ML20195J949
| ML20195J949 | |
| Person / Time | |
|---|---|
| Site: | Crane  |
| Issue date: | 06/08/1988 |
| From: | Richfeld S GENERAL PUBLIC UTILITIES CORP. |
| To: | |
| Shared Package | |
| ML20195J948 | List: |
| References | |
| SD-3526-004, SD-3526-004-R06, SD-3526-4, SD-3526-4-R6, NUDOCS 8806290293 | |
| Download: ML20195J949 (92) | |
Text
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ISSUE DATE June 1988 G lis D Non-O Hli 8 DIVISION SYSTEM DESCRIPTION FOR Auxiliary Buildinq Emermncy 2L'iquid Clean-up System (EPICOR II) 6-6 %
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OF 92 880.'3290293 880622 PDR ADOCK 05000320 P
i ES MI 3526-004 Title System Description for Page 2 of 92 Auxiliary Building Emergency Liquid Clean-up System (EPICOR II)'
Rev.
SUMMARY
OF CHANGE Approval Date 0
Initial issue per GPU Nuclear letter 4410-82-L-0017, 2/82 1
Updated per GPU tluclear letter 4410-83-L-0078.
4/83 2
Updated per GPU tluclear letter 4410-04-L-0023.
h 2/84 "h
4/85 3
Updated per GPU Nuclear letter 4410-85-L-0074.
Incor-porated ECM 3475.8, Revision 8.
4 Updated per GPU Nuclear letter 4410-86-L-0069.
p 4/86 5/87 5
Annual update to reflect the current operating configura-tion of the EPICOR II system. Adds further detail as to e
the operation of the Transfer Pump ALC-P-5.in Section 2.1.2.
Revised the description of demineralizer ALC-F-1 in Section 2.1.3.
Revised Section 2.1.19 concerning system iso htion valves. Adds new Section 3.4.2 and 3.4.3.
6/ 88 6
Annual update to reflect the following:
Clarification of Section 1.0 regarding approved a.
receiving tanks for EPIC 0R II processed water and routine /nonroutine operations.
b.
Installation of a stainless steel ALC-P-5 transfer pump has changed Section 2.1.2 and Table 2 regarding total dynamic head.
Replacement of ALC-RE-18 ( ALC Ventilation Rad Monitor) c.
required modification to Section 2.2.2.4 and Tables 10 & 12.
d.
Table 15 (ALC Valve List) has been expanded to include two new valves added for MMA 3526-07-0016 (ALC-F-1 Bypass),
e.
Table 15 also now includes the descriptions of "WG" valves commonly used when processing MWHT, RCBTs, and Neutralizer Tanks through EPICOR II.
When the "TANKFARit" S.D. #3230-003 was cancelled, these "WG" valves should have been incorporated
- g 3
into S.D. #3526 004.
e9 R
s
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5e
3526-004 TABLE OF CONTENTS SECTION PAGE
1.0 INTRODUCTION
5 1.1 System Functions 5
1.2 Summary Description of the System 6
1.3 System Design Requirements 7
2.0 DETAILEO DESCRIPTION OF THE SYSTEM 11 2.1 Components 11 2.2 Instruments, Controls, Alarms, and Protective Devices 25 3.0 PRINCIPAL MODES OF OPERATION 28 3.1 Startup 28 3.2 Normal Operation 29 3.3 Shutdown 30 3.4 Special or Infrequent Operation 31 3.5 Emergency 32 4.0 HAZARDS AND PRECAUTIONS 33 I
. Rev. 6/0185P
3526-004 TABLE OF CONTENTS (Cont'd)
TABLE PAGE 1.
EPICOR II Pumps 34 2.
Transfer Pump 35 3.
Filters 36 4.
Demineralizers 37 5.
Miscellaneous Waste Hold-up Tank 38 6.
Clean Water Receiving Tank 39-7.
Off-Spec Water Receiving /8atch Tank 40 8.
Sump Pump, Chemical Cleaning Building 41 9.
Monorail Hoist System 42
- 10. CCB Ventilation System Nameplate' Data 43
- 11. Air Compressors 44 12.
Instrumentation and. Controls 45 13.
Radwaste Processing System (EPICOR II) 54 14.
Radwaste Processing System (EPICOR II) 56
- 15. Valve List 57 16.
Radwaste Processing System (EPICOR II)'
92
, Rev. 6/0185P
___,,,.,-...,,,__,.-..,_.m,~...
3526-004
1.0 INTRODUCTION
1.1 System Functions The functions of the Auxiliary Building Emergency Liquid Clean-up (EPICOR II) System are:
1.1.1 To decontaminate, by filtration and ion exchange, radioactive waste water contained in THI Unit 2, or to serve as a polishing ion exchanger system for the Submerged Demineralizer System (SDS).
1.1.2 To transfer EPICOR II processed water from the Clean Water Receiving Tank (CC-T-2) to the following tanks:
a.
Processed Water Storage Tanks (PH-T-1 or 2).
b.
Off-Spec. Water Receiving Batch Tank (CC-T-1) to be used for decontamination of the Reactor Building and Auxiliary / Fuel Handling Buildings. CC-T-1 is also used for recycle processing when required.
c.
Evaporator Condensate Test Tanks (ECTTs or HDL-T-9A/B) to be used for various decontamination activities and make-up water / chemical additions via the Boric Acid Mix Tank (BAMT).
NOTE:
The transfer to HOL-T-9A/B passes through Unit 1 Turbine Building, but is physically isolated from all Unit I systems.
d.
On a non-routine basis to either the Condensate Storage Tank (C0-T-1A), Borated Water Storage Tank (BHST) or the "B" Spent Fuel Storage Pool via the Truck Fill Station.
1.1.3 To provide remote handling of spent resin containers from their position inside the Chemical Cleaning Building to the transport cask and truck.
1.1.4 To limit releases of radioactive material to the environment to "as low as reasonably achievable."
1.1.5 To provide for operation, and maintenance of the liquid cleanup system in compliance with "as low as reasonably achievable" radiation doses to personnel.
g 1.1.6 To accomplish the above independently from THI Unit-1 (for exception see NOTE above). Rev. 6/0185P
i 3526-006 1.2 Summary Description of the System The Auxiliary Building Emergency Cleanup System, as the name implies, was designed and constructed originally for the primary purpose of processing and cleaning up the accident-generated water that collected in Auxiliary Building.
It has, since then, evolved into a radwaste 11guld processing system, differentiated from a regular radwaste liquid processing facility, in that the water processed by the former is accident-generated.
The system is currently referred to as EPICOR II.
The system consists of a liquid radwaste process system which is located in the Chemical Cleaning Building.
It decontaminates, by filtration and ion exchange, radioactive waste water contained in the Auxiliary Building, Fuel Handling Building, Service Building, and Reactor Building of TMI Unit 2.
Contaminated water is pumped from a connection located on the Miscellaneous Waste Holdup Tank (HDL-T-2) by a pump located in the Chemical Cleaning Building through the yard and into the process system, or it will be obtained from the Monitor Tanks SDS-TIA/TIB, or the Contaminated Drain Tanks, or Reactor Coolant Bleed Tanks (RCBT's) or the Neutralizer Tanks WDL-T-8A and B.
Yard piping is shielded and enclosed within a guard pipe, the.open end of which terminates inside the Chemical Cleanirg Building.
The primary process system consists of three demineralizers (ALC-F-1, ALC-K-1, and ALC-K-2), connected in series.
Haste 11guld is transferred from the Source Tank (MHHT, WDL-T-8A/B, RCBT, CDT, or SDS-TIA/TIB) through the demineralizers, to the Clean Water Receiving Tank (CC-T-2).
Change-out Criteria for the various units are indicated in Table 13, 14, and 16.
l Processed water is delivered to the Clean Hater Receiving Tank (CC-T-2) for sampling and analysis.
The processed water is either pumped to the Liquid Waste Disposal System of TMI Unit 2, the Spent Fuel Storage Pool, the PHST's, the BHST, CO-T-1A, HDL-T-9 A/B or the truck fill station for transfer to the NLB Pump if within specification.
Additionally, the processed water can be transferred to the Off-Spec Water Receiving Batch Tank (CC-T-1) for recycling through the process system or use in the decontamination of the Reactor Building or Auxiliary and Fuel Handling Buildings.
Reprocessing under a feed and bleed scheme (via CC-T-2) can be done if it does not meet the end process criteria, but is not a routine operation since feed and bleed processing requires a long time to accomplish.
The Chemical Cleaning Building (CCB) has been made into a low leakage confinement building and provided with an exhaust ventilation system to maintain the building at a negative pressure. Rev. 6/0185P
]
3526-004 Moisture separators, HEPA filters, and charcoal filters have been provided in the exhaust ventilation system ~1n order to filter the building air before it is released to the stack at the roof line of the CCB. All effluent air is monitored for radioactivity at this point. Provisions for grab samples are available.
Normal operation of the processing system is by remote means except for infrequent operations such as sampling, spent resin container removal and new resin container installation. All remote system operations are controlled from the TV Monitor Control Building located outside the northwest corner of the Chemical Cleaning Building.
Remote handling of spent resin containers from their position inside the Chemical Cleaning Building to the transport cask and truck is via a remotely operated twenty-ton monorail hoist system.
A fire protection system is installed in the HVAC equipment room, the Control Building and the CCB.
A 4" tie-in to the existing fire main supplies a sprinkler system in the TV Monitor Control Building and a hose station in the CCB, as well as the sprinkler line to the air flitration unit charcoal filters.
The key to the lock on the valve for this sprayline is kept in the Auxiliary Building Emergency Liquid Clean-up System Control Room which is also known as the TV Monitor and Control Building.
Line and grid pressure indication is provided in the Control Building.
The system interfaces with the TMI Unit 2 Radwaste Disposal Miscellar.eous Liquids System, Demineralized Water System, the Submerged Demineralizer System, the Processed Water Storage System, the BOP Electrical System, Service Air System, the Unit I Liquid Haste Disposal System, Fire Protection System, and the Unit 2 Radwaste Disposal Reactor Coolant Liquid System.
NOTE:
Although there is an interface with the Unit I Liquid Haste Disposal System, the Unit I System will not be used.
In this respect Unit II will function independently. Valve ALC-V169 shall remain locked closed (unless transferring CC-T-1 or -2 to the "B" Spent Fuel Pool) and a spectacle flange is installed downstream of valve ALC-V169 at the transition between Unit I and Unit 2 Liquid Radwaste Systems. Valves downstream of ALC-V169 are no longer accessible to Unit 2 operators due to unit separation.
1.3 System Design Requirements 1.3.1 Process System Design Requirements 1.3.1.1 The process line pipe size is nominally 2" schedule 40 based upon the EPICOR II system flow rate of 10-30 gpm.
Other line sizes are based on service requirements and function, such as service air, demineralized water, recirculation and sampling. Rev. 6/0185P
3526-004
- 1. 3.1. 2 Pumps ALC-P-1 through P-4 have hose connections and are provided with drip trays to collect leakage.
Drip trays have nozzles as close to the bottom of the tray as possible and are served by flexible tubing which leads to the nearest floor or equipment drain using the floor slope to induce flow.
This tubing will be placed well down into the floor drain.
l.3.1.3 Remote system operations are directed and controlled from outside of the Chemical Cleaning Building from the TV Monitor and Control Building.
This area is providec' with remote closed circuit television monitoring of the operating areas inside and outside the Chemical Cleaning Building.
1.3.1.4 Process instrumentation consists of pH, and conductivity monitors.
Resin bed radiation levels, process line radiation levels, process flow rates, process totalizers, and tank /demineralizer levels are also monitored. Accelerometers for P-1 through P-4 are provided for equipment protection and an alternate method to determine processing flowrates.
1.3.1.5 The system tank vents are provided with in line heaters, demister filters, and charcoal filters for adsorption of evolved iodine.
These units are sloped to drain demisted 11gulds back into the system tanks.
1.3.1.6 Liquid waste feed to the system will be drawn from the Source Tank (MWHT, RCBT, SDS-T1A/T18, HDL-T-il A/B, WOL-T8A/B, CC-T-2, or CC-T-1) is pumped to the first EPICOR II pump (ALC-P-1).
The Miscellaneous Waste Holdup Tank pump is not used when processing the MWHT.
This provides better system pressure and flow control.
1.3.1.7 The EPICOR II System is contained within the Chemical Cleaning Building which was originally designed to meet seismic criteria per Zone 1 of the building code. The EPICOR II System and major components when constructed were considered to be non-Q.C. scope, however the system has since been reclassified ITS, in Q.C. scope.
1.3.1.8 All system piping is welded stainless steel except for air piping which is welded carbon steel or copper tubing.
Instrument tubing systems are 316 SS Tubing.
The instrument tubing system is made up using compression fittings.
The process system piping is rated at 150 lb. and is designed, installed and inspected in accordance with ANSI B31.1 (Power Piping).
)
NOTE:
Flanged and screwed connections are used as necessary on certain components. Rev. 6/0185P
l 3526-004 1.3.1.9 Capability is provided to obtain a representative sample of tanks CC-T-1 and 2, and the effluents of Demineralizers ALC-F-1, ALC-K-1 and ALC-K-2, while in a low radiation area in accordance with Regulatory Guide 1.21.
Representative sample for CC-T-1 or 2 is here defined as "after recirculating the tank contents for three volume changes".
Also the sample line for CC-T-1 and.2 shall be purged to the sample sink for five line volumes prior to drawing the sample, and for ALC-F-1, ALC-K-1 and ALC-K-2 the sample lines shall be flushed for three (3) minutes minimum prior to drawing the sample.
NOTE:
ALC-F-1 is the first demineralizer, followed in series by demineralizers ALC-K-1 and ALC-K-2.
1.3.1.10 The building sump is a covered sump.
1.3.1.11 System blowdown air and demineralized water lines are provided with individual check valves ALC-V060 through V079 to minimize contamination of these systems.
1.3.1.12 The demineralized water supply header is provided with demineralized water from THI Unit 2 in the range of 80-90 psig to meet EPICOR II requirements.
1.3.1.13 The System Air supply header is provided with a pressure regulator operating in the range of 80-90 psig, and a moisture separator. An air oiler, and an anti-freeze injector are
{
provided for the portion of the System Air header servicing the EPICOR II pumps.
Provisions are available to connect the plant Service Air System to the system if necessary. Also two air compressors (ALC-P-7/8) are available for use and tie into the air supply header via ALC-V145.
NOTE:
The Plant Service Air System is the preferred air supply.
1.3.1.14 If sampling indicates that the processed water is within limits for usage, the decontaminated liquid from CC-T-2 can be routed to the THI Unit 2 Liquid Haste Disposal System, the THI Unit 2 Spent Fuel Storage Pool, the PHST's, CC-T-1, or a truck fill hose connection that is provided as a means of transferring decontaminated liquids for use in the decontamination of the Reactor, Auxiliary and Fuel Handling Buildings.
1.3.1.15 All system overflow lines discharge to the Chemical Cleaning Building sump. All floor drains also discharge to the sump.
The water collected in the sump is staged in the Off-Spec Water Receiving Batch Tank CC-T-1 by the sump pump for recycle through the cleanup system or it is drawn and processed directly through the EPICOR II system via existing valves and piping. Rev. 6/0185P
3526-004 1
1.3.1.16 Since the elevation of the discharge nozzle of tank CC-T-2, i
and the Chemical Cleaning Building floor were fixed prior to.
design and construction of EPICOR II, the hydraulic design for draining CC-T-2 is not adequate for complete draining of the tank.
However, the system was designed to facilttate draining to~the maximum extent possible.
Final draining of CC-T-2 is accomplished with the manual drain line (valves ALC-V131 and V132).
1 1.3.1.17 Three resin traps are installed downstream of the demineralizers.
1.3.1.18 A one micron (nominally rated) cartridge type filter is I
installed downstream of the three resin traps.
1.3.1.19 The system shall have personnel shielding on various components to reduce the radiation levels in the operating areas of the building.
1.3.1.20 A resin trap is installed on the outlet from the casks overflow line to prevent resin carryover into the sump.
1.3.2 Material Handling Design Requirements 1.3.2.1 Normal operation of the Auxiliary Building liquid Processing System is by remote methods.
1.3.2.2 Demineralized water and service air connections are provided to flush and blowdown the entire system or portions of it to allow system maintenance.
1.3.2.3 4x4 liners or HIC demineralizers with adapter lif t ring attached may be removed from the building by making use of the shield bell designed for this purpose.
The shield bell is l
positioned ovu the radioactive liner.
The shield doors on l
l the bottom of the bell are opened and the liner is drawn up
)
into the bell.
The doors are reclosed and the bell is carried, by the crane, to the truck which may have a concrete shield vessel for isolating the bell during transportation to the staging facility. Monitoring of the area is carried on during these activities to assure the safety of personnel.
Another liner is positioned in the vacated space.
Shielding, l
process lines, and level instrumentation are repositioned and the unit is returned to service.
NOTE:
The transfer bell is no longer routinely used and will only be used if operation of the system results in radiation levels from the demineralizers exceeding limits for unshielded handling. Rev. 6/0185P
3526-004 1.3.2.4 6x6 liners and lightly loaded 4x4 liners are handled in and out of the building without shielding.
This is accomplished by remote operation and by establishing appropriate barriers limiting the approach of personnel to the handling operation.
Spent. resin containers are lifted directly from within-substantial shielding barriers in the Chemical Cleaning Building and deposited directly in the transfer cask located on the-unmanned truck located immediately outside the building, or loaded unshielded on a transport truck depending on the liner's radiation levels.
1.3.3 Air Handling Design Requirements 1.3.3.1 A ventilation fan is provided to maintain the Chemical Cleaning Building at a negative pressure.
1.3.3.2 The MSA Filtration Unit is designed to meet the requirements of NRC Regulatory Guide 1.140.
1.3.3.3 The moisture separator is provided to remove water vapor droplets from the air.
1.3.3.4 An electric heater is prov.ided within the Filtration Unit.to
-lower relative humidity to 30% with 100% RH-inlet air.
1.3.3.5 The prefilter has an average atmospheric air strain efficiency of 85%.
1.3.3.6 The two HEPA filter banks are DOP tested in place to assure an efficiency of 99.95% for removing 0.3 micron particles.
2.0 DETAILED DESCRIPTION OF THE' SYSTEM 2.1 Components 2.1.1 EPICOR II Pumps (ALC-P-1-through 4)
Pumps (1-4) are air-driven, positive displacement pumps with a capacity of from 10 gpm to 120 gpm.
Each pump is equipped with a pulsation dampener in the process outlet.
Pumps ALC-P-1 through 4 are utilized in the system to circulate the liquid througn the demineralizers.
The hoses furnished for the~ flexible connections to the pumps, filters, demineralizers, and traps have a design pressure of 100 psi.
Air supplied to the pumps passes through an air oiler and an i
anti-freeze injector to a valve manifold.
Pump speed and capacity will be varied by the EPICOR II operator to achieve the optimum flow through the radwaste process system.
Pump speed is controlled by throttling the drive air at the Fava Control Panel. Demineralized water and oil free air
, Rev. 6/0185P 4
3526-004 connectiors are provided on the suction and discharge side of each pump for flushing and blowdown purposes.
Refer to Table 1 for pump details.
Pump noise and vibration monitors are present for pumps ALC-P-1 through 4 and have a read-out on panel ALC-PNL-2 in the TV Monitor and Control Building.
