Attachment 2, Pump and Value Inservice Test Program for Calvert Cliffs Nuclear Power Plant Unit 2 Fourth Ten Year Interval

ML071980493
Person / Time
Site:	Calvert Cliffs
Issue date:	07/02/2007
From:	Calvert Cliffs, Constellation Energy Group
To:	Office of Nuclear Reactor Regulation
References
Download: ML071980493 (147)
v • d • e

Text

ATTACHMENT (2)-

PUMP AND VALVE INSERVICE TEST PROGRAM FOR CALVERT CLIFFS NUCLEAR POWER PLANT UNIT 2 FOURTH TEN YEAR INTERVAL Calvert Cliffs Nuclear Power Plant, Inc.

July 2, 2007

Constellation Energy (CCNPP Unit 2) IST Program PUMP AND VALVE INSERVICE TESTING PROGRAM FOURTH TEN-YEAR INTERVAL Revision Rev O00 Code Edition r

1.0 INTRODUCTION

This document outlines the Calvert Cliffs Nuclear Power Plant (CCNPP), Unit 2, IST Program for the fourth 10-year interval based on the requirements of the American Society of Mechanical Engineers (ASME) Operations and Maintenance (OM) Code, 2004 Edition. (upon approval of Relief Request GA-RR-01)

This revision of the CCNPP ASME Inservice Testing (IST) Program will be in effect through the end of the fourth 120-month (10-year) interval unless changed and re-issued for reasons other than the routine update required at the start of the next interval per 10 CFR 50.55a(f). The fourth inspection interval begins on July 1, 2008, and ends on June 30, 2018.

2.0 Reference Documents This Program Plan was developed per the requirements and guidance provided by the following documents:

2.1 Title 10, Code of Federal Regulations, Part 50.55a 2.2 Regulatory Guide 1.192, "Operations and Maintenance Code Case Acceptability, ASME OM Code" 2.3 Standard Review Plan 3.9.6, "Inservice Testing of Pumps and Valves" 2.4 ASME OM Code-2004, "Code for Operation and Maintenance of Nuclear Power Plants" 2.5 NUREG 1482, Rev. 1, "Guidelines for Inservice Testing at Nuclear Power Plants" 2.6 Summary of Public Workshops Held in NRC Regions on Inspection Procedure 73756, "Inservice Testing of Pumps and Valves and Answers to Panel Questions on Inservice Testing Issues," dated 7/18/97 2.7 Calvert Cliffs Nuclear Power Plant Updated Final Safety Analysis Report 2.8 Calvert Cliffs Nuclear Power Plant Technical Specifications

2.9 Correspondence

Letter from Mr. S. Singh Bajwa (NRC) to Mr. C. H. Cruse (BGE), dated February 11, 1998, "Safety Evaluation of the Inservice Testing Program Third Ten-Year Interval For Pumps and Valves, Calvert Cliffs Nuclear Power Plant, Unit Nos. 1 and 2 (TAC Nos. M98523 and M98524)"

Letter from CCNPP (BGE) to NRC Document Control Desk, dated December 30, 1999, "Revised and New Relief Requests for the Third Ten Year Inservice Test Program" Letter from CCNPP (BGE) to NRC Document Control Desk, dated May 19, 2000, "Response to Request for Additional Information: Relief Request PR-1 1 Low Pressure Safety Injection Pumps" Letter from Ms. M. Gamberoni (NRC) to Mr. C. H. Cruse (CCNPP, Inc), dated August 22, 2000, "Safety Evaluation of Relief Requests for the Third 10-Year Pump and Valve In-Service Testing Program Calvert Cliffs Nuclear Power Plant Units 1 and 2 (TAC Nos. MA7848 and MA7849)"

NRC letter to Calvert Cliffs, dated 1/19/01, SER for Relief Request VR-16 Letter from Mr. R. J. Laufer (NRC) to Mr. C. H. Cruse (CCNPP, Inc), dated May 16, 2002, "Request for Relief No. PR-12 Associated with the Third 10-Year Interval Inservice Testing Program, Calvert Cliffs Nuclear Power Plant, Unit Nos. 1 and 2 (TAC Nos. MB3782 and MB3783)"

Letter from J.A. Spina (CEG) to NRC Document Control Desk, dated June 20, 2007, "Notification of Extension of the Inservice Test Program Third Ten-Year Interval)"

General Information 3.0 PROGRAM DEVELOPMENT ASME OM Code-2004 (hereafter referred to as 'the OM Code') requires that the owner of each nuclear power plant prepare and submit a "plan" for testing and inspection of systems and components under the jurisdiction of the Code and in compliance with Title 10, Part 50 of the Code of Federal Regulations (Para. 50.55a).

Inservice Testing of ASME Class 1, 2, and 3 pumps and valves is performed in accordance with the OM Code 1

OF 14

Constellation Energy (CCNPP Unit 2) IST Program PUMP AND VALVE INSERVICE TESTING PROGRAM FOURTH TEN-YEAR INTERVAL Revision Rev 00 2004 Edition, except as allowed by 10CFR50 or where specific written relief has been granted by the NRC pursuant to 10CFR50.55a(f)(6)(i) for examinations and tests determined to be impracticable. Provided guidance of NUREG 1482, Revision 1, is followed, the proposed alternative examinations or tests may be implemented prior to receiving written NRC approval if so stated in the guidance document.

The OM Code, Subsections ISTA and ISTB shall be utilized for the inservice testing of pumps. Subsections ISTA and ISTC shall be utilized for the inservice testing of valves. Subsection ISTA, ISTC and Appendix I shall be utilized for the inservice testing of pressure relief devices. Appendix II, Check Valve Condition Monitoring, may be utilized for certain check valves within the IST Program scope. The OM Code of Record for the Fourth 10-Year Interval has not been approved for use in 10CFR50.55a(b)(3). This is addressed in program relief request GA-RR-01.

ASME OM Code Cases that have been approved for use by the NRC per Regulatory Guide 1.192 and are adopted for use at Calvert Cliffs are identified in the IST Program. The following Code Cases shall be used during the Fourth 10-Year Interval IST Program implementation with all conditions, as applicable:

OMN-1, "Alternative Rules for Preservice and Inservice Testing of Certain Electric Motor-Operated Valve Assemblies in Light-Water Reactor Power Plants," Revision 0 (upon approval of Relief Request GV-RR-02)

OMN-8, "Alternative Rules for Preservice and Inservice Testing of Power-Operated Valves That Are Used for System Control and Have a Safety Function per OM-10," Revision 0 (upon approval of Relief Request GV-RR-03)

In accordance with the Code and 10CFR50.55a, the following are required to be included in the testing Program:

• ASME Class 1, 2, or 3 centrifugal and positive displacement pumps that are provided with an emergency power source and are required to perform a specific function in

1) Shutting down the reactor to the safe shutdown condition;

2) Maintaining the safe shutdown condition; or

3) Mitigating the consequences of an accident.

• ASME Class 1, 2 and 3 active or passive valves (and their actuating and position indicating systems) which are required to perform a specific function in 1).Shutting down the reactor to the safe shutdown condition;

2) Maintaining the safe shutdown condition; or

3) Mitigating the consequences of an accident.

• ASME Class 1, 2 and 3 pressure relief devices that protect systems or portions of systems which perform a required function in

1) Shutting down the reactor to the safe shutdown condition;

2) Maintaining the safe shutdown condition; or

3) Mitigating the consequences of an accident.

In addition to the general Code requirements outlined above, there are other interpretations and positions that have come about as a result of past regulatory and licensee actions including NUREG-1482.

The term "accident" refers not only to the design basis accidents analyzed in Chapter 14 of the UFSAR, but to a broad range of possible adverse events which could affect plant safety. Additional accidents and operational transients, and the equipment required to mitigate the possible consequences thereof, are identified in the UFSAR.

The CCNPP safety analysis specifically requires the units to reach a safe-shutdown condition defined as hot standby and not the cold shutdown condition. Per NUREG-1482, Revision 1, pumps and valves in such plants 2

OF 14

Constellation Energy (CCNPP Unit 2) IST Program PUMP AND VALVE INSERVICE TESTING PROGRAM FOURTH TEN-YEAR INTERVAL Revision Rev 00 needed only to reach cold shutdown need not be included in the Inservice Testing Program. However, in some instances, CCNPP has decided to include cold shutdown-related components in the Program for completeness even though compliance with Code requirements may not be required.

In light of the foregoing, a set of rules was established by which the scope of the CCNPP ASME OM Code IST Program is determined including components that are to be included and the extent and type of testing required for each component. Based on these rules, the philosophy and assumptions used in determining the test requirements for selected pumps and valves were documented.

3.1 Initial Program Scope In the course of validating the Program scope for the fourth interval, each of the significant safety systems (included within the ISI-class boundaries) were evaluated with respect to the function of each component and the need for its operability as it relates to the scope of the OM Code. Supporting documents used include, Updated Final Safety Analysis Report (UFSAR);

Technical Specifications; Past program correspondence; and Operating Procedures (Normal, Emergency and Off-Normal).

The sequence followed during the review effort was as follows:

1) Each of the plant systems was subjected to an overview to determine any potential safety function as described in the scope statement. Those systems with no safety functions were then excluded from further consideration.

2) For the remaining systems, flow diagrams were studied and any components that could possibly have an active or passive safety function were identified for further evaluation.

3) The function of each component was determined. This included classifying valves and their functions as passive or active. Testing requirements were then derived based on the component function(s) and the applicable rule(s).

4) Documents were reviewed and specific or implied component operational requirements were compared to the information derived in 3, above.

5) The results of Steps 1 through 4, above, were reviewed by several knowledgeable members of the plant staff and evaluated for accuracy and consistency. Based on this review, the final program scope was derived and the IST Program Plan updated.

3.2 Program Update During the fourth 10-year interval, it is expected that the scope of the Program will occasionally be modified in response to activities including, but not limited to:

1) Plant design changes;

2) Changes in operating conditions (e.g. normal valve lineup);

3) Changes in accident mitigating procedures philosophy; or

4) Regulatory demands.

As a result, the IST Program will be revised to ensure continued compliance with the Code requirements relating to the scope of the test program, as necessary.

The supervisor responsible for maintaining the IST Program is provided input from Engineering regarding plant modifications that are designated by Engineering to have a potential IST/ISI impact. Additionally, other pertinent changes such as a significant change in plant operating or accident mitigation philosophy that might have a direct impact on the IST Program are also reviewed. Should a change require a Program revision, the IST Coordinator implements the change to the Program Plan and the appropriate test procedure(s) in a timely manner.

3.3 Program Scope Philosophy The final scope of the Fourth Ten-Year Interval IST Program was determined based on an exhaustive search and comprehensive evaluation of numerous design-basis and licensing-basis documents which included, in part, the 3

OF 14

Constellation Energy (CCNPP Unit 2) IST Program PUMP AND VALVE INSERVICE TESTING PROGRAM FOURTH TEN-YEAR INTERVAL Revision Rev 00 CCNPP UFSAR and Technical Specifications, various engineering and Q-List evaluations, various CCNPP Operating Procedures and Instructions, various CCNPP Abnormal and Emergency Operating Procedures, and numerous related NRC Generic Letters, Safety Evaluation Reports, and other current and historical docketed pieces of BGE-NRC correspondence.

The purpose of this effort was to identify and evaluate the safety function(s) of all potential candidate pumps and valves. The major criteria for including pumps and valves in the IST Program may be generalized/summarized as follows:

1. Pumps and valves credited in CCNPP UFSAR Chapter 14 Accident Analyses for accomplishing, or supporting, one or more of the Critical Safety Functions: Reactivity Control, RCS Pressure & Inventory Control, RCS Heat Removal, Containment Isolation & Environment, Radiation Control, and Vital Auxiliaries.

2. Selected pumps and valves which provide "operational flexibility," i.e. components which are not specifically credited but may be substituted for components which are credited as accomplishing or supporting the Critical Safety Functions,

3. Selected pumps and valves which support implementing selected "alternate success paths" (which are not credited) for accomplishing necessary safety functions, (However, uncontrolled scope growth would dilute Program effectiveness if additional testing did not provide additional safety benefits. To avoid this, CCNPP considered factors such as (1) the number of other "success paths" and which ones were already included in the IST Program, (2) the scope of other preventive maintenance or testing programs, (3) available equipment redundancy versus applicable single failure requirements, e.g.

multiple failure scenarios are generally not included in the IST Program scope. Additionally, there are several ways CCNPP can progress from the licensed safe shutdown condition to the cold shutdown condition. However, since CCNPP is licensed for a safe, vice cold, shutdown condition, not all these components are necessarily classified safety-related and/or ASME Code Class 1, 2, or 3.)

4. Pumps and valves for which specific commitments have been made regarding inclusion in the IST Program,

5. Pumps and valves whose inclusion in the IST Program is specifically required by CCNPP Technical Specifications,

6. Selected pumps and valves whose assumed performance is considered critical in applicable, pertinent, engineering evaluations/calculations,

7. Pressure relief devices which met the above criteria themselves, or protect systems/portions of systems which met the above criteria.

3.4 Skid-Mounted Components Code class systems may include skid-mounted components or component subassemblies. A skid-mounted component is one that is integral to, or that supports operation, of a major component. These components are usually procured as part of a larger component assembly and are often not designed to meet the requirements for components in ASME classes 1, 2, and 3. A component that functionally meets this description may be treated as "skid-mounted" even if it is not located directly on the skid of the major component. Often the "major" component is not subject to 10 CFR 50.55a and inservice testing requirements because only specific components/subcomponents are ASME Code Class 1, 2, or 3. However, the major component is typically subject to other testing requirements. As defined in Subsection ISTA-2000 and specifically addressed in Subsections ISTB-1200(c) and ISTC-1200, skid-mounted components may be excluded from the specific applicable OM testing requirements provided that their operational readiness is verified when the major component is tested and justified by the owner to be adequately tested. In NUREG-1482, Rev. 1, Section 3.4, the NRC Staff has determined that the testing of the major component is an acceptable means for verifying the operational readiness of skid-mounted components and component subassemblies provided this approach is discussed in the IST Program document.

Most air-operated control valves at Calvert Cliffs have an associated solenoid valve that supports the control valve's operation. Each solenoid valve associated with a control valve is considered to be a skid-mounted component/component subassembly and is not separately listed in the Valve Tables. These solenoid valves make up the bulk of the skid-mounted components/component subassemblies included in the Calvert Cliffs 4

OF 14

Constellation Energy (CCNPP Unit 2) IST Program PUMP AND VALVE INSERVICE TESTING PROGRAM FOURTH TEN-YEAR INTERVAL Revision Rev 00 IST Program. The manner in which each air-operated control valve is tested is adequate to ensure the operational readiness of the control valve and the associated solenoid valve.

3.5 Augmented Testing Program The reviews performed to prepare the Fourth Ten-Year Interval IST Program identified some safety-related pumps and valves that do not fall within the mandatory scope of Calvert Cliffs' IST Program even though they may be used to accomplish or support significant safety functions. However, even though these pumps and valves do not' fall within the required scope of the IST Program, some perform significant safety functions which would otherwise fall within the scope of the Code and, therefore, require some type of testing commensurate with their importance to safety.

Augmented testing refers to voluntary testing of components that are not within the mandatory IST scope, but are similar (in configuration and/or function) to components that are. Per NUREG-1482, Revision 1, Section 2.2, the testing of selected pumps and valves that are not legally required to be included in the IST Program can be consolidated with the IST Program to the maximum extent desired and/or practical for convenience, without actually including them in the scope of the mandatory IST Program. These pumps and valves are tested commensurate with their safety function. To minimize confusion, augmented testing generally follows the Code to the maximum extent practical. However, augmented testing is not required to comply with the Code and "deviations" from the Code for such components do not require an approved relief request.

These pumps and valves have been integrated into the IST Program Plan, as discussed in NUREG-1482, Revision 1, so that all related testing could be grouped and tracked considering any similar components. This was done in this manner solely for Calvert Cliffs' convenience in order to minimize confusion and improve efficiency while implementing this "Augmented Testing Program" alongside the IST Program. Furthermore, to minimize confusion, Calvert Cliffs included cold shutdown and refueling outage justifications for these components to maintain consistency and clearly identify the basis for any apparent deviations from the Code. Augmented components are clearly identified as such in the IST Program Plan tables.

The bulk of these components, although not all, fall into three general categories:

ASME/ISI Classification vs. Safety Classification The scope statements in the OM Code do not specifically limit themselves to ASME/ISI Code Class I, II, & III pumps and valves. In fact, some documents claim the Code Committee did not intend to limit the scope to only such components. However, the requirement to implement and maintain an IST Program comes from 10 CFR 50155a and Calvert Cliffs' Technical Specification 5.5.8, which are specifically limited to ASME/ISI Code Class 1, 11,

& Ill components. Therefore, the mandatory scope of Calvert Cliffs' IST Program is limited to ASME/ISI Code Class I, 11, & Ill pumps and valves. Per NUREG-1482, Revision 1, Section 2.2, non-Code Class pumps and valves are not required to be included in the IST Program. However, despite this, some of the safety functions they perform would otherwise fall within the scope of the Code and, therefore, these valves should be subject to some type of testing commensurate with their importance to safety.

Safe Shutdown Licensed Condition vs. Cold Shutdown Condition Calvert Cliffs' safety analyses specifically require the Units to reach a safe-shutdown condition defined as hot standby and not the cold shutdown condition as required by the Code. Per NUREG-1482, Revision 1, pumps and valves in such plants needed only to reach cold shutdown need not be included in the Inservice Testing Program.

Despite the fact that certain editions of the Code refer to the "cold shutdown" condition, the mandatory scope of Calvert Cliffs' IST Program is generally based on the "safe shutdown" condition that is actually specified in the plant's licensing basis. In some instances, testing of selected components needed to safely and reliably progress from the safe shutdown condition to the cold shutdown condition have been consolidated into the IST Program for completeness even though compliance with Code requirements may not be required.

Defense-in-Depth 5

OF 14

Constellation Energy (CCNPP Unit 2) IST Program PUMP AND VALVE INSERVICE TESTING PROGRAM FOURTH TEN-YEAR INTERVAL Revision Rev 00 In some cases, the single failure requirements inherent in Calvert Cliffs' Technical Specifications restrict the use of certain pumps and valves for meeting system/header operability requirements. However, the use of these pumps and valves is often included in Emergency Operating Procedures to provide alternative success paths if they are available. Additionally, the ability of some of these components to accomplish these functions has also been factored into Calvert Cliffs' PRA model. Therefore, many of these components are considered to contribute to Calvert Cliffs' philosophy of defense-in-depth and the testing of selected components have been consolidated into the IST Program for completeness even though compliance with Code requirements may not be required.

6 OF 14

Constellation Energy (CCNPP Unit 2) IST Program PUMP AND VALVE INSERVICE TESTING PROGRAM FOURTH TEN-YEAR INTERVAL Revision Rev 00 Pump Information 4.0 INSERVICE TESTING PROGRAM FOR PUMPS 4.1 Code Compliance The IST Program for pumps meets the requirements of Subsections ISTA and ISTB of the OM Code and any applicable interpretations or clarifications of existing requirements. Paragraph and table references in this section refer to specific paragraphs and tables in the OM Code. Where these requirements have been determined to be impractical, an alternative test provides an acceptable level of quality and safety, or conformance would cause unreasonable hardship without any compensating increase in safety, relief from Code requirements is/was requested pursuant to the requirements of 10CFR 50.55a(f)(5)(iii), 10CFR50.55a(a)3(i) or 10CFR50.55a(a)3(ii).

4.2 Allowable Ranges of Test Quantities The allowable ranges for test parameters as specified in the OM Code, Tables ISTB-5121-1, ISTB-5221 -1 and ISTB-5321 -1 will be used for all measurements of pressure, flow, and vibration except as provided for in specific relief requests.

4.3 Testing Intervals The test frequency for pumps included in the Program will be as set forth in the OM Code, paragraph ISTB-3400, and related relief requests. An allowable extension, not to exceed +25 percent of the surveillance interval may be applied to a test schedule as allowed by the Calvert Cliffs Nuclear Power Plant Technical Specifications to provide for operational flexibility.

The frequencies used for scheduling pump tests are defined as:

Quarterly - 92 days Refueling - 730 days Cold Shutdown - Per the applicable Relief Request consistent with the cold shutdown testing requirements for valves in the OM Code. When all cold shutdown testing will not be completed, priorities for testing will be established per approved CCNPP procedures.

4.4 Pump Program Tables lists those pumps included in the IST Program with references to parameters to be measured and applicable requests for relief.

4.5 Relief Requests for Pump Testing Relief requests are/were submitted per 1 OCFR50.55a where appropriate and are included in Attachment 1.

4.6 Instrument Accuracy Instruments will meet the requirements specified in the OM Code, paragraph ISTB-3500, and amplified in NUREG 1482, Revision 1, Section 5, except where specific relief is granted.

4.7 Vertical Line Shaft Pumps Paragraph ISTB-2000 of the OM Code defines a Vertical Line Shaft pump as "a vertically suspended pump where the pump driver and the pump element are connected by a line shaft within an enclosed column." In a vertical line shaft pump configuration, the pump bearings would be submerged in the pumped fluid and inaccessible. The Salt Water pump configuration does not meet the OM Code paragraph ISTB-2000, vertical line shaft pump definition.

7 OF 14

Constellation Energy (CCNPP Unit 2) IST Program PUMP AND VALVE INSERVICE TESTING PROGRAM FOURTH TEN-YEAR INTERVAL Revision Rev O00 These pumps are not "vertically suspended." They are mounted in a dry pit located at the intake structure with pump orientation such that they take suction through the intake structure floor. The drive motor is mounted on an elevated platform above the pump and connected to the pump via an exposed shaft. This design allows pump operation in the event of flooding. However, the salt water pump bearings are accessible and the shaft is not "within an enclosed column." CCNPP considers these pumps to be horizontal centrifugal pumps.

4.8 Pump Design Flow Comprehensive pump testing is required to be performed with the pump operating within 20% of design flow. The OM Code does not; however, define the term "design" flow. The industry has considered 4 different definitions: 1) the pump manufacturer's design flow for the pump, 2) the pump's best efficiency point (BEP), 3) the system design flow, and 4) the maximum required accident flow rate. The NRC has stated their position as this "design" flow rate must be at least the maximum credited accident flow rate. CCNPP has determined that for the comprehensive pump testing the selected reference flow rate will be at least the maximum credited accident flow rate as stipulated by the NRC.

8 OF 14

Constellation Energy (CCNPP Unit 2) IST Program PUMP AND VALVE INSERVICE TESTING PROGRAM FOURTH TEN-YEAR INTERVAL Revision Rev 00 Valve Information 5.0 INSERVICE TESTING PROGRAM FOR VALVES 5.1 Code Compliance This IST Program for valves meets the requirements of Subsections ISTA and ISTC of the OM Code and any applicable interpretations or clarifications of existing requirements provided by NUREG 1482, Revision 1.

Paragraph and table references in this section refer to specific paragraphs and tables in the OM Code. Where these requirements have been determined to be impractical, an alternative test provides an acceptable level of quality and safety, or conformance would cause unreasonable hardship without any compensating increase in safety, relief from Code requirements is/was requested pursuant to the requirements of 10CFR 50.55a(f)(5)(iii),

10CFR50.55a(a)3(i) or 10CFR50.55a(a)3(ii).

5.1.1 Code Case OMN-1 ASME OM Code Case OMN-1, "Alternative Rules for Preservice and Inservice Testing of Certain Motor-Operated Valve Assemblies in Light-Water Reactor Power Plants," allows the use of MOV diagnostic testing as an alternative to stroke time testing and position indication verification for certain motor operated valves. Use of this Code Case is authorized by Regulatory Guide 1.192, "Operation and Maintenance Code Case Acceptability, ASME OM Code." This Regulatory Guide lists ASME OM Code Cases determined acceptable for use in IST Programs by the NRC. The Regulatory Guide is incorporated by reference in the Code of Federal Regulations 10CFR50.55a(b). The Code Case is listed in Table 2 of this Regulatory Guide as a conditionally approved Code Case. A conditionally approved Code Case may be used without request to the NRC provided it is used with any identified limitations or modifications. The stipulations listed in Table 2 include the following:

(1) The adequacy of the diagnostic test interval for each motor-operated valve (MOV) must be evaluated and adjusted as necessary but not later than 5 years or three refueling outages (which ever is longer) from initial implementation of OMN-1.

(2) When extending exercise test intervals for high risk MOVs beyond a quarterly frequency, ensure that the potential increase of Core Damage Frequency (CDF) and risk associated with the extension is small and consistent with the intent of the Commissions Safety Goal Policy Statement.

(3) When applying risk insights, MOVs must be categorized according to their safety significance using the methodology described in Code Case OMN-3 or use other MOV risk ranking methodologies accepted by the NRC on a plant specific or industry-wide basis.

This Code Case will be used, (upon approval of Relief Request GV-RR-02), with the associated stipulations, as an alternative to the motor-operated valve testing required by the OM Code in Subsection ISTC. The valve tables will be annotated with "OMN1" in the "Frequency" column as appropriate.

5.1.2 Code Case OMN-8 ASME OM Code Case OMN-8, "Alternative Rules for Preservice and Inservice Testing of Power-Operated Valves That Are Used for System Control and Have a Safety Function per OM-10," provides an alternative to stroke time testing of system control valves whose only safety function is to "fail-safe" to either the open or close position.

This Code Case will be used, (upon approval of Relief Request GV-RR-03) for certain control valves. Use of the Code Case will be annotated in the Program tables "Remarks" column as appropriate.

5.2 Stroke Time Acceptance Criteria When required, the acceptance criteria for the stroke times of power-operated valves will be as set forth in the OM Code, Subsection ISTC.

5.3 Check Valve Testing 9

OF 14

Constellation Energy (CCNPP Unit 2) IST Program PUMP AND VAL VE INSERVICE TESTING PROGRAM FOURTH TEN-YEAR INTERVAL Revision Rev 00 5.3.1 Test Methods Check valves are full-stroke exercised in the open direction using the following methods:

, Using system flow equal to, or greater than, the required accident flow rate (plus allowance for analytical and instrument uncertainties).

, Non-intrusive monitoring, or other positive means, that verifies the valve disk reaches the fully-open position (recording flow rate is not necessary).

