FIELD ACTIVITIES No geologic mapping-took place this month.

DATA FLOW INFORMATION Analysis of geologic mapping field data by investigating organizations is ongoing.

The information from the Starter Tunnel and Test Alcove #1 is being processed, and has been shared with the constructor, facility design teams, and construction management.

SCHEDULE

SUMMARY

The costs and progress estimates on this activity are within the scope set by JP 92-20A.

SCP PROGRAM SCP STUDY NAME SCP STUDY TEST NAME

))Tj!

jf,!

NAME PIAN

{$ft NUMBER ETIVITY)

Rcx L Charactenstic Characteritationof Structural 8.3.1.4.2.2 Underground TPP JP Prograrn Features in tie Site Area Geologic 92-10 92 20A Mapping

.T c

Geologic Mapping (TPP 92-10/JP 92-20A)

Field Activity Working Schedule LANL ESF Test Coordination Office 3

O2'93 0393 04'93 O1 34 O2 94 ! C394 ff AlMlJJlAlSOlNlDJ}FjMA{MjJlJlAlSlOj ID Name Dur Stad Summary Acct.

M l

I' l

1 GEOLOGIC MAPPING 1923d 4!5/93 4

L l

j l

j 2

6 I

y yl j

j 3

STARTER TUNNEL 181d 4/5/93 4

Test implementation - Discrete 151d 4!5/93 t

y y

j i

10 Test implementation - Matrix Support 181d 4/5/93 yj j

l y

f.

p ),

17 STARTER TUNNEL ALCOVE 31d 11/1/93 j

l p

l l

18 Test implementation - Discrete 31d 11/1/93 lp j

j j

23 Test implementation - Matrix Support 31d 11/1/93 l

f, l

30 RAMPS & MAIN 1573d

&S/94 y

! l l

l 7._s;. ]

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31 Test implementation - D!screte 1573d

&%94 32 USGS/USBR Test implementation (*1) 1573d 8/8/94 OG32212D93 l

l l,

h ha.h

_a 33 RSN Field Survey & Processing 1573d 8394 RS3522N4 j

j y,g;

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34 REECo Test Construct!on & Procurement 1573d

&B94 OR32212L4 l

t; l

l L-35 JC Photography & Process 1573d 8.B/94 OP355L94 e

+ - - --m i

36 Test implementation - Matrix Support 1573d 8/8/94 l

l 7

+-!

w y

37 Los Alamos TCO Coordination & Planning (Field Test Coordination Support) 1573d

&S94 OA310BL4 l

l l gw 38 Los Alamos TCO Test Management (Project Engineer Support) 1573d 8394 OA616AL4 l

l g.,

y l

39 T& MSS Direct Support Services (Photo Support) 1573d 8/8/94 OT3522EL g

40 REECo Construction & Operations Support 1573d 8394 OR682L4 g;g l

j j

l ya 41 RSN Survey Support / Capita! Procurement (Interim WBS) 1573d 8394 RS614P94 g

l l

l l

42 CRWMS M&O Networking & Baseline Planning Support (Network & Progress Rpts.)

1573d 8394 TR921CA1 g,,

_4

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& (,,,

w<

% CrPP S2-10UP g2M m

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.. m Date:4/30,94 Rosed Up O

ava o div Revision #1 Nonaecal

- 44r4 CWA Westone T9210TI.MPP ADMINISTRATIVE USE ONLY e

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Appendix II

.l Page 1 of 2 i

1 PERCHED WATER TESTING IN THE ESF PROGRESS - MILESTONES AND DELIVERABLES The ESF perched water data collection contingency activity began with starter tunnel construction.

SUMMARY

OF FIELD ACTIVITIES Moisture was observed on the drill string during cleaning of the lower right hole in Test Alcove #1.

The USGS was contacted.

After evaluating the situation, it was determined that the moisture was due to higher than normal humidity resulting in condensation on the drill string.

Consequently, no water or samples were collected during the period.

Equipment to collect samples, if identified, is on station.

DATA FLOW INFORMATION Perched water sample data and observances will be recorded in a scientific notebook if encountered.

SCHEDULE SUMIRRY The costs and progress estimates on this activity are within the scope set by JP 92-20B.

SCP PROGRAM SCP S11!DY N AME SCP ST11DY TEST NAME IIf,!

R!