2.1.2 Transfer Pump ALC-P-5 The transfer pump (Table 2) is a single stage horizontal centrifugal pump with a capacity of 200 GPM at 100' head.
The l
pump motor is rated at 10 HP and is powered from MCC 2-33A in the TV Monitor and Control Building.
The pump is controlled by push buttons for START /ST00 from MCC 2-33A, a hand selector switch for low level control of tank CC-T-1 or CC-T-2 from the panel ALC-PNL-1 in the TV Monitor Control Building and level switches in panel ALC-PNL-1 for tanks CC-T-1 and CC-T-2.
The level switches receive their signals from level transmitters ALC-LT-1 and ALC-LT-2 at tanks CC-T-1 and CC-T-2, respectively. CC-T-1 and 2 also have high level cutouts to ALC-P-5.
Demineralized water is supplied to the pump mechanical seal from a solenoid operated valve, ALC-V136, controlled from the pump motor starting circuit.
The valve opens, when the motor is started, by energizing the solenoid.
The seal water flow rate is maintained at 1-2 GPM by throttling ALC-V134 when seal water injection is required.
Seal water ir,jection is only requireo if the pump is handling water which contains greater than 7000 ppm boron.
If the pump handles clean water, it is acceptable to allow the mechanical seal to be lubricated through the pump's internal passages.
As long as the water, which pump ALC-P-5 handles, has passed through the one micron filter (ALC-F-5), the water is clean enough (from a grit standpoint) to lubricate the mechanical seal.
Thus, as long as filter ALC-F-5 is in use, the demineralized seal water can be turned off with valve ALC-V134 to reduce the total volume of processed water or radwaste.
l The pump is used to transfer water from the Clean Water Receiving Tank or the Off-Spec Water Receiving Batch Tank to the TMI L' nit 2 Liquid Waste Disposal System, the Spent Fuel Storage Pool, the PHST's, or a hose connection at the truck fill station.
It is also used to transfer water from tne Clean Water Receiving Tank to the Off-Spec. Water Receiving Batch Tank.
Furthermore, the pump is also used for recirculating and sampling the contents of the Clean Water Receiving Tank and the Off Spec Water Receiving Batch Tank.
The sample connection terminates at the Sample System sink.
The pump is i
provided with a discharge pressure gage, and a flow element on Rev. 6/0185P
3526-004 the discharge line to Units No.1, No. 2, the Spent Fuel Pool, the PHST's and the truck fill station.
Remote indication of l
flow (ALC-FI-2) and a flow totalizer (ALC FQ-2) are located on Panel ALC-PNL-1.
To protect the pump from operating at shutoff or low flow, it is provided with a solenoid-operated minimum flow control valve ALC-V291.
The minimum flow line branches to both CC-T-1 and CC-T-2; the direction of the flow is to the tank where the water is originating.
The operation of the minimum flow control valve is automatic although manual control is provided as well. Automatic control is provided by differential pressure switch ALC-DPS-1.
The switch measures the flow through the pump in terms of AP across the equipment.
When the flow is less than 40 gpm, the minimum flow control valve opens and it will remain open until the flow has increased to approximately 90 gpm at which time it will close.
Manual control permits the opening and closing of the valve at any time.
2.1.3 Demineralizer (ALC-F-1)
The first stage demineralizer (Table 4),is generally used to remove sodium and other non-radioactive chemicals plus removal c' low concentrations of radioactive isotopes.
During this polisting mode, the cesium and strontium radioisotope concentrations have been reduced by SDS processing or are low enough that they do not require removal prior to polishing.
This demineralizer may be a carbon steel tank approx!aately 6 feet in diameter and 6 feet high (6x6) or 4 feet by 4 feet (4x4) loaded with organic resins.
Should conditions require gross ceslum and strontium removal, a HIC loaded with Zeolite Resins may be placed in the first position acting as a roughing filter.
This mode of operation would preclude the need for SDS providing a "once-through" process, vice two (2) systems operating in series.
The HIC is similar in size to the carbon steel 4x4.
The major difference in design being the materials used during fabrication of each type. HIC demineralizers are constructed of a very high grade stair h steel, enabling the container to mest the burial limits of Class 8 and Class C.
In all cases, the top of either a 6x6 or 4x4 or HIC have four (4) quick disconnect fittings:
an inlet (pump discharge), an outlet (pump suction), a combination vent / overflow, and an air type QD fitting for the level bubbler tube. As a means of backup level incicator, a threaded level conductivity probe also penetrates the tank top. Rev. 6/0185P
3526-004 An air connection is provided at the top of the 6x6 liner to allow removal of the plug from the top of the false bottom after final dewatering.
The false bottom is filled with an approved sorbent to absorb water that may. tend to accumulate.
The false bottom is not required because the water volume absorbed is less than the 0.5% limit for shallow land burial.
A marsay with approximately a 20" diameter opening is installed on top of the tank.
The inlet nipple is connected to a full dispersion manifold in the top of the tank.
The outlet nipple (pump suction line) connects to a single layer filter manifold which is located at the bottom of the tank.
The level probe or bubbler system maintains tank level between 4" and 6" from the top of the resin by opening and closing solenoid valve (ALC-V185) on the air supply to pump ALC-P-1, which is supplying the tank, starting the pump on low level, and stopping the pump and closing valves ALC-V043 or ALC-V242 on high level. On Hi Hi level 4" from the tank top, an audible alarm is sounded at the EPICOR Monitoring Console, located in the TV Monitor and Control Building, ALC-V255 closes, and the pump motor operated valve closes.
The EPICOR II operator may select either air bubbler or conductivity level control on the Fava Control Panel located in the TV Monitor and Control Building.
The demineralizer tank is vented, via hose connections, to a 2" vent header which leads into the top of the Off Spec Water Receiving Batch Tank (CC-T-1).
A tee is provided in this vent line for a hose connection to a common header which discharges to the CCB sump.
The line is provided as a demineralizer overflow line and demineralizer averoressure protection. A loop seal is provided to ensure that all cask gases are routed-to tank CC-T-1 and its vent filters, rather than dirtctly into the Chemica' Cleaning 0.111 ding. A lovel switch (ALC-LS-?l) is installed in the loop
.eal for indication of flow in the header and provides an alarm at panel ALC-PNL-1 in the TV Monitor and Control Building.
The shielding in the ALC-F-1 position consists of a 5 1/8" thick, square lead brick wall (3 1/8" thick on south side) plus a 1/2" of shield-supporting steel.
Radiation monitors (ALC-RM-1 and 2) are located inside this shield 180 degrees apart at different elevations to monitor accumulated radiation levels in the demineralizer. When the HIC is installed, a concrete shield (culvert) will provide additional shielding and a place to land the transfer bell while removing the spent HIC.
1 Rev. 6/0185P 1
3526-004 To avoid breakthrough of sodium to the second linar when the F-liner is organically loaded, the batch size through the ALC-F-1 demineralizer is limited.
1
)
If a High Integrity Container is.in service in the F-position, activity breakthrough will be limited through batch size or by i
the activity as measured by ALC-RM-7, installed at the influent header of ALC-K-1 demineralizer.
The second liner will then be organically loaded for sodium "val.
If the water source if very low in cesiu and strontium, but still requires further polishing (i.e., recycle processing of CC-T-1 or CC-T-2), a jumper hoie has been provided to bybass the HIC demineralizer in the ALC-F-1 position.
In this configuration, the first liner in the series will be the ALC-K-1 demineralizer followed by the ALC-K-2 denineralizer (two liners vice three).
Processing relatively clean-water will rinse cesium and/or strontium activity off of the HIC zeolites on to the downstream ALC-K-1 demineralizer.
This is why the "BYPASS" mode has been employed.
Refer to paragraph 2.1.19 for details regarding demineralizer level controls.
Refer to paragraphs 3.4.2 and 3.4.3 regarding operations and systems that prepare a HIC /demineralizer for shipping and burial.
Remote indication is provided on the Cleanup Panel ALC-PNL-1 for ALC-RM-1 and 2.
During system operation, radiation levels i
as indicated on ALC-RM-1 and 2 should not be allowed to exceed 1 R/HR.
l 2.1.4 Demineralizer (ALC-K-1, ALC-K-2) l Two demineralizers (Table 4) are installed in series with l
ALC-F-1 to further remove radioactivity from the waste liquid and polish the effluent.
The demineralizer (ALC-K-1), a 4x4 or 6x6-liner, is primarily
)
used to reduce the activity level of the process fluid through lon exchange and filtering.
For this reason, the anticipated activity levels are high and the shielding around ALC-K-1 is identical to shielding around the ALC-F-1 demineralizer when ALC-F-1 demineralizer is a 6x6 liner.
1 Demineralizer (ALC-K-2), a 4x4 or 6x5 liner, is primarily used to polish the effluent water from ALC-K-1 and act as a guard in the event of a resin breakthrough from ALC-K-1.
For this reason, the anticipated activity levels in ALC-K-2 are lower than ALC-K-1.
Each demineralizer has the same external connections c.
ALC-F-1.
The demineralizer resin composition and quanti"y will be determined on the basis of system samp es and i
operating data. Rev. 6/0185P
3526-004 As with the ALC-F-1, two radiation detectors are located at different elevations 180 degrees apart inside the lead shield. Remote indication is provided in the TV Monitor and Control Building on Panel ALC-PNL-1.
During system operation, radiation levels as indicated on ALC-RMI-3 and 4 for ALC-K-1, should not be allowed to exceed 1 R/HR.
Radiation levels as indicated on ALC-RMI-5 and 6 for ALC-K-2, should not be allowed to exceed IR/HR.
2.1.5 Miscellaneous Waste Hold-up Tank (WDL-T-2)
The Miscellaneous Waste Hold-up Tank (Table 5) which has a capacity of 19,518 gallons, can receive liquid from the following sources:
a.
Auxiliary Building' Sump Tank b.
Neutralizer Tanks c.
Contaminated Drain Tanks d.
Reactor Building Sump e.
Deborating demineralizer ba:k wash outlet f.
Fuel Storage Pool Submersible Pump Discharge 9
Demineralized Hate-System h.
Submerged Demineralizer System (SDS) 1.
Cond. Polisher Sump j.
Water Treatment Sump k.
Reactor Coolant Bleed Tanks 1.
Concentrated Haste Storage Tank The tank also has connections to the Miscellaneous Waste Tank l
Pump suction, recirculation, a caustic and sulphuric acid inlet, two nitrogen inlets, a vent, a gas sample connection and a relief valve.
The tank is normally nitrogen blanketed, but may be vented to the WDG System.
To prevent acid splashing on the inner tank walls, the iniet piping extends into the tank 8 ft. The diameter of the tank is 10'-9-1/4".
The Miscellaneous Haste Hold-up Tank is located in the Auxiliary Building elevation 305'.
A temporary tee connection is installed in place of the suction line strainer, HDL-U2028, on the Miscellaneous Haste Tank Pump WDL-P-68 suction line.
Connected to this tee is a Rev. 6/0185P 2
3526-004 2" line which supplies the 11guld from the Miscellaneous Waste Holdup Tank to the suction side of EPICOR II Pump ALC-P-1.
A 4" guard pipe with a combination of lead and concrete shleiding encloses the suction piping run from the Auxiliary Building corridor to the Chemical Cleaning Building penetration.
The guard pipe is open to the atmosphere of the Chemical Cleaning Building, which is under a slight negative pressure.
2.1.6 Clean Water Receivinc Tank (CC-T-2)
The Clean Water Receiving Tank (Table 6) is a stainless steel atmospheric pressure tank with a ccpacity of 133,700 gallons located in the Chemical Cleaning Building.
The tank receives the processed liquid frota the discharge of pump ALC-P-4 via, in order, three resin traps, a one-micron crud filter, conductivity cell, pH meter, and an inlet flowmeter / totalizer.
An overflow line with a loop seal is provided near the top of the tank. A deminerailzed water supply is provided for the loop seal. A suction line from the transfer pump (ALC-P-5) penetrates the tank skirt and connects to the bottoo of the tank. A connection on the. top of the tank is also provided for the transfer pump recirculation line, a feature that enhances mixing of the content.
Level indication and high level alarm are provided on panel ALC-PNL-1. :A future xenon hold-up tank connection is provided on the vent line. A 2" demineralized water line is also provided on top of the tank for whenever large quantities of demineralized water are required in the tank.
This would include preoperational testing or tank cleanup. A drain line is provided off the Transfer Pump (ALC-P-5) suction piping to drain the suction piping and the remaining water in the tank that the transfer pump cannot drain.
The tank has a 2" vent line exhausting to the Chemical Cleaning Building through a two-stage demister filter.
The i
first stage consists of two moisture separators and an HEPA filter.
The second stage consists of two charcoal filters and an HEPA filter. A heater in the common 2" vent line is controlled from Power Panel MP-2-33A.
The heater is normally energized.
Processed water is stored in the tank until a batch is completed. A representative sample of the processed water can be obtained from the discharge of the transfer pump at the sample sink after recirculating three volumes of the tank and purging the sample lines for five line volumes before drawing the sample.
If the sample indicates the water quality is unsatisfactory, the water can be pumped to the Off-Spec Water Receiving Batch Tank for temporary storage or routed directly back into the sucticn line of pump ALC-P-1 for reprocessing Rev 6/0185P
i 3526-004 through the filter and demineralizers until the quality is acceptable for discharge to the plant or storage tanks.
If sampling indicates that the tank's contents are satisfactory for use in the plant (e.g., decon flush or makeup to other plant processes) the water is pumped normally into the TMI Unit 2 Liquid Waste Disposal System, the Spent Fuel Storage Pool, the PHST's or to the NLB pump from the truck fill station, however, it may be stored in the Off-Spec Water Receiving Batch Tank, if desired.
The Off-Spec Water Receiving Batch Tank should be flushed clean with demineralized water or clean processed water before it is used for clean water storage.
2.1.7 Off-Spec Water Receiving Batch Tank (CC-T-1)
The Off-Spec Water Receiving Batch Tank (Table 7) is a stainless steel tank with a capacity of approximately 86,000 gallons designed for full vacuum to 75 psig.
For the Auxiliary Building Clean-up System, the tank is operated at atmospheric pressure only.
The tank can receive the discharge from the Clean Water Receiving Tank Transfer Pump whenever it is desired to either recycle the water for further processing, or store the purified water for future disposition. CC-T-1 may also-be used as a source of processed water to supply the NLB pump used for containment decon.
This feature allows greater availability of the Clean Water Receiving Tank.
The Tank is piped up to receive the discharge from the sump pump, if desired, but normally the sump is drained by a 2" suction line to the Pump ALC-P-1 (see para. 2.1.8).
A suction line at the bottom of the tank can be lined up either to Pump ALC-P-1 for reprocessing the tank's contents through the i
system or to the Transfer Pump ALC-P-5 for recirculation and sampling, or discharge.
The recirculation line connects to the top of the tank.
The tank is vented to the building in the same manner as the Clean Water Receiving Tank. An over-flow line with a loopseal is provided near the top of the tank. A demineralized water supply is provided for the loop seal. A connection at the top of the tank receives vents from the prefilter, the demineralizers and the crud filter.
Level indication and high level alarm are provided on panel ACL-PNL-1. A future xenon hold-up tank correction is provided on the vent line.
The tank has a 2" vent line exhausting to the Chemical Cleaning Building through a two-stage demister filter.
The first stage consists of two moisture separators and a HE M filter.
The second stage consists of two charcoal fi'ters and a HEPA filter. A heater in the common 2" vent line is controlled from Power Panel MP-2-33A.
The heater is normally energized. Rev. 6/0185P
3526-004 2.1.8 Chemical Cleaning Building Sump The Chemical Cleaning Building sump is a stainless steel lined pit with a capacity of 4000 gallons located in the northwest corner of the building.
All leakage from the tank-overflow, equipment, and floor drains are collected in the sump. One sump pump (Table 8), is installed to permit the transfer of the liquid from the sump to the Off Spec Water Receiving Batch Tank, if desired.
The pump is a single stage centrifugal pump with a capacity of 100 gpm.
The pump motor is rated at 20 HP and is controlled from a (MAN-0FF-AUT0) selector switch located on MCC2-33A. When in AUTO, the pump is controlled by conductivity type level switch ALC-LS-1 which starts and stops the pump automatically.
A High Sump Level Alarm is provided on Cleanup Panel ALC-PNL-1.
The pump is started when the water level in the sump reaches a level that is 48 1/4 inches below the face of the pump mounting.
The pump stops when the level of water has been lowered to a level that is 90 3/8 inches below the pump face.
The high level alarm is actuated when the water level reaches 36 1/4 inches below the face of the pump mounting.
The volume of water removed from pump START to pump STOP is approximately 1600 gallons.
There is also a volume of nearly 1700 gallons above the High Alarm before the sump overflows.
"? sump is normally drained by a 2" line provided from the samp to 2" Flushing Line just upstream of its entry into the suction line of pumo ALC-P-1.
This permits the return of the sump water to the clean up system directly from +.he sump without circulating through the pump CC-P-2A an( the Off-Spec Water Receiving Batch Tank CC-T-1.
A 3/4" branch connection is provided in this line with "Quick Disconnects" attached to permit ready access for flushing with demineralized water from an outlet downstream of valve ALC-V015 with a short it:'gth of hose.
2.1.9 20 Ton Monorail Holst System A 20 ton hoist is provided for removal and replacement of tie demineralizers and other large pieces of auxiliary equipment in and out of the building.
It is mounted on the monorail which extends from tie " th side of the Chemical Cleaning Building above the resin traps through the south end of th>s building, extending 18' outside of the building over the gask i
loading area.
Table 9 provides specifications on the monarall holst system.
In order to minimize the radiation exposure to personnel during demineralizer removal, the holst is operated remotely using a remote pendant operating station in the TV Monitor and Control Building.
Remote operation is aided through the use l
i i Rev. 6/0185P
i 3526-004' i
of a closed circuit TV system with six cameras.
The pendant has six pushbuttons for trolley and hoist operation - one.
START, one STOP, two for north / south movement of the single speed trolley, and two for the. hoist Quad-Speed Control System I
which are, a 4-step button for creep, low, medium and high speed RAISE, and a 4-step button for creep, low, medium and high speed LOWER.
There is also a local monorail hoist pendant located on the CCB operating floor.
This pendant is used for performing operations where there is little radiation exposure, such as bringing a new liner of resin into the building.
To aid positioning of the hoist remotely for demineralizer I
replacement, the monorail has visible target markings above the demineralizers, and in the cask loading area all of which can be viewed with the TV cameras.
2.1.10 Resin Filter - ALC-F-4A, B and C l
Three Resin Filters are provided downstream of-EPICOR pump, ALC-P-4, to prevent resin fines from entering the Clean Water l
Receiving Tank.
If the filters contact radiation level reaches 250 mR/HR on any part of the filter, the system must be shutdown and the filters replaced.
Four sides of the filters are shielded by solid concrete. blocks 8" thick.
The top is shielded with 1/2 inch of lead.
2.1.11 Crud Filter - ALC-F-5 A one micron nominally rated filter with isolation. valves is l
provided between the resin filter and the Clean Water Receiving Tank.
The primary purpose of this filte is to eliminate most particulates present in the processed water. A l
vent line connected to the Off-Spec Water Receiving Batch Tank and a drain line to the equipment drain system is provided for draining the filter housing prior to inserting or removing a filter cartridge.