Mechanical exercising.

, Other methods that satisfy the requirements of GL 89-04, Position 1 or as specified in an approved relief request.

Check valves are full-stroke exercised in the closed direction using the following methods:

- Verifying system flow equal to, or greater than, the required accident flow rate (plus allowance for analytical and instrument uncertainties) is achievable in a parallel flow path when the check valve being tested forms a boundary for that flow path.

- Measuring check valve gross leakage or performing a gross pressure drop test to verify the valve disk is in the closed position.

- Non-intrusive monitoring, or other positive means, that verifies the valve disk opens and then returns to the fully-closed position (recording leakage is not necessary unless required for Category A valves).

• Mechanical exercising.

• Other methods that satisfy the requirements of GL 89-04, Position 1 or as specified in an approved relief request.

5.3.2 Non-Intrusive Check Valve Testing As discussed in NUREG-1482, Revision 1, Section 4.1.2, the NRC determined that the use of non-intrusive techniques is acceptable to verify the full stroke of a check valve. The licensee may use non-intrusive techniques to verify the capability to open, close, and fully stroke in accord with quality assurance program requirements.

These techniques are considered "other positive means" in accordance with paragraph ISTC-5221 (a), and relief is not required except as would be necessary for the testing frequency if the test interval extends beyond each refueling outage as allowed by the OM Code.

During the initial test of each valve, non-intrusive techniques will be used to verify that the system pressures and flow conditions specified in the test procedures cause the valves to fully stroke. Initial testing of check valves using non-intrusive techniques shall only be performed when the valve is known to be operating acceptably.

During subsequent testing, if the system conditions are repeatable, each valve would typically be stroked and monitored using non-intrusive techniques.

Another alternative that may be employed is radiography. The position of the disk and the general condition of the internals may be determined using the radiographic method. This methodology is normally used for verification of valve closure only.

5.3.3 Check Valves Verified Closed by Leak Testing The OM Code requires that check valves performing a safety function in the closed position be exercised to that position. Certain of these valves cannot be verified in the closed position quarterly because they do not have remote position indication and are generally located inside reactor containment or at other inaccessible locations.

These valves may lack design provisions for system testing to verify closure capability at any plant condition. The only practical means of verifying valve closure may be by performing a seat leakage test. Many of these valves are Category AC valves that are Type C leak-rate tested during each refueling outage as specified in Appendix J to 10 CFR Part 50.

If no other practical means is available, it is acceptable to verify that check valves are capable of closing by performing leak-rate testing, such as local leak rate testing in accordance with Appendix J to 10 CFR Part 50, at each reactor refueling outage. Recognizing that the setup and performance limitations may render leak testing 10 OF 14

Constellation Energy (CCNPP Unit 2) IST Program PUMP AND VALVE INSERVICE TESTING PROGRAM FOURTH TEN-YEAR INTERVAL Revision Rev 00 impractical during power operation and cold shutdown outages, the NRC has determined that implementation of an extension of the test frequency for such valves is acceptable in accordance with 10 CFR 50.55a(f).

In accordance with paragraph ISTC-5222, and as discussed in NUREG-1482, Revision 1, Section 4.4.7, as an alternative to check valve closure verification by Type C seat leakage testing at refueling, the Appendix II Check Valve Condition Monitoring Program could justify extending the exercise test interval to the leak test frequencies specified in Option B of Appendix J based on the valve's performance and operating condition.

5.3.4 Check Valve Disassembly and Inspection When using check valve disassembly in a sampling plan, the IST Program may implement testing such that similar valves in the same service are grouped for testing purposes, not to exceed four valves in a single group (for valve groups of greater than four, the grouping and test schedule must be justified in the description of the testing plan). The sample examination program shall group check valves of similar design, application, and service condition and require a periodic examination of one valve from each group. Grouping of check valves shall be technically justified and shall consider, as a minimum, valve manufacturer, design, service, size, materials of construction, and orientation. Maintenance and modification history should be considered in the grouping process. The details and bases of the sampling program shall be documented and recorded. (paragraph ISTC-5221 (c))

During the disassembly process, the full-stroke motion of the obturator shall be verified. Full-motion of the obturator shall be re-verified immediately prior to completing reassembly. Check valves that have their obturator disturbed before full-stroke motion is verified shall be examined to determine if a condition exists that could prevent full opening or closure of the obturator.

At least one valve from each group shall be disassembled and examined at each refueling outage; all valves in each group shall be disassembled and examined at least once every 6 years (8 years if on a 24 month fuel cycle).

If problems are found with the sample valve, that are determined to affect the operational readiness of the valve, all valves in the group must be tested during the same outage.

Before return to service, valves that were disassembled for examination or that received maintenance that could affect their performance; shall be exercised, full or part stroke if practicable, with flow in accordance with paragraph ISTC-3520. Those valves shall also be tested for other applicable requirements (e.g., closure verification or leak rate testing) before returning them to service.

As an alternative to the aforementioned disa'ssembly and inspection frequency, the Appendix II Check Valve Condition Monitoring Program could justify extending the disassembly and inspection interval to reduce the burden of unnecessary IST based on previous disassembly and inspection results.

5.3.5 Check Valve Condition Monitoring As an alternative to the testing or examination requirements of paragraphs ISTC-351 0, ISTC-3520, ISTC-3530, ISTC-3550, and ISTC-5221, CCNPP will establish a check valve condition monitoring program per paragraph ISTC-5222 and implement the program in accordance with Appendix II "Check Valve Condition Monitoring Program."

The purpose of this program is to both (a) improve check valve performance and to (b) optimize testing, examination, and preventive maintenance activities in order to maintain the continued acceptable performance of a select group of check valves.

Examples of candidates for (a) improved valve performance are check valves that: (1) have an unusually high failure rate during inservice testing or operations; (2) cannot be exercised under normal operating conditions or during shutdown; (3) exhibit unusual, abnormal, or unexpected behavior during exercising or operation, or (4) 11 OF 14

Constellation Energy (CCNPP Unit 2) IST Program PUMP AND VALVE INSERVICE TESTING PROGRAM FOURTH TEN-YEAR INTERVAL Revision Rev O00 CCNPP elects to monitor for improved valve performance.

Examples of candidates for (b) optimization of testing, examination, and preventive maintenance activities are check valves with documented acceptable performance that: (1) have had their performance improved under the Condition Monitoring Program; (2) cannot be exercised or are not readily exercised during normal operating conditions or during shutdowns; (3) can only be disassembled and examined, or (4) CCNPP elects to optimize all the associated activities of the valve or valve group in a consolidated program.

If the Appendix II Condition Monitoring Program for a valve or valve group is discontinued then the requirements of paragraphs ISTC-3510, ISTC-3520, ISTC-3530, ISTC-3550, and ISTC-5221 must be implemented.

Valves included in the Check Valve Condition Monitoring Program (CVCMP) will be annotated with "CMP" in the "Frequency" column of the Valve Tables. The Code testing specified in the Tables is replaced by the activities/tests identified in the specific CMP Plan.

5.4 Manual Valves Manual valves within the scope of IST that perform an active safety function shall be exercised at least once every 2 years as required by 10 CFR 50.55a(b)(3)(vi).

5.5 Testing Intervals The test frequency for valves included in the Program will be as set forth in the OM Code, paragraph ISTC-3510 and related relief requests. An allowable extension, not to exceed +25 percent of the surveillance interval, may be applied to the test schedule as allowed by the CCNPP Technical Specifications to provide for operational flexibility.

The frequencies used for scheduling valve tests are defined as:

Quarterly - 92 days Refueling - 730 days 2 Year - 730 days Per App. J - Leak Rate Testing frequency determined by Appendix J requirements.

Sampling - For safety/relief valves, set-point testing per the applicable population sampling requirements specified in OM Code, Appendix I.

Sampling - For check valves, disassembly and inspection per the applicable population sampling requirements specified in Subsection ISTC-5221 (c).

Cold Shutdown - Consistent with the cold shutdown testing requirements for valves of the OM Code, paragraphs ISTC-3521(f), (g), & (h) and ISTC-3522(d), (e), & (f), and NUREG 1482, Revision 1, Sections 3.1.1, 3.1.1.1 and 3.1.1.2. When all cold shutdown testing will not be completed, priorities for testing will be established per approved CCNPP procedures.

Per the OM Code, paragraphs ISTC-3550 and ISTC-3610, valves in regular use and valves which demonstrate functionally adequate seat tightness during normal operation are not required to be additionally tested as long as the required observations and analyses are performed and documented at the otherwise required test frequency.

The frequency indicated in the valve table for such valves is the applicable required test frequency.

5.6 Valve Program Tables Specific tables list those valves included in the IST Program with references to required testing, respective test intervals, and applicable requests for relief. The following notations are used in the valve tables to identify required testing.

Description of Test Codes:

BDT-C Bi-directional exercise test in the non-safety related close direction per ISTC-3522 and ISTC-5220 12 OF 14

Constellation Energy (CCNPP Unit 2) IST Program PUMP AND VALVE INSERVICE TESTING PROGRAM FOURTH TEN-YEAR INTERVAL Revision Rev 00 BDT-O Bi-directional exercise test in the non-safety related open direction per ISTC-3522 and ISTC-5220 DI Disassembly and inspection per ISTC-5221 (c)

DIAG Inservice test per Code Case OMN-1 FE-F Full stroke exercise test in the forward flow direction per ISTC-3522 and ISTC-5220 FE-R Full stroke exercise test in the reverse flow direction per ISTC-3522 and ISTC-5220 FS Fail safe test per ISTC-3560 FSE Full stroke exercise test in the open and/or close directions LJ-C Leakage test per ISTC-3620 and 10CFR50 Appendix J LK Leakage test per ISTC-3630 (Other than Containment Isolation Valves)

PE Part-stroke exercise test PI Position Indication test per ISTC-3700 RT Relief valve test per Appendix I ST-C Exercise and stroke time in the close direction ST-CM Special exercise and stroke time in the close direction for PMT ST-O Exercise and stroke time in the open direction ST-OM Special exercise and stroke time in the open direction for PMT 5.7 Deferred Testing Where quarterly testing of valves is impractical or otherwise undesirable, testing will be deferred and performed during cold shutdown or refueling periods as permitted by the OM Code and NUREG 1482, Revision 1. The valve program tables identify those valves to which deferred testing applies and the respective technical justification for each is provided in an associated cold shutdown or refueling outage justification. The criteria for determining appropriate justification is based on NUREG 1482, Revision 1, Paragraphs 2.4.5, 3.1.1, and 4.1.6 as well as OM Code, paragraphs ISTC-3521(b), (c), (d) & (e) and ISTC-3522(b), & (c). The schedule and extent of testing valves during cold shutdown periods will be based on the requirements of OM Code, paragraphs ISTC-3521 (f), (g), & (h) and ISTC-3522(d), (e), & (f), and NUREG 1482, Revision 1, Sections 3.1.1.1 & 3.1.1.2. When all cold shutdown testing will not be completed, priorities for testing will be established per approved CCNPP procedures.

OM Code, paragraphs ISTC-3521 (h) and ISTC-3522(f) require that for valves tested during refueling outages, all testing must be completed prior to returning the plant to operation. For those cases where valves can be tested during power ascension and where the Technical Specification requirements for the valves or system determine when the valves are required to be operable, tests may be performed during power ascension. This position conforms to that stated in NUREG 1482, Revision 1, Section 3.1.1.2.

The majority of Calvert Cliffs' Test Deferral Justifications have been written for cold shutdown periods, vice only refueling outages. Many of these cold shutdown tests require very specific and unique plant conditions that may not be common during an "average" cold shutdown period. This limits Calvert Cliffs' ability to perform these tests.

However, they are classified as cold shutdown tests, vice refueling tests, because if the appropriate plant conditions exist during a cold shutdown period and the opportunity presents itself, the appropriate tests can be performed.

5.8 Relief Requests for Valve Testing Relief requests associated with valve testing are/were submitted and are provided in Attachment 1.

5.9 Active and Passive Valves 5.9.1 Active Valves Valves and pressure relief devices that perform a mechanical motion during the course of accomplishing a safety function are active components. If a valve is capable of being moved out of its safety position during either normal operation, and/or accident response and it must be capable of returning to that safety position, then the valve is considered to be active for that safety function.

13 OF 14

Constellation Energy (CCNPP Unit 2) IST Program PUMP AND VALVE INSERVICE TESTING PROGRAM FOURTH TEN-YEAR INTERVAL Revision Rev 00 NUREG 1482, Revision 1, Section 2.4.2, states that valves need not be considered active if they are only temporarily removed from their safety position for a short period of time and would be considered active only if the valve is routinely repositioned during power operation.

5.9.2 Passive Valves A valve is considered passive for a given safety function if, to perform that safety function, it is not required to move or be capable of moving (i.e. not even part-stroke or fail-safe) at any time. This means the valve must remain in that position any time the safety function might be required. This includes normal operation, as well as post-accident response until the safety function would no longer be required. If a valve does not meet this general criterion, then it should be considered to be active for that safety function. Passive valves include those valves required to perform a nuclear safety function by maintaining their position.

5.9.3 Normal Position Some valves may be moved to an alternate position during plant operations that is different from their normal position, such as to support surveillance testing. If the valve is still relied on while in its alternate position to accomplish its safety function in its normal position, then the ability to return to its normal position from its alternate position must be considered to be an active valve function that is subject to IST requirements, even if the valve is only in the alternate position for a short period of time. In this case, the alternate position is also listed in the "Normal Position" column in the Valve Tables to ensure this test requirement is captured. (The only other alternative is to consider the valve inoperable while it is out of its normal position.)

5.10 Valve Category 5.10.1 Category A Per the OM Code, these are valves for which seat leakage is limited to a specific maximum amount in the closed position for fulfillment of their required function(s). Category A applies to valves for which a specific maximum valve leakage limit exists.

5.10.2 Category B Per the OM Code, these are valves for which seat leakage in the closed position is inconsequential for fulfillment of the required function(s). Inconsequential implies a leakage limit does not exist relative to the valve's ability to perform its safety function. However, leakage past a closed valve above some level indicates the valve may be degrading and its ability to close at all (e.g., "gross" closure capability) may become threatened at some point.

5.10.3 Category C Per the OM Code, these are valves which are self-actuated in response to some system characteristic, such as pressure (relief valves) or flow direction (check valves) for fulfillment of the required function(s). If seat leakage in the closed position is consequential for a Category C valve, then it is categorized as "AC". If seat leakage in the closed position is not consequential for a Category C valve, then it may be categorized "BC". However, such valves are merely categorized as "C" and the "B" is considered to be implied. "Gross" leakage past a closed category C valve may still be used as the desired test parameter to detect when the valve may be degrading and its ability to close at all (e.g., "gross" closure capability) may become threatened, without implying the valve should be categorized AC.

14 OF 14

Constellation Energy (CCNPP Unit 2) IST Program AFW-CSJ-01 Not Approved Component ID Class Cat. System Label 2-AFW-102 3

C AFW 21 AFW Pump Discharge Check Valve 2-AFW-1 16 3

C AFW 22 AFW Pump Discharge Check Valve FUNCTION:

These valves open to provide flow paths from the respective AFW pump to the discharge headers. They close to prevent back-flow through an idle pump.

TEST REQUIREMENT:

OM Code paragraph ISTC-351 0 requires Active Category A and B valves and Category C check valves to be exercised nominally every 3 months during operation at power to the position(s) required to fulfill its function(s),

except as provided by ISTC-3520, ISTC-3540, ISTC-3550, ISTC-3570, ISTC-5221 and 5222.

BASIS:

1 OF 3

Constellation Energy (CCNPP Unit 2) IST Program AFW-CSJ-01 These are simple check valves with no external means of exercising. The only way to stroke these check valves fully open is to operate each AFW pump at the full accident flow rate while discharging to the steam generators.

Previously, the primary basis for not performing full flow testing during plant operation at power was due to the potential for thermal shock/fatigue of the steam generator nozzles or internals. Recent studies using more sophisticated analytical tools/methods indicate that the magnitude of the thermal shock and the thermal transients on the fatigue life of steam generator components would not be as significant as previously thought. However, such testing every quarter would still use up a significant portion of the allowable thermal cycles for these components.

Additionally, such testing every quarter also presents several other challenges/drawbacks:

Reducing reactor power prior to, and during, each test would be required in order to account for the positive reactivity (since the moderator temperature coefficient is negative throughout most of each operating cycle) caused by adding significant amounts of colder auxiliary feedwater into the steam generators (compared to main feedwater). The combination of the required reactor down-power and addition of positive reactivity due to the colder auxiliary feedwater, especially on such a frequent basis, is viewed as creating an increased risk of a plant trip and a reactivity management concern. Furthermore, coordinating a power reduction for AFW testing with other evolutions requiring a reduced power would complicate all these trip-risk evolutions and/or extend the period of reduced power.

Sending flow into the steam generators opens check valves 1/2-AFW-129 and 1/2-AFW-130. The primary purpose of these check valves is to isolate the AFW system piping from the steam generators so that the AFW piping may be considered to be medium-energy, vice high energy, lines during plant operation. By opening these check valves, it is possible that they may not close or seat properly. As a result, a portion of the upstream AFW piping outside containment would become high-energy lines. (This is not considered to be an issue post-accident because once AFW is initiated, these lines become pressurized anyway.) There not many ways to positively verify valve closure and non-intrusive monitoring is the only way to rapidly verify valve closure because monitoring upstream piping temperature requires a longer time. Additionally, steam binding of a turbine-driven AFW pump could also occur if the check valves in a given AFW flow leg fail to seat tightly.

The introduction of AFW flow into the steam generators will require a commensurate adjustment by the feedwater control system to maintain the desired steam generator level. These perturbations could potentially affect the stability of the feedwater control system operation.

Full-stroke exercising the check valves requires feeding the steam generators. The test currently performed during cold shutdown periods and/or refueling outages that accomplishes this adds approximately 6300 gallons into each steam generator. The supply for both the Unit 1 and Unit 2 AFW pumps is the safety-related 12 Condensate Storage Tank (12 CST). Quarterly testing would remove approximately 12,600 gallons per Unit from 12 CST each quarter and over 100,000 gallons total each year. This water cannot directly be returned to 12 CST.

This would greatly complicate the management of the safety-related water inventory in 12 CST to ensure continuous compliance with the minimum 12 CST inventory requirements specified by the Technical Specifications.

During quarterly testing of the AFW pumps, flow is routed through a minimum flow recirculation line branching off upstream of these check valves that returns condensate to the condensate storage tank and the respective pump's suction line. The manual discharge valve associated with the running pump must be shut in order to prevent injecting flow into the steam generators while still maintaining the ability to supply the steam generators from the non-running AFW pump in the event of an emergency. Therefore, no flow passes through the discharge check valve and a part-stroke exercise is not possible. Since there is no flow into the common AFW discharge header, the header remains depressurized and it is not possible to statically verify the discharge check valve of the non-running AFW pump is closed.

This is consistent with the position stated in NUREG-1482, Rev. 1, Paragraph 2.4.5.

2 OF 3

Constellation Energy (CCNPP Unit 2) IST Program AFW-CSJ-01 ALTERNATE TESTING:

These valves will be full stroke exercised open and closed during cold shutdowns.

ACCEPTANCE CRITERIA:

REFERENCES:

APPROVAL

REFERENCES:

3 OF 3

Constellation Energy (CCNPP Unit 2) IST Program AFW-CSJ-02 Not Approved Component ID Class Cat. System Label 2-AFW-183 3

C AFW 23 AFW Pump Automatic Recirculation Valve FUNCTION:

These valves open to provide flow paths from the AFW Pumps 13(23) to the discharge headers. In addition, they are internally ported to pass 140 gpm to the recirculation header for minimum pump flow regardless of the valves' position. They close in the same manner as a check valve to prevent back-flow through an idle pump when only steam-driven pump(s) are in operation - if the blocking valves remain in their normally-open position.

TEST REQUIREMENT:

OM Code paragraph ISTC-3510 requires Active Category A and B valves and Category C check valves to be exercised nominally every 3 months during operation at power to the position(s) required to fulfill its function(s),

except as provided by ISTC-3520, ISTC-3540, ISTC-3550, ISTC-3570, ISTC-5221 and 5222.

BASIS:

1 OF 3

Constellation Energy (CCNPP Unit 2) IST Program AFW-CSJ-02 These are simple check valves with no external means of exercising. The only way to stroke these check valves fully open is to operate each AFW pump at the full accident flow rate while discharging to the steam generators.

Previously, the primary basis for not performing full flow testing during plant operation at power was due to the potential for thermal shock/fatigue of the steam generator nozzles or internals. Recent studies using more sophisticated analytical tools/methods indicate that the magnitude of the thermal shock and the thermal transients on the fatigue life of steam generator components would not be as significant as previously thought. However, such testing every quarter would still use up a significant portion of the allowable thermal cycles for these components.

Additionally, such testing every quarter also presents several other challenges/drawbacks:

Reducing reactor power prior to, and during, each test would be required in order to account for the positive reactivity (since the moderator temperature coefficient is negative throughout most of each operating cycle) caused by adding significant amounts of colder auxiliary feedwater into the steam generators (compared to main feedwater). The combination of the required reactor down-power and addition of positive reactivity due to the colder auxiliary feedwater, especially on such a frequent basis, is viewed as creating an increased risk of a plant trip and a reactivity management concern. Furthermore, coordinating a power reduction for AFW testing with other evolutions requiring a reduced power would complicate all these trip-risk evolutions and/or extend the period of reduced power.

Sending flow into the steam generators opens check valves 1/2-AFW-129 and 1/2-AFW-130. The primary purpose of these check valves is to isolate the AFW system piping from the steam generators so that the AFW piping may be considered to be medium-energy, vice high energy, lines during plant operation. By opening these check valves, it is possible that they may not close or seat properly. As a result, a portion of the upstream AFW piping outside containment would become high-energy lines. (This is not considered to be an issue post-accident because once AFW is initiated, these lines become pressurized anyway.) There not many ways to positively verify valve closure and non-intrusive monitoring is the only way to rapidly verify valve closure because monitoring upstream piping temperature requires a longer time. Additionally, steam binding of a turbine-driven AFW pump could also occur if the check valves in a given AFW flow leg fail to seat tightly.

The introduction of AFW flow into the steam generators will require a commensurate adjustment by the feedwater control system to maintain the desired steam generator level. These perturbations could potentially affect the stability of the feedwater control system operation.

Full-stroke exercising the check valves requires feeding the steam generators. The test currently performed during cold shutdown periods and/or refueling outages that accomplishes this adds approximately 6300 gallons into each steam generator. The supply for both the Unit 1 and Unit 2 AFW pumps is the safety-related 12 Condensate Storage Tank (12 CST). Quarterly testing would remove approximately 12,600 gallons per Unit from 12 CST each quarter and over 100,000 gallons total each year. This water cannot directly be returned to 12 CST.

This would greatly complicate the management of the safety-related water inventory in 12 CST to ensure continuous compliance with the minimum 12 CST inventory requirements specified by the Technical Specifications.

During quarterly testing of the AFW pumps, flow is routed through a minimum flow recirculation line branching off upstream of these check valves that returns condensate to the condensate storage tank and the respective pump's suction line. The manual discharge valve associated with the running pump must be shut in order to prevent injecting flow into the steam generators while still maintaining the ability to supply the steam generators from the non-running AFW pump in the event of an emergency. Therefore, no flow passes through the discharge check valve and a part-stroke exercise is not possible.

The motor-driven AFW pump for each Unit does not share the common discharge header that the turbine-driven pumps share. Therefore, there is no practical way to pressurize this header for a static closure test using the turbine-driven AFW pumps.

2 OF 3

Constellation Energy (CCNPP Unit 2) IST Program AFW-CSJ-02 This check valve can be reverse-flow tested using the motor-driven AFW pump from the other Unit. However, opening the cross-connect valve impacts the AFW systems for both Units. For example, it requires the motor-driven train flow paths to the steam generators of both Units to be isolated in order to prevent injecting AFW flow into the steam generators. This becomes a complicated evolution that increases the risk to both Units and simultaneously places the AFW motor-driven trains out of service for both Units. (Without first exercising the check valve open, such a test would only be a static closure verification.) Therefore, performing such a test every quarter is not considered prudent. During cold shutdown periods (depending on plant conditions), as well as during refueling outages, the risk involved in performing this test is reduced by the fact that one Unit is already shut down.

This is consistent with the position stated in NUREG-1482, Rev. 1, Paragraph 2.4.5.

ALTERNATE TESTING:

These valves will be full stroke exercised open and closed during cold shutdowns.

ACCEPTANCE CRITERIA:

REFERENCES:

APPROVAL

REFERENCES:

3 OF 3

Constellation Energy (CCNPP Unit 2) IST Program cc-csJ-01 Not Approved Component ID Class Cat. System Label 2-CC-3832-CV (; 3 A

CC Containment Supply Isolation Valve 2-CC-3833-CV (;

3 A

CC Containment Return Isolation Valve FUNCTION:

Containment isolation valves, close on a CIS. On a rupture of the non-classed piping inside containment these valves are closed to provide Code Class boundary isolation.

TEST REQUIREMENT:

OM Code paragraph ISTC-3510 requires Active Category A and B valves and Category C check valves to be exercised nominally every 3 months during operation at power to the position(s) required to fulfill its function(s),

except as provided by ISTC-3520, ISTC-3540, ISTC-3550, ISTC-3570, ISTC-5221 and 5222.

BASIS:

These normally-open valves provide flow paths for cooling water (normal cooling) to and from the control rod drive mechanisms, reactor coolant pumps, and the reactor and steam generator supports. Closing any of these valves during plant operation at power will interrupt cooling flow and cause overheating and damage to the associated components. Should any one of these valves fail to re-open after closure, an immediate plant shutdown or trip and cooldown would follow. Partial closure of these valves presents the same risk as full closure; thus it is also not feasible during operation. This is consistent with the position stated in NUREG-1482, Rev. 1, Paragraph 2.4.5.

Additionally, it is consistent with NUREG-1482, Rev. 1, Paragraph 3.1.1.4, component cooling containment heat loads (such as the RCPs) will not necessarily be secured solely to test these valves.

ALTERNATE TESTING:

These valves will be exercised and stroke timed during each reactor refueling outage and during cold shutdowns of sufficient duration when the RCPs are secured.

