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ATTACHMENT B L

F Proposed Technical Specification Pages 4.6-1, 4.6-3, 4.6-4, 4.6-5, and 4.6-6.

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i 4.6 PERIODIC TESTING SAFETY INJECTION AND CONTAINMENT SPRAY SYSTEMS STEAM GENERATOR EMERGENCY FEED PUMPS i

MAIN STEAM EXCESS FLOW CHECK VALVES FEEDWATER TRIP SYSTEM REACTOR COOLANT SYSTEM EMERGENCY VENT SYSTEM Applicability Applies to the safety injection system, the containment spray system, chemical injection system, the containment cooling system, the emergency feedwater system, the main steam excess flow check valves, the feedwater trip system, and the reactor coolant system emergency vent system.

Ob.iective To verify that the subject systems will respond promptly and perform their l

intended functions, if required.

Specification A.

SAFETY INJECTION AND CONTAINMENT SPRAY SYSTEMS i

1.

The following tests will be performed whenever plant conditions are as defined in Section 3.6.A of these Specifications.

a.

Emergency Core Cooling System (ECCS) Pumps.

Both operable high pressure safety injection (HPSI) pumps shall be tested quarterly in accordanca with Specification 4.7 by operating in the charging mode.

Both operable low pressure safety injection (LPSI) pumps and both operable containment spray (CS) pumps shall be tested quarterly in accordance with Specification 4.7 by operating in the recirculation mode.

b.

ECCS Valves:

i All automatically operated valves that are required to operate to assure core flooding, or containment spray shall be exercised

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quarterly in accordance with Specification 4.7.

As part of this

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quarterly testing, the volume control tank (VCT) outlet to charging i

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pump suction valves need only be exercised through part travel.

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Monthly all other valves required for safeguards operation in l

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accordance with Specification 3.6. A.2 shall be visually checked to i

verify proper operating position.

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Amendment No. 45, 58, 52, 87, 400, 421, 437 l

4.6-1 l

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ECCS Check Valves:

The check valve barriers defined in Technical Specification 3.19.A.4 shall be determined to be intact by leak testing.

i Check valve barriers shall be determined to be intact if each barrier i

(a) leakage is less than 15 gpm and each barrier (b leakage is less than 5 gpm.

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g.

Containment Isolation Valves:

Each automatic containment isolation valve that cannot be tested every three months during reactor operation in accordance with Specification 4.6.A.4 shall be tested in accordance with i

Specification 4.7.

3.

Containment Spray Headers:

The containment sprav flow nozzles shall be tested every ten years in

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accordance with Specification 4.7.

The test shall consist of pressurizing the headers with air and verifying that the nozzles are free of obstruction.

i 4.

Containment Isolation Valves:

Where practicable, each containment isolation valve shall be stroked to the position required to fulfill its safety function every three months in accordance with the Specification 4.7.

B.

EMERGENCY FEEDWATER PUMPS Prior to plant startup following an extended cold shutdown, a flow test will be performed to verify the normal flow path from the demineralized water storage

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tank to the steam generators.

The flow test shall be conducted with the emergency feedwater system valves in their normal alignment.

When the reactor is in a power operation conditioninspections shall be performed to ver Condition 7 monthly and auxiliary feedwater systems necessary to assure emergency and auxiliary feedwater flow from the primary water source to the steam generators are locked in the proper position.

When the reactor is in a power operation condition (liary feedwater pump and Condition 7), each motor the turbine driven auxi driven emergency feed pump,d quarterly in accordance with Specification 4.7 to system valves shall be teste demonstrate operability.

Bistable actuation setpoints of the motor driven emergency. feed pumps shall be tested monthly in accordance with Table 4.1-2, number 21a.

4 During each refueling shutdown, a verification test shall be conducted to assure that each motor driven emergency feed pump auto-start circuitry actuates upon receipt of an emergency feedwater actuation test signal in accordance with Table 4.1-2, number 21b.

C.

MAIN STEAM EXCESS FLOW CHECK VALVES The main steam excess flow check valves shall be tested once every 3 months for movement of the valve disc through a distance of approximately one and one-half

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inches. These valves shall be tested through full travel distance during'each refueling interval.

Amendment No. 45, 55, 58, 87, -147 4.6-3 u \\s3=n\\s3eo

D.

FEEDWATER T & SYSTEM

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1.

The following tests shall be performed at each refueling interval:

a.

Main Feedwater Pumps Each main feedwater pump, condensate pump, and heater drain pump trip system shall be tested by tripping the actuation circuitry with a safety injection signal coincident with steam generator low pressure signal.

b.

Feedwater Valves Each main feedwater regulating valve, main feedwater regulating bypass valve, and emergency feedwater control and isolation valve trip system shall-be tested by tripping the valves with a low pressure signal from their respective steam generators.

t E.

REACTOR COOLANT SYSTEM EMERGENCY VENT SYSTEM At least once each refueling interval during cold shutdown condition:

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All remotely operated valves shall be cycled 2.

Flow through each vent path shall be verified Basi:

The safety injection system and the containment spray system are principal plant safeguards systems that are normally operable during reactor operation.