The filter is shielded by 3 1/8" lead bricks on three sides, and by a concrete wall or, the fourth side.
During removal of the filter, it should be handled as radioactive material. The filter must be replaced whenever the contact radiation level reaches 250 mR/HR or when the pressure drop reduces the process-flowrate below an acceptable value. A special lever is provided to aid in removal of the filter cartridge.
2.1.12 Ventilation Heating Unit and Motsture Separator Heating unit no. ALC-E-H1 (Table 10) is mounted on the inlet of the filtration unit at elevation 304' and consists of a moisture separator (ALC-E-FI) and a 60 KW 480 volt, 3 phase heater. The heater is powered from MCC2-33A. Rev. 6/0185P
3526-004 2.1.13 Ventilation Filter Unit i
The filter unit consists of a single housing containing, in order: a prefilter (ALC-E-F2) (not used), a high efficiency particulate air (HEPA) filter (ALC-E-F3), charcoal filter beds (ALC-E-F4) and a final HEPA filter (ALC-E-FS). A manually actuated fire protection water supply is provided for the charcoal beds.
2.1.14 Ventilation Fan Assembly Fan assembly no. ALC-E-1 (Table 10) is a 30HP, 460 volt' 3 phase, 60 cycle, radial flow centrifugal unit with a capacity of 8000 cfm.
The fan, powered from MCC2-33A, is mounted on the outlet of the filter unit and discharges the ventilation exhaust through ducting (monitored by a radiation detector) and out through the roof.
2.1.15 Ventilation Radiation Monitor The radiation monitor (Table 10) samples air in the fan discharge line isokinetically at a rate of 4 cfm to provide local (at monitor) and remote indication on Panel ALC-PNL-1 of 1
discharge particulate, and noble gas activity levels.
Remote indication of these parameters is recorded on a strip chart recorder.
The monitor will provide an alarm at a radiation level of 5,000 CPM, and 20,000 CPM for a particulate, or gaseous activity on the panel in the Control Building.
The radiation monitor is powered from MCC2-33A. A splitter block has been provided in 'he line to the radiation monitor to provide a means of taking grab samples as may be required.
1 2.1.16 Ventilation Weatherproof Enclosures The weatherproof enclosure is located at grade level and houses the components discussed in 2.1.12 through 2.1.15 (above).
l 2.1.17 Chemical Cleaning Building Radiation Monitors Four area radiation monitors (ALC-RM-8 through 11 or equivalent) and an air sampler (ALC-RM-12) are provided in the Chemical Cleening Building.
The four area radiation monitors (ALC-RM-8 through 11) are provided with remote indication on the Radiatica Monitoring Panel ALC-PNL-1 in the Control Building.
The air sampler (ALC-RM-12) is located in the HVAC Building, but draws its sample from the Chemical Cleaning Building near ALC-F-1.
Remote indication for ALC-RM-12 is also provided on the Radiation Monitoring Panel ALC-PNL-1.
The area monitors and air sampler will provide a common alarm
=t a high radiation level and monitor failure on Panel ALC-PNL-1.
These radiation monitors are provided for operator Information.
' Rev. 6/0185P l
3526-004 2.1.18 Closed Circuit TV System A closed circuit TV system is provided to aid in remote handling of the demineralizers and to~ aid in system surveillance during operation.
The system consists of seven TV cameras strategically located in the Chemical Cleaning Building. The TV monitors and necessary controls are mounted on the TV Honitor Console located in the TV Monitor and Control Building. Camera No. 3 has a PAN-TILT control and is mounted to provide a view of ALC-K-2 for remote handling.
The PAN-TILT control allows remote movement of the camera to permit scanning a large area of the Chemical Cleaning Building for surveillance during system operation.
Camera No. 6 is mounted to provide a view of the EPICOR II pumps ALC-P-1 tnrough 4.
This camera provides the operator with a remote surveillance capacity for viewing this area of the building during system operation.
Camera No. 1 mounted on the monorail support structure outside the Chemical Cleaning Building to allow viewing of the prefilter or demineralizer while being loaded into the transfer cask. Camera No. 2 is mounted directly on the 20 Ton Holst and provides a direct view of the monorail.
Target markings which can be viewed with this camera are.provided on the monorail to aid in the positioning of the Holst. Cameras No. 4 and No. 5 provide a view of the top area ALC-F-1 and ALC-K-1 to aid in remote handling of these casks and to provide a surveillance capability for these casks during operation of the system. Camera No. 7 has a PAN-TIll antrol and is mounted on the west wall between ALC-K-1 and C-K-2 to provide remote monitoring of potential leak areas.
2.1.19 Major System Valves Inlet Isolation Valve to EPICOR II System - ALC-V043 One stainless steel, 2", 120V motor operated ball valve is installed on the inlet line from the source tank to the EPICOR II radwaste processing system.
The valve is powered from the 120/208V Power Panel MP-2-33A and controlled by a handswitch located on MCC-2-33A, Comp 3rtment 3D and a prefilter level probe. Valve position and control power availability indications are provided by red, green and white indicating lights also located on Compartment 3D.
The three lights will be on while the valve is in an intermediate position.
The valve is provided with a manual override for "close" operation only. Valve ALC-V043 is interlocked with valve ALC-V242 to assure that only one of these two valves can be OPEN at a time. ALC-V043 is also interlocked with the level monitor of ALC-F-1 and ALC-K-1.
The valve closes automatically when a high level occurs in the controlling demineralizer, to prevent overfilling of the vessel.
The choice of the controlling Rev. 6/0185P
ll 3526-004 i
.demineralizer is dictated by the configuration of the processing train through selector switch ALC-SS-1 (F-1 ON LINE
- F-1 BYPASSED).
If ALC-F-1 is in the processing train, its level controller will control ALC-V043; if ALC-F-1 is bypassed, control of ALC-V043 is transferred to ALC-K-1 level controller.
Service Air Regulator - ALC-V109 One 3" pressure regulating valve with a 300# rating is installed on the service air header supply to the EPICOR II-system to reduce the pressure to 80 psig.
Process Supply Line Valve (ALC-V255) to Demineralizer (ALC-F-1)
One 2" solenoid valve (ALC-V255) with a 150 # rating at 120*F is installed on the line from ALC-P-1 to ALC-F-1 between manual valves ALC-V191 and ALC-V207, the valve ALC-V255 is normally closed unless energized and is interlocked to close on high level in ALC-F-1.
Additionally it closes on loss of electrical power or when system is not running.
Off Spec. Water Supply Isolation Valves to ALC-P ALC-V086 and ALC-V242 One stainless steel, 2", air operated ball valve, ALC-V242, is installed on the supply line from Off Spec Water Receiving Batch Tank CC-T-1 to the suction of Pump ALC-P-1.
The valve allcws reprocessing of water from CC-T-1 or CC-T-2.
The valve is powered from the 120/208V Power Panel MP-2-33A and controlled by a handswitch located on MCC-2-33A, Compartment i
3E. Valve position and power availability indications function in the same manner as for ALC-V043.
Valve ALC-V242 is interlocked with Valve ALC-V943 to assure that only one of these two valves can be OPEN at a time.
Valve ALC-V242-is an air operated ball valve which is energized to open.
This valve will close on toss of power thus avoiding uncontrolled draining of tanks CC-T-1 or CC-T-2.
The valve is interlocked with ALC-V043 such that only one valve can be opened et a time to prevent crossflow.
It is also interlocked with the level controller of ALC-F-1 and ALC-K-1, in the same arrangement as ALC-V043.
Valve ALC-V086 is a stainless steel, 2",
120V motor operated ball valve which is also installed on the outlet line of the Off Spec. Water Receiving Batch Tank CC-T-1.
It is controlled by a manual handswitch mounted in MCC-2-33A, compartment 3E.
i By opening valve ALC-V086 and closing ALC-V242, clean water can be sent from tank CC-T-1 to the suction of the transfer pump (ALC-P-5) for transfer to the Processed Hater Storage Tanks or other transfer points. Rev. 6/0185P 1,
3526-004 2.1.20 Sample System A Sample System is provided to obtain a representative sample of tanks CC-T-1 and 2 and the effluents of Demineralizers ALC-F-1, ALC-K-1 and ALC-K-2.
The samples from the Demineralizers and the sample obtained from the Miscellaneous Waste Holdup Tank are used to determine the isotopic inventory held up on the resin beds.
The determination is made by analyzing the influent and effluent isotopic concentrations, the difference of which is held up on the bed.
This information is required for shipment of the spent containers to the waste disposal site.
A common collection station shielded by an 8 inch thick solid block wall is located on the Chemical Cleaning Building mezzanine, and is provided for controlled and safe sampling.
The col?ection station consists of individual sample stations for CC-T-1 and 2, ALC-F-1, ALC-K-1 and ALC-K-2, and a sample sink.
The sample sink is provided.with demineralized water for the sink spray header:and bottle washing.
The drain from the sink is routed to the Chemical Cleaning Building sump.
The sink 13 also provided with ventilation which consists of a hood and ductwork which is tied into the Chemical Cleaning Building ventilation system.
Recirculation of the sample lines from ALC-F-1, ALC-K-1 and ALC-K-2 back to the suction of ALC-P-2, and the collection of samples is controlled by solenoid valves.
The ability to obtain grab samples is provided in the recirculation line for flow verification.
Piping for the sample lines is 1/2" stainless steel tubing with compression type connectors.
NOTE:
See sections 2.1.6 and 2.1.7 for obtaining a sample from CC-T-1 and 2.
2.1.21 Auxiliary Building Cleanup System Air Compressors Rotary air compressors ALC-P-7 and 8 (Table 11) are provided t
as a backup air supply for the EPICOR II system, while the plant Service Air system is the normal air supply.
Either of these air compressors have sufficient capacity for the operation of the EPICOR II system.
These compressors are located in the ventilation unit's building.
These compressors are single stage rotary screw, electrically driven, packaged units (pre-wired and pre-plumbed) with capacities of 115 and 98 CFM at 100 psig (the compressors are not the same model).
' Rev. 6/0185P i
3526-004 The compressors are' controlled by local hand switches which allow the choice of either START /STOP (for intermittent air demand) or CONTINUOUS (for continuous air demand) control modes for flexibility.
The units are piped up so that they can be used individually when a small volume of air is required or in parallel to handle larger air demands.
In all of the operating modes, the air pressure in each unit's reservoir is automatically maintained within preset limits.
2.1.22 ALC-F-1 Liner Breakthrough Monitor ALC-RMI-7 is installed on the discharge of ALC-F-1 liner to monitor for activity breakthrough on the first demineralizer.
The monitor has two alarm setpoints.
The Alert Alarm setpoint is 68,000 cpm above background, and the High Alarm setpoint is 136,000 cpm above background.
2.2 Instruments, Controls, Alarms, and Protective Devices 2.2.1 Cleanup System The Auxiliary Building Emergency Liquid Cleanup System is normally operated and monitored from control panel ALC-PNL-1 located in the TV Honitor and-Control Building which is a separate prefabricated building.
The TV Monitor and Control Building is adjacent to the northwest corner of the Chemical Cleaning Building.
Electrical power is supplied to the Auxiliary Building Emergency Cleanup System from 750 KVA Unit Substation USS 2-33 located on the mezzantrie floor at elevation 305' in the southeast corner of the Turbine Building for Unit 2.
USS 2-33 was originally the power supply to the Control Rod Drive Motors.
480V power from USS 2-33 is supplied to MCC 2-33A located inside the TV Monitor and Control Building.
The HVAC system fan and heaters, the transfer pump, building sump pump, and the 20-ton hoist are powered from MCC 2-33A. A 480-120/208 Vac, 25 KVA transformer, supplied from MCC 2-33A, supplies all other system electrical loads from Power Panel i
MP2-33A, except heat traces and ALC-P-8 which'are supplied from the control rod breaker (2-43).
The EPICOR 11 pumps are controlled through an automatic cor. trol unit which provides AUT0/ MANUAL on-off switches and indicating lights for the pumps, demineralizer high level alarms, and an ON/0FF switch for the unit.
Control power is provided for the EPICO:1 II solenoid operated air supply valves through these units.
The speed of the pumps is controlled by throttling motor operated valves ALC-V260, 261, 262 and 263.
A turbine flowmeter (ALC-FI-1) is provided to monitor process flow rates. Rev. 6/0185P
-, - -. - - - -... - _, - _ -. - - ~. - -. -., - - - _ - _ -
3526-004 All process instrumentation monitored in the control center is mounted on Cleanup Panel, ALC-PNL-1. Audible alarms and indicating lights are provided on this panel for CCB Sump High Level, CCB Ventilation System Trouble, CCB Charcoal Filter High Temperature, CCB High Exhaust Radiation Level, CCB Radiation Monitor Failed, Building Radiation Level, and ALC-F-1, ALC-K-1 and 2 Loop Seal Flow.
Remote indication is provided for the area radiation monitors and the air sampler on the Radiation Monitoring Panel located adjacent to the Cleanup Panel. A complete instrument list including range and setpoints is provided in Table 12, 2.2.2 Ventilation System 2.2.2.1 Heating Unit and Moisture Separator The moisture separator is instrumented with a differential pressure indicator and switch, ALC-OPI-il and ALC-DPS-11.
The heating unit (ALC-E-Hl) is provided with a temperature indicating controller and a high temperature switch.
The temperature indicating controller functions to maintain the heaters energized providing a heater outlet air temperature of no more than 146'F.
Should the air temperature rise to 160*F, the high temperature switch will automatically deenergize the heaters.
If the heaters are to be reenergized, the reset button must be depressed when air temperature at the thermocouple drops below the 160*F temperature switch setpc* int.
Indication of operation of the temperature indicating controller and high temperature switches are provided on the switches, both of which are located in the heater control panel near the heaters on the filtration unit.
Manual energizing /deenergizing of the heater control panel occurs at MCC2-33A.
The heater panel is also deenergized automatically should the system ventilation fan trip or in any other way fail to maintain minimum flow at the fan discharge flow switch.
A red light cn the heater controller panel indicates power available to the heater control panel.
2.2.2.2 Filter Unit Differential pressure indication is provided for the filter unit's moisture separator (ALC-E-F1). While a differential pressure indication (DPI-11) is provided locally, a differential pressure switch (DPS-II) will actuate a remote "Trouble" alarm warning the operator of a restricted flow condition existing in the moisture separator.
(Note:
The moisture separator should be replaced when it exhibits a pressure drop of 1" w.g.) Rev. 6/0185P
i 3526-004 Two differential pressure switches (one not connected) and a differential pressure Indicator (DPI-13) are located on the first HEPA filter (ALC-E-F3) in the Filter Unit for indication and alarm: DPS-13 warns of a high differential pressure condition by actuating the Ventilation Unit common "Trouble" alarm at 3" W.G.
The charcoal filter.is instrumented with a fire detection system. A prealarm (TS-15-1 set at 250*F) will actuate a local amber light, a remote high temperature alarm and a horn warning of increasing temperature in the charcoal bed. At 300*F, (remote common "Trouble" and local red light) alarms will be actuated from TS-15-2 indicating a Hi Hi temperature condition exists in the ced.
Indication of operability of the fire detection system is provided by an "Abnormal Detection" white light, located on the filtration unit fire detection panel.
Also provided on the charcoal absorber is a differential pressure indicating controller (ALC-DPI-14).
This is not connected.
The final stage of filtration in the filtration unit occurs in l
the last HEPA filter (ALC-E-F5).
In addition to being provided with local differential pressure indication (DPI-16),
the remote "Trouble" alarm is actuated on a high HEPA filter differential pressure of 3" W.G. by the locally mounted differential pressure switch (DPS-16).
2.2.2.3 Fan Assembly The fan assembly, as previously noted, is interlocked with the 60 KW heater. A control interlock is provided through the fan and heater circuitry such that the heater may not be energized unless the fan is running. A flow indicating switch (FIS-17) on the discharge of the fan provides a safety interlock:
if the flitration unit is operating and the discharge flow of the fan falls below 4,000 cfm, the hea.ter and fan monitor will trip.
FIS-17 is also tied into the common, remote panei mounted "Trouble" alarm.
The fan is started and stopped from HCC2-33A.
2.2.2.4 Radiation Monitor (Controls)
The Radiation Monitor (ALC-RE-18) is energized and deenergized locally at the monitor cabinet.
Separate control switches are provided: one on the unit itself and another for the monitor sample pump.
(Note: During operation of the Chemical Cleaning Building Ventilation System, the Radiation Monitor O
must be energized at all times). A "Power Available" light is provided on the unit.
i I Rev. 6/0145P i
I
3526-004 Local indication of the ventilation exhaust particulate and/or gaseous activity level is provided on the monitor. At a level of 4.11E-2 pCl particulate, or 3.81E-4 pCi/cc noble gas the High Radiation alarm will sound on the panel in the control shed.
3.0 PRINCIPAL HODES OF OPERATION 3.1 Startup i
3.1.1 Ventilation System Prior to startup of this unit, the manual dampers ALC-E-01 and 02 shall be checked open.
Ensure that the radiation monitor is energized and operational.
When the fan is started (at MCC2-33A) ensure sufficient air flow exists (approx. 4000 CFM minimum) through the unit before energizing the heaters (Note:
Heaters should not energize,if insufficient air flow exists). After startup, verify that ventilation unit temperature, flow and activity indications are normal before leaving unit unattended.
NOTE:
Start push button will have to be depressed and held until flow increases above lower limit or fan will trip.
3.1.2 Cleanup System Initial startup of the Auxiliary Building Emergency Cleanup System will be with the Demineralizers empty of liquid.
The Chemical Cleanup Building Ventilation System shall be in operation prior to operating the cleanup system.
Normal Startup of the Auxiliary Building Emergency Cleanup J
System is accomplished by supplying the system with the process feedwater from CC-T-1, CC-T-2, SOS, or the various source tanks.
Except for the Miscellaneous Haste Holdup Tank (MHHT) the process feedwater is delivered to the process stream by source tank's motive power system.
In the case HHHT is the feedwater source, the supply header is primed initially. Depending on the source of the process feed, the feed supply valve (e.g., ALC-V043, ALC-V242) is then opened 1
and process pump ALC-P-1 started. Startup of ALC-P-1 is accomplished by opening the air supply valve (ALC-V011), stop valve (ALC-V185) and control va've (ALC-V260), the latter is used to control the pump speed.
The water drawn from the feedwater supply header by ALC-P-1 is pumped to demineralizer ALC-F-1.
When ALC-F-1 is full, pump ALC-P-1 will stop automatically on high level.
Similarly, process pump ALC-P-2 is operated until demineralizer ALC-K-1 is full, then ALC-P-3 is operated until demineralizer ALC-K-2 is full.
As soon as the demineralizers are full, processing is then commenced by Rev. 6/0185P i
3526-004 starting pump ALC-P-4 and opening discharge valve ALC-V277.
Using the process pumps respective control valves (ALC-V260 through ALC-V263), the pump speed is adjusted to attain and maintain a balanced flow of about 10 gpm through the demineralizers.
NOTE:
The initial batch quantity will be determined by the efficiency of the demineralizer resin charge and may require a change in resin composition and/or flow rate to effectively process the radioactive waste water.
3.2 Normal Operation 3.2.1 Ventilation System Ouring normal operation, the ventilation unit should require little operator action.