ACCEPTANCE CRITERIA:

REFERENCES:

APPROVAL

REFERENCES:

1 OF 1

Constellation Energy (CCNPP Unit 2) IST Program CPA/HP-CSJ-01 Not Approved Component ID Class Cat. System Label 2-CPA-1410-CV N

A CPA/HP Containment Air Purge Supply Isolation Valve 2-CPA-1412-CV N

A CPA/HP Containment Air Purge Exhaust Isolation Valve FUNCTION:

These valves close to provide containment isolation for penetrations 13 and 14 during Modes 5 & 6.

TEST REQUIREMENT:

OM Code paragraph ISTC-351 0 requires Active Category A and B valves and Category C check valves to be exercised nominally every 3 months during operation at power to the position(s) required to fulfill its function(s),

except as provided by ISTC-3520, ISTC-3540, ISTC-3550, ISTC-3570, ISTC-5221 and 5222.

BASIS:

These valves are normally locked shut with power removed in Modes 1-4 per Technical Specification 3.6.1.7.

They are only required to stroke in Modes 5 and 6 in the event of a refueling accident. During all other modes of operation, they remain closed and are essentially passive. If containment purge is established during a cold shutdown period, then these valves will be stroke tested; however, they are not necessarily opened during each cold shutdown period. Note that, if they are not opened they remain in their safety position and are not required to be operable with respect to their automatic closure capability. It is undesirable to stroke these valves during each cold shutdown since excessive operation can damage the sealing surfaces of these valves and cause degradation of the valve's leak-tight capability which would result in additional testing, maintenance, and potential cold shutdown extension. Partial closure of these valves presents the same risks and problems that are associated with full closure; thus it is also not feasible during operation. This is consistent with the position stated in NUREG-1482 Rev. 1, Paragraph 2.4.5. Note that these valves are not within the ASME/ISI class boundaries.

ALTERNATE TESTING:

These valves will be stroke tested during each refueling outage and during cold shutdown periods whenever containment purge is established.

ACCEPTANCE CRITERIA:

REFERENCES:

APPROVAL

REFERENCES:

1 OF 1

Constellation Energy (CCNPP Unit 2) IST Program CVC-CSJ-01 Not Approved Component ID Class Cat. System Label 2-CVC-228 2

C CVC Boric Acid Storage Tank Gravity Feed Check Valve FUNCTION:

During emergency boration operations these valves open to provide flow paths from the boric acid storage tanks to the charging pump suction header. They close to prevent recirculation from the emergency boration line when the boric acid pumps are operating.

TEST REQUIREMENT:

OM Code paragraph ISTC-3510 requires Active Category A and B valves and Category C check valves to be exercised nominally every 3 months during operation at power to the position(s) required to fulfill its function(s),

except as provided by ISTC-3520, ISTC-3540, ISTC-3550, ISTC-3570, ISTC-5221 and 5222.

BASIS:

These are simple check valves with no means of noting obturator position nor for manual exercising. Exercising these valves in the open direction requires realignment of the CVCS system and injection of concentrated boric acid into the reactor coolant system via the charging pumps. During plant operation this could disrupt the CVCS system balance with the potential for causing severe pressurizer level transients or reactor coolant make-up boron concentration variations. Partial-stroke exercising of these valves in the open direction presents the same risks and problems that are associated with full-stroke exercising, thus it is also not feasible during operation. These valves can be confirmed closed (statically tested) quarterly. This is consistent with the position stated in NUREG-1482, Rev. 1, Paragraph 2.4.5.

ALTERNATE TESTING:

These valves are verified closed quarterly and will be full stroke exercised open and closed during cold shutdowns.

ACCEPTANCE CRITERIA:

REFERENCES:

APPROVAL

REFERENCES:

1 OF 1

Constellation Energy (CCNPP Unit 2) IST Program CVC-CSJ-02 Not Approved Component ID Class Cat. System Label 2-CVC-235 2

C CVC Boric Acid Pumps Direct Feed Check Valve FUNCTION:

During emergency boration operations these valves open to provide flow paths from the discharge of the boric acid pumps to the charging pump suction headers.

TEST REQUIREMENT:

OM Code paragraph ISTC-3510 requires Active Category A and B valves and Category C check valves to be exercised nominally every 3 months during operation at power to the position(s) required to fulfill its function(s),

except as provided by ISTC-3520, ISTC-3540, ISTC-3550, ISTC-3570, ISTC-5221 and 5222.

BASIS:

These are simple check valves with no means of noting obturator position nor for manual exercising. Exercising these valves in the open direction requires injection of concentrated boric acid into the reactor coolant system via the charging pumps. During plant operation this could disrupt the CVCS system balance with the potential for causing severe pressurizer level transients or reactor coolant make-up boron concentration variations.

Partial-stroke exercising of these valves presents the same risks and problems that are associated with full-stroke exercising, thus it is also not feasible during operation. This is consistent with the position stated in NUREG-1482, Rev. 1,, Paragraph 2.4.5.

ALTERNATE TESTING:

These valves will be full stroke exercised open and closed during cold shutdowns.

ACCEPTANCE CRITERIA:

REFERENCES:

APPROVAL

REFERENCES:

1OF 1

Constellation Energy (CCNPP Unit 2) IST Program CVC-CSJ-03 Not Approved Component ID Class Cat. System Label 2-CVC-251 2

C CVC Demineralized Water Supply to VCT Check Valve FUNCTION:

If emergency boration is initiated while concentrated boric acid is being added to the VCT, this check valve must close to prevent diversion of boric acid into the demineralized water system and ensure sufficient boric acid is delivered to the suction of the charging pumps.

TEST REQUIREMENT:

OM Code paragraph ISTC-351 0 requires Active Category A and B valves and Category C check valves to be exercised nominally every 3 months during operation at power to the position(s) required to fulfill its function(s),

except as provided by ISTC-3520, ISTC-3540, ISTC-3550, ISTC-3570, ISTC-5221 and 5222.

BASIS:

1 OF 3

Constellation Energy (CCNPP Unit 2) IST Program CVC-CSJ-03 Verifying the ability of this check valve to close requires applying a back-pressure. The only source of a back-pressure during normal operation is a boric acid pump (temporarily installing a test pump each quarter is not considered practical).

However, the boric acid pump discharge pressure is high enough to create a concern regarding possible introduction of concentrated boric acid into the VCT. This could occur due to leakage past 1/2-CVC-512-CV into the VCT (since there are no isolation valves between 1/2-CVC-512-CV and the VCT) or by lifting 1/2-CVC-194-RV.

Relief valve 1/2-CVC-194-RV is configured to relieve around 1/2-CVC-512-CV into the VCT. Its set point is 123

+0/-2 psig. The only way to apply a test pressure against 1/2-CVC-251 is to run a Boric Acid pump using a modified minimum recirculation flow path. This also places the same pressure against 1/2-CVC-512-CV and 1/2-CVC-1 94-RV. Historical pump test results show the discharge pressure of the Boric Acid pumps under low flow conditions typically falls in the range of 117 psig to 127 psig. This will clearly challenge 1/2-CVC-1 94-RV.

Regardless of the source (i.e. leakage past 1/2-CVC-512-CV or lifting of 1/2-CVC-194-RV) inadvertent addition of concentrated boric acid into the VCT can have an effect on reactivity control. (Under accident conditions with CV21OY open, such in-leakage into the VCT does not present a concern because enough boric acid will still reach the charging pump suction.) However, during power operation, any leakage of concentrated boric acid into the VCT will affect reactivity and possibly cause a reactor power transient. Furthermore, as the fuel cycle progresses and less boric acid is required in the RCS, the impact of such a reactivity change will become more pronounced.

Late in the fuel cycle, reactor power becomes still more sensitive to even small changes in reactivity.

The significance of such an inadvertent addition of concentrated boric acid into the VCT increases during the fuel cycle as the VCT boron concentration is reduced and batch adds of concentrated boric acid become less frequent.

It may be physically possible to attempt to mitigate this addition of concentrated boric acid into the VCT by injecting reactor make-up water directly into the charging pump suction or into the VCT. However, it would be impossible to know exactly how much concentrated boric acid was added to the VCT until after it occurred. As a result, the Operators would be put in a position of reacting to a change in reactivity rather than controlling a change in reactivity. This is not considered to be prudent.

When concentrated boric acid is batch added to the VCT during power operation, the operators are required to verify the plant response by checking the appropriate parameters, including VCT level, VCT pressure, and boric acid flow rate. The piping upstream of 1/2-CVC-251 includes the normally shut control valve 1/2-CVC-210X-CV and check valves 1/2-CVC-244 and 1/2-CVC-247. However, relief valve 1/2-CVC-376-RV is located between 1/2-CVC-251 and 1/2-CVC-210X-CV. Its setpoint is 72 +0/-2 psig. Even at their maximum flow rate, the discharge pressure of the Boric Acid pumps is greater than 100 psig. Therefore, if 1/2-CVC-251 is leaking but the upstream valves are leak-tight, it is likely that 1/2-CVC-376-RV will lift: If the valves upstream of 1/2-CVC-251 are also leaking, than there will be a discrepancy between the level increase noted in the VCT and the total flow indicated by the 1/2-FIC-210Y Boric Acid Integrator Reading.

This effectively verifies 1/2-CVC-251 is adequately closed. After each addition of concentrated boric acid to the VCT, demineralized water is used to flush the piping. This also strokes 1/2-CVC-251 open. Therefore, over time, this check valve is at least part-stroked open and closed several times. However, since the degree of RCS boration declines as the fuel cycle progresses, the frequency of adding concentrated boric acid to the VCT also decreases. (t is not practical to add concentrated boric acid to the VCT solely for the purpose of part-stroking 1/2-CVC-251.) Additionally, during power operation, changes to the VCT boric acid concentration are made by simultaneously adding demineralized water and concentrated boric acid to achieve the desired blended mixture.

Batch adds of boric acid are very rare and short-lived in duration, such as, to perform a small downpower for turbine valve testing or waterbox cleaning.

Since this evolution is not performed on a consistent basis, these check valves are not typically operated in the manner described on a reliable schedule. Therefore, this is not considered to be a true a periodic closure verification of these check valves.

This is consistent with the position stated in NUREG-1482, Rev. 1, Paragraph 2.4.5.

2 OF 3

Constellation Energy (CCNPP Unit 2) IST Program CVC-CSJ-03 ALTERNATE TESTING:

These valves will be full stroke exercised open and closed during cold shutdowns.

ACCEPTANCE CRITERIA:

REFERENCES:

APPROVAL

REFERENCES:

3 OF 3

Constellation Energy (CCNPP Unit 2) IST Program CVC-CSJ-04 Not Approved Component ID Class Cat. System Label 2-CVC-257 2

C CVC RWT to Charging Pump Suction Check Valve FUNCTION:

During normal plant operation, charging pump suction is from the VCT with makeup water supplied from the demineralized water storage tanks. However, should the VCT level decrease to 5%, the normally-closed upstream MOV (504-MOV) automatically opens, VCT discharge valve (501-MOV) closes, and these valves open to ensure a continuous supply of borated water to the charging pumps. If emergency boration were required while in this line-up, thes check valves would shut to prevent diversion of boric acid flow to the RWT, since MOV-504 does not receive an emergency closure-actuating signal. Additionally, following a SIAS (after the BASTs are empty) the charging pumps would be aligned to take suction from the RWT (requiring these valves to open) to de-pressurize the RCS to the shutdown cooling window upon the loss of the letdown system with or without auxiliary spray.

TEST REQUIREMENT:

OM Code paragraph ISTC-3510 requires Active Category A and B valves and Category C check valves to be exercised nominally every 3 months during operation at power to the position(s) required to fulfill its function(s),

except as provided by ISTC-3520, ISTC-3540, ISTC-3550, ISTC-3570, ISTC-5221 and 5222.

BASIS:

Exercising these valves requires realignment of the CVCS system and shifting the suction of the charging pumps to the refueling water storage tank (RWT). During plant operation this could disrupt the CVCS system balance with the potential for causing severe pressurizer level transients or reactor coolant make-up boron concentration variations due to the high boron concentration in the RWT water. Partial-stroke exercising of these valves presents the same risks and problems that are associated with full-stroke exercising, thus it is also not feasible during operation.

There are only two possible sources of pressure to perform a closure verification, either the VCT or the Boric Acid pumps. The Boric Acid pumps can not be used as this would result in delivery of concentrated boric acid to the suction of the charging pumps and isolating the suction of all three charging pumps is not acceptable. This, or securing charging pumps, would create the potential for causing severe pressurizer level transients or variations in the reactor coolant make-up boron concentration. The relative sizes and heights of the VCT and RWT make the VCT unsuitable.

This is consistent with the position stated in NUREG-1482, Rev. 1, Paragraph 2.4.5.

ALTERNATE TESTING:

These valves will be full stroke exercised open and closed during cold shutdowns.

ACCEPTANCE CRITERIA:

REFERENCES:

APPROVAL

REFERENCES:

1 OF 1

Constellation Energy (CCNPP Unit 2) IST Program CVC-CSJ-05 Not Approved Component ID Class Cat. System Label 2-CVC-505-CV 2

A CVC RCPc 2-CVC-506-CV (: 2 A

CVC RCPE eal Bleedoff Containment Isolation Valve Seal Bleedoff Containment Isolation Valve FUNCTION:

Close on a safety injection actuation signal (SIAS)to provide containment isolation.

TEST REQUIREMENT:

OM Code paragraph ISTC-351 0 requires Active Category A and B valves and Category C check valves to be exercised nominally every 3 months during operation at power to the position(s) required to fulfill its function(s),

except as provided by ISTC-3520, ISTC-3540, ISTC-3550, ISTC-3570, ISTC-5221 and 5222.

BASIS:

Exercising these valves to the closed position when the reactor coolant pumps (RCP's) are in operation would interrupt flow from the RCP seals and can result in damage to the pumps' seals. This is consistent with the position stated in NUREG-1482, Rev. 1, Paragraph 2.4.5.

ALTERNATE TESTING:

These valves will be full stroke exercised and stroke timed closed during cold shutdowns.

ACCEPTANCE CRITERIA:

REFERENCES:

APPROVAL

REFERENCES:

1 OF 1

Constellation Energy (CCNPP Unit 2) IST Program CVC-CSJ-06 Not Approved Component ID Class Cat. System Label 2-CVC-515-CV (; 1 A

CVC Letdown Stop Valve 2-CVC-516-CV (; 1 A

CVC Letdown Containment Isolation Valve FUNCTION:

Close on SIAS and CVCS isolation signals to secure letdown flow from the RCS and in the event of a letdown piping rupture. During plant cooldown they may be required to be closed to prevent voiding in the steam generators. They close for containment isolation.

TEST REQUIREMENT:

OM Code paragraph ISTC-3510 requires Active Category A and B valves and Category C check valves to be exercised nominally every 3 months during operation at power to the position(s) required to fulfill its function(s),

except as provided by ISTC-3520, ISTC-3540, ISTC-3550, ISTC-3570, ISTC-5221 and 5222.

BASIS:

Closing either of these valves during operation would result in severe pressurizer level or CVCS system transients with the potential for a plant trip. In addition, such an operation would cause unnecessary thermal cycles on the Regenerative Heat Exchanger and, in general, is not a prudent action in the context of plant operation. If either valve failed to re-open, an expedited plant shutdown would be required. Partial closure of these valves presents the same risks and problems-that are associated with full closure, thus it is also not feasible during operation. This is consistent with the position stated in NUREG-1482, Rev. 1, Paragraph 2.4.5.

ALTERNATE TESTING:

These valves will be full stroke exercised and stroke timed closed during cold shutdowns.

ACCEPTANCE CRITERIA:

REFERENCES:

APPROVAL

REFERENCES:

1 OF 1

Constellation Energy (CCNPP Unit 2) IST Program CVC-CSJ-07 Not Approved Component ID Class Cat. System Label 2-CVC-517-CV (: 1 B

CVC Charging Line Stop Valve FUNCTION:

Open to provide flow paths to de-pressurize and cool the pressurizer when the RCP's are not in operation.

Although there are alternate methods of reducing RCS pressure during an accident, the pathways including these valves is the preferred method. In the event of a cold leg break, these valves are required to open to provide flow paths from the safety injection pumps into the pressurizer for core flush. They also close for containment isolation.

TEST REQUIREMENT:

OM Code paragraph ISTC-351 0 requires Active Category A and B valves and Category C check valves to be exercised nominally every 3 months during operation at power to the position(s) required to fulfill its function(s),

except as provided by ISTC-3520, ISTC-3540, ISTC-3550, ISTC-3570, ISTC-5221 and 5222.

BASIS:

Opening these valves would result in initiation of auxiliary pressurizer spray flow and injection of cold water into the pressurizer spray nozzle placing significant thermal stress on the spray line and spray nozzle, as well as unnecessarily consuming the limited number of thermal cycles allowed for the pressurizer nozzles. Such an evolution could result in an unacceptable reactor pressurizer transient and a potential plant shutdown or trip.

Partial stroking of these valves presents the same risks and problems that are associated with full stroking; thus, it is also not feasible during operation. This is consistent with the position stated in NUREG-1482, Rev. 1, Paragraph 2.4.5.

ALTERNATE TESTING:

These valves will be full stroke exercised and stroke timed closed during cold shutdowns.

ACCEPTANCE CRITERIA:

REFERENCES:

APPROVAL

REFERENCES:

1 OF 1

Constellation Energy (CCNPP Unit 2) IST Program IA-CSJ-01 Not Approved Component ID Class Cat. System Label 2-IA-2085-CV (2( N B

IA Sys Containment Air Control Valve FUNCTION:

These normally-open valves close following a containment isolation signal when downstream line pressure drops to 75 psig. to extend the air supply to the containment air inlet valves and other critical containment air loads for as long as possible. This also ensures that it is safe to re-open 1/2-2080-MOV later in an accident scenario to allow operation of CVCS valves 1/2-CVC-517-CV, 1/2-CVC-518-CV, and 1/2-CVC-519-CV and the PASS isolation valves.

TEST REQUIREMENT:

OM Code paragraph ISTC-351 0 requires Active Category A and B valves and Category C check valves to be exercised nominally every 3 months during operation at power to the position(s) required to fulfill its function(s),

except as provided by ISTC-3520, ISTC-3540, ISTC-3550, ISTC-3570, ISTC-5221 and 5222.

BASIS:

Closing these valves will isolate instrument air to the containment and secure operating air to several components critical for plant operation including the pressurizer spray control valves. If the valve were to fail in the closed position, a plant shutdown would be required. Partial closure of these valves presents the same risk as full closure; thus, it is also not feasible during operation. This is consistent with the position stated in NUREG-1482, Rev. 1, Paragraph 2.4.5. Note that these valves are augmented components and are not within the ASME/ISI class boundaries.

ALTERNATE TESTING:

These valves will be full-stroke exercised and stroke timed in the closed direction during cold shutdowns in accordance with OM Code paragraph ISTC-3521.

ACCEPTANCE CRITERIA:

REFERENCES:

APPROVAL

REFERENCES:

1 OF 1

i Constellation Energy (CCNPP Unit 2) IST Program IA-ROJ-01 Not Approved Component ID Class Cat. System Label 2-IA-175 (2CKVI, N

AC IA Sys Instrument Air Supply to Containment Isolation Check Valve FUNCTION:

This check valve closes for containment isolation. It opens if sufficient operating air is available and operation of selected air-operated control valves in containment is desired.

TEST REQUIREMENT:

OM Code paragraph ISTC-3510 requires Active Category A and B valves and Category C check valves to be exercised nominally every 3 months during operation at power to the position(s) required to fulfill its function(s),

except as provided by ISTC-3520, ISTC-3540, ISTC-3550, ISTC-3570, ISTC-5221 and 5222.

BASIS:

This valve is a small spring-loaded piston-type check valve with no external position indication or other means of easily verifying its position.

Operation of numerous air-operated control valves in containment during normal operation, including quarterly surveillance testing of selected air-operated control valves in containment, verifies the ability of the check valve to open on an ongoing basis.

There is no means of verifying its ability to full-stroke closed other than by performing a back seat leakage test. In order to do this, the upstream side of the check valve must be isolated and a test connection removed through which air flow can be verified after passing back through the check valve. However, this secures at least one, and sometimes the only, flowpath for safety-related air to the downstream air loads. Verifying closure of this valve requires containment access and a back-leakage test. Such access is not practical on a routine basis during plant operation at power. The coordination and resources needed to secure instrument air to the containment to permit testing during cold shutdown periods would be an unreasonable burden with no appreciable gain in plant safety.

Performing this test requires extensive system realignments which (1) effect operation of the AFW valves supplied by this portion of the IA system, (2) includes opening numerous capped test connections and (3) has the potential to effect operation of air operated valves in other systems. The number of instrument air valves, the complex system re-alignments, and the necessity of removing and replacing numerous test connection caps is considered impractical to perform during normal operation or during cold shutdown periods. This is consistent with NUREG-1482, Rev. 1, Sections 3.1.1 and 4.1.6. Note that this check valve is an augmented component and is not within the ASME/ISI class boundaries.

ALTERNATE TESTING:

This valve will be full-stroke exercised in the open and closed directions during refueling.outages in accordance with OM Code paragraph ISTC-3522.

ACCEPTANCE CRITERIA:

REFERENCES:

APPROVAL

REFERENCES:

1 OF 2

Constellation Energy (CCNPP Unit 2) IST Program IA-ROJ-01 2 OF 2

Constellation Energy (CCNPP Unit 2) IST Program IA-ROJ-02 Not Approved Component ID Class Cat. System Label 2-1A-31 0 N

AC IA Sys Normal Instrument Air Supply to Containment Air Header Check Valve FUNCTION:

These check valves close to isolate the non-safety related portion of the instrument air header from the safety related header supplying several important safety-related instrument air loads, including several in the containment.

TEST REQUIREMENT:

OM Code paragraph ISTC-3510 requires Active Category A and B valves and Category C check valves to be exercised nominally every 3 months during operation at power to the position(s) required to fulfill its function(s),

except as provided by ISTC-3520, ISTC-3540, ISTC-3550, ISTC-3570, ISTC-5221 and 5222.

BASIS:

These are small spring-loaded piston-type check valves with no external position indication or other means of easily verifying their position. Due to their size, design, and system configuration, they cannot be non-intrusively monitored.

Operation of numerous air-operated control valves in containment during normal operation, including quarterly surveillance testing of selected air-operated control valves in containment, verifies the ability of these check valves to open on an ongoing basis.

There are no means of verifying their ability to full-stroke closed other than by performing a back seat leakage test.

In order to do this, the upstream side of each check valve must be isolated and a test connection removed through which air flow can be measured using a leak rate monitor after passing back through the check valve. Verifying closure of these valves requires isolation of the normal air supply to critical system components inside containment. Although there is a backup supply of air stored in the associated containment air receiver, failure to return the normal supply to service in a timely manner could result in equipment failure and plant shutdown. Also, the backup air supply is capable of providing air to only a limited number of critical loads.

Performing these tests requires extensive system realignments which (1) effect operation of the AFW valves supplied by this portion of the IA system, (2) include opening numerous capped test connections, (3) include installing and removing flow rate instrumentation and leak rate instrumentation at numerous locations, and (4) has the potential to effect operation of air operated valves in other systems. The number of instrument air valves, the complex system re-alignments, the necessity of removing and replacing numerous test connection caps, and the difficulty of installing, removing, and relocating a flow instrument and leak rate monitor to test each check valve is considered impractical to perform during normal operation or during cold shutdown periods. This is consistent with NUREG-1 482, Rev. 1, Sections 3.1.1 and 4.1.6. Note that these check valves are augmented components and are not within the ASME/ISI class boundaries.

ALTERNATE TESTING:

These valves will be full-stroke exercised in the open and closed directions during refueling outages in accordance with OM Code paragraph ISTC-3522.

ACCEPTANCE CRITERIA:

1 OF 2

Constellation Energy (CCNPP Unit 2) IST Program IA-ROJ-02

REFERENCES:

APPROVAL

REFERENCES:

2 OF 2

Constellation Energy (CCNPP Unit 2) IST Program IA-ROJ-03 Not Approved Component ID Class Cat. System Label 2-IA-741 N

C IA Sys SWAC Discharge Check Valve 2-IA-743 N

C IA Sys SWAC Discharge Check Valve FUNCTION:

These valves open to provide pathways for instrument air from the SWACs to the various air loads. They close in the event a SWAC fails to maintain supply train isolation.

TEST REQUIREMENT:

OM Code paragraph ISTC-3510 requires Active Category A and B valves and Category C check valves to be exercised nominally every 3 months during operation at power to the position(s) required to fulfill its function(s),

except as provided by ISTC-3520, ISTC-3540, ISTC-3550, ISTC-3570, ISTC-5221 and 5222.

BASIS:

These are small spring-loaded piston-type check valves with no external position indication or other means of easily verifying their position. Due to their size, design, and system configuration, they cannot be non-intrusively monitored.

There are no means of verifying their ability to full-stroke open other than passing the required air flow in the forward direction. This can only be achieved by either isolating the normal non-safety-related sources of air and operating the downstream air loads simultaneously. However, operating all the downstream air loads simultaneously is not typically practical. Alternatively, the forward flowrate through each check valve may individually measured. In order to do this, the downstream side of each check valve must be isolated and a test connection removed through which air flow can be measured using a flow instrument after passing through the check valve. These check valves are part-stroked open whenever the SWACs are operated.

There are no means of verifying their ability to full-stroke closed other than by performing a back seat leakage test.

In order to do this, the upstream side of each check valve must be isolated and a test connection removed through which air flow can be measured using a leak rate monitor after passing back through the check valve.

Performing these tests requires extensive system realignments which (1) effect operation of the AFW valves supplied by this portion of the IA system, (2) include opening numerous capped test connections, (3) include installing and removing flow rate instrumentation and leak rate instrumentation at numerous locations, and (4) has the potential to effect operation of air operated valves in other systems. The number of instrument air valves, the complex system re-alignments, the necessity of removing and replacing numerous test connection caps, and the difficulty of installing, removing, and relocating a flow instrument and leak rate monitor to test each check valve is considered impractical to perform during normal operation or during cold shutdown periods. This is consistent with NUREG-1482, Rev. 1, Sections 3.1.1 and 4.1.6. Note that these check valves are augmented components and are not within the ASME/ISI class boundaries.