M MI, ELAN 11 2

~

NUMBER ACTIVITY)

Crohydmkyy 1%grarn Characterizationof Yuma 8.3.1.2.2.4 Perchx1 Water IPP JP Mountain Unsaturated-2kmc in the Testing in the 9211 92-208 ESF ESF i

i l

1

-l I

l l

Perch:d Water (TPP 92-11/JP 92-208)

~

l Field Activity Working Schedule LANL ESF Test Coordination Office 2 93 03 33 04'93 01 34 02 94 0394 04 94 01' 10 Name Dur Start Summary Acct. MlJ JlAlS OlNjD JIFlM A MlJ JjAlS OlNID JjF 1

PERCHED WATER 1893d 5/1&S3 l

l j

l I

t l

l 3

STARTER TUNNEL 197d S/1653 gy y

4 Test implementation - Discrete 121d S/16/93 y

y l

l

'y l

, y j

j l

6 Test Implementation - Matrix Support 197d 5/16/93 4-13 STARTER TUNNEL ALCOVE 84d 11/183 y

y l

14 Test implementation - Discrete 84d 11/1/93 y

9 y

{

16 Test implementation - Matrix Support 84d 11/1/93 y

y l

23 RAMPS & MAIN 1573d 8/8/94 y

24 Test implementation - Discrete 1573d 8/8S4 l

y 25 USGS Test iniplementation 1573d aB94 OG33124G94 l

gp ;

,gu, j.

26 Test implementation - Matrix Support 1573d 8/854 l

y

~

27 Los Alamos TCO Coordination & Planning (Fletd Test Coordination Support) 1573d 8394 OA3978L4 t -. s.1, 28 Los Alamos TCO Test Management (Project Engineer Support) 1573d 8/8/94 OA616AL4 l pt - r_mn 29 T& MSS Direct Support Services (Photo Support) 1573d 8/8/94 OT3522EL l

L q. mq.,, 4.j

[

30 REECo Construction & Operations Support (Contingency)-(*1) 1573d 8894 OR682L4 pg;mgm 31 RSN ESF Test Support 1573d 8394 RS3522N4 p.m _ raw

,.3 ll 32 CRWMS M&O Project Control Support 1573d 8/B/94 TR921CA1 g g y r:-

,,a

• i Pm6mc1 Perched Weene (TPP st.t WP R208) gg

~--...-..,

g,,g Cw,g y Date:4/3G94 Revision #1 Nonenecei

' M ':

• W '

Milestone Rosed Up O

• + aim T9211TLMPP ADMINISTRATIVE USE ONLY

~.

Appendix III Page 1 of 2 CONSOLIDATED SAMPLING IN THE ESF PROGRESS - MILESTONES AND DELIVERABLES The consolidated sampling data collection and observation activity began when the starter tunnel construction exposed suitable rock.

The TPP'and JP for consolidated sampling were revised during October.

SUMMARY

OF FIELD ACTIVITIES No consolidated sampling took place this month.

Work continues on assembling Field Document and Records Center files for activities conducted in the ESF.

This effort includes the maintenance of an administrative data base that identifies sample locations and their corresponding photo identifiers.

DATA FLOW INFORMATION Consolidated sampling data and sample collection activities are controlled by the JP Document and Records Center files, scientific notebooks, AP-6.260, sample collection report records and bar codes.

Test-related photo and survey mission data is being submitted to the JP record file and the Principal Investigators (PIs).

SCHEDULE

SUMMARY

The costs and progress estimates on this activity are within the scope set by JP 92-20C.

SCP PROGR AM SCP STUDY NAME SCP STUDY TEST NAME TPP#

IP_#

NAME PLAN

@Cf NUMBER ACTIVITY)

Geochemistry Water Mosement Tests 83.1.2.2.2 Consolidated TPP JP Program Sempting in the 92 14 92 20C Characterization of the Yucca 83.1.2.2.3 ESF Mountain Unsaturated-Zone Percolation

[

Study Plan for Illstory of 83.13.2.2 Mineralogic Alteration of Yucca Mountain

,..-.r

Consolidated Sampling (TPP 92-14/JP 92-20C)

Field Activity Working Schedule LANL ESF Test Coordination Office 2 93 0393 04 93 01 94 O2 94 03 94 04' ID Name Dur Start Summary Acet. MlJ JlAlS OjNID JlFlM A U[J JlAlS OlN 1