The unit should be periodically checked to ensure that indication is operable and that temperatures, flows and radiation levels are within the normal ranges.
Increasing differential pressures across the moisture separator and HEPA filters are an indication that che components are retaining dirt, etc.
These components should be replaced as required to ensure that flow through the ventilation unit is maximized.
The radiation monitor and recorder should be checked periodically and reviewed for evidence of trends indicating that increasing levels of activity are being discharged. A trend showing increasing discharge activity levels can be indicative of carryover from the filter unit and should be treated accordingly.
3.2.2 Cleanup System Once the flow rate is established for the process, the system operates automatically by starting and stopping the pumps (ALC-P-1, 2, 3 and 4) in order to maintain the proper level in the process tanks.
Instrumentation is provided on the control panel to monitor system parameters and to balance the system to minimize pump cycling.
When a desired volume has been reached in CC-T-2, Transfer Pump ALC-P-5 is started to recirculate at least three tank volumes of water through the Clean Water Receiving Tank after which a sample is drawn for analysis by the THI water chemistry laboratory. Water acceptable for use in the plant will be pumped to the TMI Unit 2 Liquid Waste Disposal System, CC-T-1, COT-1-A or to the Processed Water Storage Tanks. Out of Specification water may be pumped to the Off-Spec Water
, Rev. 6/0185P 4
3526-004 Receiving Batch Tank for reprocessing (See para. 2.1.6 and 2.1.7) or it may be processed directly from CC-T-2 under a feed and bleed scheme.
NOTE:
Normal operation is the same whether the system is being used in the Auxiliary Liquid Cleanup Mode, or in the SDS Polishing Mode.
The exception to this is when the ALC-F-1 liner is bypassed depending on l
cesium and strcntium concentrations.
3.3 Shutdown 3.3.1 Ventilation System The purpose of the ventilation system is to ensure that all air leaving the Chemical Cleaning Building is filtered and monitored for radiation.
Shutdown of the ventilation system will preclude filtration and monitoring of the air and should not be performed unless dictated by other casualty /operationai considerations.
To shutdown the ventilation unit, deenergize the 60 KH heaters, fan (ALC-E-1) and radiation monitor from their respective breakers in MCC 2-33A.
3.3.2 Cleanup System The system is shutdown and flow through the process system stopped by closing the air supply valves to EPICOR II Pumps, ALC-P-1 through 4.
To shutdown the system upon completion of processing a batch, the pumps are secured and the liquid supply valve ALC-V043 or ALC-V086 is closed. Valves ALC-V242 and ALC-V255 close automatically as power is shutdown. Close ALC-V277 to prevent syphoning of the third demineralizer to CC-T-2.
The system is shut down and the affected unit replaced when radiation monitors on any of the demineralizers indicate the unit has collected a quantity of material which is limited by shipping regulations, or system sampling indir.ates that the resins are exhausted chemically.
To replace one of the units, the liner is emptied of water, the three hoses, the level probe cable and the bubbler unit disconnected from the liner, and the remotely operated hoist used to transport the demineralizer to the outside of the Chemical Cleaning Building to the transfer cask. The replacement unit is then installed, the hoses, the level probe cable and the bubbler line reconnected and the system started as described in paragraph 3.1.
Each liner has its own level probe which will be discarded with the liner.
N0_TE :
Shutdown is the same whether the system is being used in the Auxiliary Building Liquid Cleanup mode or in the SDS Polishing mode. Rev. 6/0185P
s 3526-004
- 3. 4 - Special or Infrequent Operation 3.4.1 Filter Change-out When a filter bank requires changing, the Aux. Building Emergency Liquid Clean-up System should be. shutdown.
The ventilation system shall be in operation during the filter change-out.
3.4.2 HIC /Demineralizer Dewatering and Drying The Zeolite Resin Drying System. dries process media (i.e.,
zeolite resin, activated carbon and/or sand) in a 50 cu. ft.
HIC /demineralizer for transportation and disposal at a low level waste disposal facility This is accomplished in a three (3) step process.
First the
' bulk of the free water is removed using procedures associated with HIC installation and removal in EPICOR II and DHCS.
Second, the drying unit's sandpiper is started and its blower is energized to recirculate air down through~the media.
The air is heated as it passes through the blower and as this warm dry air passes through the media it entrains and vaporizes moisture. This warm air then passes.through.the entrainment separator, enroute to the blower inlet, where refrigeration coils condense the water vapor in the air and any entrained water is removed.
Water is removed from the entrainment separator using the dewatering pump. Air is circulated down through the media for four (4) hours.
Finally.-the drying process shifts from downflow to upflow.
This is done in order to have the driest mec"a at the bottom of the container where they can best absorb any water generated through condensation as the container cools during storage and shipment. Air is circulated up through zeolite resin for 12 hours1.388889e-4 days <br />0.00333 hours <br />1.984127e-5 weeks <br />4.566e-6 months <br /> or activated carbon for 20 hours2.314815e-4 days <br />0.00556 hours <br />3.306878e-5 weeks <br />7.61e-6 months <br />. At this point, the relative humidity of the air stream leaving the container should be at or below the required value, indicating thct the media is dry.
The system is then shut down and the container is ready to be sealed and shipped.
)
The dewatering pump (sandpiper) not only removes entrained water from the separator tank but, for the most part, maintains the process under a vacuum thereby minimizing the potential spread of contamination due to hose / connection leaks.
The excess air removed by the dewatering pump is directed through a filtered drain path / container approved by Rad Con personnel.
The drying system is a skid mounted unit which provides the mobility necessary to dry HIC /demineralizers at their respective locations (EPICOR II/0HCS), vice relocating liners to a central area.
This will reduce the amount of manrem i
r 1 Rev. 6/0185P m,. - - _.. _ -. - _ _. _ _ _ _, _ _. _,,, -
3526-004 exposure generally received when handling radwaste processing liners.
The services required for drying operations are 480 VAC (standard 4 pole welding receptacle), 100 psi service air and DH or processed water needed to fill and flush the system.
3.4.3 Remove Closure Device The Remote Closure Device is designed to provide a safe and efficient means of sealing an EPICOR II or DHCS HIC /demineralizer to meet the requirements for disposal at a low level waste disposal facility.
Performing this operation (installing the ENVIR0 ALLOY Lid) to a HIC /demineralizer is done remotely in order to minimize exposure of operating personnel to ionizing radiation.
This is accomplished by means of hydraulic skid. Aligning the closure head with the HIC /demineralizer is performed using the CCTV cameras and monitor. Maintaining proper alignment is important so that the eight wedges are driven evenly into their respective holes on top'of the HIC /demineralizer.
This operation pushes down on the lid and seals the container.
Once the container is sealed, it can be removed from service for storage and/or shipment to the burial site.
3.5 Emergency 3.5.1 Loss of Chemi:al Building Ventilation System On loss of the Chemical Cleaning Building Ventilation System, the Auxiliary Building Emergency Liquid Cleanup System shall be shutdown, and the Chemical Cleaning Building sealed.
3.5.2 Loss of Electrical Power On loss of electrical power to the Chemical Cleaning Building MCC 2-33A, EPICOR II Pumps ALC-P-1, 2, 3 and 4 will automatically stop as the solenoid valves on the air supply lines fall closed on loss of power.
Valves ALC-V043 and V086 fall "As Is".
Valve ALC-V255 falls closed. Valve ALC-V242 falls closed on loss of power to stop flow from tank CC-T-1.
If flow through the system is from the Misc. Haste Holdup Tank HDL-T-2, operator action is required to close valve HDL-V2628.
Power will be lost to Ventilation System 60KH heaters, exhaust fan and radiation monitor.
The ventilation unit inlet and outlet dampers should be closed.
This same procedure should be followed in the event that only the exhaust fan is lost.
\\
On loss of power to the 2-43 supply, backup air supply and j
heat traces will not be available.
, Rev. 6/0185P
3526-004 When electrical power is lost, place all automatically controlled equipment to the manual 0FF position.
Then, when-emergency power is available, restart the system.
3.5.3 Loss of System Air Loss of System Air will cause the EPICOR II Pumps to secure until either the system compressors can be put into service or the Service Air System can be returned to service.
NOTE:
EPICOR II uses in-plant service air as normal supply air.
3.5.4 Fire 3.5.4.1 Ventilation System Should they become too ilot, the charcoal absorber beds in the ventilation unit could ignite. Upon verification of ignition of the charcoal bed, the manually actuated fire protection sprays should be cut in.
3.5.4.2 Cleanup System If a fire occurs in the TV Monitor Control Building the sprinkler system will automatically initiate.
The Chemical Cleaning Building is provided with a hose station on the mezzanine for manual firefighting.
4.0 HAZARDS AND PRECAUTIONS 1
Since the system is handling radioactivity contaminated fluids, all appropriate health physics precautions must be observed during operation and maintenance. Under no circumstances will discharges be made to the environment without proper authorization.
j i
The Chemical Cleaning Butiding Ventilation System will process potentially contaminated air. As such, any operations or maintenance associated with the system should fully incorporate appropriate Health Physics guidelines / requirements. Any solid or liquid ventilation system waste must be sampled and cleared by HP before release to environment.
Ensure that positive verification of charcoal bed fire exists before manual initiation of fire protection spray system since water will damage the charcoal bed.
Flushing connections are provided at various locations in the system and provide a means for reducing the radiation levels in the piping.
Flushing should be exercised when maintenance is performed.
, Rev. 6/0185P
3526-004 TABLE l' EPICOR II PUMPS Pump Details Identification ALC-P-1, 2, 3, 4 Number Installed 4
Manufacturer Warren Rupp Co.
Model no.
SA 2-A Type Double opposed diaphragm 0
Maximum rated capacity at 90 psi air supply 120 GPM at 45 ft of head j
Operating point capacity it 90 psi air supply 20 GPM at 170 Ft of head Max. air pressure, psi 125 4
Lubricant 011 8
J 0
)
t i
i
! Rev. 6/0185P
3526-004 TABLE 2 TRANSFER PUMP Pump Details Identification ALC-P-5 Number Installed 1
Manufacturer Ingersoll Rand Model No.
3 x 2 x 10 Type HOC, Group 2, ANSI A60 Type Horizontal Centrifugal Standard Material Desigration Col. DI Rated Speed, rpm 1750 Rated Capacity, gpm 200 Rated Total Dynamic Head, Ft 100 l
Shutoff Head, Ft 121 Design Pressure, Casing, psig 200 Design Temperature, *C 110 Lubricant SAE 20 or 30 Oil Motor Details Manufacturer Gould Century Elect. Div.
Type F-C Enclosure TEFC Rated Horsepower, HP 10 Speed, rpm 1700 Lubricant / Coolant Grease / air Power Requirements 480V AC/12.5A, 3 Phase, 60HZ Power Source MCC-2-33A 4 Rev. 6/0185P
i 3526-004 TABLE 3 FILTERS Resin Filters (Traps)
Tank Details l
Identification ALC-F-4A, B, C l
Number Installed 3
Manufacturer Capolupo & Gundal, Inc.
Installation Horizontal Outside diameter / height, ft 10 x 28 Shell material PVC Design pressure, psi 100 CRUD FILTERS Identification ALC-F-5 Number Installed 1
Manufacturer of Housing Pall Trinity Micro Corp.
l Installation Vertical Outside diameter / height, inches 7 x 34 Shell thickness, inches 0.165 Shell material SA-312 TP304 l
Design pressure, psi 150 l
Particle size rating 1 micron, nominal'
, Rev. 6/0185P
3526-004 TABLE 4 DEMINERALIZERS Tank Details Identification ALC-F-1, ALC-K-1, ALC-K-2 Number Installed 3
Manufacturer EPICOR Installation Vertical Outside diameter / height, ft-in 6x6 (ALC-F-1, ALC-K-1 and ALC-K-2) 4x4 (ALC-K-2 optional)
Shell thickness 1/4" Shell material Carbon Steel Design pressure, psi 2
03 Identification ALC-F-1 Number Installed 1
Manufacturer Nuclear Packaging Inc.
Installation Vertical Outside diameter / height, ft-in 4'0" x 4'3" Shell thie.kness 3/8" Shell material Ferallum (ASTM A240 UNS Desig S-32550)
Design pressure, psi 10 Rev 6/0185P
3526-004 TABLE 5 MISCELLANEOUS HASTE HOLD-UP TANK Tank Details Identification WDL-T-2 Manufacturer Richmond Engineering Co. Inc.
Capacity - gallons 19,518 Installation Horizontal Outside diameter and length, ft-in 10' - 9 1/4"; 32' - 4 5/8" Shell material SA-240, 304 S/S Shell thickness, in.
3/8 Desian temperature, *F 150 Design pressure, psig 20 Corrosion allowance, in.
O Design code 1968 ASME, Sec. III, Class 3 Code stamp required ASME Code i Rev. 6/0185P j
)
3526-004 TABLE 6 CLEAN HATER RECEIVING TANK
- Tank Details Identification CC-T-2 Number Installed 1
Manufacturer Chicago Bridge & Iron Co.
Capacity - gallons 133,689 Installation Vertical Outside diameter & height - ft 25' - 35' Shell material 304 Stainless Steel Shell thickness 1/16" to 3/8" Design pressure Atmospheric Corrosion allowance O
Code stamp required No Rinse Hold Tank for 0.T.S.G. Chem. Clean Sys. Rev. 6/0185P
3526-004 1
TABLE 7 0FF-SPEC HATER RECEIVING /8ATCH TANK
- Tank Details Identification CC-T-1 Number Installed 1
Manufacturer Chicago Bridge & Iron Co.
Capacity - gallons 85,978 Installation Vertical Outside diameter & height, ft-in.
21'-10" & 39'-0" Shell material 304 Stainless Steel Shell thickness Design temperature. *F 250*F Design pressure Full vacuum to 75 psig Corrosion allowance O
Code stamp required Yes Chemical Cleaning Solution Tank for 0.T.S.G. Chem. Clean Sys. Rev. 6/0185P
il' 3526-004-i TABLE 8 l
l SUMP PUMP l
' CHEMICAL CLEANING BUILDING
-Pump Detail Identification CC-P-2A Number Installed 1
Manufacturer
.Gould Model No.
3171 Type Vertical Rated speed, rpm 3600 Rated'capactty, gpm
.100 Rated total heu ft 250 Min. SL-
,e required
'l Foot Design pressure, casing, psig 150 Design temperature, *F 450 Lubricant Hater-Min. Flow requirements, gpm Motor Details
'l Manufact er General Electric Type Vertical Induction Enclosure TEFC Rated Horsepower, HP a
Speed, rpm 3600 Lubricant / Coolant Grease / Air Power lequirements 480V AC, 3 Phase, 60 HZ-Power Source MCC ?-33A Rev. 6/0185P 4
-.. _ ~ -
3526-004 TABLE 9 MONORAIL HOIST SYSTEM Number Installed:
1 Manufacturer:
'Harnischfeger, Inc., P&H Model:
- 36CS23E Capacity:
20 ton Total Lift:
25'-6" Sp6ed:
Holst:
20 FPM maximum (90%. load) 10 FPM n.edium 5 FPM low 1
FPM creep-Trolley:
50 FPM
- Control:
Holst:
Quad - Speed
.s Trolley:
Single Speed Power Supply:
460 V AC, 3. Phase, 60 Hz MCC 2-33A Control Voltage:
110 V AC Control Station:
local and Remote six pushbutton pendant control; deadman type element:
control Reeving:
Four part single reeved Rev. 6/0185P
. _.,. _.....__, ~ ~._~ _,_ _ _..., _ _....
3526-004 TABLE 10 CHEMICAL CLEANING BUILDING VENTILATION SYSTEM NAMEPLATE DATA MSA Filter l'qit Identification No. ALC-E-H1 60KW Chromolax Heater Unit 480v,.3 Phase, 60 Hz Cat. Number SCCP-080-3480 Type J 0-800 *F Temperature Controller Type J 0-800 *F High Limit with Manual Reset Internal Industrial Fan Identification No. ALC-E-1
-3000'CFM Fan Unit 30 HP 460 volts AC, Phase, 60 Hz ID Number P28G353G-G7-XD Eberline Ping - 2A Off Line Effluent Monitor 3 Channel Readout - gaseous, particulate, iodine 110 volts, AC, 1 Phase, 60 Hz Self contained sample / return pump (4 cfm)
) Rev. 6/0185P
~
__...._..._..._-.._.__,__.._.a
H 3526-004-TABLE 11 AIR COMPRESSORS Identification ALC-P-7 ALC-P-8 Number Installed 1
1 Vendor le Roi (Dresser Industries Inc.)
Type Single Stage. Rotary Screw Model No.
30SS 25SS Capacity (CFM at PSIG) 115 at 100 98 at 100 110 at 125 (Ma.<.)
95 at 125 (Max.)
'30, 1755 25, 1760 Power Source 460V, 3 Phase, 60 Hz 460V, 3 Phase -60 Hz MCC 2-33A Power Panel PDP-W2 l
1 Rev. 6/0185P
3526-004 TABLE 12 Page 1 of 9 i
i INSTRUMENTATIuN AND CON 1ROL I
INPUT / SPAN TAG NC SERVIrE LOCATION SUPPLIER MODEL NO.
OUTPUT / SCALE SET POINT REMARKS ALT-AE-1 EPICOR II Sys. influent Piping L&N 4909-010-0-1000 MMH 0/CM N/A conductivity cell 44-088-1-02 I
ALC-AI-1 EPICOR II Sys. influent ALC-PNL-1 L&N 7075-1-01i-0-1000 MMH 0/CM N/A conductivity indicator 120-0a1 ALC-AE-3 ALC-K-1 demin. effluent Piping L&N 4909-10 0-1000 MMH 0/CM N/A conductivity cell 088-1-02 ALC-AI-3 ALC-K-1 demin. effluent ALC-PNL-1 L&N 7075-1-011-0-1000 MMH 0/CM N/A-conductivity indicator 120-001 I
ALC-AE-4 EPICOR II Sye.. effluent Piping L&N 4909-10 0-1000 MMH 0/CM N/A conductivity cell 088-1-02 i
ALC-AI-4 EPICOR II Sys. effluent ALC-PNL-1 L&N 7075-1-011-0-1000 MMH 0/CM N/A t
conductivity indicator 123-001-000
?
ALC-AE-6 ALC-K-1 demin. ef fluent Piping L&N 7774-3-1-01 0-14 N/A pH cell ALC-AI-6 ALC-K-1 demin. effluent ALC-PNL-1 L&N 7075-1-011-0-14 N/A pH indicator 120-001 ALC-AE-7 EPICOR II Sys. effluent Fiping L&N 7774-3-1-01 0-14 N/A pH call I
ALC-AI-7 EPICOR II Sys. effluent ALC-PNL-1 L&N 7075-1-011-0-14 N/A pH indicator 120-001 t Rev. 6/0185P
3526-004 l
TABLE 12 (Cont'd)
Page 2 of 9
.l i
INSTRUMENTATION AND CONTROL INPUT / SPAN TAG NO.
SERVICE LOCATION SUPPLIER MODEL NO.
OUTPUT /SCAlf SET POINT REMARKS l
~
ALC-FE-1 CC-T-2 inlet flow Piping Hoffer H0 3/4 2.5-29 GPM N/A turbine flow meter 2529-B-F1 i
ALC-FQI-1 CC-T-2 inlet flow ALC-PNL-1 Hoffer 26ECPRTA 0-99,999,999 GAL N/A totalizer / indicator 0-999MGPM t
ALC-FE-2 CC-T-2 discharge Pipir.g Foxboro OP-FTT 0-100 GPM N/A I
flow orifice plate 0-250" WG.