ALTERNATE TESTING:

These valves will be full-stroke exercised in the open and closed directions during refueling outages in accordance with OM Code paragraph ISTC-3522.

ACCEPTANCE CRITERIA:

1 OF 2

Constellation Energy (CCNPP Unit 2) IST Program IA-ROJ-03

REFERENCES:

APPROVAL

REFERENCES:

2 OF 2

Constellation Energy (CCNPP Unit 2) IST Program IA-ROJ-04 Not Approved Component ID Class Cat. System Label 2-lA-1 101 N

AC IA Sys Normal (NSR) Instrument Air Supply Check Valve 2-iA-1 106 N

AC IA Sys Normal (NSR) Instrument Air Supply Check Valve FUNCTION:

These valves close to isolate the NSR instrument air header and maintain the integrity of the SWAC air supply system.

TEST REQUIREMENT:

OM Code paragraph ISTC-3510 requires Active Category A and B valves and Category C check valves to be exercised nominally every 3 months during operation at power to the position(s) required to fulfill its function(s),

except as provided by ISTC-3520, ISTC-3540, ISTC-3550, ISTC-3570, ISTC-5221 and 5222.

BASIS:

These are small spring-loaded piston-type check valves with no external position indication or other means of easily verifying their position. Due to their size, design, and system configuration, they cannot be non-intrusively monitored.

There are no means of verifying their ability to full-stroke closed other than by performing a back seat leakage test.

In order to do this, the upstream side of each check valve must be isolated and a test connection removed through which air flow can be measured using a leak rate monitor after passing back through the check valve.

Performing these tests requires extensive system realignments which (1) effect operation of the AFW valves supplied by this portion of the IA system, (2) include opening numerous capped test connections, (3) include installing and removing flow rate instrumentation and leak rate instrumentation at numerous locations, and (4) has the potential to effect operation of air operated valves in other systems. The number of instrument air valves, the complex system re-alignments, the necessity of removing and replacing numerous test connection caps, and the difficulty of installing, removing, and relocating a flow instrument and leak rate monitor to test each check valve is considered impractical to perform during normal operation or during cold shutdown periods. This is consistent with NUREG-1482, Rev. 1, Sections 3.1.1 and 4.1.6. Note that these check valves are augmented components and are not within the ASME/ISI class boundaries.

ALTERNATE TESTING:

These valves will be full-stroke exercised in the open and closed directions during refueling outages in accordance with OM Code paragraph ISTC-3522.

ACCEPTANCE CRITERIA:

REFERENCES:

APPROVAL

REFERENCES:

1 OF 1

Constellation Energy (CCNPP Unit 2) IST Program IA-ROJ-05 Not Approved Component ID Class Cat. System Label 2-IA-300 N

AC IA Sys IA to 2-IA-4520-PCV & 2-IA-4510-PCV Check Valve 2-IA-301 N

AC IA Sys IA 2-IA-4520-PCV & 2-IA-4510-PCV Check Valve FUNCTION:

These valves open to provide air to AFW Steam Generator supply/control valves. They close to maintain supply train isolation to preclude blowdown of the associated AFW air accumulator.

TEST REQUIREMENT:

OM Code paragraph ISTC-3510 requires Active Category A and B valves and Category C check valves to be exercised nominally every 3 months during operation at power to the position(s) required to fulfill its function(s),

except as provided by ISTC-3520, ISTC-3540, ISTC-3550, ISTC-3570, ISTC-5221 and 5222.

BASIS:

These are small spring-loaded piston-type check valves with no external position indication or other means of easily verifying their position. Due to their size, design, and system configuration, they cannot be non-intrusively monitored.

There are no means of verifying their ability to full-stroke open other than passing the required air flow in the forward direction. This can only be achieved by either isolating the normal non-safety-related sources of air and operating the downstream air loads simultaneously. However, operating all the downstream air loads simultaneously is not typically practical. Alternatively, the forward flowrate through each check valve may individually measured. In order to do this, the downstream side of each check valve must be isolated and a test connection removed through which air flow can be measured using a flow instrument after passing through the check valve.

There are no means of verifying their ability to full-stroke closed other than by performing a back seat leakage test.

In order to do this, the upstream side of each check valve must be isolated and a test connection removed through which air flow can be measured using a leak rate monitor after passing back through the check valve.

Testing these valves requires significant re-alignment of the air supplies to the AFW flow control valves, including securing the safety-related air supply to each set of AFW Blocking valves and Flow Control valves (one set at a time). The air headers/safety-related accumulators are configured such that one of the two AFW Blocking valves in each AFW Flow Leg is supplied by independent air headers/accumulators. As a result, isolating one safety-related air accumulator isolates air to one AFW Blocking valve in each AFW Flow Leg. Since the AFW Blocking valves fail open, this would result in limited capacity of the AFW supply system to respond to an ASFAS in the event steam generator isolation should be required. Therefore, all AFW Flow Legs would be rendered inoperable, Performing these tests requires extensive system realignments which (1) effect operation of the AFW valves supplied by this portion of the IA system, (2) include opening numerous capped test connections, (3) include installing and removing flow rate instrumentation and leak rate instrumentation at numerous locations, and (4) has the potential to effect operation of air operated valves in other systems. The number of instrument air valves, the complex system re-alignments, the necessity of removing and replacing numerous test connection caps, and the difficulty of installing, removing, and relocating a flow instrumentand leak rate monitor to test each check valve is considered impractical to perform during normal operation or during cold shutdown periods. This is consistent with NUREG-1 482, Rev. 1, Sections 3.1.1 and 4.1.6. Note that these check valves are augmented components and are not within the ASME/ISI class boundaries.

1 OF 2

Constellation Energy (CCNPP Unit 2) IST Program IA-ROJ-05 ALTERNATE TESTING:

These valves will be full-stroke exercised in the open and closed directions during refueling outages in accordance with OM Code paragraph ISTC-3522.

ACCEPTANCE CRITERIA:

REFERENCES:

APPROVAL

REFERENCES:

2 OF 2

Constellation Energy (CCNPP Unit 2) IST Program IA-ROJ-06 Not Approved Component ID Class Cat. System Label 2-IA-315A N

AC IA Sys Normal Instrument Air Supply to the IA Amplifier Check Valve FUNCTION:

These valves close to isolate the normal (NSR) instrument air header from the safety-related header in order to permit supplying SWAC air to the AFW portion of the IA System if desired.

TEST REQUIREMENT:

OM Code paragraph ISTC-3510 requires Active Category A and B valves and Category C check valves to be exercised nominally every 3 months during operation at power to the position(s) required to fulfill its function(s),

except as provided by ISTC-3520, ISTC-3540, ISTC-3550, ISTC-3570, ISTC-5221 and 5222.

BASIS:

These are small spring-loaded piston-type check valves with no external position indication or other means of easily verifying their position. Due to their size, design, and system configuration, they cannot be non-intrusively monitored.

There are no means of verifying their ability to full-stroke closed other than by performing a back seat leakage test.

In order to do this, the upstream side of each check valve must be isolated and a test connection removed through which air flow can be measured using a leak rate monitor after passing back through the check valve.

Performing these tests requires extensive system realignments which (1) effect operation of the AFW valves supplied by this portion of the IA system, (2) include opening numerous capped test connections, (3) include installing and removing flow rate instrumentation and leak rate instrumentation at numerous locations, and (4) has the potential to effect operation of air operated valves in other systems. The number of instrument air valves, the complex system re-alignments, the necessity of removing and replacing numerous test connection caps, and the difficulty of installing, removing, and relocating a flow instrument and leak rate monitor to test each check valve is considered impractical to perform during normal operation or during cold shutdown periods. This is consistent with NUREG-1 482, Rev. 1, Sections 3.1.1 and 4.1.6. Note that these check valves are augmented components and are not within the ASME/ISI class boundaries.

ALTERNATE TESTING:

These valves will be full-stroke exercised in the open and closed directions during refueling outages in accordance with OM Code paragraph ISTC-3522.

ACCEPTANCE CRITERIA:

REFERENCES:

APPROVAL

REFERENCES:

1 OF 1

Constellation Energy (CCNPP Unit 2) IST Program IA-ROJ-07 Not Approved Component ID Class Cat. System Label 2-IA-304 N

AC IA Sys IA Amplifier Outlet to Receiver 21B Check Valve 2-IA-305 N

AC IA Sys IA Amplifier Outlet to Receiver 21A Check Valve FUNCTION:

These valves close to isolate the normal (NSR) instrument air header from the safety-related header to maintain supply train isolation and preclude blowdown of the associated AFW air accumulator.

TEST REQUIREMENT:

OM Code paragraph ISTC-351 0 requires Active Category A and B valves and Category C check valves to be exercised nominally every 3 months during operation at power to the position(s) required to fulfill its function(s),

except as provided by ISTC-3520, ISTC-3540, ISTC-3550, ISTC-3570, ISTC-5221 and 5222.

BASIS:

These are small spring-loaded piston-type check valves with no external position indication or other means of easily verifying their position. Due to their size, design, and system configuration, they cannot be non-intrusively monitored.

There are no means of verifying their ability to full-stroke closed other than by performing a back seat leakage test.

In order to do this, the upstream side of each check valve must be isolated and a test connection removed through which air flow can be measured using a leak rate monitor after passing back through the check valve.

Performing these tests requires extensive system realignments which (1) effect operation of the AFW valves supplied by this portion of the IA system, (2) include opening numerous capped test connections, (3) include installing and removing flow rate instrumentation and leak rate instrumentation at numerous locations, and (4) has the potential to effect operation of air operated valves in other systems. The number of instrument air valves, the complex system re-alignments, the necessity of removing and replacing numerous test connection caps, and the difficulty of installing, removing, and relocating a flow instrument and leak rate monitor to test each check valve is considered impractical to perform during normal operation or during cold shutdown periods. This is consistent with NUREG-1482, Rev. 1, Sections 3.1.1 and 4.1.6. Note that these check valves are augmented components and are not within the ASME/ISI class boundaries.

ALTERNATE TESTING:

These valves will be full-stroke exercised in the open and closed directions during refueling outages in accordance with OM Code paragraph ISTC-3522.

ACCEPTANCE CRITERIA:

REFERENCES:

APPROVAL

REFERENCES:

1 OF 1

Constellation Energy (CCNPP Unit 2) IST Program IA-ROJ-08 Not Approved Component ID Class Cat. System Label 2-IA-1213 N

C IA Sys Instrument Air Supply to 4070/4071 Air Accumulators Check Valve 2-IA-1228 N

C IA Sys Instrument Air Supply to 4070/4071 Air Accumulators Check Valve FUNCTION:

These check valves close to isolate the normal (NSR) instrument air header from the safety-related air header to maintain supply train isolation and preclude blowdown of the associated AFW air accumulator. They also close in the event SWAG air is aligned to the AFW portion of the IA System.

TEST REQUIREMENT:

OM Code paragraph ISTC-3510 requires Active Category A and B valves and Category C check valves to be exercised nominally every 3 months during operation at power to the position(s) required to fulfill its function(s),

except as provided by ISTC-3520, ISTC-3540, ISTC-3550, ISTC-3570, ISTC-5221 and 5222.

BASIS:

These are small spring-loaded piston-type check valves with no external position indication or other means of easily verifying their position. Due to their size, design, and system configuration, they cannot be non-intrusively monitored.

There are no means of verifying their ability to full-stroke closed other than by performing a back seat leakage test.

In order to do this, the upstream side of each check valve must be isolated and a test connection removed through which air flow can be measured using a leak rate monitor after passing back through the check valve.

Performing these tests requires extensive system realignments which (1) effect operation of the AFW valves supplied by this portion of the IA system, (2) include opening numerous capped test connections, (3) include installing and removing flow rate instrumentation and leak rate instrumentation at numerous locations, and (4) has the potential to effect operation of air operated valves in other systems. The number of instrument air valves, the complex system re-alignments, the necessity of removing and replacing numerous test connection caps, and the difficulty of installing, removing, and relocating a flow instrument and leak rate monitor to test each check valve is considered impractical to perform during normal operation or during cold shutdown periods. This is consistent with NUREG-1482, Rev. 1, Sections 3.1.1 and 4.1.6. Note that these check valves are augmented components and are not within the ASME/ISI class boundaries.

ALTERNATE TESTING:

These valves will be full-stroke exercised in the open and closed directions during refueling outages in accordance with OM Code paragraph ISTC-3522.

ACCEPTANCE CRITERIA:

REFERENCES:

APPROVAL

REFERENCES:

1 OF 1

Constellation Energy (CCNPP Unit 2) IST Program IA-ROJ-09 Not Approved Component ID Class Cat. System Label 2-IA-1203 N

C IA Sys Instrument Air Supply to Steam Supply Valves Check Valve 2-lA-1220 N

C IA Sys Instrument Air Supply to Steam Supply Valves Check Valve FUNCTION:

These check valves close to isolate the normal (NSR) instrument air header from the safety-related air header to maintain supply train isolation and preclude blowdown of the associated AFW air accumulator. They also open in the event SWAC air is aligned to the AFW portion of the IA System.

TEST REQUIREMENT:

OM Code paragraph ISTC-351 0 requires Active Category A and B valves and Category C check valves to be exercised nominally every 3 months during operation at power to the position(s) required to fulfill its function(s),

except as provided by ISTC-3520, ISTC-3540, ISTC-3550, ISTC-3570, ISTC-5221 and 5222.

BASIS:

These are small spring-loaded piston-type check valves with no external position indication or other means of easily verifying their position. Due to their size, design, and system configuration, they cannot be non-intrusively monitored.

There are no means of verifying their ability to full-stroke open other than passing the required air flow in the forward direction. This can only be achieved by either isolating the normal non-safety-related sources of air and operating the downstream air loads simultaneously. However, operating all the downstream air loads simultaneously is not typically practical. Alternatively, the forward flowrate through each check valve may individually measured. In order to do this, the downstream side of each check valve must be isolated and a test connection removed through which air flow can be measured using a flow instrument after passing through the check valve.

There are no means of verifying their ability to full-stroke closed other than by performing a back seat leakage test.

In order to do this, the upstream side of each check valve must be isolated and a test connection removed through which air flow can be measured using a leak rate monitor after passing back through the check valve.

Performing these tests requires extensive system realignments which (1) effect operation of the AFW valves supplied by this portion of the IA system, (2) include opening numerous capped test connections, (3) include installing and removing flow rate instrumentation and leak rate instrumentation at numerous locations, and (4) has the potential to effect operation of air operated valves in other systems. The number of instrument air valves, the complex system re-alignments, the necessity of removing and replacing numerous test connection caps, and the

-difficulty of installing, removing, and relocating a flow instrument and leak rate monitor to test each check valve is considered impractical to perform during normal operation or during cold shutdown periods. This is consistent with NUREG-1482, Rev. 1, Sections 3.1.1 and 4.1.6. Note that these check valves are augmented components and are not within the ASME/ISI class boundaries.

ALTERNATE TESTING:

These valves will be full-stroke exercised in the open and closed directions during refueling outages in accordance with OM Code paragraph ISTC-3522.

ACCEPTANCE CRITERIA:

1 OF 2

Constellation Energy (CCNPP Unit 2) IST Program IA-ROJ-09

REFERENCES:

APPROVAL

REFERENCES:

2 OF 2

Constellation Energy (CCNPP Unit 2) IST Program MS-CSJ-01 Not Approved Component ID Class Cat. System Label 2-MS-4043-CV (; 2 B

MS Sys Main Steam Header Isolation Valve (MSIV) 2-MS-4048-CV (; 2 B

MS Sys Main Steam Header Isolation Valve (MSIV)

FUNCTION:

These valves close on CSAS and SGIS to prevent the unrestricted release of steam from multiple steam generators in the event of an upstream steamline rupture and to isolate the steam generators in the event of a LOCA, steam generator tube rupture, or downstream steamline rupture. When closed, they provide isolation of the unaffected steam generator thus ensuring an adequate supply of steam for AFW pump turbine operation.

These valves are also required to be tested per Technical Specifications SR 3.7.2.1.

TEST REQUIREMENT:

OM Code paragraph ISTC-351 0 requires Active Category A and B valves and Category C check valves to be exercised nominally every 3 months during operation at power to the position(s) required to fulfill its function(s),

except as provided by ISTC-3520, ISTC-3540, ISTC-3550, ISTC-3570, ISTC-5221 and 5222.

BASIS:

During plant operation at power, full closure of any of these valves would result in a major plant transient and a turbine and reactor plant trip.

These valves are provided with the capability of partial stroke (closure) exercising; however, the valves will not be part stroke exercised quarterly based on the guidance from NUREG-1482, Revision 1, Section 4.2.6, Note:

Related to MSIVs, a number of plants perform a partial-stroke exercise quarterly during power operations. The revised standard techncial specifications bases for MSIV surveillance requirements states that "MSIVs should not be tested at power, since even a part-stroke exercise increases the risk of a valve closure when the unit is generating power."

ALTERNATE TESTING:

These valves will be full-stroke exercised, verifying stroke time in the closed direction following a cold shutdown period in accordance with OM Code paragraph ISTC-3521.

ACCEPTANCE CRITERIA:

REFERENCES:

APPROVAL

REFERENCES:

1 OF 1

Constellation Energy (CCNPP Unit 2) IST Program MS-CSJ-02 Not Approved Component ID Class Cat. System Label 2-MS-3938-CV 2

B MS Sys Atmospheric Dump Valve 2-MS-3939-CV 2

B MS Sys Atmospheric Dump Valve FUNCTION:

The Atmospheric Dump Valves automatically open in response to system transients and also function (open and close) as control valves. The valves are designated closed-piping system containment isolation valves per UFSAR Figure 5-10 that are exempted from App. J LLRT.

TEST REQUIREMENT:

OM Code paragraph ISTC-351 0 requires Active Category A and B valves and Category C check valves to be exercised nominally every 3 months during operation at power to the position(s) required to fulfill its function(s),

except as provided by ISTC-3520, ISTC-3540, ISTC-3550, ISTC-3570, ISTC-5221 and 5222.

BASIS:

The atmospheric dump valves are positioned by the reactor coolant average temperature error signal when the turbine is tripped. In the event of a turbine trip above a preset power level, a quick-opening signal is provided to fully open the atmospheric dump valves. When Tavg is reduced to less than T?, the steam dump valves are modulated as a function of Tavg. The total capacity of the atmospheric steam dump valves are 5% of steam flow with the reactor at full power. This flow is sufficient to control the secondary steam pressure on a turbine trip at full power without necessitating operation of the spring-loaded safety valves.

Full/part-stroking these valves during power operation would release main steam to the atmosphere and could cause significant and unacceptable secondary steam pressure transients. Additionally, such stroking could also result in the failure of one of these valves to reseat properly which would lead to system/equipment damage, reduced plant reliability, and a possible plant shutdown. This is consistent with the position stated in NUREG-1482, Rev. 1, Paragraph 2.4.5.

ALTERNATE TESTING:

These valves will be full-stroke exercised in the closed direction during cold shutdowns in accordance with OM Code paragraph ISTC-3521.

ACCEPTANCE CRITERIA:

REFERENCES:

APPROVAL

REFERENCES:

1 OF 1

Constellation Energy (CCNPP Unit 2) IST Program RC-CSJ-01 Not Approved Component ID Class Cat. System Label 2-RC-105-SV (21 1

B RC Pressurizer Vent Valve 2-RC-106-SV (2, 1

B RC Pressurizer Vent Valve FUNCTION:

These valves are opened as needed to vent non-condensable gases trapped in the pressurizer during natural recirculation to enhance core cooling. If opened during accident recovery, they must be capable of closing in order to conserve reactor coolant inventory.

TEST REQUIREMENT:

OM Code paragraph ISTC-351 0 requires Active Category A and B valves and Category C check valves to be exercised nominally every 3 months during operation at power to the position(s) required to fulfill its function(s),

except as provided by ISTC-3520, ISTC-3540, ISTC-3550, ISTC-3570, ISTC-5221 and 5222.

BASIS:

These valves are administratively controlled in the closed position to prevent inadvertent operation. Since these are Class 1 reactor coolant system isolation valves, failure of a valve to close or leakage following closure could result in a loss of coolant in excess of the limits imposed by the Plant Technical Specifications necessitating a plant shutdown. Furthermore, failure of the valve to indicate a return to the fully closed position following exercising could likely result in a containment entry at power or a plant shutdown. Partial-stroke exercising of these valves presents the same risks and problems that are associated with full-stroke exercising; thus, it is also not feasible during operation. This is consistent with the position stated in NUREG-1482, Rev. 1, Paragraph 2.4.5.

Technical Requirements Manual TVR 15.4.6.2 requires verification of this vent path.

ALTERNATE TESTING:

These valves will be full-stroke exercised and stroke timed in the open and closed directions during cold shutdowns in accordance with OM Code paragraph ISTC-3521.

ACCEPTANCE CRITERIA:

REFERENCES:

APPROVAL

REFERENCES:

1 OF 1

Constellation Energy (CCNPP Unit 2) IST Program RC-CSJ-02 Not Approved Component ID Class Cat. System Label 2-RC-103-SV (2,1 1

B RC Reactor Vessel Vent Valve 2-RC-104-SV (21 1

B RC Reactor Vessel Vent Valve FUNCTION:

These valves are opened as needed to vent non-condensable gases trapped in the reactor vessel head during natural recirculation to enhance core cooling.

If opened during accident recovery, they must be capable of closing in order to conserve reactor coolant inventory.

TEST REQUIREMENT:

OM Code paragraph ISTC-351 0 requires Active Category A and B valves and Category C check valves to be exercised nominally every 3 months during operation at power to the position(s) required to fulfill its function(s),

except as provided by ISTC-3520, ISTC-3540, ISTC-3550, ISTC-3570, ISTC-5221 and 5222.

BASIS:

These valves are administratively controlled in the closed position to prevent inadvertent operation. Since these are Class 1 reactor coolant system isolation valves, failure of a valve to close or leakage following closure could result in a loss of coolant in excess of the limits imposed by the Plant Technical Specifications necessitating a plant shutdown. Furthermore, failure of the valve to indicate a return to the fully closed position following exercising could likely result in a containment entry at power or a plant shutdown. Partial-stroke exercising of these valves presents the same risks and problems that are associated with full-stroke exercising, thus it is also not feasible during operation. This is consistent with the position stated in NUREG-1482, Rev. 1, Paragraph 2.4.5. Technical Requirements Manual TVR 15.4.6.2 requires verification of this vent path.

ALTERNATE TESTING:

These valves will be full-stroke exercised and stroke timed in the open and closed directions during cold shutdowns in accordance with OM Code paragraph ISTC-3521.

ACCEPTANCE CRITERIA:

REFERENCES:

APPROVAL

REFERENCES:

1 OF 1

Constellation Energy (CCNPP Unit 2) IST Program RC-CSJ-03 Not Approved Component ID Class Cat. System Label 2-RC-100E-CV (: 1 B

RC Pressurizer Spray Valve 2-RC-100F-CV (; 1 B

RC Pressurizer Spray Valve FUNCTION:

These valves close to prevent diversion of flow to the reactor coolant cold legs when the auxiliary pressurizer spray lines are used for core flush.

TEST REQUIREMENT:

OM Code paragraph ISTC-351 0 requires Active Category A and B valves and Category C check valves to be exercised nominally every 3 months during operation at power to the position(s) required to fulfill its function(s),

except as provided by ISTC-3520, ISTC-3540, ISTC-3550, ISTC-3570, ISTC-5221 and 5222.

BASIS:

Due to dynamic flow conditions in the reactor coolant system under normal steaming conditions repeatable full-stroke test results for these valves are not possible; thus, these valves can only be tested during cold shutdown periods when stable test conditions can be established. (These conditions include securing RCP's and depressurizing the RCS, both of which minimize variations in flow through, and differential pressure across, these valves which could affect their performance.) Additionally, full-stroking these valves while the plant is pressurized will cause significant and unacceptable reactor coolant system pressure transients. These valves are part-stroked on an on-going basis in order to maintain pressure control while the plant is pressurized. This is consistent with the position stated in NUREG-1482, Rev. 1, Paragraph 2.4.5.

ALTERNATE TESTING:

These valves will be full-stroke exercised and stroke timed in the closed direction during cold shutdowns when the RCP's are secured and the RCS is de-pressurized in accordance with OM Code paragraph ISTC-3521.

ACCEPTANCE CRITERIA:

REFERENCES:

APPROVAL

REFERENCES:

1 OF 1

Constellation Energy (CCNPP Unit 2) IST Program SI-CsJ-01 Not Approved Component ID Class Cat. System Label 2-SI-434 (2CKVW 2

C SI LPSI Pump Discharge Check Valve 2-SI-446 (2CKVW 2

C SI LPSI Pump Discharge Check Valve FUNCTION:

These valves open to provide flow paths from the LPSI pumps to the low pressure injection header. They close to prevent recirculation flow through an idle pump and minimum flow line that could adversely impact the effectiveness of the operating pump.

TEST REQUIREMENT:

OM Code paragraph ISTC-351 0 requires Active Category A and B valves and Category C check valves to be exercised nominally every 3 months during operation at power to the position(s) required to fulfill its function(s),

except as provided by ISTC-3520, ISTC-3540, ISTC-3550, ISTC-3570, ISTC-5221 and 5222.

BASIS:

These are simple check valves with no external means of exercising, thus exercising (open) requires operating a LPSI pump at full flow and injecting into the reactor coolant system. At power operation, this is not possible because the LPSI pumps cannot develop sufficient discharge pressure to overcome reactor coolant system pressure. These valves are part-stroked exercised and verified closed quarterly. The full-stroke exercise open and closed is accomplished during cold shutdown periods (depending on plant conditions) and every refueling outage. This is consistent with the position stated in NUREG-1482, Rev. 1, Paragraph 2.4.5.

ALTERNATE TESTING:

These valves will be full-stroke exercised in the open and closed directions during cold shutdowns in accordance with OM Code paragraph ISTC-3522.