CONSOLIDATED SAMPLING 1888d 5,24/93 i

l l

r i~_

2 P

I i

l l

1

)

y y

l

{

3 STARTER TUNNEL 116d 5/24/93 4

Test implementation - Discrete 116d 5/24/93 y

y j

9 i

13 Test implementation - Matrix Support 101d 6/13/93 y

y j

y l j

22 STARTER TUNNEL ALCOVE 84d 11/1/93 j

y 23 Test implementation - Discrete 84d 11/1/93 j

y y

y y l l

28 Test implementation - Matrix Support 84d 11/1/93 l

l l

ly 37 RAMPS & MAIN 1573d 8/8/94 a

38 Test implementation - Discrete 1573d 8/8/94 i

j l

i y

J m

39 USGSAJSBR Structural Features 1573d, EB/94 OG32212D94 j

j

g. a._,

l ggg 40 History of Mineralogic & Geochemical Afteraton at YM 1573d 8394 OA32112CB4 41 RSN Field Survey & Processing 1573d 8/a94 RS3522N4 y,,

,.,g l

{

j mg 42 REECo Test Construction & Procurement 1573d aB94 OR644L4 43 T& MSS Photography & Process 1573d 8394 OT761EL

{

l j

i w _.

m_

f j

j y 44 Test implementation - Matrix Support 1573d 8/8/94

{

j u.,4 45 Los Alamos TCO Coordination & Planning (Field Test Coordination Support) 1573d 8/8/94 OA397BL4 l

46 Los Alamos TCO Test Management (Project Engineer Support) 1573d aB94 OA616AL4 t

m _;cy f

l 47 T& MSS Direct Support Services EDD 1573d 8394 OT3522EL wg y l

l l

48 T& MSS Sample Management Facility 1573d

&B94 OT351EL t =__

f l

l 6..n;,, a 49 REECo Construction & Operations Support (Interim WBS) 1573d EB/94 OR662L3 50 Engineering Survey Support / Survey Processing (Interim WBS) 1573d 8/a94 RS3522N4

} '

j mw 51 CRWMS M&O Networking & Baseline Planning Support (Monthly Cost & Progress Rpt:

1573d EB94 TR921CA1 pm

!t 52 JC Photography & Process (Interim WBS) 1573d aB94 OP3522L94 l

g_m, : q_ y WL Pee,m Ceceameed $% (rPP medP W 20C) m

-jg3 C Progress summary y

y Checked by:

^

Date: 4/30/94 Revision #1 Noncrecal 6 19# " A

• Westone RAed up O acae der T9214TI.MPP ADMINISTRATIVE USE ONLY '

Appendix IV Page 1 of 2 CONSTRUCTION MONITORING IN THE ESF PROGRESS - MILESTONES AND DELIVERABLES The construction monitoring data collection and observation activity began with starter tunnel construction.

SUMMARY

OF FIELD ACTIVITIES The SNL Field Team monitored the Multipoint Borehole Extensometer gauges and convergence pins located in Test Alcove #1 and the main ESF.

Readings for rockbolt load cells located in the ESF were also recorded.

DATA FLOW INFORMATION Construction monitoring data was recorded in a scientific notebook.

Test-related photo and survey mission data is being submitted to the JP record file and the PIs.

SCHEDULE

SUMMARY

The costs and progress estimates on this activity are within the scope set by JP 92-20D.

Illustrations are provided to show progress and test status.

SCP PROGLA3J SCP STUDY N A51E SCP STUDY IESLNAMF; Ill,#

JP!

NAME PIAN GG NUStilER ACTIVITY)

Thermal and in Situ Design Verification 8.3.1.1.5.13 Construction TPP JP Mechanical Roth Monitoring in T-93-2 92 20D--

Properties Program the ESF l

Construction Monitoring (TPP 93-2/JP 92-20D)

Field Activity Working Schedule LANL ESF Test Coordination Office 2 93 03'93 04'93 Q194 j O2 94 03 94 l 04

• tD (Jarne Dur Start Summary Acct. MlJ JlAIS OlNl0 JlFIMiA MlJ JlAlSIOlN 1

CONSTRUCTION MONITORING 1883d 5/31!93 l

j 2

r i

3 STARTER TUNNEL 111d 5f30/93 y

y 4

Test Implementation - Discrete 111d 5/30/93 y

y

{

l 8

Test implementation - Matrix Support 111d 5/30/93 y

y l

{

y 3y f 16 STARTER TUNNEL ALCOVE 140d 11/1/93 i

17 Test implementation - Discrete 140d 11/1/93 y

.y 22 Test Implementation - Matrix Support 36d 11/1/93 l

l y

30 RAMPS & MAIN 1573d 8/8/94 31 Test imoternertation - Discrete 1573d 8/8/94

{

y g

32 SNL Test implementation 1573d 8894 OS42114L93 I

l w,..,_j 33 RSN Field Survey & Processing 1573d 8,E94 RS3522N4 l

m7;.z l

l f

j g,.. _

34 REECo Test Construction & Procurement 1573d 8894 OR42114L3 l

l ggy 35 Monitoring & Data Collection 1573d 8894 OS42114L93

- -1 36 Test implementation - Matrix Support 1573d 8/8/94 l

l

y 37 Los Alamos TCO Coordination & Planning (Field Test Coordination Support) 1573d 8394 OA310BL3 i