1 l
ALC-FT-2 CC-T-2 discharge ALC-RCK-1 Foxboro
.NE 13DM-0-100" WG.
N/A flow transmitter II H2-A-E 4-20 MADC ALC-FY-3 CC-T-2 discharge flow ALC-PNL-1 Foxboro 66AT-03 4 to 20 MADC N/A.
i j
square root converter 4
ALL-iQ-2 CC-T-2 discharge ALC-PNL-1 Fisher &
52-ET 4-20 MADC N/A flow integrator Porter 0-107 TPH i
i ALC-FI-2 CC-T-2 discharge' ALC-PNL-1 Fisher &
51-1371 4-20 MADC N/A j
flow indicator Porter 0-100 GPM i
I ALC-FY-4 CC-T-2 discharge ALC-PNL-1 Foxboro 610-AT-03
- 20V 60 Hz'
_ I j
flow power supply 4-20 MADC I
L
'ALC-LI-1 CC-T-1 tank level ALC-PNL-1 Foxboro 257P-1C 4-20 MADC f
indicator 0-33 ft i
ALC-LT-1 CC-T-1 tank level Local Foxboro NE13DH-.
4-20MADC N/A l
j transmitter II H -A-E 0-340" H O 2
2 24"-480"
,! Rev. 6/0185P 4
L i
l 2
3526-004 TABLE 12 (Cont'd)
Page 3 of 9 INSTRUMENTATION AND CONTROL INPUT / SPAN TAG NO.
SERVICE LOCATION SUPPLIER HDDEL NO.
OUTPUT / SCALE SET POINT REMARKS ALC-LY-1 CC-T-1 tank level ALC-PNL-1 foxboro 610AT-34 120V 60 Hz N/A transm. PWR supply 4-20 MADC' t
J ALC-LI-2 CC-T-2 tank level ALC-PNL-1 foxboro 257P-1C 4-20HADC
{-
indicator 0-35 ft ALC-LT-2 CC-T-2 tank level Local Foxboro NE13DH-0-414" H O.
N/A 2
transmitter II H2-A-3 4-20 HADC q
8"-428" ALC-LY-2 CC-T-2 tank level ALC-PNL-1 Foxboro 610AI-03 120V 60 Hz N/A f
transa. PWR supply 4-20 r1ADC ALC-LS-1 Chem. Clean. Bldo.
Local Warrick 2CIFO 0-35 ft.
36 1/4 in. Below mntg.
sump level switcn 48 1/4 in, face.
90 3/8 in.
ALC-LAH-1 Chem. Clean. Bldg.
ILC-PNL-1 ROCHESTER 36 1/4 in. Below entg..
sump Hi alarm face.
ALC-PI-l ALC-P-5 discharge ALC-RCL-1 Arthur U.S. Ga, 0-160PSIG N/A Purchased with diaphragm f
l pressure gage Moore 1981 seal & capillary.
ALC-PI-2.
Service air ALC-RCL-1 Arthur U.S. Gage 0-160PSIG N/A l
pressure gage Moore 1981 f
i ALC-FI-3 ALC-P-5 seal water Local Fisher &
10A1152W/5 0-14.9 GPH N/A l
1 flow indicator Porter' 1-1400KA & 50 0-100%
-i WT4000 i
t 4
Rev. 6/0185P L -
f
3526-004 j
TABLE 12 (Cont'd)
Pane 4 of 9 INSTRUMENTATION AND CONTROL INPUT /SFAN t
TAG NO.
SERVICE LOCATION SUPPLIER MODEL NO.
OUTPUTrSCALE SET POINT REMARKS l
ALC-PI-3 Demin. water header ALC-RCL-1 Arthur U.S. Gage 0-160 PSIG N/A pressure gage Moore 1981 ALC-PI-4 CC-P-2A discharge ALC-RCK-1 Arthur U.S. Gage 0-160 PSIG N/A f
pressure gage Moore 1981 l
l ALC-RM-1 ALC-F-1 gamma detector Local Victoreen 847-1 1-10,000 REM /HR N/A i
(lef t shield) 4 i
ALC-RM-2 ALC-F-1 gamma detector Local Victoreen 84/-1 1-10,000 REM /HR N/A i
(right shield)
J ALC-RM-3 ALC-K-1 gamma detector Local Victoreen 847-1 1-10,000 REM /HR N/A (left shield)
ALC-RM-4 ALC-K-1 gamma detector Local Victoreen 847-1 1-10,000 REM /HR N/A (right shield)
ALC-RM-5 ALC-K-2 gamma detector Local victoreen 847-1 1-10,000 REM /HR N/A (left shield)-
1 j
ALC-RM-6 ALC-K-2 gamma detector Local Victoreen-847-1 1-10,000 REN/HR N/A (right shield) i ALC-RM-7 EPICOR II "f" Liner Local Victoreen 843-30 1-10E7 CPM N/A Effluent Monitor ALC-RM-8 Area Monitor -
Local Victoreen 847-1 0.1 to 10E7 MR/HR N/A ALC-F-1 1
i i
i i
i j Rev. 6/018SP j
f I
I 3526-004 i
TABLE 12 (Cont'd)
Page 5 of 9 l
INSTRUMENTATION AND CONTROL' l
1 INPUT / SPAN TAG NO.
SERVICE LOCATION SUPPLIER MODEL NO.
OUTPUT / SCALE SET POINT REMARKS I
ALC-Rt+-9 Area Monitor -
Local Victoreen 857-30 0.1 to 10E5 HR/HR N/A Mezzanine ALC-RM-10 Area Monitor -
Field Victoreen 857-30 0.1 to 10E5 MR/HR N/A j
Tank Area ALC-RM-11 Area Monitor -
Field Victoreen 857-30 0.1 to 10E5 HR/HR-N/A^
Sump Area f
I ALC-RMI-1 ALC F-1 ganuna read-out ALC-PNL-1 Victoreen 856-30 1-10,000 REM /HR N/A' (left shield) 846-2 ALC-RMI-2 ALC-F-1 gasuna read-out ALC-PNL-1 Victoreen 856-30 1-10,000 REM /HR N/A 1
(right shield) 846-2 ALC-RMI-3 ALC-K-1 gasuna read -cut ALC-PNL-1 Victoreen 856-30 1-10,000 REM /HR N/A.
(left shield) 846-2 ALC-RMI-4 ALC-K-1 gasuna read-out ALC-PNL-1 Victoreen 856-30 1-10,000 REM /HR N/A (right shield) 846-2 t
ALC-RMI-5 ALC-K-2 gasuna read-out ALC-PNL-1 Victoreen 856-30 1-100 REM /HR N/A
}
(left shield)
Jf j
ALC-RMI-6 ALC-K-2 gasuna read-out ALC-PNL-1 Victoreen 856-30 1-100 REM /HR N/A (right shield)
I ALC-RMI-7 EPICOR II "F" Liner ALC-PNL-1 Victoreen 842-11 1-10E7 CPM N/A f
Ef fluent Monitor i
l l'
i Rev. 6/0185P' i
t 2
i l
3526-0o4 TABLE _12 (Cont'd)
Page 6 of 9 INSTRUMENTATION AND CONTROL INPUT / SPAN TAG NO.
SERVICE LOCATION SUPPLIER MODEL NO.
OUTPU'/ SCALE SET POINT REMARKS ALC-RMI-8 Area Monitor ALC-PNL-2 Victoreen 846-2 0.1 to 10E7 MR/HR N/A Readout ALC-F-1 ALC-RMI-9 Area Monitor ALC-PNL-2 Victoreen 856-30 1 to 10E5 HR/H N/A Readout-Hezzanine ALC-RMI-10 Area Monitor ALC-PNL-2 Victoreen 856-30 1 to 10E5 MR/H N/A Readout-!ank area ALC-RMI-11 Area Monitor ALC-PNL-2 Victoreen 856-30 1 to 10E5 MR/H 10 MR/HR Readout-Sump area ALC-TI-1 Influent Temp. Indicator Local ALC-IS-10 El. Heater Temp Switch filter Unit Chromolax C76 AK-1200 160*f 106-20-AA ALC-TIC-10 El. Heater Temp Indicator filter Unit Chromolax 0-200f 146*f and Control ALC-DPI-11 Prefilter filter Unit HSA 0-1" WG.
N/A DP Indicator 0-2" WG.
ALC-DPS-11 Prefilter filter Unit DWYER 1824-2 0.5-2" WG.
1.75" WG.
DP Switch ALC-DPI-13 HEPA filter DP Indicator filter Unit MSA 0-4" WG.
N/A ALC-DPS-13 HEPA filter DP Switch filter Unit DWYER 1824-5 1.5-5" WG.
3" WG. Rev. 6/0185P
l 3526-004 TABLE 12 (Cont'd)
Page 7 of 9 INSTRUMENTATION AND CONTROL INPUT / SPAN 1
. TAG NO.
SERVICE LOCATION SUPPLIER MODEL NO.
OUTPUT / SCALE SET POINT REMARKS
[
ALC-TE-15 Charcoal Filter Temp Filter Unit HSA f
Element
?
r I
ALC-TS-15-1 Charcoal Filter Temp Filter Unit MSA 220'F l
Switch for Hi Alarm ALC-TAH-15A Charcoal Temp. Alarm Filter Unit ALC-TAH-158 Charcoal Temp. Alarm ALC-PNL-1 4
4 ALC-TS-15-2 Charcoal Filter Temp Filter Unit MSA 325'F 1
i l
ALC-TAHH-15 ALC-E-F4 Charcoal Filter Unit Adsorber Temp.
l ALC-DPI-16 HEPA Filter DP Indicator Filter Unit MSA-0-4" WG.
r.
ALC-DPS-16 HEPA Filter DP Switch Filter Unit MSA 1.5-5" WG.
3" WG.
ALC-FE-17 Exhaust Flow Element Duct Dietrich ANR-76 0-0.3" WG.
(0-8000 scfe) 3 ALC-FIS-17 Exhaust Flow Indicator Local DWYER 0-0.5" WG.
0.1" WG.
)
and Switch 0-0.5" WG.
l ALC-RE-18 Exhaust Radiation Local Eberline PING-2A Detector l
ALC-RI-18 Exhaust Radiation Local Eberline PING-2A 10-106 4,ji -2 pCi Particulate E
cp, Indicator Iodine (not in service)
E 3.81 -4 pCi/cc j
, Rev. 6/0185P 1
c
~
i 3526-004 TABLE 12 (Cont'd)
Page 8 of 9 INSTRUMENTATION AND CONTROL INPUT / SPAN
[
TAG NO.
SERVICE LOCATION SUPPLIER N00EL NO.
OUTPUT / SCALE SET POINT REMARKS I
ALC-RR-18 Exhaust Radiation Local Eberline PING-2A Recorder t
ALC-UA-19 Air Filtration Unit ALC-PNL-1 Rochester (Later)
Trouble t
i ALC-FHS-20 Air filtration Unit MCC GE CR-2940 Fan Control ALC-OPS-1 ALC-P-5 DP Switch Local SOR 102AS-K603 Psid corresponding to 40 gpm and 90 gpm.
SI-TTX l'
ALC-LS-21 Loop Seal Level High Local B/W 2-RH 2-1/2" ALC-UA-22 Cap-Gun Rad.
ALC-PNL-1 Rochester From RM-1-12
+
Trouble ALC-FG-23 Aux. Bldg. Liquid Clean Piping N/A Up Sampling System Flow ALC-HS-24 Tank CC-T-1&2 ALC-PNL-1 GE CR2940 W/UB Selector Switch 200A Contact Level Interlock
^
L N/A ALC-F-1 Level Field CAP-GUN
-(Later)
(Later)
High-5" from
-Controls air supply F
controller top of tank to ALC-P Low-12" from top of tank Rev. 6/0185P l
l l,
i l
3526-034 TABLE 12 (Cont'd)
Page 9 of 9 INSTRUMENTATION AND CONTROL INPUT / SPAN TAG NO.
SERVICE LOCATION SUPPLIER MODEL NO.
OUTPUT / SCALE SET POINT REMARKS N/A ALC-K-1 Level field CAP-GUN (Later)
Controls air supply cont roller to ALC-P-2 N/A ALC-K-2 Level field CAP-GUN (Later)
Controls air supply controller to ALC-P-3 N/A ALC-F-1 Hi Hi Ca p-Gun CAP-GUN 3" from top Level Alarm Control Unit of tank N/A ALC-K-1 Hi Hi Cap-Gun CAP-GUN 3" from top Level Alarm Control Unit of tank N/A ALC-K-2 ni Hi Cap-Gun CAF-GUN 3" from top Level Alara Control Unit of tank Rev. 6/0185P
3526-004 TABLE 13 Page 1 of 2 i
EPICOR II RADWASTE PROCESSING SYSTEM AUX. BLDG. EMERGENCY LIQUID CLEANUP MODE OVERALL OBJECTIVES: (a) Achieve sufficiently high DF's to release processed water at 10 GPM to satisfy tech. spec. criteria.
(b) Process water at 10 GPM.
(c) Minimize personnel exposure.
(d) Process water at the lowest possible cost.
SPECIFIC OBJECTIVES:
Process Vessel Contact Gallons Radiation Prece. sed Total Level to Reach Number of Projected Changeout Changeout Containers Shipping Container Vessel size Primarv Purnose Comoosition Criteria Criteria Reauiredf5)
Cateaorv
- 1 First Demin.
4'D x 4'H 1.
Na Removal Mixed Cation 1.000 R/Hr.
Up to 50 Large Quantity 2.
Other Cation Resin on top / (1) 100.000 (6) or Type B Removal Anion on 3.
Anion Removal bottom C2 Second Demin.
4'D x 4'H Cation Polishing Mixed Cation 400 R/Hr.
Up to 15 Type B or LSA Anion Polishing Resin (2) 150.000
] Type A (6)
Anion Resin 03 Third Demin.
6'D x 6'H Water Polishing Mixed Resin 20 R/Hr. (3)
Up to 7
LSA ] Type A 250.000 Guard Bed C4 Strainer 2'H x 1 1/2'W x Catch Resin fines Strainer 2-3 R/Hr.
150.000 LSA I 1/2'L (4) 05 Post Filter 2' x 1 1/2' x 1 1/2' Colloids Removal 1 Micron 2-3 R/Hr.
150.000 2
LSA Cart ridge Rev. 6/0185P
f 3526-004 TABLE 13 (Cont'd)
Page 2 of 2
?
NOTES:
l (1) The 1.000 R/Hr. limit is based upon the 1,300 curie limit of the LL-60-150/TVA shipping cask projected for use.
l l
(2) The 400 R/hr. limit is based upon a level af margin required to prevent inadvertent contamination of the 6' x 6' demin. causing this larger demin. to become a large quantity versus an LSA shipment. This change in shipping category could be caused by excessive strontium loading occurring during breakthrough of the cation polishing first demin.
l (3) The 20 R/hr. limit is based upon a handling limit to control personnel exposure and a LSA category shipping limit (25 R/hr.).
(4) The 2-3 R/hr. limit is a handling limit.
(5) The total number of containers is based upon processing the 28f 000 gallons of water existing on July 24, 1979. This value will change as the stored water f rom daily inleakage increases.
(6) A large quantity category will result sirce the liner will contain greater than 0.3 mc/gn of activity.
(7) Table updated to conclusion of original EPICOR II design objectives, namely the completion of processing accident generated Auxiliary and fuel Handling Building Water.
- Rev.'6/0185P l
i
'I
~
3526-004 l
TABLE 14 EPICOR II i
RADWASTE PROCESSING SYSTEM (SDS POLISHING MODE) l l
OVERALL OBJECTIVES: (a) Polish the Submerged Demineralizer System ef fluent water suf ficiently to satisfy tech. spec. criteria.
(b) Process water at 10 GPM.
(c) Hinimize personnel exposure.
(d) Process water at the lowest possible cost.
l l
SPECIFIC 08,1ECTIVES:
Process Vessel Contact Gallons Radiation Processed Total Level to Reach Number of Projected Changeout Changeout Containers Shipping Container Vessel Size Primarv Purgnie Cocoosition Criteriafil Criteria Reouired Cateoorv 01 First Demin.
6'D x 6*H Na Removal Cation (top)/ [ 20R/Hr Up to 70 LSA ] Type A' Other Cation Anion (bottom) 50,000 Removal Anion Removal
- 2 Seconj Demin.
6*D x 6*H Anion Removal Mixed Resin
[ 1 R/Hr 200,000 20 LSA or LSA ] Type A Cation Removal 03 Third Demin.
4'O x 4'H Polishing Mixed Resin
[ 1 R/Hr 200,000 15 LSA Guard Bed j
i 04 Strainer 2*H x 1 1/2'W x Catch Resin Fines Strainer
[ 1 R/Hr 150,000 LSA 1 1/2't
[
05 Post Filter 2' x 1 1/2' x 1 1/2' Colloids Removal 1 Micron
[ l R/Hr' 150,000 2
LSA Cartridge l
NQlE:
(1) Process ' Vessels will not be changed out on radiation levels. Values shown are the anticipated dose rates when chemical analysis indicates change out.
l (2) Reflects usage projecting through 1984. Rev. 6/0185P
TABLE 15 3526-004 AUXILIARY BUILDING EMERGENCY LIQUID CLEANUP SYSTEM (EPICOR II)
VAUVE LIST DESIGN MANUFACTURERI PRESSURE VALVE NO.
SIZE TYPE DESCRIPTION PC NO.
MODEL TEMPERA TURE CDHMENTS ALC-V0001 3/4 GLOBE-600#-SH-40S Process Suction 68817 LADDISH 150/120 line Vent CAT.# 7661-2407-07A ALC-V0002 3/4 GLOBE-600#-SW-40S Process Suction 68817 LADDISH 150/120 Line Vent CAT.# 7661-2407-07A ALC-V0003 3/4 GLOBE-600#-SH-40S Process Suction HANCOCK 150/120 Line Prime and CAT.# 5500W-1 Fill Valve ALC-V0004 1
GLOBE-600#-SH-40S Chemical Addition HANC0CK 150/120 Line for CC-T-1 CAT.# 5500W-1 ALC-V0005 2
GLOBE-600#-SW-40S Discharge Line HANC0CK 150/120 From CC-T-1 CAT.# 5500W-1 ALC-V0006 2
GATE-600#-SW-40S Clean Water Dis-ALOYC0 150/120 charge Line to FIG.# 110 Units 1 & 2 ALC-V0007 2
GATE-600#-SW-40S Truck Fill ALOYC0 150/120 Connection FIG.# 110 ALC-V0008 2
GATE-600#-SN-40S Truck Fill ALOYC0 150/120 Connection FIG.# 110 ALC-V0009 3/4 GLOBE-600#-SW-40 Service Air to HANC0CK 150/120 ALC-P-2 CAT.# 5500W-1 1 Rev. 6/0186P
l TABLE 15 (Cont'd) 3526-004 AUXILIARY BUILDING EMERGENCY LIQUID CLEANUP SYSTEM (EPICOR II)
VALVE LIST DESIGN MANUFACTURER /
PRESSURE VALVE NO.
SIZE TYPE DESCRIPTION PO NO.