ACCEPTANCE CRITERIA:

REFERENCES:

APPROVAL

REFERENCES:

1 OF 1

Constellation Energy (CCNPP Unit 2) IST Program SI-CSJ-02 Not Approved Component ID Class Cat. System Label 2-SI-1 14 (2CKVW 2

C SI LPSI Header Isolation Check Valve 2-SI-124 (2CKVW 2

C SI LPSI Header Isolation Check Valve 2-SI-134 (2CKVW 2

C SI LPSI Header Isolation Check Valve 2-S1-144 (2CKVW 2

C SI LPSI Header Isolation Check Valve FUNCTION:

These normally-closed check valves open to provide flow paths for borated water from the LPSI pumps to each of the RCS cold legs. They close to isolate the LPSI system from the HPSI injection headers to prevent diversion of HPSI flow to the low-pressure-rated LPSI piping and loss through the associated relief valve and can serve as an optional reactor coolant pressure isolation valve.

TEST REQUIREMENT:

OM Code paragraph ISTC-3510 requires Active Category A and B valves and Category C check valves to be exercised nominally every 3 months during operation at power to the position(s) required to fulfill its function(s),

except as provided by ISTC-3520, ISTC-3540, ISTC-3550, ISTC-3570, ISTC-5221 and 5222.

BASIS:

These are simple check valves with no external means of exercising, thus exercising (open) requires operating a LPSI pump at full flow and injecting into the reactor coolant system. At power operation, this is not possible because the LPSI pumps cannot develop sufficient discharge pressure to overcome reactor coolant system pressure. These valves are part-stroked exercised and verified closed quarterly. The full-stroke exercise open and closed is accomplished during cold shutdown periods (depending on plant conditions) and every refueling outage. This is consistent with the position stated in NUREG-1482, Rev. 1, Paragraph 2.4.5.

ALTERNATE TESTING:

These valves will be full-stroke exercised in the open and closed directions during cold shutdowns in accordance with OM Code paragraph ISTC-3522.

ACCEPTANCE CRITERIA:

REFERENCES:

APPROVAL

REFERENCES:

1 OF 1

Constellation Energy (CCNPP Unit 2) IST Program SI-CSJ-03 Not Approved Component ID Class Cat. System Label 2-SI-1 18 (2CKVW 1

AC SI Safety'Injection Header Check Valve 2-SI-128 (2CKVE 1

AC SI Safety Injection Header Check Valve 2-SI-138 (2CKVW 1

AC SI Safety Injection Header Check Valve 2-S1-148 (2CKVW 1

AC SI Safety Injection Header Check Valve FUNCTION:

These valves provide flow paths for borated water from the HPSI and LPSI pumps to each of the RCS cold legs.

They close to isolate the safety injection system from the reactor coolant system. They also serve as pressure isolation valves (PIVs) during normal operation.

TEST REQUIREMENT:

OM Code paragraph ISTC-3510 requires Active Category A and B valves and Category C check valves to be exercised nominally every 3 months during operation at power to the position(s) required to fulfill its function(s),

except as provided by ISTC-3520, ISTC-3540, ISTC-3550, ISTC-3570, ISTC-5221 and 5222.

BASIS:

These are simple check valves with no external means of exercising, thus exercising (open) requires operating a LPSI pump at full flow and injecting into the reactor coolant system. At power operation, this is not possible because the LPSI pumps cannot develop sufficient discharge pressure to overcome reactor coolant system pressure. These valves are part-stroked exercised open quarterly and whenever the associated HPSI pump is run to fill a safety injection tank and verified closed quarterly. The full-stroke exercise open and closed is accomplished during cold shutdown periods (depending on plant conditions) and every refueling outage. This is consistent with the position stated in NUREG-1482, Rev. 1, Paragraph 2.4.5.

.ALTERNATE TESTING:

These valves will be full-stroke exercised in the open and closed directions during cold shutdowns in accordance with OM Code paragraph ISTC-3522.

ACCEPTANCE CRITERIA:

REFERENCES:

APPROVAL

REFERENCES:

1 OF 1

Constellation Energy (CCNPP Unit 2) IST Program SI-CSJ-04 Component ID 2-SI-491 2-SI-492.

2-SI-493 2-SI-494 Class Cat.

2 C

2 C

2 C

2 C

System SI SI.

SI SI Not Approved Label SI Tank Nitrogen Inlet Check Valve SI Tank Nitrogen Inlet Check Valve SI Tank Nitrogen Inlet Check Valve SI Tank Nitrogen Inlet Check Valve FUNCTION:

These check valve form the safety-related to non-safety boundary of the nitrogen supply piping to the Safety Injection Tanks. If a control valve is open to raise SIT pressure at the time of an accident, the check valve would close to protect the nitrogen inventory/pressure in the SIT.

TEST REQUIREMENT:

OM Code paragraph ISTC-351 0 requires Active Category A and B valves and Category C check valves to be exercised nominally every 3 months during operation at power to the position(s) required to fulfill its function(s),

except as provided by ISTC-3520, ISTC-3540, ISTC-3550, ISTC-3570, ISTC-5221 and 5222.

BASIS:

1 OF 2

Constellation Energy (CCNPP Unit 2) IST Program SI-CSJ-04 These check valves are normally closed and only need to perform their active closure function in the event an accident requiring the SITs is initiated while nitrogen pressure to one of the SITs is being increased. (Additionally, these check valves are in series with O-N2-344 & O-N2-347.) Since this is a relatively infrequent and short duration evolution affecting only one SIT at a time, testing these check valves quarterly would significantly increase the time during which the plant is dependent upon their active closure function.

The volume and mass of nitrogen contained in each SIT is substantial. Even if the test connection were used, a significant leak rate through one of these check valves would be required for a long period of time in order to see a verifiable effect of SIT pressure. This would require breaching the containment pressure boundary for a long period of time. Alternatively, the leak rate could be determined using one of two methods. First, a leak rate monitor may be installed at the test connection. However, installing a leak rate monitor is acknowledged in NUREG-1482, Rev. 1, as a basis for deferring testing. Alternatively, a pressure gauge may be installed at the test connection and the rate at which the isolated piping pressurizes measured, as is done in the cold shutdown test.

However, installing a pressure gauge and performing such a test quarterly would significantly increase the amount of time during which the administratively controlled upstream containment isolation control valves (1/2-CVC-612-CV, 1/2-CVC-622-CV, 1/2-CVC-632-CV, and 1/2-CVC-642-CV) are open (as well as the capped test connection).

Opening the capped test connection and the associated manual valve which form part of the containment boundary but not part of the penetration flow path is not considered to be prudent. Technical Specification 3.6.3 allows that "penetration flow paths may be unisolated intermittently under administrative controls." The Technical Specification Basis does not address what, if any, limitations there are on the reasons for using this allowance.

However, it is considered consistent with the intent of this Technical Specification that the reasons for opening a valve under administrative controls should be to accomplish a function which is necessary for continued safe operation. This logic is supported by the use of the phrase "penetration flow path" instead of a more generic term such as containment boundary. Performing a test in the manner described would breach the containment boundary by opening valves which are not part of the penetration flow path. Therefore, Calvert Cliffs considers such a test to be contrary to the intent of the Technical Specification.

Additionally, more frequent testing would require increased personnel radiation exposure and present more frequent situations in which potential component failure or human error could affect the operability of a SIT and place the plant in a very short-duration action statement. This is consistent with the position stated in NUREG-1482, Rev. 1, Paragraph 2.4.5.

ALTERNATE TESTING:

These valves will be exercised in the open and closed directions during cold shutdowns in accordance with OM Code paragraph ISTC-3522.

ACCEPTANCE CRITERIA:

REFERENCES:

APPROVAL

REFERENCES:

2 OF 2

Constellation Energy (CCNPP Unit 2) IST Program SI-CSJ-05 Not Approved Component ID Class Cat. System Label 2-SI-313 2

C SI Containment Spray Discharge Check Valve 2-SI-323 2

C SI Containment Spray Discharge Check Valve FUNCTION:

These valves open to provide flow paths from the containment spray pumps to the containment spray headers.

TEST REQUIREMENT:

OM Code paragraph ISTC-3510 requires Active Category A and B valves and Category C check valves to be exercised nominally every 3 months during operation at power to the position(s) required to fulfill its function(s),

except as provided by ISTC-3520, ISTC-3540, ISTC-3550, ISTC-3570, ISTC-5221 and 5222.

BASIS:

These are simple check valves with no means of external position indication or operation. During power operation, the only way to full-stroke exercise these check valves open would be to operate the containment spray pumps discharging into the containment spray headers. This is not acceptable because it would result in spraying contaminated borated water into the containment and result in equipment contamination and damage.

The containment spraypump discharge bypass lines do not allow sufficient flow to full-stroke these valves during quarterly pump testing. Establishing a flow path requires that 1/2-SI-459 be opened. Valve 1/2-SI-459 is maintained closed (and is leak-tested every two years) to ensure no highly contaminated fluid will reach the RWT following entry into recirculation mode subsequent to a LOCA involving partial fuel failure. This ensures Calvert Cliffs meets the applicable assumptions in the Off-Site Boundary Dose and Control Room Habitability Studies.

Opening these valves during power operation violates the parameters of these studies. A dedicated Operator.

could be stationed at the valves, which are located in the Radiologically Controlled Area, while they are open.

However, given the additional radiation exposure that would be incurred by stationing a dedicated Operator at the valves during a part-stroke exercise, this is not considered to be practical. Therefore, quarterly part-stroke testing is not considered practical.

The containment spray pumps and the associated discharge check valves can be full-flow tested by substituting the containment spray pumps for the low-pressure safety injection pumps into the shutdown cooling lineup after sufficient decay heat has been removed. Therefore, these check valves are full-stroke exercised open during cold shutdown periods (depending on plant conditions) and during every refueling outage when the containment spray pumps' high flow rate test is performed.

This is consistent with the position stated in NUREG-1482, Rev. 1, Paragraph 2.4.5.

ALTERNATE TESTING:

These valves will be full-stroke exercised open and verified closed during cold shutdowns in accordance with OM Code paragraph ISTC-3522.

ACCEPTANCE CRITERIA:.

REFERENCES:

1 OF 2

Constellation Energy (CCNPP Unit 2) IST Program SI-CSJ-05 APPROVAL

REFERENCES:

2 OF 2

Constellation Energy (CCNPP Unit 2) IST Program SI-ROJ-01 Not Approved Component ID Class Cat. System Label 2-SI-113 2

C St HPSI Header Isolation Check Valve 2-S1-123 2

C SI HPSI Header Isolation Check Valve 2-SI-133 2

C SI HPSI Header Isolation Check Valve 2-SI-143 2

C SI HPSI Header Isolation Check Valve FUNCTION:

These check valves open to provide flow paths for HPSI into the reactor coolant system. They close to prevent diversion of LPSI into the HPSI headers and can serve as an optional reactor coolant pressure isolation valve.

TEST REQUIREMENT:

OM Code paragraph ISTC-351 0 requires Active Category A and B valves and Category C check valves to be exercised nominally every 3 months during operation at power to the position(s) required to fulfill its function(s),

except as provided by ISTC-3520, ISTC-3540, ISTC-3550, ISTC-3570, ISTC-5221 and 5222.

BASIS:

These are simple check valves with no means of external position indication or operation. In order to open these valves, the HPSI pumps must be operated with injection into the reactor coolant system. This cannot be performed during plant operation at power because normal RCS pressure is above the shut-off head of the HPSI pumps. RCS pressure cannot be lowered sufficiently to permit full-stroke testing these valves unless the plant is shut down. Full stroke exercising these valves during cold shutdowns has the potential for over pressurizing the RCS. Full stroke xercising can be performed when the RCS is depressurized and vented during refueling outages, This is consistent with the position stated in NUREG-1 482, Rev. 1, Paragraph 2.4.5.

ALTERNATE TESTING:

These valves will be full-stroke exercised in the open direction during refueling outages in accordance with OM Code paragraph ISTC-3522.

ACCEPTANCE CRITERIA:

REFERENCES:

APPROVAL

REFERENCES:

1 OF 1

Constellation Energy (CCNPP Unit 2) IST Program SI-ROJ-02 Not Approved Component ID Class Cat. System Label 2-SI-405 2

C SI 23 HPSI Pump Discharge Check Valve 2-SI-414 (2CKVr 2

C SI 22 HPSI Pump Discharge Check Valve 2-SI-427 2

C SI 21 HPSI Pump Discharge Check Valve FUNCTION:

These check valves open to provide flow paths for water from the HPSI pumps to the HPSI discharge headers during SIAS or RAS.

TEST REQUIREMENT:

OM Code paragraph ISTC-3510 requires Active Category A and B valves and Category C check valves to be exercised nominally every 3 months during operation at power to the position(s) required to fulfill its function(s),

except as provided by ISTC-3520, ISTC-3540, ISTC-3550, ISTC-3570, ISTC-5221 and 5222.

BASIS:

These are simple check valves with no means of external position indication or operation. In order to open these valves, the HPSI pumps must be operated with injection into the reactor coolant system. This cannot be performed during plant operation at power because normal RCS pressure is above the shut-off head of the HPSI pumps. RCS pressure cannot be lowered sufficiently to permit full-stroke testing these valves unless the plant is shut down. Full stroke exercising these valves during cold shutdowns has the potential for over pressurizing the RCS. Full stroke xercising can be performed when the RCS is depressurized and vented during refueling outages. These valves are part-stroked exercised open quarterly during pump testing. This is consistent with the position stated in NUREG-1482, Rev. 1, Paragraph 2.4.5.

ALTERNATE TESTING:

These valves will be full-stroke exercised in the open direction during refueling outages in accordance with OM Code paragraph ISTC-3522.

ACCEPTANCE CRITERIA:

REFERENCES:

APPROVAL

REFERENCES:

1 OF 1

Constellation Energy (CCNPP Unit 2) IST Program SI-ROJ-03 Not Approved Component ID Class Cat. System Label 2-Si-330 (2CKV$

2 AC SI Containment Spray Supply Header Check Valve 2-SI-340 (2CKVc 2

AC SI Containment Spray Supply Header Check Valve FUNCTION:

These check valves open to provide flow paths from the containment spray pumps to the containment spray headers in containment. They close for containment isolation.

TEST REQUIREMENT:

OM Code paragraph ISTC-351 0 requires Active Category A and B valves and Category C check valves to be exercised nominally every 3 months during operation at power to the position(s) required to fulfill its function(s),

except as provided by ISTC-3520, ISTC-3540, ISTC-3550, ISTC-3570, ISTC-5221 and 5222.

BASIS:

These are in-line nozzle check valves, located in the containment buildings, which have no external means to exercise them. Full-stroke exercising these valves to the open position would require operating each containment spray pump at nominal accident flow rate. Since no recirculation flow path exists downstream of these valves, the only flow path available for such a test would result in injecting radioactive-contaminated borated water into the containment spray headers and into the containment building via the spray nozzles. There is also no way during plant operation to verify the check valves travel to the closed position.

The check valves were designed with a removable "test plug." This facilitates manually exercising each check valve, using an instrumented probe to measure the breakaway force of the valve disk, per OM Code-2004 paragraph ISTC-5221 (b). The associated piping is normally filled with water and the test plug forms part of the system pressure boundary. Mechnically exercising these check valves requires the headers to be drained and the system pressure boundary to be breached. Additionally, these check valves are located in containment and require scaffolding to reach (resulting in more man-power and radiation dose if they are tested shortly after reactor shut down). Therefore, mechanically exercising these check valves is not considered to be practical during cold shutdowns and is only performed during refueling outages. After the test plugs are reinstalled, the check valves are part-stroked with flow in order to leak-check the test plugs.

ALTERNATE TESTING:

These valves will be mechanically exercised open and closed during refueling outages in accordance with OM Code paragraphs ISTC-3522 & ISTC-5221 (b).

ACCEPTANCE CRITERIA:

REFERENCES:

APPROVAL

REFERENCES:

1 OF 1

Constellation Energy (CCNPP Unit 2) IST Program SRW-CSJ-01 Not Approved Component ID Class Cat. System Label 2-SRW-323 3

C SRW Turbine Building SRW Return Header Check Valve 2-SRW-324 3

C SRW Turbine Building SRW Return Header Check Valve 2-SRW-325 3

C SRW Turbine Building SRW Return Header Check Valve FUNCTION:

These normally-open check valves provide flow paths for normal cooling water return from non-essential components in the turbine building critical to the continued operation of the generating plant. They close to isolate the non-class return piping from the essential load return piping during an accident when the turbine building headers are isolated.

TEST REQUIREMENT:

OM Code paragraph ISTC-3510 requires Active Category A and B valves and Category C check valves to be exercised nominally every 3 months during operation at power to the position(s) required to fulfill its function(s),

except as provided by ISTC-3520, ISTC-3540, ISTC-3550, ISTC-3570, ISTC-5221 and 5222.

BASIS:

Closing any of these check valves during plant operation at power requires interrupting cooling flow from the turbine auxiliaries and associated components. This would ultimately result in a plant shutdown and overheating and damage to plant equipment. Partial closure of these valves presents the same risk as full closure; thus, it is also not feasible during operation. This is consistent with the position stated in NUREG-1482, Rev. 1, Paragraph 2.4.5.

ALTERNATE TESTING:

These valves will be full-stroke exercised in the closed direction during cold shutdowns in accordance with OM Code paragraph ISTC-3522.

ACCEPTANCE CRITERIA:

REFERENCES:

APPROVAL

REFERENCES:

1 OF 1

Constellation Energy (CCNPP Unit 2) IST Program SRW-CSJ-02 Not Approved Component ID Class Cat. System Label 2-SRW-1600-CV 3

B SRW Turbine Building SRW Isolation Valve 2-SRW-1637-CV 3

B SRW Turbine Building SRW Isolation Valve 2-SRW-1638-CV N

B SRW Turbine Building SRW Isolation Valve 2-SRW-1639-CV N

B SRW Turbine Building SRW Isolation Valve FUNCTION:

These normally-open valves provide flow paths for normal cooling water to non-essential components in the turbine building critical to the continued operation of the generating plant. They close on a SIAS to isolate non-essential heat loads and ensure adequate cooling water flow to critical heat loads. During an accident when the turbine building headers are isolated, these valves must close to isolate the non-class piping from the critical load piping.

TEST REQUIREMENT:

OM Code paragraph ISTC-3510 requires Active Category A and B valves and Category C check valves to be exercised nominally every 3 months during operation at power to the position(s) required to fulfill its function(s),

except as provided by ISTC-3520, ISTC-3540, ISTC-3550, ISTC-3570, ISTC-5221 and 5222.

BASIS:

Closing any of these valves during plant operation at power will interrupt cooling flow to the turbine auxiliaries and associated components. This would ultimately result in a plant shutdown and overheating and damage to equipment. Partial closure of these valves presents the same risk as full closure; thus, it is also not feasible during operation. This is consistent with the position stated in NUREG-1482, Rev. 1, Paragraph 2.4.5.

ALTERNATE TESTING:

These valves will be full-stroke exercised and stroke timed in the closed direction during cold shutdowns in accordance with OM Code paragraph ISTC-3521.

ACCEPTANCE CRITERIA:

REFERENCES:

APPROVAL

REFERENCES:

1 OF 1

Constellation Energy (CCNPP Unit 2) IST Program SW-CSJ-01 Not Approved Component ID Class Cat. System Label 2-SW-5149-CV (

3 B

SW Emergency Saltwater Discharge to Bay Valve FUNCTION:

These normally-closed valves remain closed to isolate the 11 (21) saltwater supply headers from the Emergency Overboard saltwater discharge flow paths to the bay in order to ensure normal flow of saltwater is maintained to the components and heat exchangers cooled by the 11 (21) saltwater trains. Under Emergency Overboard operations, they are opened to provide proper overboard flow paths.

TEST REQUIREMENT:

OM Code paragraph ISTC-3510 requires Active Category A and B valves and Category C check valves to be exercised nominally every 3 months during operation at power to the position(s) required to fulfill its function(s),

except as provided by ISTC-3520, ISTC-3540, ISTC-3550, ISTC-3570, ISTC-5221 and 5222.

BASIS:

Operation of these valves is tied to operation of the three valve pairs CV-5155 & CV-5156, CV-5165 & CV-5166, and CV-5177 & CV-5178. The normal way to stroke CV-5149 is to open one of these valve pairs using the appropriate handswitch. However, each of these valve pairs is operated from a single handswitch and preventing them from opening in order to operate CV-5149 alone would require placing them in an abnormal configuration (e.g. securing air to their actuators or installing jumpers in the valves' control circuit). Opening of any of these valve pairs during plant operation at power is not acceptable (see CSJ-02).

Override keyswitch HS-5149 is used to override 1(2)-SW-5149-CV in the closed direction. The switch has two positions 'Remote' and 'Override' (but no remote indication). In the 'Remote' position, 1(2)-SW-5149-CV will open when either HS-5155, HS-5167 or HS-5179 is taken to the open position to open either of the valve pairs 1(2)-SW-5155-CV & 1(2)-SW-5156-CV, 1(2)-SW-5165-CV & 1(2)-SW-5166-CV, and 1(2)-SW-5177-CV &

1(2)-SW-5178-CV. If the switch is in the 'Override' position, then 1(2)-SW-5149-CV will remain shut when either of the other handswitches is operated or, if already open, will travel shut. Therefore, while 1(2)-SW-5149-CV may be independently closed using HS-5149 after being opened, they can not be independently opened using only HS-5149. (Furthermore, placing HS-5149 in the 'Override' position so that 1(2)-SW-5149-CV remains shut when any of these other three handswitches are operated does not negate CSJ-02 because both valves in a valve pair still operate when the associated handswitch is operated, resulting in a loss of independence and separation between the two saltwater headers/trains.)

These valves also have a back-up nitrogen bottle available for emergency operation. However, the size of this nitrogen bottle is such that there is only sufficient gas for approximately two valve strokes. This would necessitate replacing the bottle after each test. More importantly, the nitrogen bottle is not permanently tied to the valve actuator. Stroking these valves with nitrogen requires installation of an air jumper and pressure regulator.

Installing the air jumper and replacing the nitrogen bottle quarterly increases the potential for damaging piping/tubing connections and is considered a hardship consistent with NUREG-1482, Rev. 1, Section 3.1.1.

ALTERNATE TESTING:

These valves will be full-stroke exercised and stroke timed in the open direction during cold shutdowns in accordance with OM Code paragraph ISTC-3521.

ACCEPTANCE CRITERIA:

1 OF 2

Constellation Energy (CCNPP Unit 2) IST Program Sw-cSJ-01

REFERENCES:

APPROVAL

REFERENCES:

2 OF 2

Constellation Energy (CCNPP Unit 2) IST Program SW-CSJ-02 Not Approved Component ID Class Cat. System Label 2-SW-5155-CV (

3 B

SW SRW Heat Exchangers Saltwater Auxiliary Outlet/Back-Up Outlet Valve 2-SW-5156-CV (

3 B

SW SRW Heat Exchangers Saltwater Auxiliary Outlet/Back-Up Outlet Valve 2-SW-5165-CV (

3 B

SW 22 CC Heat Exchangers Saltwater Auxiliary Outlet/Back-Up Outlet Valve 2-SW-5166-CV (

3 B

SW 22 CC Heat Exchangers Saltwater Auxiliary Outlet/Back-Up Outlet Valve 2-SW-5177-CV (

3 B

SW 22 ECCS Pump Room Air Coolers Saltwater Auxiliary Outlet/Back-Up Oul 2-SW-5178-CV (

3 B

SW 22 ECCS Pump Room Air Coolers Saltwater Auxiliary Outlet/Back-Up Oul FUNCTION:

These normally-closed valves remain closed to isolate the 12 (22) saltwater discharge headers from the 11 (21) saltwater supply headers, at the Emergency Overboard discharge flow path cross-connects between the Service Water Heat Exchangers, Component Cooling Heat Exchangers, and ECCS Pump Room Air Coolers, to ensure the normal cooling water flow is maintained to the components and heat exchangers cooled by the 11 (21) saltwater trains. They are opened when cooling is required in the emergency overboard lineup.

TEST REQUIREMENT:

OM Code paragraph ISTC-3510 requires Active Category A and B valves and Category C check valves to be exercised nominally every 3 months during operation at power to the position(s) required to fulfill its function(s),

except as provided by ISTC-3520, ISTC-3540, ISTC-3550, ISTC-3570, ISTC-5221 and 5222.

BASIS:

Each pair of valves is operated from a single handswitch and neither valve in each pair can be individually opened without placing the other valve in an abnormal configuration (e.g. securing air to the actuator or installing jumpers in a valve control circuit). Exercising any of these valve pairs during plant operation at power would allow significant bypass flow between the headers at the respective heat exchanger or cooler. Depending on saltwater header pressure, hot discharge flow from the 12 (22) header could be introduced into the 11 ( 21) supply header, or supply flow from the 11 (21) header could bypass each respective heat exchanger or cooler and pass into the 12 (22) discharge header. In either case, flow between the saltwater headers would significantly degrade the heat removal capacity of the heat exchangers or coolers supplied by the 11 (21) saltwater headers.

Additionally, while these valves are open, the two saltwater headers are not independent. As a result, both saltwater headers are considered inoperable and the plant is placed in a short-duration action statement. Should any valve pair fail to re-close after being opened, the saltwater system would no longer remain capable of performing its safety function in view of the associated single failure requirements, thereby necessitating a plant shutdown and cooldown.

Partial opening of these valves presents the same risk as full opening, thus it is also not feasible during operation.

This is consistent with the position stated in NUREG-1482, Rev. 1, Paragraph 2.4.5.

ALTERNATE TESTING:

These valves will be full-stroke exercised and stroke timed in the open direction during cold shutdowns in accordance with OM Code paragraph ISTC-3521.

ACCEPTANCE CRITERIA:

1 OF 2

Constellation Energy (CCNPP Unit 2) IST Program SW-CSJ-02

REFERENCES:

APPROVAL

REFERENCES:

2 OF 2

Constellation Energy (CCNPP Unit 2)1ST Program VALVE TABLE SYSTEM NAME:

Auxiliary Feedwater SYSTEM NUMBER:

AFW Active I Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat., Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-AFW-102 3

C Active.