en.

1 I

l l

j y.

38 Los Alamos TCO Test Management (Project Engineer Support) 1573d BB/94 OA616AL3 gc_.

1 a

39 T& MSS Direct Support Services (Photo Support) 1573d 8094 OT3522DL i

! gwp i

40 REECo Construction & Operations Support (Contingency)- (*1) 1573d 8894 OR682L3 l

! t sqg 41 RSN Survey Support / Survey Procarement (Contingency) 1573d 8394 RS614P92 j

fg l

l l

42 Engineering Verification 1573d 8894 RS614P92 m.3 ;_.

l l

l g g.:

43 CRWMS M&O Networking & Baseline Planning Support (Monthly Cost & Progress Rpt:

1573d 8394 TR9228A

• s N4 gg Date:4/30,94 Rded up O apa-a

• Revision #1 Noncrecal Westme T932TI.MPP ADMINISTRATIVE USE ONLY

Appendix V Page 1 of 4 ENGINEERED BARRIER-FRAN RIDGE LARGE BLOCK EXPERIMENT PROGRESS - MILESTONES AND DELIVERABLES The Engineered Barrier - Large Block Experiment Site Preparation activity began with site cleaning and selection activities.

The Level III milestone MOL67 " Complete Saw Cuts" (Isolation Saw Cuts) was completed on February 25, 1994.

SUMMARY

OF FIELD ACTIVITIES REECo completed drilling 30 holes, 2 meters (6 ft) deep for the rockbolt pull-tests; ten of the holes were grouted with HLN(cc) grout, ten holes with Wil-X grout and the final ten holes were grouted with Sika grout.

Pull-testing of the rockbolts commenced and the early results showed that the HLN(cc) grout had a strength well below the other two.

The pull-testing of the HLN(cc) rockbolts was discontinued; the pull-testing of the other bolts will be completed early next month.

REECo also grouted selected holes in the large block to fill fractures discovered during the logging of the holes.

The grouting and redrilling of the holes has been completed.

REECo lengthened four holes on the perimeter of the block by 1.5 meters (5 ft) to allow the installation of anchors to put the block in compression subsequent to commencing excavation.

REECo completed drilling the presplit (horseshoe) holes around the large block, approximately 120 holes were drilled.

These holes will help facilitate future sample collection.

Raytheon Services Nevada (RSN) surveyed all the instrument, holes on the large block, as well as the four holes drilled at the dye test area, i

REECo completed installing wood forms around the top of the large I

block and 3000 pounds per square inch (PSI) concrete was poured on top of the block.

The concrete was to level the block in preparation for putting the block under compression prior to excavating the rock around the block.

The installation of the grouted rockbolts and the construction of the frame has been completed.

A 65 kilowatt generator was placed next to the existing REECo generator and the Lawrence Livermore National Laboratory (LLNL) trailer was modified to accept the 208 volts output of the new generator.

i DATA FLOW INFORMATION Permeability measurements in the vertical boreholes was completed and the results entered into the scientific notebook, SCHEDULE

SUMMARY

See attached illustrations for detailed schedule information.

SCP PROGRANI SCP STl'IW N A NIE SCP SntDY TEST NAN 1E TPP#

ll' #

hut 0 ELAN

[Kl*

NUN 1HER ACTIVITY)

Repmttwy H.mam large Bktk Experirnmt 8.3.42.44 Enginected NA JP 93-10 R<si-Water Interactkm Bamer-Fran large Bksk Exprinent Ridge large Bktk Experment l

l

Engineered Barrier-Large Block Experim nt (JP 93-10)

Field Activity Working Schedule Los Alamos National Lab 2 93 03'93 04'93 Q194 02 94 03 94 04*

10 Name Dur Start Summary Acct.

M1J JlAlS OlNlD JlF[M AlMlJ JlAlS O]N.