MODEL TEMPERATURE COMMENTS ALC-V0010 3/4 GLOBE-600#-SW-40 Service Air to HANCOCK 150/120 l
ALC-P-1 CAT.# 5500W-1 ALC-V0011 3/4 GLO6E-600#-SW-40 Olled Air to HANC0CK 150/120 ALC-P-1 CAT.# 5500W-1 ALC-V0012 3/4 GLOBE-600#-SW-40 Service Air to HANC0CK 150/120 ALC-P-1 CAT.# 5500W-1 ALC-VC013 3/4 GLOBE-600#-SW-40S Demin. Water to 68817 LADDISH 150/120 ALC-P-4 CAT.# 7661-2407-07A ALC-V0014 3/4 GLOBE-600#-SW-40S Demin. Water to 68817 LADDISH 150/120 ALC-P-4 CAT.# 7551-2407-07A ALC-V0015 3/4 GLOBE-600#-SW-40S Demin. Water to 69001 OBERT 150/120 ALC-P-3 TYPE # 103 j
ALC-V0016 3/4 GLOBE-600#-SW-40S Demin. Water to 69001 OBERT 150/120 ALC-P-3 TYPE # 103 ALC-V0017 3/4 GLOBE-600#-SW-40S Demin. Water to 69001 OBERT 150/120 i
ALC-P-2 TYPE # 103 ALC-V0018 3/4 GLOBE-600#-SW-40S Demin. Water to 69001 OBERT 150/120 ALC-P-2 TYPE # 103 1
ALC-V0019 3/4 GLOBE-600#-SH-40S Demin. Water to 69001 OBERT 150/120 ALC-P-1 TYPE # 103 I Rev. 6/0186P
I TABLE 15 (Cont'd) 3526-004 AUXILIARY BUILDING EMERGENCY LIQUID CLEANUP SYSTEM (EPICOR II)
VALVE LIST DESIGN MANUFACTURER /
PRESSURE VALVE NO.
SIZE TYPE DESCRIPTION PO NO.
MODEL TEMPERATURE COMMENTS ALC-V0020 3/4 GLOBE-600#-SH-40S Process Line Flush 69001 CBERT 150/120 Connection TYPE # 103 ALC-V0021 3/4 GLOBE-600#-SW-40 Service Air to HANC0CK 150/120 ALC-P-4 CAT.# 5500W-1 ALC-V0022 3/4 GLOBE-600#-SW-40 Olled Air to HANC0CK 150/120 i
ALC-P-4 CAT.# L500W-1 ALC-V0023 3/4 GLOBE-600#-SW-40 Service Air to HANCOCK 150/120 ALC-P-4 CAT.# 5500W-1 ALC-V0024 3/4 GLOBE-600#-SW-40 Service Air to HANC0CK 150/120 ALC-P-3 CAT.# 5500W-1 l
i ALC-V0025 3/4 GLOBE-600#-SW-40 Olled Air to HANC0CK 150/120 ALC-P-3 CAT.# 5500W-1 ALC-V0026 3/4 GLOBE-600#-SH-40 Service Air to HANCOCK 150/120 ALC-P-3 CAT.# 5500W-1 ALC-V0027 3/4 GLOBE-600#-SW-40 Service Air to HANCOCK 150/120 ALC-P-2 CAT.# 5500W-1 ALC-V0028 3/4 GLOBE-600#-SW-40 Olled Air to HANC0CK 150/120 ALC-P-2 CAT.# 5500W-1 ALC-V0029 3/4 GLOBE-600#-SW-40S Sampled Line From 68817 LADISH 150/120 ALC-P-5 CAT.# 7661-2407-07A i Rev. 6/0186P-
TABLE 15 (Cont'd) 3526-004 AUXILIARY BUILDING EMERGENCY LIQUID CLEANUP' SYSTEM (EPICOR II)
VALVE LIST DESIGN MANUFACTURER /
PRESSURE-VALVE NO.
SIZE TYPE DESCRIPTION PO NO.
MODEL TEMPERATURE COMMENTS ALC-V0030 3/4-GLOBE-600#-SW-40S Sampled Line From 68817 LADISH 150/120 ALC-P-5 CAT.# 7661-2407-07A l
ALC-V0031 3/4 GLOBE-600#-SW-40S Loop Seal Fill 68817 LADISH 150/120 Connection On CAT.# 7661-CC-T-1 2407-07A ALC-V0032' 2 BALCHK-600#-SH-40S Discharge of 69001 OBERT 150/120 j
CC-P-2A TYPE # 50 ALC-V0033 2
GLOBE-600#-SW-40S Discharge of 69001 OBERT 150/120 ALC-P-5 to CC-T-1 TYPE # 103 ALC-V0034 3/4 GLOBE-600#-SW-40S Pres. Ind. Root 68817 LADISH 150/120 Va. On Dischg. of CAT.# 7661-ALC-P-5 2407-07A ALC-V0035 2
GLOBE-600#-SW-40S
'Recirc. Line From 69001 OBERT 150/120 ALC-P-5 to CC-T-2 TYPE # 103 ALC-V0036 3
GLOBE-150#-FLGD-40S Suction Line From 69001 NEWC0 150/120 i
CC-T-2 to ALC-P-5 CAT.# 6415R ALC-V0037 2
BALCHK-600#-5W-40S Inlet to CC-T-2 69001 OBERT 150/120 TYPE # 50 ALC-V0038 1/2 GLOBE-CMP-FIG Sens; Line On PARKER HAN-150/120
Va.
NIFIN CAT.#-436 At t, '. - 4 09 g Rev. 6/0186P
TABLE 15 (Cont'd) 3526-004-l AUXILIARY BUILDING EMERGENCY LIQUID CLEANUP SYSTEM (EPICOR II)
VALVE LIST DESIGN MANUFACTURER /
PRESSURE VALVE NO.
SIZE TYPE DESCRIPTION PO NO.
MODEL TEMPERATURE COMMENTS 4
ALC-V0039 3/4 GLOBE-600#-SH-40S Root Va. For 69001 HANC0CK 150/120 CC-T-2 Level CAT.# 5500W-1 Indicator 4
ALC-V0040 1/2 GLOBE-600#-SW-40S Root Va. On HANCOCK 150/120 ALC-P-5 Dischg.
CAT.# 5500W-1 Flow Transmit ALC-V0041 1/2 GLOBE-600#-SW-40S Root Va. On HANCOCK 150/120 ALC-P-5 Dischg.
CAT.# 5500W-1 Flow Transmit ALC-V0042 3/4 GLOBE-600#-SW-40S Loop Seal Fill 68817 LADISH 150/120 Connection On CAT.# 7661-CC-T-2 2407-07A ALC-V0042 2
BALL-SW-40S Process Suction 69000 QUARTROL 150/120 Motor Operated, Line From WDL-T CAT.# 521SSSO 120 Volts
-2 to ALC-P-1 ALC-V0044 3/4 GLOBE-SW-40 Blowdn. Line From HANCOCK 150/120 Strainer ALC-U-1 CAT.# 5500W-1 ALC-V0045 2
SWGCHK-150#-SW-40S Process System ALOYC0 150/120 Demin. Water Flush l
Supply ALC-V0046 2
BALCHK-SW-40S Process System 69001 OBERT 150/120 Internals of Valve From CC-T-1 TYPE #50 are Removed ALC-V0047 Deleted
. Rev. 6/0186P
~
TABLE 15 (Cont'd) 3526-004 AUXILIARY BUILDING EMERGENCY LIQUID CLEANUP SYSTEM (EPICOR II)
VALVE LIST DESIGN 4
i MANUFACTURER /
PRESSURE VALVE NO.
SIZE TYPE DESCRIPTION P0 NO.
MCDEL TEMPERATURE COMMENTS 1
ALC-V0048 3/4 GLOBE-SW-40S Demin. Water To 69001 OBERT 150/120 ALC-P-1 TYPE #103 ALC-V0049 1/2 GLOBE-600#-SH-40S Root Va. On HaNC0CK 150/120 CC-T-2 Inlet Flow CAT.#5500W-1 Transmit ALC-V0050 1/2 GLOBE-600#-SW-40S Root Va. On HANC0CK 150/120 CC-T-2 Inlet Flow CAT.#5500W-1 Transmit ALC-V0051 Deleted ALC-V0052 3/4 GLOBE-SW-40S Root Va. On HANCOCK 150/120 CC-T-1 Level CAT.#5500W-1 Indicator Line ALC-V0053 2
GLOBE-SW-40S Recirc Line 69001 OBERT 150/120 From ALC-P-5 to TYPE # 103 CC-T-2 ALC-V0054 2
GLOBE-600#-SW-40S Clean Water ALOYC0 150/120 Discharge to Units FIG.# 110 1&2 ALC-V0055 2
GLOBE-600#-SW-40S Inlet Line From HANCOCK 150/120 CC-T-2 to ALC-F-2 CAT.# 5500W-1 t
ALC-V0056 2
GLOBE-600#-SW-40S Future Xenon Hold-HANC0CK 150/120 Up Connect. On CAT.# 5500W-1 CC-T-2 s Rev. 6/0186P
TABLE 15 (Cont'd) 3526-004 AUXILIARY BUILDING EMERGENCY LIQUID CLEANUP SYSTEM (EPICOR II)
VALVE LIST DESIGN MANUFACTURER /
PRESSURE VALVE NO.
SIZE TYPE DESCRIPTION PO NO.
MODEL TEMPERATURE COMMENTS ALC-V0057 2
GLOBE-600#-SH-40S Inlete Line From HANCOCK 150/120 CC-T-1 to ALC-F-3 CAT. # 5500W-1 i
ALC-V005G 2
GLOBE-600#-SW-40 Service Air Hdr./
HENRY V0GT 150/120 Unit #2 Isolation DWG. #
Va.
E-44248-RG 1
ALC-V0059 2
BALCHK-600#-SW-40S Process Sys.
69001 OVERT 150/120 Suction Line TYPE #50 Al.C-V0060 1
POPCHK-SCRD-40S Service Air Supply 68819 NUPRO 150/120 to ALC-P-1 CAT.# B-16C4-1 j
ALC-V0061 1
POPCHK-SCRD-40S Demin. Water to-68819 NUPRO 150/120 to ALC-P-1 CAT.# B-16C4-1 ALC-V0062 1
POPCHK-SCRD-40 Oiled Air to 68819 NUPRO 150/120 ALC-P-1 CAT.# B-16C4-1 ALC-V0063 1
POPCHK-SCRD-40 Service Air to.
68819 NUPRO 150/120 ALC-P-1
' CAT.# B-16C4-1 ALC-V0064 1
POPCHK-SCRD-40 Demin. Water to 68819 NUPRO 150/120 ALC-P-l' CAT.# B-16C4-1 ALC-V0065 1
POPCHK-SCRD-40 Demin. Water to.
68819 NUPRO 150/120 l
ALC-P-2 CAT.# B-16C4-1 ALC-V0066 1
POPCHK-SCRD-40S Service Air to 68819 NUPRO 150/120 ALC-P CAT.# B-16C4-1 i
e l Rev. 6/0186P
TABLE 15 (Cont'd) 3526-004 J
AUXILIARY BUILDING EMERGENCY LIQUID CLEANUP SYSTEM (EPICOR II) l VALVE LIST-l DESIGN
{
MANUFACTU.ER/
PRESSURE VALVE NO.
SIZE TYPE DESCRIPTION PO NO.
MODEL TEMPERATURE COMMENTS ALC-V0067 1
POPCHK-SCRD-40 011ed Air to 68819 NUPRO 150/120 4
ALC-P-2 CAT.# B-16C4-1 i
ALC-V0068 1
POPCHK-SCRD-40S Demin. Water To 68819 NUPRO 150/120 ALC-P-2 CAT.# B-16C4-1 ALC-V0069 1
POPCHK-SCRD-40S Service Air To 68819 NUPRO 150/120 ALC-P-2 CAT.# B-16C4-1 i
ALC-V0070 1
POPCHK-SCRD-40S Demin. Water To 68819 NUPRO 150/120 j
ALC-P-3 CAT.# B-16C4-1 ALC-V0071 1
POPCHK-SCRD-40 Service Air To 68819 NUPRO 150/120-ALC-P-3 CAT.# B-16C4-1 ALC-V0072 1
'POPCHK-SCRD-40S Oiled Air To 68819 NUPRO 150/120.
ALC-P-3 CAT.# B-16C4 ALC-V0073 1
POPCHK-SCRD-40S Demin. Water To 68819 NUPRO 150/120 ALC-P-3 CAT.# B-16C4-1 I
ALC-V0074 1
POPCHK-SCRD-40S Service Air To 68819 NUPRO 150/120 ALC-P-3 CAT.# B-16C4-1 ALC-V0075 1
POPCHK-SCRD-40S Demin. Water To 68819 NUPRO 150/120 ALC-P-4 CAT.# B-16C4-1 t
ALC-V0076 1
POPCHK-SCRD-40S Service Air To 68819 NUPRO 150/120 ALC-P-4 CAT.# B-16C4-1 i
i t
j Rev. 6/0186P
TABLE 15 (Cont'd) 3526-004 AUXILIARY BUILDING EMERGENCY LIQUID CLEANUP SYSTEM (EPICOR II)
VALVE LIST DESIGN MANUFACTURER /
PRESSURE VALVE NO.
SIZE TYPE DESCRIPTION P0 NO.
MODEL TEMPERATURE COMMENTS ALC-V0077 1
POPCHK-SCRD-40S Olled Air To 68819 NUPRO 150/120 ALC-P-4 CAT.# B-16C4-1 ALC-V0078 1
POPCHK-SCRD-40S Demin. Water To 68819 NUPRO 150/120 ALC-P-4 CAT.# B-16C4-1 ALC-V0079 1
POPCHK-SCRD-40S Service Air To 68819 NUPRO 150/120 ALC-P-4 CAT.# B-16C4-1 ALC-V0080 3/4 GLOBE-600#-SH-40 Root Va. for Pres.
HANC0CK 150/120 Ind. on Demin.
CAT.# 5500W-1 Water Header t
ALC-V0081 3/4 GLOBE-600#-SW-40 Root Va. for Pres.
HENRY V0GT 150/120 Ind. on Service DWG.#
Air Header E-44244-R7 ALC-V0r82 2
GLOBE-SW-40S Future Xenon HANC0CK 150/120 Holdup Connect.
CAT.# 5500W-1 On CC-T-1 ALC-V0083 1 1/4 BALL-SW-40S Root VA. for 68875 APOLLO 150/120 Conductivity Probe CAT.# 316 On CC-T-2 Inlet ALC-V0084 1 1/4 BALL-SH-40S Root VA. for 68875 APOLLO 150/120 pH Probe On CAT.# 316 CC-T-2 Inlet ALC-V0085 Deleted
! Rev. 6/0186P
TABLE 15 (Cont'd) 3526-004 i
AUXILIARY BUILDING EMERGENCY LIQUID CLEANUP SYSTEM (EPICOR II)
VALVE LIST DESIGN
+
MANUFACTURER /
PRESSURE VALVE F.O.
SIZE TYPE DESCRIPTION PO NO.
MODEL TEMPERATURE COMMENTS i
i ALC-V0086 2
BA L-SW-40S Discharge from 80322 QUARTROL 150/120 Motor Operated.
Tank CC-T-1 CAT.# 521SSSO 120 Volts ALC-V0087 1 1/2 BALL-SH-40S Clean Water Dis 80792 QUARTROL 150/120 Motor Operated.
Charge to Unit #2 CAT.# 521SSSO 120 Volts 4
Cond. Test Tks.
[
j WDL-T-9A & B i
ALC-V0088 1 1/2 BALL-SH-40S Clean Water Dis 80792 QUARTROL 150/120 Motor Operated.
Charge to Unit #2 CAT.# 521SSSO 120 Volts 1
Cond. Test Tks.
I WDL-T-9A & B l
i ALC-V0089 2
GLOBE-600#-SW-40S Discharge Line HANC0CK 150/120 From Sump Pump CAT.# 5500W-1 CC-P-2A ALC-V0090 Deleted ALC-V0091 1 1/4 BALL-SW-40S Root Valve for 68875 APOLLO 150/120 Cond Probe at CAT.# 316 Inlet to Pump l
ALC-P-1 ALC-V0092 1 1/4 BALL-SW-40S Root Valve for 68875 APOLLO 150/120 Cond Probe at CAT.# 316 Inlet to Pump ALC-P-3 i
i i
?
i Rev. 6/0186P
TABLE 15 (Cont'd) 3526-004 AUXILIARY BUILDING EMERGENCY LIQUID CLEANUP SYSTEM (EPICOR II)
VALVE LIST DESIGN MANUFACTURER /
PRESSURE VALVE NO.
SIZE TYPE DESCRIPTION PO NO.
MODEL TEMPERATURE COMMENTS ALC-V0093 1 1/4 BALL-SW-40S Root Valve for 68875 APOLLO 150/120 Cond Probe at CAT.# 316 Inlet to Pump ALC-P-3 ALC-V0094 3/4 GLOBE-600#-SW-40S Root Valve for 69001 OBERT 150/120 Pres. Ind. On TYPE # 103 Sump Pump CC-P-2A Discharge ALC-V0095 2
GLOBE-600#-SH-40S Process System HANC0CK 150/120 Flush Line Near CAT.# 5500W-1 Inlet to ALC-P-1 ALC-V0096 Deleted ALC-V0097 3/4 GLOBE-600#-SW Olled Air to HANC0CK-150/120 ALC-P-6 CAT.# 5500W-1 ALC-V0098 3/4 GLOBE-600#-SW-40S Demin. Water to VELAN 150/120 i
ALC-P-6 CAT.# 374B ALC-V0099 3/4 GLOBE-600#-SW-40 Service Air to HANC0CK 150/120 ALC-P-6 CAT.# 5500W-1 i
ALC-V0100 3/4 GLOBE-600#-SW-40 Service Air to HENRY V0GT 150/120 ALC-P-6 DWG.#
E-44244-R11 I
ALC-V0101 3/4 GLOBE-600#-SW-40S Demin. Water to 69001 OBERT 150/120 ALC-P-6 TYPE # 103 i
l
-! Rev. 6/0186P
1 TABLE 15 (Cont'd) 3526-004 AUXILIARY BUILDING EMERGENCY LIQUID CLEANUP SYSTEM (EPICOR II) i VALVE LIST DESIGN l
MANUFACTURER /
PRESSURE VALVE NO.
SIZE TYPE DESCRIPTION PO NO.