6 CHV SE 62583 SH 2 C

O/C FE-F CS AFW-CSJ - 01 (D8)

FE-R CS 21 AFW Pump Discharge Check Valve 2-AFW-114 3

C Active 6

CHV SE 62583 SH 2 C

0 BDT-C R

(C9)

FE-F Q

21 AFW Pump Recirculation Check Valve 2-AFW-116 3

C Active 6

CHV SE 62583 SH 2 C

O/C FE-F CS AFW-CSJ - 01 (F8)

FE-R CS 22 AFW Pump Discharge Check Valve 2-AFW-128 3

C Active 6

CHV SE 62583 SH 2 C

0 BDT-C R

(E9)

FE-F Q

22 AFW Pump Recirculation Check Valve 2-AFW-129 3

C Active 4

CHV SE 62583 SH 2 C

O/C FE-F CMP (C2)

FE-R CMP Condition Monitoring Program component AFW to 21 Steam Generator Check Valve 2-AFW-130 3

C Active 4

CHV SE 62583 SH 2 C

O/C FE-F CMP (G2)

FE-R

. CMP Condition Monitoring Program component AFW to 22 Steam Generator Check Valve 2-AFW-131 3

B Passive 6

GTV MAN 60717 SH 1 C

C PI 2Y (H10) 21 Condensate Storage Tank AFW Pump Suction Valve 2-AFW-161 3

B Passive 6

GTV MAN 60717 SH 1 0

0 PI 2Y (G11) 12 Condensate Storage Tank Unit-I/Unit-2 AFW Pump Suction Valve 2-AFW-167 3

B Passive 6

GTV MAN 60717 SH 1 C

C PI 2Y (H 11) 21 Condensate Storage Tank AFW Pump Suction Valve 2-AFW-183 3

C Active 4

CHV SE 62583 SH 2 C

O/C FE-F CS AFW-CSJ - 02 (H8)

FE-R CS 23 AFW Pump Automatic Recirculation Valve

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Auxiliary Feedwater SYSTEM NUMBER:

AFW Active /

Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-AFW-190 3

C Active 6

CHV SE 62583 SH 2 C

0 BDT-C CMP Condition Monitoring Program component (H7)

FE-F CMP AFW Pump 13 to Unit 2 AFW Header Cross-Connect Check Valve 2-AFW-193 3

C Active 4

CHV SE 62583 SH 2 C

0 BDT-C CMP Condition Monitoring Program component (C4)

FE-F CMP 21 & 22 AFW Pump to 21 Steam Generator Check Valve 2-AFW-194 3

C Active 4

CHV SE 62583 SH 2 C

0 BDT-C CMP Condition Monitoring Program component (G4)

FE-F CMP 21 & 22 AFW Pump to 22 Steam Generator Check Valve 2-AFW-199 3

C Active 4

CHV SE 62583 SH 2 C

0 BDT-C CMP Condition Monitoring Program component (C2)

FE-F CMP 23 AFW Pump to 21 Steam Generator Check Valve 2-AFW-200 3

C Active 4

CHV SE 62583 SH 2 C

0 BDT-C CMP Condition Monitoring Program component (G2)

FE-F CMP 23 AFW Pump to 22 Steam Generator Check Valve 2-AFW-201 3

C Active 2

CHV SE 62583 SH 2 C

0 BDT-C CMP Condition Monitoring Program component (H9)

FE-F CMP 23 AFW Pump Recirculation to Suction Check Valve 2-AFW-202 3

C Active 2-CHV SE 62583 SH 2 C

0 BDT-C CMP Condition Monitoring Program component (19)

FE-F CMP 23 AFW Pump Recirculation to 12 CST Check Valve 2-AFW-4511-CV 3

B Active 3

GLV AO 62583 SH 2 0

T 0

FS 0

(2CV451 1)

(C3)

ST-C 0

AFW to 21 Flow Control Valve ST-0 Q

PI 2Y 2-AFW-4512-CV 3

B Active 3

GLV AO 62583 SH 2 0

T 0

FS 0

(2CV4512)

• (G3)

ST-C 0

AFW to 22 Flow Control Valve ST-0 Q

PI 2Y

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Auxiliary Feedwater SYSTEM NUMBER:

AFW Active /

Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-AFW-4520-CV 3

B Active 6

GLV AO 62583 SH 2 0

O/C 0

ES O

(2CV4520)

(C5)

ST-C Q

AFW to 21 Steam Generator Blocking Valve ST-C Q

PI 2Y 2-AFW-4521-CV 3

B Active 6

GLV AO 62583 SH 2 0

O/C 0

FS Q

(2CV4521)

(C4)

ST-C Q

AFW to 21 Steam Generator Blocking Valve ST-O Q

PI 2Y 2-AFW-4522-CV 3

B Active 6

GLV AO 62583 SH 2 0

O/C C

FS Q

(2CV4522)

(D4)

ST-C 0

AFW to 21 Steam Generator Blocking Valve ST-C Q

PI 2Y 2-AFW-4523-CV 3

B Active 6

GLV AO 62583 SH 2 C

O/C C

FS Q

(2CV4523)

(D3)

ST-C C

AFW to 21 Steam Generator Blocking Valve ST-C Q

PI 2Y 2-AFW-4525-CV 3

B Active 4

GLV AO 62583 SH 2 0

T 0

FS Q

(2CV4525)

(D2)

ST-C a

AFW pump 23 to Steam Generator 21 Flow Control Valve ST-O Q

PI 2Y 2-AFW-4530-CV 3

B Active 6

GLV AO 62583 SH 2 0

O/C 0

FS Q

(2CV4530)

(G5)

ST-C Q

AFW to 22 Steam Generator Blocking Valve ST-0 Q

PI 2Y 2-AFW-4531-CV 3

B Active 6

GLV AO 62583 SH 2 0

O/C 0

FS Q

(20V4531)

(G4)

ST-C Q

AFW to 22 Steam Generator Blocking Valve ST-O Q

PI 2Y

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Auxiliary Feedwater SYSTEM NUMBER:

AFW Active /

Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-AFW-4532-CV 3

B Active 6

GLV AO 62583 SH 2 0

O/C 0

FS Q

(2CV4532)

(F4)

ST-C Q

AFW to 22 Steam Generator Blocking Valve ST-O Q

PI 2Y 2-AFW-4533-CV 3

B Active 6

GLV AO 62583 SH 2 0

O/C 0

FS Q

(2CV4533)

(F2)

ST-C Q

AFW to 22 Steam Generator Blocking Valve ST-C Q

PI 2Y 2-AFW-4535-CV 3

B Active 4

GLV AO 62583 SH 2 C

T 0

FS Q

(2CV4535)

(F2)

ST-C Q

AFW pump 23 to Steam Generator 22 Flow Control Valve ST-O Q

PI 2Y 2-AFW-4550-CV 3

B Active 6

GLV AO 62583 SH 2 C

O/C C

ST-C Q

(2CV4550)

(H7)

PI 2Y Motor-Driven AFW Unit-2/Unit-1 Cross-Connect Valve

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Steam Generator Blowdown SYSTEM NUMBER:

BD Active I Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-BD-4011-CV 2

B Active 2

GTV AO 62749 SH -

0 C

C FS Q

(2CV4011)

(E2)

ST-C Q

Steam Generator Bottom Blowdown Containment Isolation Valve PI 2Y 2-BD-4013-CV 2

B Active 2

GTV AO 62749 SH -

0 C

C FS Q

(2CV4013)

(C2)

ST-C Q

Steam Generator Bottom Blowdown Containment Isolation Valve PI 2Y V

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Component Cooling SYSTEM NUMBER:

CC Active /

Size Valve Actuator Drawing Position Required Code Valve ID/Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-CC-115 3

C Active 16 CHV SE 62710 SH 1 O/C O/C FE-F Q

(2CKVCC-1 15)

(14)

FE-R Q

CC Pump Discharge Check Valve 2-CC-1 20 3

C Active 16 CHV SE 62710 SH 1 O/C O/C FE-F Q

(2CKVCC-120)

(G4)

FE-R Q

CC Pump Discharge Check Valve 2-CC-125 3

C Active.

16 CHV SE 62710 SH 1 O/C O/C FE-F Q

(2CKVCC-1 25)

(E4)

FE-R Q

CC Pump Discharge Check Valve 2-CC-3823-CV 3

B Active 10 BFV AO 62710 SH 2 T

C C

FS Q

Code Case OMN-8 (2CV3823)

(B7)

CC Heat Exchanger Temperature Control/Bypass Valve 2-CC-3823-RV 3

C Active 1

REV SE 62710 SH 2 C

0 aT 1 Y-S GV-RR -01 (87) 21 CC Heat Exchanger Shell-Side Relief Valve 2-CC-3824-CV 3

B Active 16 BFV AO 62710 SH 2 O/C 0

0 FS 0

(2CV3824)

(B6)

ST-O Q

CC Heat Exchanger Outlet Control Valve PI 2Y 2-CC-3825-CV 3

B Active 10 BFV AO 62710 SH 2 T

C C

FS Q

Code Case OMN-8 (2CV3825)

(C7)

CC Heat Exchanger Temperature Control/Bypass Valve 2-CC-3825-RV 3

C Active 1

REV SE 62710 SH 2 C

0 RT 1OY-S GV-RR - 01 (2RV3825)

(D7) 22 CC Heat Exchanger Shell-Side Relief Valve 2-CC-3826-CV 3

B Active 16 BFV A0 62710 SH 2 O/C 0

0 FS Q

(2CV3826)

(C6)

ST-O Q

CC Heat Exchanger Outlet Control Valve PI 2Y 2-CC-3827-RV 3

C Active 1

REV SE 62710 SH 2 C

0 RT 10Y-S GV-RR - 01 (H8) 21 Shutdown Cooling Heat Exchanger CC Inlet Relief Valve

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Component Cooling SYSTEM NUMBER:

CC Active /

Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-CC-3828-CV 3

B Active 16 BFV AO 62710 SH 2 C

0 0

FS 0

(2CV3828)

(H9)

ST-O 0

Shutdown Cooling Heat Exchanger Outlet Control Valve PI 2Y 2-CC-3829-RV 3

C Active 1

REV SE 62710 SH 2 C

0 RT 1OY-S GV-RR- 01 (F8) 22 Shutdown Cooling Heat Exchanger CC Inlet Relief Valve 2-CC-3830-CV 3

B Active 16 BFV AO 62710 SH 2 C

0 0

FS Q

(2CV3830)

(E9)

ST-0 Q

Shutdown Cooling Heat Exchanger Outlet Control Valve PI 2Y 2-CC-3831-RV 3

C Active 1

REV SE 62710 SH 2 C

0 RT 10Y-S GV-RR - 01 (B2)

Letdown Heat Exchanger Relief Valve 2-CC-3832-CV 3

A Active 10 BFV AO 62710 SH 2 0

C C

FS CS (2CV3832)

(B2)

ST-C CS CC-CSJ - 01 Containment Supply Isolation Valve Li-C APPJ PI 2Y 2-CC-3833-CV 3

A Active 10 BFV AO 62710 SH 2 0

C C

FS CS (2CV3833)

(14)

ST-C CS CC-CSJ - 01 Containment Return Isolation Valve LJ-C APPJ PI 2Y 2-CC-3840-CV 3

B Active 10 BFV AO 62710 SH 2 O/C C

C FS Q

(2CV3840)

(B8)

ST-C Q

CC Waste Evaporator Supply Isolation Valve PI 2Y 2-CC-3841-RV N

C Active 0.75 REV SE 62710 SH 2 C

0 RT 10Y-S (D2)

CEDM Cooler Outlet Relief Valve 2-CC-3842-CV N

B Active 10 BFV AO 62710 SH 2 O/C C

C FS Q

(2CV3842)

(89)

ST-C Q

CC Waste Evaporator Supply Isolation Valve Pt 2Y

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Component Cooling SYSTEM NUMBER:

CC Active /

Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-CC-3842-RV N

C Active 0.75 REV SE 62710 SH 2 C

0 RT 1OY-S (E3)

Steam Generator Support Coolers Outlet Relief Valve 2-CC-459 3

C Active 10 CHV SE 62710 SH 2 0

C BDT-O CMP Condition Monitoring Program component (D10)

FE-R CMP CC Waste Evaporator Return Check Valve 2-CC-6450A-RV 3

C Active

.75 REV SE 60724 SH 1 C

0 RT 10Y-S GV-RR -01 (G8)

NSSS Sample Cooler Outlet Relief Valve 2-CC-6471-RV 3

C Active

.75 REV SE 60724 SH 1 C

0 RT 10Y-S GV-RR - 01 (El1) 21 Steam Generator Blowdown Sample Coolers Relief Valve 2-CC-6472-RV 3

C Active

.75 REV SE 60724 SH 1 C

0 RT 1OY-S GV-RR -01 (El0) 22 Steam Generator Blowdown Sample Coolers Relief Valve

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Containment Ventilation SYSTEM NUMBER: IA/HP Active I Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-CPA-1410-CV N

A Active 8

BFV AO 60723 SH 3 DE C

C FS R

(2CV1410)

(B11)

LK R

Containment Air Purge Supply Isolation Valve ST-C R

CPA/HP-CSJ -

01 PI 2Y 2-CPA-1 412-CV N

A Active 8

BFV AO 60723 SH 3 DE C

C FS R

(2CV1412)

(D1 1)

LK R

Containment Air Purge Exhaust Isolation Valve ST-C R

CPA/HP-CSJ -

01 PI 2Y 2-HP-104 2

AC Active 4

CHV SE 60723 SH 2 C

C BDT-0 CMP Condition Monitoring Program component (2CKVHP-104)

(F4)

FE-R CMP Hydrogen Purge Replacement Air Check Valve LJ-C APPJ 2-HP-6900-MOV N

A Active 4

GTV MO 60723 SH 2 C

C DIAG OMN1 (2MOV6900)

(G5)

LJ-C APPJ Containment Hydrogen Purge Isolation Valve FSE 2Y 2-HP-6901-MOV 2

A Active 4

GTV MO 60723 SH 2 C

C DIAG OMN1 (2MOV6901)

(G5)

LJ-C APPJ Containment Hydrogen Purge Isolation Valve FSE 2Y 2-HP-6903-MOV 2

A Active 4

GTV MO 60723 SH 2 C

C DIAG OMN1 (2MOV6903)

(F5)

FSE CS Hydrogen Purge Replacement Air Containment Isolation Valve LJ-C APPJ

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Containment SYSTEM NUMBER: /ILRT Active /

Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-CPI-5313A-SV N

B Passive

.75 GLV SO 60723 SH 2 0

0 0

Pl 2Y (C3)

Containment Pressure Instrument Containment Isolation Valve 2-CPI-5313B-SV N

B Passive

.75 GLV SO 60723 SH 2 0

0 0

PI 2Y (B3)

Containment Pressure Instrument Containment Isolation Valve 2-CPI-5313C-SV N

B Passive

.75 GLV SO 60723 SH 2 0

0 0

PI 2Y (D3)

Containment Pressure Instrument Containment Isolation Valve 2-CPI-5313D-SV N

B Passive

.75 GLV SO 60723 SH 2 0

0 0

PI 2Y (C3)

Containment Pressure Instrument Containment Isolation Valve 2-ILRT-1 2

A Passive

.75 GLV MAN 60723 SH 2 C

C U-C APPJ (A6)

Containment ILRT Pressure Instrument Containment Isolation Valve 2-ILRT-2 2

A Passive

.75 GLV MAN 60723 SH 2 C

C LJ-C APPJ (86)

Containment ILRT Pressure Instrument Containment Isolation Valve

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Chemical & Volume Control SYSTEM NUMBER:

CVC Active I Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-CVC-103 2

A Passive 2

GTV MAN 62730 SH 3 O/C O/C LJ-C APPJ (2HVCVC-1 03)

(B3)

Letdown Control Inlet Valve 2-CVC-105 2

A Passive 2

GTV MAN 62730 SH 3 O/C O/C LJ-C APPJ (2HVCVC-105)

(83)

Letdown Control Inlet Valve 2-CVC-125-RV 2

C Active

.75 REV SE 62730 SH 1 C

0 RT 10Y-S GV-RR -01 (2RV125)

(F9)

Boric Acid Pump Recirculation Relief Valve 2-CVC-132-RV 2

C Active

.75 REV SE 62730 SH 1 C

0 RT 10Y-S GV-RR - 01 (2RV132)

(G8)

Boric Acid Storage Tank Discharge Relief Valve 2-CVC-133-RV 2

C Active

.75 REV SE 62730 SH 1 C

0 RT 10Y-S GV-RR - 01 (F8)

Boric Acid Pump Discharge Relief Valve 2-CVC-141-RV 2

C Active

.75 REV SE 62730 SH 1 C

0 RT 10Y-S GV-RR - 01 (2RV141)

(G12)

Boric Acid Storage Tank Discharge Relief Valve 2-CVC-149-RV 2

C Active

.75 REV SE 62730 SH 1 C

0 RT 10Y-S GV-RR- 01 (2RV149)

(F12)

Boric Acid Pump Recirculation Relief Valve 2-CVC-150-RV 2

C Active

.75 REV SE 62730 SH 1 C

0 RT 10Y-S GV-RR - 01 (2RV150)

(F1 2)

Boric Acid Pump Discharge Relief Valve 2-CVC-157-RV 2

C Active

.75 REV SE 62730 SH 1 C

0 RT 1OY-S GV-RR - 01 (2RV1 57)

(F6)

Boric Acid Pump Common Discharge Relief Valve 2-CVC-160-RV 2

C Active

.75 REV SE 62730 SH 1 C

0 RT 1OY-S GV-RR- 01 (F7)

Boric Acid Strainer Inlet Relief Valve

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Chemical & Volume Control SYSTEM NUMBER:

CVC Active /

Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-CVC-162 2

C Active 4

CHV SE 62730 SH 1 O/C C

BDT-O CMP Condition Monitoring Program component (F2)

FE-R CMP VCT Outlet Check Valve 2-CVC-165 2

C Active 2

CHV SE 62730 SH 2 O/C O/C FE-F 0

(2CKVCVC-165)

(F6)

FE-R 0

Charging Pump Discharge Check Valve 2-CVC-171 2

C Active 2

CHV SE 62730 SH 2 O/C O/C FE-F Q

(2CKVCVC-171)

(G6)

FE-R Q

Charging Pump Discharge Check Valve 2-CVC-171-RV 2

C Active

.75 REV SE 62730 SH 1 C

0 RT 10Y-S GV-RR - 01 (2RV171)

(E7)

Boric Acid Strainer Outlet Relief Valves 2-CVC-177 2

C Active 2

CHV SE 62730 SH 2 O/C O/C FE-F Q

(2CKVCVC-177)

(16)

FE-R Q

Charging Pump Discharge Check Valve 2-CVC-184 2

C Active 2

CHV SE 62730 SH 2 0

O/C FE-F CMP (2CKVCVC-184)

(D5)

FE-R CMP Condition Monitoring Program component Regenerative Heat Exchanger Charging Inlet Check Valve 2-CVC-185 1

C Active 2

CHV SE 62730 SH 2 C

O/C FE-F CMP (C8)

FE-R CMP Condition Monitoring Program component Auxiliary Pressurizer Spray Check Valve 2-CVC-186 1

C Active 2

CHV SE 62730 SH 2 O/C O/C FE-F CMP (E8)

FE-R CMP Condition Monitoring Program component Charging Check Valve 2-CVC-187 1

C Active

. 2 CHV SE 62730 SH 2 O/C O/C FE-F CMP (E12)

FE-R CMP Condition Monitoring Program component Charging Check Valve 2-CVC-217 2

C Active 3

CHV SE 62730 SH 1 O/C O/C FE-F 0

(G8)

FE-R Q

Boric Acid Pump Discharge Check Valve

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Chemical & Volume Control SYSTEM NUMBER:

CVC Active /

Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-CVC-222 2

C Active 3

CHV SE 62730 SH 1 O/C O/C FE-F 0

(H1O)

FE-R 0

Boric Acid Pump Discharge Check Valve 2-CVC-228 2

C Active 3

CHV

- SE 62730 SH 1 C

O/C FE-F CS CVC-CSJ -01 (H3)

FE-R CS Boric Acid Storage Tank Gravity Feed Check Valve 2-CVC-235 2

C Active 3

CHV SE 62730 SH 1 O/C 0

BDT-C CS (F5)

FE-F CS CVC-CSJ - 02 Boric Acid Pumps Direct Feed Check Valve 2-CVC-251 2

C Active 3

CHV SE 62730 SH 1 O/C C

BDT-O CS (D5)

FE-R CS CVC-CSJ - 03 Demineralized Water Supply to VCT Check Valve 2-CVC-257 2

C Active 3

CHV SE 62730 SH 1 O/C O/C FE-F CS CVC-CSJ -04 (F3)

FE-R CS RWT to Charging Pump Suction Check Valve 2-CVC-269-MOV 2

B Active 2

GTV MO 62730 SH 2 C

O/C DIAG OMN1 (2MOV269)

(F3)

FSE 2Y Safety Injection to Charging Header Stop Valve 2-CVC-311-RV 2

C Active

.75 REV SE 62730 SH 2 C

0 RT 1IY-S GV-RR - 01 (2RV311)

(G1 0)

Charging Pump Suction Relief Valve 2-CVC-315-RV 2

C Active

.75 REV SE 62730 SH 2 C

0 RT 10Y-S GV-RR - 01 (2RV315)

(E8)

Charging Pump Suction Relief Valve 2-CVC-318-RV 2

C Active

.75 REV SE 62730 SH 2 C

0 RT 10Y-S GV-RR - 01 (2RV318)

(G8)

Charging Pump Suction Relief Valve 2-CVC-321-RV 2

C Active

.75 REV SE 62730 SH 2 C

0 RT 10Y-S GV-RR - 01 (2RV321)

(H8)

Charging Pump Suction Relief Valve

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Chemical & Volume Control SYSTEM NUMBER:

CVC Active I Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-CVC-324-RV 2

C Active

.75 REV SE 62730 SH 2 C

0 RT 10Y-S GV-RR - 01 (2RV324)

(H6)

Charging Pump Discharge Relief Valve 2-CVC-325-RV 2

C Active

.75 REV SE 62730 SH 2 C

0 RT 10Y-S GV-RR - 01 (2RV325)

(G6)

Charging Pump Discharge Relief Valve 2-CVC-326-RV 2

C Active

.75 REV SE 62730 SH 2 C

0 RT 10Y-S GV-RR - 01 (2RV326)

(E6)

Charging Pump Discharge Relief Valve 2-CVC-435 1

AC Active 2

CHV SE 62730 SH 2 0

O/C FE-F CMP (2CKVCVC-435)

(F1 1)

FE-R CMP Condition Monitoring Program component Charging Control Valve Bypass Check Valve 2-CVC-501-MOV 2

B Active 4

GTV MO 62730 SH 1 0

C DIAG OMN1 (2MOV501)

(F2)

FSE CS VCT Outlet Isolation Valve 2-CVC-504-MOV 2

B Active 3

GTV MO 62730 SH 1 C

O/C DIAG OMN1 (2MOV504)

(F3)

FSE 2Y RWT to Charging Pump Suction Valve 2-CVC-505-CV 2

A Active

.75 GLV AO 62730 SH 2 0

C C

FS CS (2CV505)

(B8)

ST-C CS CVC-CSJ - 05 RCP Seal Bleedoff Containment Isolation Valve LJ-C APPJ PI 2Y 2-CVC-506-CV 2

A Active

.75 GLV AO 62730 SH 2

-O C

C FS CS (2CV506)

(B6)

ST-C CS CVC-CSJ - 05 RCP Seal Bleedoff Containment Isolation Valve LJ-C APPJ PI 2Y 2-CVC-508-MOV 2

B Active 3

GTV MO 62730 SH 1 C

0 DIAG OMN1 (2MOV508)

(H12)

FSE 2Y Boric Acid Storage Tank Gravity Feed Isolation Valve

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Chemical & Volume Control SYSTEM NUMBER:

CVC Active /

Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-CVC-509-MOV 2

B Active 3

GTV MO 62730 SH 1 C

0 DIAG OMN1 (2MOV509)

(G8)

FSE 2Y Boric Acid Storage Tank Gravity Feed Isolation Valve 2-CVC-510-CV 2

B Active 1.5 GTV AO 62730 SH 1 0

C C

FS 0

(2CV51 0)

(EH)

ST-C Q

Boric Acid Pump Recirculation Valve PI 2Y 2-CVC-511-CV 2

B Active 1.5 GTV AO 62730 SH 1 0

C C

FS Q

(2CV51 1)

(E12)

STC 0

Boric Acid Pump Recirculation Valve PI 2Y 2-CVC-512-CV N

B Active 3

GLV AO 62730 SH 1 O/C C

C FS 0

(2CV512)

(D4)

ST-C Q

Make-up Stop Valve PI 2Y 2-CVC-514-MOV 2

B Active 3

GTV MO 62730 SH 1 C

0 DIAG OMN1 (2MOV514)

(F6)

FSE 2Y Boric Acid Pumps to Charging Pumps Suction Direct Feed Valve 2-CVC-515-CV 1

A Active 2

GLV AO 62730 SH 2 0

C C

FS CS (2CV515)

(D2)

ST-C CS CVC-CSJ - 06 Letdown Stop Valve LJ-C APPJ PI 2Y 2-CVC-516-CV 1

A Active 2

GLV AO 62730 SH 2 0

C C

FS CS (2CV516)

(D4)

ST-C CS CVC-CSJ - 06 Letdown Containment Isolation Valve LJ-C APPJ PI 2Y 2-CVC-517-CV 1

B Active 2

GLV AO 62730 SH 2 C

O/C C

FS CS (2CV51 7)

(C9)

ST-C CS CVC-CSJ - 07 Charging Line Stop Valve ST-O CS PI 2Y

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME: Chemical & Volume Control SYSTEM NUMBER:

CVC Active /

Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-CVC-518-CV 1

B Active 2

GLV AO 62730 SH 2 0

O/C 0

FS Q

(2CV518)

(E9)

ST-C Q

Charging Line Stop Valve ST-O Q

PI 2Y 2-CVC-519-CV 1

B Active 2

GLV AO 62730 SH 2 0

O/C 0

FS Q

(2CV519)

(El )

ST-C Q

Charging Line Stop Valve ST-0 Q

PI 2Y

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

EDG Fuel Oil Storage & Transfer SYSTEM NUMBER:

DFO Active I Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2A-DFO-124 N

C Active 1.5 CHV SE 60727 SH 1 C

C.