1 PHASE I-SITE PREPARATION - EB LRG. BLOCK TEST (JP 93-10) 219d 8/29/93 l

7; y

j 2

Site Preparation - Discrete 219d 8/29/93 y

y 3

LLNL Sca Preparation Monitoring 219d 8/30/93 OL224HZA y

4 RSN Field Survey & Processing 219d 8/29.93 RS224A94 p

5 REECo Test Construction & Procurement 219d

&"30.93 OR224(TBD)

~

6 Construction implementation - Matrix Support Elements 219d 8/30/93 y

y 7

Los Alamos TCO Coord. & Planning (Field Test Coord) 219d 8/30/93 OA397CL4 gg j

p 8

Los Alamos TCO Test Mgt. (Project Engineer Support) 219d 8/3093 OA616AL4 gg

. - ~

9 T& MSS Sample Management Facility 124d 1/1094 OT351EL l

~ ~ '

10 REECo Construction & Operations Support - Interim WBS 219d 8/30/93 OR682LH 11 Engineering & Survey Support / Survey Processing - Interim WBS 219d 8/3G93 TR614CAFI

_gg l

12 CRWMS M&O Network & Baseline Plan Support (Mo Cost / Progress Rpt) 219d 8/30/93 TR921BA1 13 JC Photo & Processing 114d 1/24/94 OP3522L94 m 4.gg 14 PHASE II-TEST CONSTRUCTION - EB LRG. BLOCK TEST (JP 93-10A) 164d 3/1/94 y

y 15 Test Construction - Discrete 162d 3/1/94 y;

16 LLNL Test Construction 162d 3/1/94 OL224HZA 17 RSN Fdd Engineenng & Survey 162d 3/1/94 RS224A94 eg, p. A 18 REECo Test Construction & Procurement 162d 3/1/94 OR224(TBD) 19 Test Construction - Matrix Support Elements 164d 3/1/94 y

y 20 Los Alamos TCO Coord. & Planning (Field Test Coord) 162d 3/1/94 OA397CL4 M

21 Los Alamos TCO Test Mgt. (Project Engineer Support) 162d 3/1/94 OA616AL4 pug a g 22 T& MSS Sample Management Facility 20d 9/19.94 OT351EL Q

23 CRWMS M&O Network & Baseline Plan Support (g Cost / Progress Rpt) 162d 3/1/94 TR921BA1 l

g 24 JC Phom & Processing 10d 10G94 OP3522L94

]

crocad Progrees summary y

y Checked ty k

Rosed up O

• = ed iv Revision #1 Noncnacal

• - -i "

"-[

Westone T93LBT94.MPP ADMINISTRATIVE USE ONLY

Appendix VI Page 1 of 3 i

HYDEQfHEMLSTRY TESTS IN THE ESF l

l PROGRESS - MILESTONES AND DELIVERABLES 1

The Hydrochemistry Tests in Alcove #1 began in September and will run though October of 1994.

The TCO will submit weekly activity reports to the Field Test Coordinator (FTC) and monthly data collection status reports.

SUMMARY

OF FIELD ACTIVITIES The USGS completed a log of the upper and lower holes using a

~

television camera / video recorder.

The first run to clean out the lower right hole was accomplished.

As the drill string was being removed from the hole, it was noted that the pipe was " wet" in various locations from approximately 6 meters (20 ft) to 20 meters (65 ft).

The following day, the USGS completed running a television I

camera to approximately 29 meters (90 ft) in the lower right hole l

where some rubble was encountered, but no indication of moisture.

The camera was pulled out of the hole and the hole was cleaned.

The cuttings removed from the cleaning did not indicate any moisture, and the drill string did not show any moisture.

It was then determined the drill string was cold, the air humidity was high, and the hole was warm from being closed in, resulting in condensation on the drill string.

DATA FLOW INFORMATION All field issues affecting data collection shall be brought to the attention of the LANL Field Test Representative (LANL FTR).

The Sample Management Facility (SMF) will submit all records called for in AP-6.260 or associated procedures, such as sample collection forms and records documenting visual core recording techniques (video, etc.) to the LANL FTR.

The TCO will submit a close out report under this JP.

COST AND SCHEDULE

SUMMARY

The costs and progress estimates on this activity are within the scope set by JP 92-20E.

Illustrations are provided to show progress and test status.

SCE_IAQGLMi_H M SCP_SIUDLHAME SIF._SI M IISI hm IER_t JP_ i 21,AK

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