MODEL TEMPERATURE COMMENTS ALC-V0102 1
POPCHK-SCRD-40 Oiled Air to 68819 NUPRO 150/120 ALC-P-6 CAT.# B-16C4-1 i
ALC-V0103 i
BALCKH-600#-SW-40S Filter ALC-F-1 69001 OBERT 150/120 l
Precoat Supply TYPE # 50 Line l
ALC-V0104 1
POPCHK-SCRD-40 Service Air to 68819 NUPRO 150/120 ALC-P-6 CAT.# B-16C4-1 ALC-V0105 Deleted ALC-V0106 2
GLOBE-600#-SH-40S Discharge From HANCOCK 150/120 One Micron Filter CAT.# 5500W-1 HA'C0CK 150/120 N
ALC-V0107 3/4 GLOBE-600#-SW-40S Vent on One Micron Filter CAT.# 5500W-1 J, l ALC--V0108 3/4 GLOBE-600#-SW-40S Drain on One HANC0CK i50/120 Micron Filter CAT.# 5500W-1 ALC-V0109 2
CONTROL-FLGD-40 Service Air Supply 69005 FISHER 150/120 Header TYPE # 310-32 l
ALC-V0110 3
GLOBE-FLGD-40S Suction Line From 69001 NEWC0 150/120 CC-T-1 to ALC-P-5 CAT.# 6415R 1
ALC-V0lli Deleted ALC-V0ll2 2
GLOBE-600#-SW-40S Inlet to One HANC0CK 150/120 Micron Filter CAT.# 5500W-1 J
1 l Rev. 6/0186P
l TABLE 15 (Cent'd) 3526-004 AUXILIARY BUILDING EMERGENCY LIQUID CLEANUP SYSTEM (EPICOR II)
VALVE 1.IST DESIGN MANUFACTURER /
PRESSURE 2
VALVE NO.
SIZE TYPE DESCRIPTION PD NO.
MODEL TEMPERATUP" COMMENTS ALC-P 1
POPCHK-SW-40S Chemical Addition 68819 NUPRO 150/120 cine to CC-T-1 CAT.# ?-16C4
- ALC-V0i.,
2 BALC"-50%-SW-40S Discharge from 69001 OBERT 150/120 ALC-P-5 TYPE # 50 I
1 ALC-V0ll5
. F iW-40S Drain Line on 150/120 1
Process Suction j
Line ALC-V0116
.0BE-SH-40S Drain Line on 150/120 Process Suction Line ALC-V0117 3/4
+4 4-600#-SW-40S Pressiire Test HANC0CK 150/120 Connection Near CAT.# 5500W-1 Suction of ALC-l P-1 1
ALC-V0118 No Longer in Use Located in Unit 1 4
i
-123 (Unaccesible)
ALC-V0124 1
GLOBE-600#-SW-40S Filter ALC-F-1 HANC0CK 150/120 Precoat Supply CAT.# 5500W-1 Line i
A' C V0125 3/4 GLOBE-6LO#-SW-40S Pressure Test HANCOCK 150/120 Conne; tion On CAT.# 5500W-1 i
Demin. Water l
Header l
1 Rev. 6/0186P
%,.w,
..,y,-
i-,____
u
1 TABLE 15 (Cont'd) 3526-004 AUXILIARY BUILDING EMERGENCY LIQUID CLEANUP SYSTEM (EPICOR II)
L VALVE LIST DESIGN MANUFACTURER /
PRESSURE VALVE NO.
SIZE TYPE DESCRIPTION PO NO.
MODEL TEMPERATURE COMMENTS ALC-V0126 3/4 CLOBE-600#-SW-40S Pressure Test HANC0CK 150/120 Connection On CAT.# 5500W-1 Service Air Header ALC-V0127 3/4 GLOBE-600#-SW-40S Pressure Test HANC0CK 150/120 Connection On CAT.# 5500W-1 Sump Pump Discharge ALC-V0128 3/4 GLORE-600#-SW-40S Priming Vent 68817 LADISH 150/120 For ALC-P-5 CAT.# 7661-2407-07A ALC-V0129 3/4 GLOBE-600#-SW-405 Priming Vent
.68817 LADISH 150/120 For ALC-P-5 CAT.# 7661-2407-07A ALC-V0130 3/4 BALCHK-600#-SW-405 Drain on One 69001 OBERT 150/120 Micron Filter TYPE # 103 ALC-V0131 3/4 BALCHK-600#-SW-40S Drain on Suction 69001 OCERT 150/120 Line From CC-T-2 TYPE #'103 to ALC-P-5 ALC-V0132 3/4 GLOBE-600#-SW-40S Drain on Suction 69001 OBERT 150/120 Line From CL-T-2 TYPE # 103 to ALC-P-5 ALC-V0133 3/4 GLOBE-600#-SW-40S ALC-DPS-1 LP Leg 69001 OBERT 150/120 Root Valve TYPE # 103 Rev. 6/0186P
TABLE 15 (Cont'd) 3526-004 AUXILIARY BUILDING EMERGENCY LIQUID CLEANUP SYSTEM (EPICOR II)
VALVE LIST DESIGN MANUFACTURER /
PRESSURE VALVE N0_,_
SIZE TYFE DESCRIPTION PO NO.
MODEL TEMPERATURE COMMENTS s
ALC-V0114 3/4 GLOBE-600#-SH-40S Demin. Water to HANCOCK 150/120 ALC-P--5 Seal s CAT.# 5500W-1 ALC-V0135 1
POPCHK-SCRF-40S Demin. Water to 68819 NUPRO 150/120 ALC-P-5 Seals CAT.# B16C4-1 ALC-V0136 3/4 SOLND-SCRD-40S Demin. Water to 82188 ASCO 150/120 2 Way Normally Closed ALC-P-5 Seals CAT.# 8210D9 Energized to Open ALC-V0137 e
GLOBE-SW-40S Demin. Water to 150/120 Flush Line to CC-T-2 ALC-V0138 2
BALCHK-600#-SH-40S Discharge Line 69001 OBERT 150/120 From CC-P-2A TYPE # 50 ALC-V0139 2
GLOBE-600#-SH-40 Service Air HANC0CK 150/120 Header CAT.# 5500W-1 ALC-V0140 2
GLOBE-600#-SW-40S FLture Waste HANCOCK 150/120 4
Supply Line CAT.# 5500W-1 ALC-V0141 2
GLOBE-600#-SW-40S Future Waste HANCOCK 150/120 Supply Line CAi.# 5500H-1 ALC-V0142 2
LIFCHK-SH-40S Demin. Water VELAN 150/120 SLsply Header SERIAL # S-50-1 ALC-V0143 1 1/2 RELIEF-SCRD-40S Demin. Water J. E. LONERGAN 150/120 Set Pressure at 150 Supply Header CORP. MODEL LOT P.S.I.G.
11 Rev. 6/0186P 7
TABLE 15 (Cont'd) 3526-004 AUXILIARY BUILDING EMERGENCY LIQUID CLEANUP SYSTEM (EPICOR II)
VALVE LIST DESIGN MANUFACTURER /-
PRESSURE VALVE NO.
SIZE TYPE DESCRIPTICN PO NO.
MODEL TEMPERATURE COMMENTS ALC-V0144 2
GLOBE-600#-SW-40S Demin. Water HANC0CK 150/120 Supply Header CAT.# 5500W-1 CC-T-2 ALC-V0145 2
G!.0BE-600#-SW-40S Spare Plant Air /
HANCGCK 150/120 EPICOR II Air CAT.# 5500W-1 Sup. Calc-P-788 Isolation Va.
ALC-V0146 1/2 BALL-COM FTG Sample Line 80498 WHITEY 150/120 From ALC-P-2 CAT.#
A SS-45S8 ALC-V3147 1/2 BALL-COM FTG Sample Line 80498 LHITEY 150/120 From ALC-P-3 CAT.#
SS-4558 ALC-V0148 1/2 BALL-COM FTG Sample Line 80498 WHITEY 150/120 From ALC-P-4 CAT.#
SS-45S8 ALC-V0149 1/2 GLOSE COM FTG Grab Sa,aple HOKE 150/120 From ALC-P-2 CAT.#
N281108Y15 ALC-V0150 1/2 GLOBE-COM FTG Grab Sample HOKE 150/120 From ALC-P-3 CAT.#
N2811Q8Y15 ALC-V0151 1/2 GLOBE-COM FTG Grab Sample HOKE 150/120 Frc.: fdC-P-4 CAT.#
N2811Q8Y15
, Rev. 6/0186P i
e -
TABLE 15 (Cont'd) 3526-004 AUXILIARY BUILDING EMERGENCY LIQUIO CLEANUP SYSTEM (EPICOR II)
VALVE LIST DESIGN MANUFACTURER /
PRESSURE VALVE NO.
SIZE TYPE DESCRIPTION PO NO.
MODEL TEMPERATURE COMMENTS.
ALC-V0152 1/2 GLOBE-COM FTG Grab Sample HOKE 150/120 From ALC-P-5 CAT.#
N2811Q8Y15 ALC-V0153 1
BALL-COM FTG Sample Recirc.
80498 WHITEY 150/120 Line CAT.#
SS-65F16 ALC-V0154 1/2 BALL-COM FTG Grab Sa.iple From 80498 WHITEY 150/120 ALC-P-5 CAT.#
SS-45S8 1
ALC-V0155 1/2 BALL r0M FTG Grab Sample From 80498 WHITEY 150/120 ALC-P-4 CAT.#
SS-45S8 ALC-V0156 1/2 BALL-COM FTG Grab Sample From WHITEY 150/120 ALC-P-3 CAT.#
SS-45S8 ALC-V0157
'2 BALL-COM FTG
' Grab Sample From 80498 WHITEY 150/120 ALC-P-2 CAT.#
SS-45S8 ALC-V0158 3/4 GLOBE-600#-SW-40S Demin. Water to 68817 LADISH 150/120 Sample Sink Spray CAT.# 7661-Header 2407-07A
-ALC-V0159 3/4 GLOBE-600#-SH-405 Demin. Water to 68817 LADISH 150/120 Sample Bottle CAT.# 7661-Wash Hose 2407-07A. Rev. 6/0186P
TABLE 15 (Cont'd) 3526-004 AUXILIARY BUILDING EMERGENCY LIQUID CLEANUP' SYSTEM (EPICOR II)
VALVE LIST DESIGN MANUFACTURER /
PRESSURE VALVE NO.
SIZE TYPE DESCRIPTION P0 NO.
MODEL TEMPERATURE COMMENTS ALC-V0160 1/2 LIFCHK-COM FTG Recirc. Line From 80493 WHITNEY' 150/120 ALC-P-2 CAT.# SS-58S8 ALC-V0161 1/2 LIFCHK-COM FTG Recirc. Line From 80498 WHITNEY 150/120 ALC-P-3 CAT.# SS-5858 ALC-V0162 1/2 LItChK-COM FTG Retirc. Line From 80498 WHITNEY 150/120 ALC-P-4 CAT.# SS-58S8 ALC-V0163 1/2 SOLND SCRD Recirc. Line From 80548 ASCO 150/120 2 Way Normally Closed i
ALC-P-4 CAT.# 8210C94 Energized to Open ALC-V0164 1/2 SOLND SCR0 Sample Line From 80548 ASCO 150/120 2 Way Normally Closed ALC-P-4 CAT.# 8210C94 Energized to Open ALC-V0165 1/2 SOLND SCRD Recirc. Line From 80548 ASCO 150/120 2 Way Normally Closed ALC-P-3 CAT.# 8210C94 Energized to Open ALC-V0166 1/2 SOLND SCRD Sample Line From 80548 ASCO 150/120 2 Way N3rmally Closed ALC-P-3 CAT.# 8210C94 Energized to Open ALC-V0167 1/2 SOLND SCRD Recirc. Line From 80548 ASCO 150/120 2 Way Normally Closed ALC-P-2 CAT.# 8210C94 Energized to Open ALC-V0168 1/2 SOLND SCRD Sample Line From 80548 ASCO 150/120 2 Way Normally Closed ALC-P-2 CAT.# 8210C94 Energized to Open ALC-V0169 2
CLOBE-600#-SW-40S Clean Water Dis-POWEL 150/120 charge to Unit #1-FIG.# 2474 Rev. 6/0186P
TABLE 15 (Cont'd) 3526-004 AUXILIARY BUILDING EMERGENCY LIQUID CLEANUP SYSTEM (EPICOR II)
VALVE LIST DESIGN MANUFACTURER /
PRESFSE VALVE M0.
SIZE TYPE DESCRIPTION PO NO.
MODEL TEMPERATURE COMMENTS ALC-V0170 2
GLOBE-600#-SH-40S Clean Water Dis-hEWC0 150/120 charge to Unit #2 CAT.# 28TF32 ALC-V0171 3/4 GLOBE-600#-SW-40S Clean Water Dis-68817 LADISH 150/120 charge to Unit #2 CAT.# 7661-4 Drain Line 2407-07A ALC-V0172 3/4 GLOBE-SW-40S Clean Water Dis-150/120 charge to Unit #2 Vent Line ALC-V0173 3/4 GLOBE-SW-40S Clean Water Dis-150/120 charge to Unit #2 Drain Line ALC-V0174 3/4 GLOBE-600#-SW-40S Cask Overflow 68817 LADISH 150/120 Loop Seal Leveling CAT.# 7661-Line 2407-07A ALC-V0175 3/4 GLOBE-600#-SW -40S Cask Overflow 68317 LADISH 150/120 Loop Seal Fill CAT.# 7661-Line 2407-07A ALC-V0176 3/4 GLOBE-600#-SW-40 Oiled Air Line HENRY V0GT 150/120 For ALC-P-6 DWG.#
E44244-R11 ALC-V0177 1/2 POPCHK-COM FTG Sample Line From 82033 NUPRO 150/120 ALC-P-2 CAT.#
SS-8C-1/3 Rev. 6/0186P
TABLE 15 (Cont'd) 3526-004 AUXILIARY BUILDING EMERGENCY LIQUID CLEANUP SYSTEM (EPICOR II)
VALVE LIST DESIGN MANUFACTURER /
PRESSURE VALVE NO.
SIZE TYPE DESCRIPTION PO NO.
MODEL TEMPERATURE COMMENTS ALC-V0178 1/2 POPCHK-COM FTG Sample '_ine From 82033 NUPRO 150/120 ALC-P-3 CAT.#
SS-8C-1/3 ALC-V0179 1/2 POPCHK-COM FTG Sample Line From 82033 NUPRO 150/i20 ALC-P-4 CAT.#
SS-8C-1/3 ALC-V0180 2
BALL SCRD Process Inlet To JAMESBURY
/
Supplied by CAP-GUN Pump ALC-P-1 TYPE 1000 FIG. NO.
Il-1100TT ALC-V0181 3/4 BALL SCRD Service Air To JAMESBURY
/
Supplied by CAP-GUN Pump ALC-P-1 TYPE 1000 FIG. NO.
11-1100TT ALC-V0182 3/4 BALL SCRD Demin. Water To JAMESBURY
/
Supplied by CAP-GUN Pump ALC-P-1 TYPE 1000 FIG. NO.
11-1100TT ALC-V0183 3/4 BALL SCRD Service Air To JAMESBURY
/
Supplied by CAP-GUN Pump ALC-P-1 TYPE 1000 FIG. NO.
il-1100TT ALC-V0184 3/4 BALL SCRD Demin. Water To JAMESB' RY
/
Supplied by CAP-GUN J
Pump ALC-P-1 TYPE 1000 FIG. NO.
ll-1100TT Rev. 6/0186P
TABLE IS (Cont'd) 3526-004 AUXILIARY BUILDING EMERGENCY LIQUID CLEANUP SYSTEM (EPICOR II)
VALVE LIST DESIGN MANUFACTURER /
PRESSURE VALVE NO.
SIZE TYPE DESCRIPTION PO NO.
MODEL TEMPERATURE COMMENTS ALC-V0185 3/4 SOLND SCRD Olled Air To ASCO.
/
Supplied by CAP-GUN Pump ALC-P-1 CAT. NO.
8210D95 ALC-V0186 3/4 BALL SCRD 011ed Air to JAMESBURY
/
Supplied by CAP-GUN Pump ALC-P-1 TYPE 1000 FIG. NO.
11-1100TT ALC-V0187 3/4 ANCLE SCR0 Oiled Air to WARREN RUPP
/
Supplied by Mfr..of Pump ALC-P-1 CO., PART #
Pump ALC-P-1 (Harren 893-048-162 Rupp)
ALC-V0188 3/4 BALL SCRD Service Air to JAMESBURY
/
Supplied by CAP-GUN Pump ALC-P-1 TYPE 1000 FIG. NO.
11-1100TT ALC-V0189 3/4 BALL SCRD Sample Point Va.
JAMESBURY
/
Supplied by CAP-GUN On Outlet Of Pump TYPE 1000 This Sample Point ALC-P-1 FIG. NO.
Not Used 11-1100TT ALC-V0190 3/4 BALL SCRD Demin. Water to JAMESBURY
/
Supplied by CAP-GUN Pump ALC-P-1 TYPE 1000 FIG. NO.
11-1100TT ALC-V0191 1
BALL SCRD Process Outlet JAMESBURY Supplied by CAP-GUN From Pump ALC-P-1 TYPE 1000 FIG. NO.
11-1100TT Rev. 6/0186P
TABLE 15 (Cont'd) 3526-004 AUXILIARY BUILDING EMERGENCY LIQUID CLEANUP SYSTEM (EPICOR II)
VALVE LIST DESIGN MANUFACTURER /
PRESSURE VALVE NO.
SIZE TYPE DESCRIPTION PO NO.
MODEL TEMPERATURE COMMENTS j
ALC-V0192 3/4 BALL SCRD Service Air to JAMESBURY Supplied by CAP-GUN Pump ALC-P-1 TYPE 1000 FIG. NO.
ll-1100TT ALC-V0193 3/4 BALL SCRD Demin. Water to JAMESBURY Supplied by CAP-GUN Pump ALC-P-1 TYPE 1000 FIG. NO.
ll-1100TT ALC-V0194 2
BALL SCRD Process Inlet To JAMESBURY Supplied by CAP-GUN Pump ALC-P-2 TYPE 1000 FIG. NO.
11-1100TT ALC-V0195 3/4 BALL SCRD Demin. Water To JAMESSURY Supplied by CAP-GUN Pump ALC-P-2 TYPE 1000 FIG. NO.
11-1100TT ALC-V0196 3/4 BALL SCRD Service Air To JAMESBUPY Supplied by CAP-GUN Pump ALC-P-2 TYPE 1000 FIG. NO.
11-1100TT i
ALC-V0197 3/4 BALL SCRD Service Air To JAMESBURY Supplied by CAP-GUN Pump ALC-P-2 TYPE 1000 FIG. NO.
ll-1100TT Rev. 6/0186P i
i
=.
TABLE 15 (Cont'd) 3526-004 AUXILIARY BUILDING EMERGENCY LIQUID CLEANUP SYSTEM (EPICOR II)
VALVE LIST J
DESIGN i
MANUFACTURER /
PRESSURE VALVE NO.
SIZE TYPE DESCRIPTION P0 NO.
MODEL TEMPERATURE COMMENTS ALC-V0198 3/4 BALL SCRD Service Air To JAMESBURY Supplied by CAP-GUN Pump ALC-P-2 TYPE 1000 FIG. NO.
11-1100TT ALC-V0199 3/4 SOLND SCRD Olled Air To ASCO Supplied by CAP-GUN Pump ALC-7-2 CAT. NO.
B210D95 4
i ALC-V0200 3/4 ANGLE SCRD 011ed Air To WARREN RUPP Su; plied by Mfr. of Pump ALC-P-2 CO., PART #
Pump ALC-P-2 (Harren 893-043-162 Rupp)
ALC-V0201 2
BALL SCRD Process Supply JAMESBURY Supplied by CAP-GUN l
From Pump ALC-P-2 TYPE 1000 j
FIG. NO.