FE-R SKID (C6) 2A Hand Priming Pump Discharge Check Valve 2A-DFO-125 N

C Active 1.5 CHV SE 60727 SH 1 C

0 FE-F SKID (C6) 2A Engine Driven F.O. Pump discharge Check Valve 2A-DFO-136 N

C Active 3

CHV SE 60736 SH 1 C

0 FE-F SKID (E6)

DFOT pump suction line check valve 2A-DFO-179 N

C Active 1

CHV SE 60727 SH 1 C

0 FE-F SKID (B3) 2A DFOT pump discharge check valve 2B-DFO-123 N

C Active 2

CHV SE 60736 SH 1 C

0 FE-F SKID (E9)

DFOT pump suction line check valve 2B-DFO-124 N

C Active 1.5 CHV SE 60727 SH 3 C

C FE-R SKID (C6) 2B Hand Priming Pump Discharge Check Valve 2B-DFO-125 N

C Active 1.5 CHV SE 60727 SH 3 C

0 FE-F SKID (C6) 28 Engine Driven F.O. Pump discharge Check Valve 2B-DFO-179 N

C Active 1

CHV SE 60727 SH 3 C

0 FE-F SKID (B3) 2B DFOT pump discharge check valve

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Demineralized Water SYSTEM NUMBER:

DW Active /

Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-DW-5460-CV 2

A Active 2

GLV AO 62729 SH 1 O/C C

C FS Q

(2CV5460)

(B 11)

ST-C Q

Demineralized Water Supply to Containment L-C APPJ PI 2Y

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Plant Drains SYSTEM NUMBER:

EAD Active I Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-EAD-5462-MOV 2

B Active 4

GTV MO 60733 SH 4 O/C C

FSE 0

(2MOV5462)

(C5)

DIAG OMN1 Normal Containment Sump Discharge to Auxiliary Building Sump Inboard Isolation Valve LJ-C APPJ 2-EAD-5463-MOV N

B Active 4

GTV MO 60733 SH 2 O/C C

FSE 0

(2MOV5463)

(16)

DIAG OMN1 Normal Containment Sump Discharge to Auxiliary Building Sump Outboard Isolation Valve LJ-C APPJ

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Extraction Steam SYSTEM NUMBER:

ES Active /

Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-ES-42 2

A Passive 1

GLV MAN 60734 SH 3 C

C LJ-C APPJ (2HVES-1 42)

(D8)

Extraction Steam Supply to Containment 2-ES-144 2

A Passive 1

GLV MAN 60734 SH 3 C

C LJ-C APPJ (2HVES-144)

(E8)

Extraction Steam Supply to Containment

Constellation Energy (CCNPP Unit 2)IST Program VALVE TABLE SYSTEM NAME:

Fire Protection SYSTEM NUMBER: -P Sys Active /

Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 0-FP-145A 2

AC Active 6

CHV SE 60714 SH 2 C

C BDT-O CMP Condition Monitoring Program component (OCKVFP-1 45A)

(C9)

FE-R APPJ Fire Main Supply to Containment Check Valve LJ-C APPJ 0-FP-145B 2

AC Active 6

CHV SE 60714 SH 2 C

C BDT-O CMP Condition Monitoring Program component (OCKVFP-145B)

(C8)

FE-R APPJ Fire Main Supply to Containment Check Valve LJ-C APPJ

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Feedwater SYSTEM NUMBER:

FW Active /

Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-FW-130 2

C Active 16 CHV SE 62702 SH 4 0

C BDT-O CMP Condition Monitoring Program component (F6)

FE-R CMP Steam Generator Feedwater Header Check Valve 2-FW-133 2

C Active 16 CHV SE 62702 SH 4 0

C BDT-O CMP Condition Monitoring Program component (86)

FE-R CMP Steam Generator Feedwater Header Check Valve 2-FW-4516-MOV 2

B Active 16 GLV MO 62702 SH 4 0

C DIAG OMNI (2MOV4516)

(B7)

FSE CS Steam Generator Feedwater Isolation Valve 2-FW-4517-MOV 2

B Active 16 GLV MO 62702 SH 4 0

C DIAG OMNI (2MOV4517)

(F7)

FSE CS Steam Generator Feedwater Isolation Valve

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Instrument Air SYSTEM NUMBER: 'A Sys Active Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-IA-1101 N

AC Active

.50 CHV SE 62712 SH 3 O/C C

BDT-O R

(F10)

FE-R R

IA-ROJ -04 Normal (NSR) Instrument Air Supply Check Valve LK 2Y 2-IA-1106 N

AC Active

.50 CHV SE 62712 SH 3 O/C C

BDT-0 R

(F10)

FE-R R

IA-ROJ - 04 Normal (NSR) Instrument Air Supply Check Valve LK 2Y 2-IA-1110 N

B Active

.75 GTV MAN 62712 SH 3 C

0 FSE 2Y (F8)

SWAC Supply to AFW Isolation Valve 2-1A-1203 N

C Active

.50 CHV SE 62712 SH 3 O/C O/C FE-F R

(H110)

FE-R R

IA-ROJ - 09 Instrument Air Supply to Steam Supply Valves Check Valve 2-1A-1213 N

C Active

.50 CHV SE 62712 SH 3 O/C C

BDT-O R

(18)

FE-R R

IA-ROJ - 08 Instrument Air Supply to 4070/4071 Air Accumulators Check Valve 2-IA-1220 N

C Active

.50 CHV SE 62712 SH 3 O/C O/C FE-F R

(H110)

FE-R R

IA-ROJ - 09 Instrument Air Supply to Steam Supply Valves Check Valve 2-IA-1228 N

C Active

.50 CHV SE 62712 SH 3 O/C C

BDT-O R

(18)

FE-R R

IA-ROJ - 08 Instrument Air Supply to 4070/4071 Air Accumulators Check Valve 2-IA-1387 N

C Active

.75 CHV SE 62712 SH 3 O/C 0

FE-F SKID (F8) 21 A SWAC Discharge Check Valve 2-1A-1388 N

C Active

.75 CHV SE 62712 SH 3 O/C 0

FE-F SKID (F8) 21B SWAC Discharge Check Valve 2-IA-1389 N

C Active

.75 CHV SE 62712 SH 3 O/C 0

FE-F SKID (E8) 22A SWAC Discharge Check Valve

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Instrument Air SYSTEM NUMBER: [A Sys Active /

Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-lA-1390 N

C Active

.75 CHV SE 62712 SH 3 O/C 0

FE-F SKID (E9) 228 SWAC Discharge Check Valve 2-IA-175 N

AC Active 2

CHV SE 62712 SH 3 O/C O/C FE-F R

IA-ROJ -01 (2CKVIA-175)

(C7)

FE-R R

Instrument Air Supply to Containment Isolation Check Valve LJ-C APPJ 2-IA-2058-RV N

C Active 1

REV SE 62712 SH 3 C

0 RT 10Y-S (F8)

Instrument Air Supply to AFW Air Relief Valve 2-IA-2080-MOV 2

A Active 2

GTV MO 62712 SH 3 0

O/C DIAG OMN1 (2MOV2080)

(C7)

FSE CS Containment Air Isolation Valve LJ-C APPJ 2-IA-2085-CV N

B Active 3

GLV AO 62712 SH 3 0

C C

FS CS (2CV2085)

(C8)

ST-C CS IA-CSJ - 01 Containment Air Control Valve PI 2Y 2-IA-300 N

AC Active 1

CHV SE 62712 SH 3 O/C O/C FE-F R

IA-ROJ - 05 (G8)

FE-R R

IA to 2-IA-4520-PCV & 2-IA-4510-PCV Check Valve LK 2Y 2-IA-301 N

AC Active 1

CHV SE 62712 SH 3 O/C O/C FE-F R

IA-ROJ -05 (G8)

FE-R R

IA 2-IA-4520-PCV & 2-IA-4510-PCV Check Valve LK 2Y 2-IA-304 N

AC Active

.50 CHV SE 62712 SH 3 O/C C

BDT-O R

(H8)

FE-R R

IA-ROJ -07 IA Amplifier Outlet to Receiver 21B Check Valve LK 2Y 2-IA-305 N

AC Active

.50 CHV SE 62712 SH 3 O/C C

BDT-O R

(H8)

FE-R R

IA-ROJ - 07 IA Amplifier Outlet to Receiver 21 A Check Valve LK 2Y

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Instrument Air SYSTEM NUMBER: "A Sys Active /

Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-IA-310 N

AC Active 2

CHV SE 62712 SH 3 O/C C

BDT-O R

(C5)

FE-R R

IA-ROJ - 02 Normal Instrument Air Supply to Containment Air Header Check Valve LK 2Y 2-IA-314 N

B Active

.75 GTV.

MAN 62712 SH 3 C

0 FSE 2Y (F9)

SWAC Supply to AFW Isolation Valve 2-IA-315A N

AC Active 1

CHV SE 62712 SH 3 O/C C

BDT-O R

(E6)

FE-R R

IA-ROJ - 06 Normal Instrument Air Supply to the IA Amplifier Check Valve LK 2Y 2-IA-317 N

B Active

.75 GTV MAN 62712 SH 3 C

0 FSE 2Y (F10)

SWAC Supply to AFW Isolation Valve 2-IA-4070A-RV N

C Active

.75 REV SE -

62712 SH 3 C

0 RT 10Y-S (17)

AFW Instrument Air Supply to 2-MS-4070-CV & 2-MS-4070A-CV Relief Valve 2-IA-4070-RV N

C Active

.75 REV SE 62712 SH 3 C

0 RT 10Y-S (17)

AFW Instrument Air Supply to 2-MS-4070-CV & 2-MS-4070A-CV Relief Valve 2-IA-4071A-RV N

C Active

.75 REV SE 62712 SH 3 C

0 RT 10Y-S (H9)

AFW Instrument Air Supply to 2-MS-4071 -CV & 2-MS-4071 A-CV Relief Valve 2-IA-4071-RV N

C Active

.75 REV SE 62712 SH 3 C

0 RT laY-S (19)

AFW Instrument Air Supply to 2-MS-4071-CV & 2-MS-4071A-CV Relief Valve 2-IA-520OA-RV N

C Active

.25 REV SE 62712 SH 3 C

0 RT SKID (F8) 21A SWAC Discharge Relief Valve 2-IA-5200B-RV N

C Active

.25 REV SE 62712 SH 3 C

0 RT SKID (F8) 21 B SWAC Discharge Relief Valve

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Instrument Air SYSTEM NUMBER:

iA Sys Active /

Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-IA-5200-RV N

C Active

.25 REV SE 62712 SH 3 C

0 RT 10Y-S (F7)

SWAC 21A & 21B Air Receiver Relief Valve 2-IA-5201A-RV N

C Active

.25 REV SE 62712 SH 3 C

0 RT SKID (E8) 22A SWAC Discharge Relief Valve 2-IA-5201B-RV N

C Active

.25 REV SE 62712 SH 3 C

0 RT SKID (E9) 22B SWAC Discharge Relief Valve 2-IA-5201-RV N

C Active

.25 REV SE 62712 SH 3 C

0 RT 10y-S (E8)

SWAC 22A & 22B Air Receiver Relief Valve 2-IA-6301A-RV N

C Active

.75 REV SE 62712 SH 3 C

0 RT 10Y-S (G9)

AFW Air Receiver 21 A Relief Valve 2-IA-6301B-RV N

C Active

.75 REV SE 62712 SH 3 C

0 RT 10Y-S (G7)

AFW Air Receiver 21B Relief Valve 2-IA-741 N

C Active

.75 CHV SE 62712 SH 3 O/C O/C FE-F R

IA-ROJ -03 (F10)

FE-R R

SWAC Discharge Check Valve 2-IA-743 N

C Active

.75 CHV SE 62712 SH 3 O/C O/C FE-F R

IA-ROJ -03 (F10)

FE-R R

SWAC Discharge Check Valve

Constellation Energy (CCNPP Unit 2)1IST Program VALVE TABLE SYSTEM NAME:

Main Steam SYSTEM NUMBER: IS Sys Active /

Size Valve ID / Name Class Cat.

Passive (in.)

Valve Actuator Drawing Position Required Code Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-MS-103

.2 C

Active 6

CHV SE 62583 SH 1 C

O/C FE-F CMP Condition Monitoring Program component (B9)

FE-R CMP Main Steam Header to AFW Pump Turbines Check Valve 2-MS-106 2

C Active 6

CHV SE 62583 SH 1 C

O/C FE-F CMP Condition Monitoring Program component (B8)

FE-R CMP Main Steam Header to AFW Pump Turbines Check Valve 2-MS-108 2

C Active 6

CHV SE 62583 SH 1 C

0 BDT-C CMP Condition Monitoring Program component (D7)

FE-F CMP Main Steam Inlet to AFW Pump Turbines Check Valves 2-MS-110 2

C Active 6

CHV SE 62583 SH 1 C

0 BDT-C CMP Condition Monitoring Program component (B7)

FE-F CMP Main Steam Inlet to AFW Pump Turbines Check Valves 2-MS-3938-CV 2

B Active 5

GLV AO 62700 SH 1 O/C C

C FS CS MS-CSJ - 02 Code Case OMN-8 (E8)

PI 2Y Atmospheric Dump Valve 2-MS-3939-CV 2

B Active 5

GLV AO 62700 SH 1 O/C C

C FS CS MS-CSJ - 02 Code Case OMN-8 (B8)

PI 2Y Atmospheric Dump Valve 2-MS-3986-CV 2

B Active 4

GLV AO 62583 SH 1 0

O/C 0

FSE SKID (E5)

AFW Pump Steam Trip & Throttle Valve 2-MS-3988-CV 2

B Active 4

GLV AO 62583 SH 1 0

O/C 0

FSE SKID (H5)

AFW Pump Steam Trip & Throttle Valve 2-MS-3992-RV 2

C Active 6

REV SE 62700 SH 1 C

0 RT 10Y-S (2RV3092)

(F6)

Steam Generator Safety Relief Valves 2-MS-3993-RV 2

C Active (2RV3993)

Steam Generator Safety Relief Valves 6

REV SE 62700 SH 1 C

(F6) 0 RT 10Y-S

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Main Steam SYSTEM NUMBER: IS Sys Active/

Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-MS-3994-RV 2

C Active 6

REV SE 62700 SH 1 C

0 RT 1 OY-S (2RV3994)

(F6)

Steam Generator Safety Relief Valves 2-MS-3995-RV 2

C Active 6

REV SE 62700 SH 1 C

0 RT 1 OY-S (2RV3995)

(F5)

Steam Generator Safety Relief Valves 2-MS-3996-RV 2

C Active 6

REV SE 62700 SH 1 C

0 RT I0Y-S (2RV3996)

(F5)

Steam Generator Safety Relief Valves 2-MS-3997-RV 2

C Active 6

REV SE 62700 SH 1 C

0 RT 1 OY-S (2RV3997)

(F4)

Steam Generator Safety Relief Valves 2-MS-3998-RV 2

C Active 6

REV SE 62700 SH 1 C

0 RT 1 OY-S (2RV3998)

(F4)

Steam Generator Safety Relief Valves 2-MS-3999-RV 2

C Active 6

REV SE 62700 SH 1 C

0 RT 10Y-S (2RV3999)

(F4)

Steam Generator Safety Relief Valves 2-MS-4000-RV 2

C Active 6

REV SE 62700 SH 1 C

0 RT 10Y-S (2RV4000)

(B6)

Steam Generator Safety Relief Valves 2-MS-4001-RV 2

C Active 6

REV SE 62700 SH 1 C

0 RT 10Y-S (2RV4001)

(16)

Steam Generator Safety Relief Valves 2-MS-4002-RV 2

C Active 6

REV SE 62700 SH 1 C

0 RT tOY-S (2RV4002)

(B6)

Steam Generator Safety Relief Valves 2-MS-4003-RV 2

C Active 6

REV SE 62700 SH 1 C

0 RT 1 OY-S (2RV4003)

(85)

Steam Generator Safety Relief Valves

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME: Main Steam SYSTEM NUMBER:

IS Sys Active I Size Valve Actuator Drawing Position Required Code Valve ID /Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-MS-4004-RV 2

C Active 6

REV SE 62700 SH 1 C

0 RT 10y-S (2RV4004)

(B5)

Steam Generator Safety Relief Valves 2-MS-4005-RV 2

C Active 6

REV SE 62700 SH 1 C

0 RT lay-S (2RV4005)

(B4)

Steam Generator Safety Relief Valves 2-MS-4006-RV 2

C Active 6

REV SE 62700 SH 1 C

0 RT lay-S (2RV4006)

(84)

Steam Generator Safety Relief Valves 2-MS-4007-RV 2

C Active 6

REV SE 62700 SH 1 C

0 RT 10Y-S (2RV4007)

(B4)

Steam Generator Safety Relief Valves 2-MS-4043-CV 2

B Active 36 GLV AO 62700 SH 1 0

C ST-C CS MS-CSJ -01 (2CV4043)

(F3)

PI 2Y Main Steam Header Isolation Valve (MSIV) 2-MS-4045-MOV 2

B Passive 2

GLV MO 62700 SH 1 C

C PI 2Y (F3)

Main Steam Header Isolation Valve Bypass Valve 2-MS-4048-CV 2

B Active 36 GLV AO 62700 SH 1 0

C ST-C CS MS-CSJ -01 (2CV4048)

(13)

PI 2Y Main Steam Header Isolation Valve (MSIV) 2-MS-4052-MOV 2

B Passive 2

GLV MO 62700 SH 1 C

C PI 2Y (B3)

Main Steam Header Isolation Valve Bypass Valve 2-MS-4070A-CV 2

B Active 2

GLV AO 62583 SH 1 C

O/C 0

FS Q

(2CV4070A)

(B9)

ST-C Q

Steam Generator Bypass Supply to Auxiliary Feedwater (AFW) Pump Turbines Valve ST-0 Q

ST-CM n/a PMT in Cold Shutdown ST-OM n/a PMT in Cold Shutdown PI 2Y

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME: Main Steam SYSTEM NUMBER: IS Sys Active /

Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-MS-4070-CV 2

B Active 6

GLV AO 62583 SH 1 C

O/C 0

FS 0

(2CV4070)

(B9)

ST-C 0

Steam Generator Auxiliary Feedwater (AFW) Pump Turbine Steam Supply Valve ST-0 0

ST-CM n/a PMT in Cold Shutdown ST-OM n/a PMT in Cold Shutdown PI 2Y 2-MS-4071A-CV 2

B Active 2

GLV AO 62583 SH 1 C

O/C 0

FS 0

(2CV4071 A)

(88)

ST-C 0

Steam Generator Bypass Supply to Auxiliary Feedwater (AFW) Pump Turbines Valve ST-O Q

ST-CM n/a PMT in Cold Shutdown ST-OM n/a PMT in Cold Shutdown PI 2Y 2-MS-4071-CV 2

B Active 6

GLV AO 62583 SH 1 C

O/C 0

FS 0

(2CV4071)

(B8)

ST-C Q

Steam Generator Auxiliary Feedwater (AFW) Pump Turbine Steam Supply Valve ST-0 Q

ST-CM n/a PMT in Cold Shutdown ST-OM n/a PMT in Cold Shutdown PI 2Y 2-MSH-4042A-CV N

B Active 0.5 GLV HYD 62747 SH -

C 0

C ST-O SKID (86)

MSIV Pilot Actuator Valve 2-MSH-4042B-CV N

B Active 0.5 GLV HYD 62747 SH -

C 0

C ST-O SKID (D6)

MSIV Pilot Actuator Valve 2-MSH-4047A-CV N

B Active 0.5 GLV HYD 62747 SH -

C 0

C ST-O SKID (H6)

MSIV Pilot Actuator Valve 2-MSH-4047B-CV N

B Active 0.5 GLV HYD 62747 SH -

C 0

C ST-0 SKID (F6)

MSIV Pilot Actuator Valve

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Nitrogen SYSTEM NUMBER:

N2 Active /

Size Valve Actuator Drawing Position Required Code Valve ID /Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks O-N2-347 2

AC Active 1

CHV SE 60726 SH -

O/C C

BDT-O CMP Condition Monitoring Program component (OCKVN2-347)

(H8)

FE-R CMP Nitrogen Supply to Safety Injection Tanks Outboard Check Valve LJ-C APPJ O-N2-348 2

AC Active 1

CHV SE 60726 SH -

C C

BDT-O CMP Condition Monitoring Program component (OCKVN2-348)

(H8)

FE-R CMP Nitrogen Supply to Reactor Coolant Drain Tanks Check Valve LJ-C APPJ O-N2-349 2

AC Active 1

CHV SE 60726 SH -

C

• C BDT-O CMP Condition Monitoring Program component (OCKVN2-349)

(19)

FE-R CMP Nitrogen Supply to Steam Generators Check Valve LJ-C APPJ O-N2-395 2

AC Active 1

CHV SE 60726 SH -

C C

BDT-O CMP Condition Monitoring Program component (OCKVN2-395)

(Hg)

FE-R CMP Nitrogen Supply to Reactor Coolant Drain Tanks Check Valve LJ-C APPJ O-N2-398 2

AC Active 1

CHV SE 60726 SH -

C C

BDT-O CMP Condition Monitoring Program component (OCKVN2-398)

(110)

FE-R CMP Nitrogen Supply to Steam Generators Check Valve LJ-C APPJ

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Plant Air SYSTEM NUMBER:

PA Active /

Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-PA-1044 2

A Passive 2

GTV MAN 60746 SH 2 C

C LJ-C APPJ (2HVPA-1044)

(14)

Plant Air Supply Isolation Valves to Containment 2-PA-1 37 2

A Passive 2

GTV MAN 60746 SH 2 C

C LJ-C APPJ (2HVPA-137)

(C11i)

Plant Air Supply Isolation Valves to Containment

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Primary/Post-Accident Sampling SYSTEM NUMBER:

PAS Active /

Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequendy Dev.

Remarks 2-PS-5464-CV 1

A Active

.75 GTV AO 60724 SH 1 O/C C

C FS 0

(2CV5464)

(C 10)

ST-C Q

RCS Common Sample Isolation Valve LJ-C APPJ PI 2Y 2-PS-5465-CV 1

A Active

.75 GTV AO 60724 SH 1 O/C C

C FS 0

(2CV5465)

(Bl11)

ST-C Q

Pressurizer Sample Isolation Valve LJ-C APPJ PI 2Y 2-PS-5466-CV 1

A Active

.75 GTV AO 60724 SH 1 O/C C

C FS Q

(2CV5466)

(C11i)

ST-C Q

Pressurizer Sample Isolation Valve LJ-C APPJ P1 2Y 2-PS-5467-CV 1

A Active

.75 GTV AO' 60724 SH 1 O/C C

C FS Q

(2CV5467)

(C 11)

ST-C Q

RCS Hot Leg Sample Isolation Valve LJ-C APPJ PI 2Y 2-PS-6529-SV 1

A Active

.25 GLV AO 60724 SH 3 O/C C

C FS Q

(2SV6529)

(El0)

ST-C Q

PASS Sample Return Containment Isolation Valve LJ-C APPJ PI 2Y

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Gas Analyzing SYSTEM NUMBER:

PS Active /

Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-PS-6507A-SV 2

A Active

.25 GLV so 60744 SH 1 O/C C

C FS Q

,(2Sy6507A)

(C3)

ST-C Q

Outboard Containment Sampling Isolation Valve LJ-C APPJ PI 2Y 2-PS-6507B-SV 2

A Active

.25 GLV so 60744 SH 1 O/C C

C FS Q

(2SV6507B)

(C11i)

ST-C Q

Outboard Containment Sampling Isolation Valve LJ-C APPJ PI 2Y 2-PS-6507C-SV 2

A Active

.25 GLV so 60744 SH 1 O/C C

C FS Q

(2SV6507C)

(C11i)

ST-C Q

Outboard Containment Sampling Isolation Valve LJ-C APPJ PI 2Y 2-PS-6507D-SV 2

A Active

.25 GLV so 60744 SH 1 O/C C

C FS Q

(2SV6507D)

(C12)

ST-C Q

Outboard Containment Sampling Isolation Valve LJ-C APPJ PI 2Y 2-PS-6507E-SV 2

A Active

.25 GLV SO 60744 SH 1 O/C C

C FS Q

(2SV6507E)

(C4)

ST-C Q

Outboard Containment Sampling Isolation Valve LJ-C APPJ PI 2Y 2-PS-6507F-SV 2

A Active

.25 GLV SO 60744 SH 1 O/C C

C FS Q

(2SV6507F)

(C4)

ST-C Q

Outboard Containment Sampling Isolation Valve LJ-C APPJ PI 2Y 2-PS-6507G-SV 2

A Active

.25 GLV so 60744 SH 2 O/C C

C FS Q

(2SV6507G)

(19)

ST-C Q

Containment Atmosphere Sample Return Valve LJ-C APPJ PI 2Y

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME: Gas Analyzing SYSTEM NUMBER:

PS Active I Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-PS-6531-SV 2

A Active

.25 GLV so 60744 SH 1 O/C C

C FS Q

(2SV6531)

(F6)

ST-C Q

Pressurizer Quench Tank Sample Isolation Valve LI-C APPJ PI 2Y 2-PS-6540A-SV N

A Active

.25 GLV so 60744 SH 1 O/C C

C FS 0

(2SV6540A)

(83)

ST-C Q

Inboard Containment Sampling Isolation Valve LI-C APPJ PI 2Y 2-PS-6540B-SV N

A Active

.25 GLV SO 60744 SH 1 O/C C

C FS a

(2SV6540B)

(Bi11)

ST-C Q

Inboard Containment Sampling Isolation Valve LJ-C APPJ PI 2Y 2-PS-6540C-SV N

A Active

.25 GLV so 60744 SH I O/C C

C FS

ýQ (2SV6540C)

(812)

ST-C 0

Inboard Containment Sampling Isolation Valve LJ-C APPJ PI 2Y 2-PS-6540D-SV N

A Active

.25 GLV so 60744 SH 1 O/C C

C*

FS Q

(2SV6540D)

(B112)

ST-C Q

Inboard Containment Sampling Isolation Valve LJ-C APPJ PI 2Y 2-PS-6540E-SV N

A Active

.25 GLV so 60744 SH 1 O/C C

C FS Q

(2SV6540E)

(B4)

ST-C 0

Inboard Containment Sampling Isolation Valve LJ-C APPJ PI 2Y 2-PS-6540F-SV N

A Active

.25 GLV so 60744 SH 1 O/C C

C FS Q

(2SV6540F)