Complete system tests cannot be performed when tire reactor is operating because of their inter-relation with operating systems. The method of assuring operability of these systems is a combination of complete system tests performed during refueling eutdowns and inservice testing of active system components (pumps and valves., which can be performed during reactor operation.

The test interval is based on the judgement that more frequent testing would not significantly increase the reliability (i.e., the probability that the component would operate when required), yet more frequent tests would result in increased wear over a long period of time.

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Valve performance is monitored as part of the In-Service Testing Program, which

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encompassesSection XI of the ASME Code.Section XI of the ASME Code provides

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the activities and frequencies necessary to satisfy the surveillance

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requirements.

The part travel exercising of the VCT outlet to charging pump.

suction valves, in lieu of the full travel exercise, is conducted to preclude an interruption of normal plant operations.

Redundant valves have been used to assure proper lineup in the event of ECCS actuation.

Amendment 45, 65, 68, 62, M, 87, MO, MO Correction Letter of 08/18/87 4.6-4 Li\\93mn\\9360

Other ECCS valves whose operation is not required to assure core flooding or

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containment spray shall be tested during each refueling shutdown period in

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accordance with Specification A.2.b.

The three check valves in the ECCS line to each loop provide assurance that a valve failure will not result in unrestricted flow of pressurized reactor coolant into lower pressure connecting piping outside the containment. The valve integrity testing required by Technical Specification 4.6.A.2.f assures that the rate of flow under a valve failure condition will not exceed the pressure relief capacity of the line.

It further provides periodic assurance that the check valves are intact.

The two check valves closest to the loop are grouped together as a single cht-k valve barrier for test purposes.

The first valve provides a thermal barrier preventing thermal distortion from affecting the tightness of the second valve. The third valve alone constitutes a check valve barrier.

The check valves are hard seated swing checks designed to withstand the rigors of long term RHR operation without damage and the greatest assurance of integrity and dependability.

The leakage criteria provide an acceptable oalance between the need to maintain a degree of tightness as a criterion of integrity and ALARA on one hand and power dependability considerations on the other. This criteria gives due credit to the design of, and protection provided by, the three check valve: in series.

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Verification that the spray piping and nozzles are open shall be made

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initially by a suitably sensitive method, and at least every ten years thereafter.

Since all piping material is all stainless steel, normally in a dry condition and with no plugging mechanism available, the retest every

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ten years is considered to be more than adequate.

Other systems that are important to the emergency cooling function are the SI tanks, the component cooling system and the service water system. The SI tanks are a passive safety feature.

In accordance with Specification 4.1 (Table 4.1-2, Item T, the water volume and pressure in the SI tanks are checked periodically.

woonent cooling and service water systems operate when the reactor is o

f ration and are continuously monitored for satisfactory performance.

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The quarterly test of the steam generator motor driven emergency feed pumps and the turbine driven auxiliary feedwater pump verifies their operability by recirculating water to the demineralized water tank.

The bistable actuation setpoints for the motor driven emergency feed pumps are checked monthly in accordance with #21 of Table 4.1-2 to verify that the setpoints have not drifted.

Prior to plant startup following an extended cold shutdown, a flow test is

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performed on the emergency feedwater system to functionally verify the system alignment from the demineralized water storage tank to the steam generators.

Amendment No. 64, 87, MO, m, W 4.6-5 u\\%\\suo a

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Monthly inspections are performed to verify that all manual valves in the

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emergency and auxiliary feedwater systems from the primary water source to the i

steam generators are locked in the proper position.

Proper functioning of the steam turbine admission valve and starting of the auxiliary feed pump will demonstrate the operability of the steam driven

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pump.

Verification of correct operation shall be made both from instrumentation in the Main Control Room and direct visual observation of the l

pumps.

The main steam excess flow check valves serve to limit an excessive reactor i

coolant system cooldown rate and resultant reactivity insertion following a

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main steam break incident. Their freedom to move shall be verified periodically.

The feedwater trip system acts to limit excessive reactor coolant system cooldown and the resultant reactivity insertion produced by excessive feedwater flow to the steam generators in the event of a main steam line break. The system acts to trip feedwater pumps, condensate pumps, and heater drain pumps, and-close the main feedwater regulating valve, feedwater regulating valve bypass valve, and emergency feedwater control a.nd isolation valves to the affected steam generator.

Signals activating the system are developed by instrumentation, logic, and relaying associated with the safety injection actuation system and the excess flow check valve actuation system.

The circuitry which develops these signals is subject to surveillance requirements of Tables 4.1-1 and 4.1-2 which assure their reliability.

The main feedwater pumps, condensate pumps, and heater drain pumps trip upon coincidence of SIAS and a low steam generator pressure.

The valves close on the low steam generator pressure in the associated steam generator.

The reliability of the coincidence logic is assured by testing in accordance with

1. 20 of Table 4.1-2.

Cycling of the reactor coolant system emergency vent system valves and verification of flow through each path documents the operability of the system. Operability of this system assures the ability to remove noncondensible gases from the reactor coolant system urder severe post accident conditions in order to help prevent or mitigate core damage.

5 Amendment No. GB, 76, 87, 400 4.E 3 ugsw\\sno

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