Il-1100TT i
ALC-V0202 3/4 BALL SCRD Demin. Water To JAMESBURY Supplied by CAP-GUN s
]
Pump ALC-P-2 TYPE 1000 FIG. NO.
l ll-1100TT 1
ALC-V0203 Deleted i
ALC-V0204 3/4 BALL SCRD Service Air To JAMESBURY Supplied by CAP-GUN Pump ALC-P-2 TYPE 1000 FIG. NO.
ll-1100TT
! Rev. 6/0186P a
TABLE 15 (Cont'd) 3526-004 1
AUXILIARY BUILDING EMERGENCY LIQUID CLEANUP SYSTEM (EPICOR II)
VALVE LIST DESIGN MANUFACTURER /
PRESSURE VALVE NO.
SIZE TYPE DESCRIPTION PO NO.
MODEL TEMPERATURE COMMENTS ALC-V0205 3/4 BALL SCRD Demin. Water To JAMESBURY Supplied by CAP-GUN.
Pump ALC-P-2 TYPE 1000 FIG. NO.
11-1100TT ALC-V0206 3/4 BALL SCRD Service Air To JAMESBURY Supplied by CAP-GUN Pump ALC-P-2 TYPE 1000 FIG. NO.
11-1100TT ALC-V0207 2
BALL SCRD Process Supply JAMESBURY Supplied by CAP-GUN To ALC-F-1 TYPE 1000 FIG. NO.
11-1100TT ALC-V0208 2
BALL SCRD Process Supply JAMESBURY Supplied by CAP-GUN i
l To ALC-F-1 TYPE 1000 t
J FIG. NO.
11-1100TT ALC-V0209 2
BALL SCRD Process Supply JAMESBURY Supplied by CAP-GUN To ALC-K-1 TYPE 1000 i
FIG. NO.
j 11-1100TT 3
/1C-V0210 2
BALL SCRD Process Supply JAMESBURY Supplied by CAP-GUN To ALC-K-1 TYPE 1000 1
I FIG. NO.
i 11-1100TT i
j i Rev. 6/0186P 1
I
TABLE 15 (Cont'd) 3526-004 AUXILIARY BUILDING EMERGENCY LIQUID CLEANUP SYSTEM (EPICOR II)
VALVE LIST DESIGN MANUFACTURER /
PRESSURE VALVE NO.
SIZE TYPE DESCRIPTION P0 NO.
___ MODEL TEMPERATURE COMMENTS ALC-V0211 2
BALL SCRD Process Supply J/4tESBURY Supplied by CAP-GUN To ALC-K-2 TYPE 1000 FIG. NO.
11-1100TT ALC-V0212 2
BALL SCRD Process Supply JAMESBURY Supplied by CAP-GUN To ALC-K-2 TYFE 1000 FIC. NO.
11-1100TT ALC-V0213 2
BALL SCRD Process Inlet JAHESBURY Supplied by CAP-GUN To ? ump ALC-P-3 TYPE 1000 FIC. NO.
11-1100TT ALC-V0214 3/4 BALL SCR0 Demin. Water To JAMESBURY Supplied by CAP-GUN Pump ALC-P-3 TYPE 1000 FIG. NO.
11-1100TT ALC-V0215 3/4 BALL SCRD Service Air To JAMESBURY Supplied by CAP-GUN Pump ALC-P-3 TYPE 1000 FIG. NO.
Il-1100TT i
ALC-V0216 3/4 BALL SCRD Demin. Water To JAMESBURY Supplied by CAP-GUN a
1 Pump ALC-P-3 TYPE 1000 FIC. NO.
11-1100TT
' ' Rev. 6/0186P
TABLE-15 (Cont'd) 3526-004 AUXILIARY BUILDING EMERGENCY LIQUID CLEANUP SYSTEM (EPICOR II)
VALVE LIST DESIGN MANUFACTURER /
PRESSURE VALVE NO.
SIZE TYPE DESCRIPTION PO NO.
MODEL TEMPERATURE COMMENTS ALC-V0217 3/4 BALL SCRD Service Air To JAMESBURY Supplied by CAP-GUN Pump ALC-P-3 TYPE 1000 FIG. NO.
11-1100TT ALC-V0218 3/4 SOLND SCRD Oiled Air To ASCO.
Supplied by CAP-GUN Pump ALC-P-3 CAT. NO.
8230D95 ALC-V0219 3/4 ANGLE SCRD Oiled Air To WARREN RUPP Supplied by "fr. cf Pump ALC-P-3 CO. PART #
Pump ALC-P-3 (Warren 893-048-162 Rupp)
ALC-V0220 3/4 BALL SCRD 011ed Air To JAMESBURY Supplied by CAP-GUN Pump ALC-P-3 TYPE 1000 FIG. NO.
11-1100TT ALC-V0221 3/4 BALL SCRD Demin. Water Tc JAMESBdRY Supplied by CAP-GUN Pump ALC-P-3 TYPE 1000 FIG. NO.
11-1100TT ALC-V0222 3/4 BALL SCRD Service Air To JAMESBURY Supplied by CAP-GUN Pump ALC-P-3 TYPE 1000 FIG. NO.
11-1100TT ALC-V0223 3/4 BALL SCRD Demin. Water To JAMESBURY Supplied by CAP-GUN Pump ALC-P-3 TYPE 1000 FIG. NO.
11-1100TT
, Rev. 6/0186P 1
m-
~ _,.,.,
-e.-
.. - _.. ~-, <,.-- --,,
- - _-.-=.
TABLE 15 (Cont'd) 3526-004 AUXILIARY BUILDING EMERGENCY LIQUID CLEANUP SYSTEM (EPICOR II)
VALVE LIST DESIGN MANUFACTURER /
PRESSURE VALVE NO.
SIZE TYPE DESCRIPTION PO NO.
MODEL TEMPERATURE COMMENTS.
ALC-V0224 3/4 BALL SCRD Sample Point Va.
JAMESBURY Supplied by CAP-GUN on Outlet of Pump TYPE 1000 ALC-P.3 FIG. NO.
11-1100TT ALC-V0225 3/4 BALL SCRD Service Air to JAMESBURY Supplied by CAP-GUN Pump ALC-P-3 TYPE 1000 FIG. NO.
11-1100TT i
ALC-V0226 2
BALL SCRD Process Outlet JAMESBURY Supplied by CAP-GUN from Pump ALC-P-3 TYPE 1000 FIG. NO.
11-1100TT ALC-V0227 2
BALL SCRD Process Inlet JAMESBURY Supplied by CAP-GUN To Pump ALC-P-4 TYPE 1000 FIG. NO.
11-1100TT ALC-V0228 3/4 BALL SCRD Demin. Water To JAMESBURY Supplied by CAP-GUN Pump ALC-P-4 TYPE 1000 FIG. NO.
11-1100TT ALC-V0229 3/4 BALL SCR0 Service Air To JAMESBURY Supplied by CAP-GUN Pump ALC-P-4 TYPE 1000 FIG. NO.
11-1100TT Rev. 6/0186P
~.
TABLE 15 (Cont'd) 3526-004 AUXILIARY BUILDING EMERGENCY LIQUID CLEANUP SYSTEM (EPICOR II)
VALVE LIST DESIGN MANUFACTURER /
PRESSURE VALVE NO.
SIZE lYPE DESCRIPTION PO NO.
MODEL TEMPERATURE COMMENTS ALC-V0230 3/4 BALL SCRD Demin. Water To JAMESBURY Supplied by CAP-GUN Pump ALC-P-4 TYPE 1000 FIG. NO.
11-1100TT
^
ALC-V0231 314 BALL SCRD Service Air To JAMESBURY Supplied by CAP-GUN Puas ALC-P-4 TYPE 1000 FIG. NO.
11-1100TT ALC-V0232 3/4 SOLND SCR0 Olled Air To ASCO Supplied by CAP-GUN Pump ALC-P-4 CAT. NO.
8210D95 ALC-V0233 3/4 BALL SCRD Oiled Air To JAMESBURY Supplied by CAa-GUN Pump ALC-P-4 TYPE 1000 FIG. NO.
11-1100TT ALC-V0234 3/4 BALL SCRD Olled Air To WARREN RUPP Supplied by Mfr. of Pump ALC-P-4 CO., PART #
pump ALC-P-4 893-048-162 (Harren Rupp)
ALC-V0235 3/4 BALL SCRD Demin. WaterTo JAMESBURY Supplied by CAP-GUN Pump ALC-P 4 TYPE 1000 FIG. NO.
11-1100TT ALC-V0236 3/4 BALL SCRD Service Air To JAMESBURY Supplied by CAP-GUN Pump ALC-P-4 TYPE 1000 FIG. NO.
11-1100TT Rev. 6/0186P
TABLE 15 (Cont'd) 3526-004 AUXILIARY BUILDING EMERGENCY L1 QUID CLEANUP SYSTEM (EPICOR II)
VALVE LIST DESIGN MANUFACTURER /
PRESSURE VALVE ND.
Si1E TYPE DESCR1P11DN P_D ND.
NODEL TEMPERA 1DRE EDNNENTS ALC-V0237 3/4 BALL SCRD Demin. Hater To JAMESBURY Supplied by CAP-GUN
)
Pump ALC-P-4 TYPE 1000 FIG. NO.
11-l100TT ALC-V0238 3/4 BALL SCRD Sample Point Va.
JAMESBURY Supplied by CAP-GUN On Outlet Of Pump ifPE 1000 ALC-P-4 FIG. NO.
11-1100TT 1
ALC-V0239 3/4 BALL SCRD Service Air to JAMESBURY Supplied by CAP-GUN Pump ALC-P-4 TYPE 1000 FIG. NO.
4 11-1100TT ALC-V0240 3/4 BALL SCRD Process Outlet JAMESBURY Supplied by CAP-GUN from Pump ALC-P-4 TYPE 1000 FIG. NO.
i ll-1100TT ALC-V0241 3/4 BALL SCRD 011ed Air To JAMESBURY Supplied by CAP-GUN Pump ALC-P-2 TYPE 1000 FIG. NO.
11-1100TT t
4 ALC-V0242 2
i.IR OPERATED BALL Discharge From HILLS-McCANNA 150/120 2 Way Normally Closed SCRD-40S Tank CC-T-1 FIG.
Energized To Open S302-56-T-S6 ALC-V0243-DELETED 249
. Rev. 6/0186P
TABLE 15 (Cont'd) 3526-004 i
AUXILIARY BUILDING EMERGENCY LIQUID CLEANUP SYSTEM (EPICOR II)
VALVE LIST DESIGN MANUFACTURER /
PRESSURE VALVE NO.
SIZE TYPE DESCRIPTION PO NO.
MODEL TEMPERATURE COMMENTS ALC-V0250 2
GLOBE-SW-40 Discharge t.ine HENRY V0GT 150/120 From Compressor DWG. #
ALC-P-7 E-44248-R6 ALC-V0251 2
GLOBE-SW-40 Discharge Line HENRY V0GT 150/120 From Compressor DWG. #
ALC-P-8 E-44248-RS l
ALC-V0252 3/4 GLOBE-SW-40 Air Supply Line Stock HANC0CK 150/120 From ALC-P-7 &
CAT. #
ALC-P-8 Drain 5500W-1 ALC-V0253 3/4 GLOBE-SW-40S Priming Vent Line 150/120 l
ALC-V0254 1/2 GLOBE-SCRD-40S Pressure Tap on 150/120 Priming Vent Line ALC-V0255 2
AIR OPERATED BALL Process Supply HILLS-McCANNA 150/120-2 Way Normally Closed SCRD-40S Line to Prefilter FIG.
Energized to Open ALC-F-1 5302-56-T-S6 l
ALC-V0256 2
CHECK Sump to ALC-P-1 Suction ALC-V0257 2
GLOBE Sump to ALC-P-1 Suction l
l ALC-V0258 GATE EPICOR to spent Located in Unit'l Fuel Pool 'B' l
l Rev. 6/0186P
TABLE 15 (Cont'd) 3526-004 AUXILIARY BUILDING EMERGENCY LIQUID CLEANUP SYSTEM (EPICOR II)
VALVE LIST DESIGN MANUFACTURER /
PRESSURE VALVE NO.
SIZE TYPE DESCRIPTION PO NO.
MODEL TEMPERATURE COMMENTS ALC-V0259 GATE EPICOR to spent Located in Unit 1 Fuel Pool 'B' i
ALC-V0260 3/4 GLOBE ALC-P-1 Air Supply Motor Operated Throttle ALC-V0261 3/4 GLOBE ALC-P-2 Air Supply Motor Operated Throttle ALC-V0262 3/4 GLOBE ALC~P-3 Air Supply Motor Operated Throttle ALC-V0263 3/4 GLOBE ALC-P-4 Air Supply Mo or Operated Throttle ALC-V0264 1/2 NEEDLE ALC-F-1 Bubbler Air Isolation ALC-V0265 1/2 NEEDLE ALC-K-1 Bubbler Air Isolation I
ALC-V0266 1/2 NEEDLE ALC-K-2 Bubbler Air Isolation ALC-V0267 3/8 NEEDLE Bubbler Air Isolation ALC-V0268 1/2 PRESSURE REGULA}DR ALC-F-1 Bubbler Self Contained Regulator (Int. Tap) i i Rev. 6/0186P
.. - ~
~
TABLE 15 (Cont'd) 3526-004 AUXILIARY BUILDING EMERGENCY LIQUID CLEANUP SYSTEM (EPICOR II) 2 VALVE LIST DESIGN MANUFACTURER /
PRESSURE j
VALVE NO.
SIZE TYPE DESCRIPTION PO NO.
MODEL TEMPERATURE COMMENTS l
ALC-V0269 1/2 PRESSURE REGULATOR ALC-K-1 Bubbler Self Contained 4
Regulator (Int. Tap)
I ALC-V0270 1/2 PRESSURE REGULATOR ALC-K-2 Bubbler Self Contained Regulator (Int. Tap) 7 ALC-V0271 1
CHECK Service Air to Bubblers /ALC-V-255 i
ALC-V0272 3/8 GLOBE Service Air to Bubblers /ALC-V-255 ALC-V0273 2
GLOBE Sump to ALC-P-1 j
Suction Isolation i
ALC-V0274 3/4 GLOBE Sump to ALC-P-1 Suction Drain 9
ALC-V0275 3/8 NEEDLE Air to ALC-V-242 Isolation ALC-V0276 2
GLOBE Sump to ALC-P-1 Suction Final Isolation ALC-V0277 2
GLOBE ALC-P-4 Discharge ALC-V0278 1
GLOBE ALC-F-1 Shield Drain i
l 1 Rev. 6/0186P 1
i
TABLE 15 (Cont'd) 3526-004 AUXILIARY BUILDING EMERGENCY LIQUID CLEANUP SYSTEM (EPICOR II)
VALVE LIST DESIGN MANUFACTURER /
PRESSURE VALVE NO.
SIZE TYPE DESCRIPTION PO NO.
MODEL TEMPERATURE COMMENTS ALC-V0279 1
GLOBE tsLC-K-1 Shield Drain ALC-V0280 1
GLOBE ALC-K-2 Shield Drain ALC-V0281 Deleted ALC-V0282 Deletei ALC-V0283 Deleted ALC-V0284 3/4 GLOBE ALC-P-6 Discharge to ALC-P-2 ALC-V0285 3/4 GLOBE ALC-P-6 Discharge to ALC-P-3 ALC-V0286 2
GLOBE CC-T-2 Process Inlet Isolation ALC-V0287 2
BALL MWHT Process Isolation ALC-V0290 1 1/4 GLOBE Minimum Flow TP-034598 Shutoff ALC-V0291 1
SOLEN 0ID Minimum Flow Automatic Cat #8400 Solenoid Rev. 6/0186P
TABLE 15 (Cont'd) 3526-004 AUXILIARY BUILDING EMERGENCY LIQUID CLEANUP SYSTEM (EPICOR II)
VALVE LIST DESIGN MANUFACTURER /
PRESSURE VALVE NO.
SIZE TYPE DESCRIPTION PO NO.
MODEL TEMPERATURE COMMENTS ALC-V0292 1 1/4 GLOBE CC-T-1 Minimum TP-034598 Flow Shutoff ALC-V0293 1 1/4 GLOBE CC-T-2 Minimum TP-034598 Flow Shutoff ALC-V0294 3/4 GLOBE ALC-DPS-1 HP teg TP-034598 Root Valve ALC-V0295 3/4 GLOBE ALC-P-5 Vent IP-034398 Valve ALC-V0296 2
BALL ALC-F-1 Bypass MMA 3526-87-0016 Inlet Isol.
ALC-V0297 2
BALL ALC-F-1 Bypass MMA 3526-87-0016 Outlet Isol.
WG-V-05 2
BALL Storage Tank Inlet ECA 3230-87-0442 from MWHT FCR #87-079 WG-V-24 2
PLUG WG Flush Conn.
150#
WG-V-29 2
PLUG SDS Filters Bypass 150#
WG-V-34 1
PLUG WG-U-3 Conn. Isol.
150#
WG-V-47 2
PLUG Fuel Pool Stor.
150#
to ALC Isol. Rev. 6/0186P
.... _ _ = _ - = - - -.
4 TABLE 15 (Cont'd) 3526-004 AUXILIARY BUILDING EMERGENCY LIQUID CLEANUP SYSTEM (EPICOR II)
VALVE LIST 1
DESIGN MANUFACTURER /
PRESSURE UALVE NO.
SIZE TYPE DESCRIPTION PO NO.
MODEL TEMPERATURE COMMENTS i
NG-V-71 2
PLUG Feed to SDS Filters 150#
WG-V-72 2
PLUG Misc. Hst. Sys.
150#
f Isol.
4 WG-V-87 1/2 GLOBE CN-FE-22 Root VLV 4000#
ECM-S-366 R.1 Capped Hi Isol.
Downstream Lines NG-V-88 1/2 GLOBE CN-FE-22 Root VLV 4000#
ECM-S-366 R.1' Capped Lo Isol.
Downstream Lines WG-V-99 2
BALL WG Spool Piece ECA 3230-87-0442 Isol.
.FCR #87-011 l
i i
4 i
4 I
1 i
j 1 Rev. 6/0186P
= _, -..
,, ~ ~ _
I
_=.
3526-004 TABLE 16 EPICOR II RADWASTE PROCESSING SYSTEM (HIC POLISHING MODE)
OVERALL OBJECTIVES:
(a) Polish influent water sufficiently to satisfy tech. spec. criteria.
(b) Process water at 10 GPM.
(c) Minimize personnel exposure.
(d) Process water at the lowest possible cost.
SPECIFIC OBJECTIVES:
Process 4
Vessel Contact Gallons Radiation Processed Level to Reach Projected Changeout Changeout Shipping Container Vessel Size Primary Purpose Composition Criteria Criteria Category
- 1 First Demin.
4'D x 4'H Ceslum & Strotium Zeolite (top) <1000 C1 dependent
< Class C (HIC)
Removal Sand (bottom) on feed
- 2 Second Demin.
6'D x 6'H Na Removal Cation (top)
< 1 uC1/cc 25,000 LSA Catton Removal Anton (bottom)
Anton Removal
- 3 Third Demin.
Polishing Mixed Resin
< 1 R/Hr 200,000 LSA Guard Bed
- 4 Strainer 2'H x 1 1/2'W x Catch Resin Fines Strainer
< 1 R/Hr 200.000 LSA 1 1/2't
- 5 Post Filter 2' x 1 1/2' x 1 1/2' Celloid Removal 1 Micron
< 1 R/Hr 150,000 LSA Cartridge M Rev. 6/0185P
-