(14)

Si-C 0

Inboard Containment Sampling Isolation Valve LJ-C APPJ P1 2Y

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME: Gas Analyzing SYSTEM NUMBER:

PS Active /

Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-PS-6540G-SV N

A Active

.25 GLV SO 60744 SH 2 O/C C

C FS Q

(2SV6540G)

(H9)

ST-C Q

Containment Atmosphere Sample Return Valve LJ-C APPJ P1 2Y

Constellation Energy (CCNPP Unit 2)1ST Program VALVE TABLE SYSTEM NAME:

Plant Water SYSTEM NUMBER:

PSW Active I Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 0-PSW-1009 2

A Passive 3

GLV MAN 60746 SH 3 C

C LJ-C APPJ (OHVPSW-1 009)

(19)

Plant Water Supply Isolation Valve to Containment O-PSW-1020 2

A Passive 3

GLV MAN 60746 SH 3 C

C LJ-C APPJ (OHVPSW-1020)

(110)

Plant Water Supply Isolation Valve to Containment

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Reactor Coolant SYSTEM NUMBER:

RC Active /

Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-RC-100E-CV 1

B Active 3

GTV AO 62729 SH I O/C C

C FS CS (2RC100ECV)

(D8)

ST-C CS RC-CSJ - 03 Pressurizer Spray Valve PI 2Y 2-RC-10OF-CV 1

B Active 3

GTV AO 62729 SH 1 O/C C

C FS CS (2RC10OFCV)

(E8)

ST-C CS RC-CSJ - 03 Pressurizer Spray Valve PI 2Y 2-RC-103-SV 1

B Active

.75 GLV SO 62729 SH 1 C

O/C C

FS CS (2SV103)

(17)

ST-C CS RC-CSJ - 02 Reactor Vessel Vent Valve ST-O CS PI 2Y 2-RC-104-SV 1

B Active

.75 GLV so 62729 SH 1 C

O/C C

FS CS (2SV104)

(16)

ST-C CS RC-CSJ.- 02 Reactor Vessel Vent Valve ST-O CS PI 2Y 2-RC-i05-SV 1

B Active

.75 GTV so 60724 SH 1 C

O/C C

FS CS (2SV105)

(All)

ST-C CS RC-CSJ - 01 Pressurizer Vent Valve ST-O CS PI 2Y 2-RC-106-SV 1

B Active

.75 GTV SO 60724 SH 1 C

O/C C

FS CS (2SVi 06)

(A10)

ST-C CS RC-CSJ - 01 Pressurizer Vent Valve ST-C CS PI 2Y 2-RC-200-RV 1

C Active 2.5 REV SE 62729 SH 1 C

0 RT 5Y-S RC-RR - 01 (2RV200)

(84)

Pressurizer Safety Valve 2-RC-201-RV 1

C Active 2.5 REV SE 62729 SH 1 C

C RT 5Y-S RC-RR - 01 (2RV201)

(B8)

Pressurizer Safety Valve

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Reactor Coolant SYSTEM NUMBER:

RC Active /

Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-RC-402-ERV 1

B Active 2.5 GLV STO 62729 SH 1 C

O/C C

FS R

(2ERV402)

(A5)

ST-C R

Power-Operated Relief Valve (PORV)

ST-O R

PI 2Y RT 2-RC-403-MOV 1

B Active 4

GLV MO 62729 SH 1 0

O/C FSE Q

(2MOV403)

(B5)

DIAG OMN1 PORV Blocking Valve 2-RC-404-ERV 1

B Active 2.5 GLV STO 62729 SH 1 C

O/C C

FS R

(2ERV404)

(A7)

ST-C R

Power-Operated Relief Valve (PORV)

ST-O R

PI 2Y RT 2-RC-405-MOV 1

B Active 4

GLV MO 62729 SH 1 0

O/C FSE Q

(2MOV405)

(B7)

DIIAG OMN1 PORV Blocking Valve

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Liquid Waste SYSTEM NUMBER:

RCW Active I Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-RCW-4260-CV 2

A Active 2

GTV AO 60734 SH 1 O/C C

C FS Q

(2CV4260)

(D7)

ST-C Q

Reactor Coolant Waste Containment Isolation Valve LJ-C APPJ P1 2Y

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Area Radiation Monitoring SYSTEM NUMBER:

RE Active /

Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-RE-5291-CV 2

A Active 1

GLV AO 60738 SH 1 0

C C

FS 0

(2CV5291)

(C9)

ST-C 0

Containment Atmosphere Gaseous Sample Containment Isolation Valve LJ-C APPJ PI 2Y 2-RE-5292-CV 2

A Active 1

GLV AO 60738 SH 1 0

C C

FS 0

(2CV5292)

(C 10)

ST-C Q

Containment Atmosphere Gaseous Sample Containment Isolation Valve LJ-C APPJ PI 2Y

Constellation Energy (CCNPP Unit 2)1ST Program VALVE TABLE SYSTEM NAME:

Spent Fuel Pool Cooling SYSTEM NUMBER:

SFP Active /

Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks O-SFP-178 2

A Passive 8

GTV MAN 60716 SH -

C C

LJ-C APPJ (OHVSFP-178)

(811)

Unit 2 Reactor Cavity Inboard Return Valve 0-SFP-179 2

A Passive 8

GTV MAN 60716 SH -

C C

LJ-C APPJ (OHVSFP-179)

(811)

Unit 2 Reactor Cavity Outboard Return Valve O-SFP-180 N

A Passive 8

GTV MAN 60716 SH -

C C

LJ-C.

APPJ (OHVSFP-1 80)

(C1 0)

Unit 2 Reactor Cavity Inboard Drain Valve 0-SFP-182 N

A Passive 8

GTV MAN 60716 SH -

C C

LJ-C APPJ (OHVSFP-182)

(C9)

Unit 2 Reactor Cavity Inboard Drain Valve 0-SFP-184 N

A Passive 2

GTV MAN 60716 SH -

C C

LJ-C APPJ (0HVSFP-184)

(C9)

Unit 2 Reactor Cavity Skimmer Outlet Valve 0-SFP-186 2

A Passive 8

GTV MAN 60716 SH -

C C

LJ-C APPJ (OHVSFP-186)

(C8)

Unit 2 Reactor Cavity Outboard Supply Valve 0-SFP-2 N

A Passive 36 GTV MAN 60716 SH -

C C

(87)

Unit 2 Spent Fuel Pool Transfer Tube Closure Valve

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Safety Injection/Containment Spray SYSTEM NUMBER:

SI Active /

Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-SI-113 2

C Active 2

CHV SE 62731 SH 1 C

O/C FE-F CS SI-ROJ - 01 (D2)

FE-R CS HPSI Header Isolation Check Valve 2-SI-114 2

C Active 6

CHV SE 62731 SH 2 C

O/C FE-F CS SI-CSJ - 02 (2CKVSI-1 14)

(W3)

FE-R CS LPSI Header Isolation Check Valve 2-SI-118 1

AC Active 6

CHV SE 62731 SH 2 C

O/C FE-F CS SI-CSJ - 03 (2CKVSI-1 18)

(D4)

FE-R CS Safety Injection Header Check Valve LK 2Y 2-S1-123 2

C Active 2

CHV SE 62731 SH 1 C

O/C FE-F CS SI-ROJ -01 (E2)

FE-R CS HPSI Header Isolation Check Valve 2-SI-124 2

C Active 6

CHV SE 62731 SH 2 C

O/C FE-F CS SI-CSJ - 02 (2CKVSI-1 24)

(H3)

FE-R CS LPSI Header Isolation Check Valve 2-SI-128 1

AC Active 6

CHV SE 62731 SH 2 C

O/C FE-F CS SI-CSJ - 03 (2CKVSI-1 28)

(H4)

FE-R CS Safety Injection Header Check Valve LK 2Y 2-SI-133 2

C Active 2

CHV SE 62731 SH 1 C

O/C FE-F CS SI-ROJ - 01 (F2)

FE-R CS HPSI Header Isolation Check Valve 2-SI-134 2

C Active 6

CHV SE 62731 SH 2 C

O/C FE-F CS SI-CSJ - 02 (2CKVSI-134)

(D9)

FE-R CS LPSI Header Isolation Check Valve 2-SI-138 1

AC Active 6

CHV SE 62731 SH 2 C

O/C FE-F CS SI-CSJ - 03 (2CKVSI-1 38)

(D8)

FE-R CS Safety Injection Header Check Valve LK 2Y

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Safety Injection/Containment Spray SYSTEM NUMBER:

SI Active I Size Valve Aciuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-SI-143 2

C Active 2

CHV SE 62731 SH 1 C

O/C FE-F CS SI-ROJ - 01 (H2)

FE-R CS HPSI Header Isolation Check Valve 2-SI-144 2

C Active 6

CHV SE 62731 SH 2 C

O/C FE-F CS SI-CSJ - 02 (2CKVSI-144)

(H9)

FE-R CS LPSI Header Isolation Check Valve 2-SI-148 1

AC Active 6

CHV SE 62731 SH 2 C

O/C FE-F CS SI-CSJ - 03 (2CKVSI-148)

(H8)

FE-R CS Safety Injection Header Check Valve LK 2Y SI-211-RV 2

C Active 1

REV SE 62731 SH 2 C

0 RT 1OY-S GV-RR - 01 (2RV211)

(A5)

Safety Injection Tank Relief Valve 2-SI-215 2

AC Active 12 CHV SE 62731 SH 2 C

O/C FE-F

• CMP Condition Monitoring Program component (2CKVSI-215)

(C4)

FE-R CMP Safety Injection Tank Outlet Check Valve LK 2Y 2-SI-217 1

AC Active 12 CHV SE 62731 SH 2 C

O/C FE-F CMP Condition Monitoring Program component (D6)

FE-R CMP Safety Injection Loop Inlet Check Valve LK 2Y Monitored by PIA-319 2-SI-221-RV 2

C Active 1

REV SE 62731 SH 2 C

0 RT 10Y-S GV-RR - 01 (2RV221)

(E5)

Safety Injection Tank Relief Valve 2-SI-225 2

AC Active 12 CHV SE 62731 SH 2 C

O/C FE-F CMP Condition Monitoring Program component (2CKVSI-225)

(G4)

FE-R CMP Safety Injection Tank Outlet Check Valve LK 2Y 2-SI-227 1

AC Active 12 CHV SE 62731 SH 2 C

O/C FE-F CMP Condition Monitoring Program component (H6)

FE-R CMP Safety Injection Loop Inlet Check Valve LK 2Y Monitored by PIA-329

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Safety Injection/Containment Spray SYSTEM NUMBER:

SI Active I Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-SI-231-RV 2

C Active 1

REV SE 62731 SH 2 C

0 RT 1OY-S GV-RR- 01 (2RV231)

(A10)

Safety Injection Tank Relief Valve 2-SI-235 2

AC Active 12 CHV SE 62731 SH 2 C

O/C FE-F CMP Condition Monitoring Program component (2CKVSI-235).

(C9)

FE-R CMP Safety Injection Tank Outlet Check Valve

.LK 2Y 2-SI-237 1

AC Active 12 CHV SE 62731 SH 2 C

O/C FE-F CMP Condition Monitoring Program component (D7)

FE-R CMP Safety Injection Loop Inlet Check Valve LK 2Y Monitored by PIA-339 2-SI-241-RV 2

C Active 1

REV SE 62731 SH 2 C

0 RT I0Y-S GV-RR- 01 (2RV241)

(E8)

Safety Injection Tank Relief Valve 2-SI-245 2

AC Active 12 CHV SE 62731 SH 2 C

O/C FE-F CMP Condition MonitoringProgram component (2CKVSI-245)

(G9)

FE-R CMP Safety Injection Tank Outlet Check Valve LK 2Y 2-SI-247 1

AC Active 12 CHV SE 62731 SH 2 C

O/C FE-F CMP Condition Monitoring Program component (H7)

FE-R CMP Safety Injection Loop Inlet Check Valve LK 2Y Monitored by PIA-349 2-SI-306-CV 2

B Passive 12 GLV AO 62731 SH 2 0

0 PI 2Y (Dll)

LPSI Flow Control Valve 2-SI-313 2

C Active 8

CHV SE 62731 SH 3 C

0 BDT-C CS (B8)

FE-F CS SI-CSJ - 05 Containment Spray Discharge Check Valve 2-SI-314 2

B Active 8

GTV MAN 62731 SH 3 0

O/C FSE 2Y (88)

Containment Spray Pump Discharge Isolation Valve

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Safety Injection/Containment Spray SYSTEM NUMBER:

SI Active /

Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-SI-316 2

AC Active 8

CHV SE 62731 SH 3 C

O/C PE CS Part-stroke only required after D&I (2CKVSI-316)

(D4)

DI CMP Condition Monitoring Program component Containment Spray Supply Header Check Valve FE-R APPJ LJ-C APPJ 2-SI-319 2

B Active 8

GTV MAN 62731 SH 3 0

O/C FSE 2Y Remote Manual Operator (D6)

Shutdown Cooling Heat Exchanger Outlet to Containment Spray Isolation Valve 2-SI-323 2

C Active 8

CHV SE 62731 SH 3 C

0 BDT-C CS (F8)

FE-F CS Sl-CSJ - 05 Containment Spray.Discharge Check Valve 2-SI-324 2

B Active 8

GTV MAN 62731 SH 3 0

O/C FSE 2Y Remote Manual Operator (F8)

Containment Spray Pump Discharge Isolation Valve 2-SI-326 2

AC Active 8

CHV SE 62731 SH 3 C

O/C PE CS Part-stroke only required after D&I (2CKVSl-326)

(G4)

DI CMP Condition Monitoring Program component Containment Spray Supply Header Check Valve FE-R APPJ LJ-C APPJ 2-SI-329 2

B Active 8

GTV MAN 62731 SH 3 0

O/C FSE 2Y Remote Manual Operator (G6)

Shutdown Cooling Heat Exchanger Outlet to Containment Spray Isolation Valve 2-SI-330 2

AC Active 8

CHV SE 62731 SH 3 C

O/C FE-F R

Sl-ROJ - 03 (2CKVSI-330)

(D4)

FE-R APPJ Containment Spray Supply Header Check Valve LJ-C APPJ 2-SI-334 2

C Active 2

CHV SE 62731 SH 3 C

0 FE-F Q

(A9)

FE-R CMP Condition Monitoring Program component Containment Spray Pump Minimum-Flow Return Check Valve 2-SI-340 2

AC Active 8

CHV SE 62731 SH 3 C

O/C FE-F R

SI-ROJ -03 (2CKVSI-340)

(G4)

FE-R APPJ Containment Spray Supply Header Check Valve LJ-C APPJ

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Safety Injection/Containment Spray SYSTEM NUMBER:

SI Active I Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-SI-344 2

C Active 2

CHV SE 62731 SH 3 C

0 FE-F 0

(E9)

FE-R CMP Condition Monitoring Program component Containment Spray Pump Minimum-Flow Return Check Valve 2-SI-399-MOV 2

B Active 2

GTV MO 62731 SH 2 C

O/C DIAG OMNI (2MOV399)

(H6)

FSE 2Y Shutdown Cooling Heat Exchanger Recirculation Stop Valve 2-SI-401 2

C Active 6

CHV SE 62731 SH 1 C

0 BDT-C CMP Condition Monitoring Program component (G8)

FE-F CMP 23 HPSI Pump Suction Check Valve 2-SI-405 2

C Active 3

CHV SE 62731 SH 1 C

O/C FE-F CS SI-ROJ - 02 (G6)

FE-R CS 23 HPSI Pump Discharge Check Valve 2-SI-409-RV 2

C Active

.75 REV SE 62731 SH 1 C

0 RT 1OY-S GV-RR- 01 (2RV409)

(F4)

High Pressure Safety Injection Header Relief Valve 2-SI-410 2

C Active 8

CHV SE 62731 SH 1 C

0 BDT-C CMP Condition Monitoring Program component (E9)

FE-F CMP 21 & 22 HPSI Pump Suction Header Check Valve 2-SI-414 2

C Active 3

CHV SE 62731 SH 1 C

O/C FE-F CS Sl-ROJ - 02 (E6)

FE-R CS 22 HPSI Pump Discharge Check Valve 2-SI-4142-MOV 2

B Active 18 GTV MO 62731 SH 1 0

O/C DIAG OMNI (2MOV4142)

(F10)

FSE 2Y RWT Outlet Valve 2-SI-4143-MOV 2

B Active 18 GTV MO 62731 SH 1 0

O/C DIAG OMNI (2MOV4143)

(El0)

FSE 2Y RWT Outlet Valve 2-SI-4144-MOV 2

B Active 24 GTV MO 62731 SH 3 C

O/C FSE a

(2MOV4144)

(J5)

DIAG OMNI Containment Sump Outlet Isolation Valve

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Safety Injection/Containment Spray SYSTEM NUMBER:

SI Active I Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-SI-4145-MOV 2

B Active (2MOV4145)

Containment Sump Outlet Isolation Valve 24 GTV MO 62731 SH 3 (15)

C O/C FSE DIAG Q

OMN1 2-SI-4146 2

C Active 18 CHV SE 62731 SH 1 C

O/C DI CMP Condition Monitoring Program component (El0)

FE-F CMP RWT Outlet Check Valve FE-R CMP PE CMP Part-stroke only required after D&I 2-SI-4147 2

C Active 18 CHV SE 62731 SH 1 C

O/C DI CMP Condition Monitoring Program component (F9)

FE-F CMP RWT Outlet Check Valve FE-R CMP PE CMP Part-stroke only required after D&I 2-SI-4148 2

C Active 24 CHV SE 62731 SH 3 C

O/C DI CMP Condition Monitoring Program component (J7)

FE-F CMP Containment Sump Check Valve FE-R CMP PE CMP Part-stroke only required after D&I 2-SI-4149 2

C Active 24 CHV SE 62731 SH 3 C

O/C DI CMP Condition Monitoring Program component (17)

FE-F CMP Containment Sump Check Valve FE-R CMP PE CMP Part-stroke only required after D&I 2-SI-4150-CV 2

B Active 8

GLV AO 62731 SH 3 C

0 0

FS Q

(2CV4150)

(C3)

ST-O Q

Containment Spray Discharge Header Isolation Valve PI 2Y 2-SI-4151-CV 2

B Active

• 8 GLV AO 62731 SH 3 C

0 0

FS Q

(2CV4151)

(F3)

ST-O Q

Containment Spray Discharge Header Isolation Valve PI 2Y 2-SI-417-RV 2

C Active 1

REV SE 62731 SH 1 C

0 RT 10Y-S GV-RR- 01 (2RV417)

(D4)

High Pressure Safety Injection Header Relief Valve

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Safety Injection/Containment Spray SYSTEM NUMBER:

SI Active /

Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-SI-422 2

C Active 2

CHV SE 62731 SH 1 C

O/C FE-F Q

(E8)

FE-R CMP Condition Monitoring Program component 22 HPSI Pump Minimum-Flow Return Check Valve 2-SI-424 2

C Active 2

CHV SE 62731 SH 1 C

O/C FE-F Q

(C8)

FE-R CMP Condition Monitoring Program component 21 HPSI Pump Minimum-Flow Return Check Valve 2-SI-426 2

C Active 2

CHV SE 62731 SH 1 C

O/C FE-F Q

(F8)

FE-R CMP Condition Monitoring Program component 23 HPSI Pump Minimum-Flow Return Check Valve 2-SI-427 2

C Active 6

CHV SE 62731 SH 1 C

O/C FE-F CS SI-ROJ - 02 (D6)

FE-R CS 21 HPSI Pump Discharge Check Valve 2-SI-430-RV 2

C Active

.75 REV SE 62731 SH 3 C

0 RT lay-S GV-RR - 01 (G8)

Shutdown Cooling Recirculation to High Pressure Safety Injection Pump Relief Valve 2-SI-431-RV 2

C Active

.75 REV SE 62731 SH 3 C

0 RT 10y-S GV-RR - 01 (C8)

Shutdown Cooling Recirculation to High Pressure Safety Injection Pump Relief Valve 2-SI-432 2

B Active 14 GTV MAN 62731 SH 1 0

O/C FSE 2Y (H8)

LPSI Pump Normal Suction Isolation Valve 2-SI-434 2

C Active 10 CHV SE 62731 SH 1 C

O/C FE-F CS Sl-CSJ -01 (H5)

FE-R CS LPSI Pump Discharge Check Valve 2-SI-439-RV 2

C Active

.75 REV SE 62731 SH 2 C

0 RT 10Y-S GV-RR - 01 (G10)

Low Pressure Safety Injection Header Relief Valve 2-SI-440 2

B Active 14 GTV MAN 62731 SH 1 C

O/C FSE 2Y (H7)

LPSI Pump Shutdown Cooling Suction Isolation Valves

Constellation, Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Safety Injection/Containment Spray SYSTEM NUMBER:

SI Active /

Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-SI-441 2

B Active 14 GTV MAN 62731 SH 1 C

O/C FSE 2Y (C7)

LPSI Pump Shutdown Cooling Suction Isolation Valve 2-SI-444 2

B Active 14 GTV MAN 62731 SH 1 0

O/C FSE 2Y (C8)

LPSI Pump Normal Suction Isolation Valve 2-SI-446 2

C Active 10 CHV SE 62731 SH 1 C

O/C FE-F CS SI-CSJ - 01 (C5)

FE-R CS LPSI Pump Discharge Check Valve 2-SI-446-RV 2

C Active 2.5 REV SE 62731 SH 2 C

0 RT 1OY-S GV-RR - 01 (B6)

Safety Injection Leak-Off Relief Valve 2-SI-448 2

C Active 2

CHV SE 62731 SH 1 C

O/C FE-F 0

(B8)

FE-R CMP Condition Monitoring Program component LPSI Pump Minimum-Flow Return Check Valve 2-SI-451 2

C Active 2

CHV SE 62731 SH1 C

O/C FE-F Q

(G8)

FE-R CMP Condition Monitoring Program component LPSI Pump Minimum-Flow Return Check Valve 2-SI-452 2

B Active 10 GTV MAN 62731 SH 3 C

O/C FSE 2Y Remote Manual Operator (C8)

Shutdown Cooling Heat Exchanger Inlet Cross-Connect Valve 2-SI-453 2

B Active 10 GTV MAN 62731 SH 3 C

O/C FSE 2Y Remote Manual Operator (E7)

Shutdown Cooling Heat Exchanger Inlet Cross-Connect Valve 2-SI-455 2

A Passive 2

GLV MAN 62731 SH 2 C

C LJ-C APPJ (2HVSI-455)

(A8)

SI Leak-off Return Header Back-up Isolation Valve 2-SI-456 2

B Active 8

GTV MAN 62731 SH 3 C

O/C FSE 2Y Remote Manual Operator (E6) 21 & 22 Shutdown Cooling Heat Exchanger Outlet to LPSI Header Isolation Valve

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Safety Injection/Containment Spray SYSTEM NUMBER:

SI Active I Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-SI-457 2

8 Active 8

GTV MAN 62731 SH 3 C

O/C FSE 2Y Remote Manual Operator (G7) 21 & 22 Shutdown Cooling Heat Exchanger Outlet to LPSI Header Isolation Valve 2-SI-459 2

A Passive 6

GTV MAN 62731 SH 1 C

C LK 2Y (85)

SI Tank Leakage to RWT Isolation Valve 2-SI-463 2

A Passive 2

GTV MAN 62731 SH 2 C

C LJ-C APPJ (2HVSI-463)

(A8)

SI Leak-off to RWT Isolation Valve 2-SI-468-RV 2

C Active 1.5 REV SE 62731 SH 2 C

0 RT 1 OY-S GV-RR - 01 (2RV468)

(18)

Shutdown Cooling Return Header Relief Valve 2-SI-469-RV 2

C Active

.75 REV SE 62731 SH 2 C

0 RT 10Y-S GV-RR - 01 (2RV469)

(16)

Shutdown Cooling Isolation Valve Relief Valve 2-SI-491 2

C Active 1

CHV SE 62731 SH 2 O/C C

BDT-O CS (85)

FE-R CS SI-CSJ - 04 SI Tank Nitrogen Inlet Check Valve 2-SI-492 2

C Active 1

CHV SE 62731 SH 2 O/C C

BDT-O CS (F5)

FE-R CS SI-CSJ - 04 SI Tank Nitrogen Inlet Check Valve 2-SI-493 2

C Active 1

CHV SE 62731 SH 2 O/C C

1DT-O CS (B10)

FE-R CS SI-CSJ - 04 SI Tank Nitrogen Inlet Check Valve 2-SI-494 2

C Active 1

CHV SE 62731 SH 2 O/C C

B1DT-O CS (F7)

FE-R CS SI-CSJ - 04 SI Tank Nitrogen Inlet Check Valve 2-SI-611-CV 2

B Passive 1

GTV AO 62731 SH 2 C

C C

PI 2Y (03)

SI Tank Fill Valve

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Safety Injection/Containment Spray SYSTEM NUMBER:

SI Active /

Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-SI-612-CV N

A Active 1

GTV AO 62731 SH 2 O/C C

C FS a

(2CV612)

(B5)

ST-C Q

SI Tank Nitrogen Supply Valve LJ-C APPJ PI 2Y 2-SI-613-CV 2

B Passive 1

GLV AO 62731 SH 2 C

C PI 2Y (83)

SI Tank Vent Valve 2-SI-614-MOV 2

B Passive 12 GLV MO 62731 SH 2 0

0 PI 2Y (2MOV614)

(D4)

SI Tank Outlet Isolation Valve 2-SI-615-MOV 2

B Active 6

GLV MO 62731 SH 2 C

O/C DIAG OMNI (2MOV615)

(D3)

FSE 2Y LPSI Header Isolation Valve 2-SI-616-MOV 2

B Active 2

GLV MO 62731 SH 1 C

0 FSE Q

(2MOV616)

(D3)

DIAG OMNI Main HPSI Header Isolation Valve 2-SI-617-MOV 2

B Active 2

GLV MO 62731 SH 1 C

O/C FSE Q

(2MOV617)

(C3)

DIAG OMNI Auxiliary HPSI Header Isolation Valve 2-SI-618-CV 2

B Active 1

GLV AO 62731 SH 2 O/C C

C FS Q

(2CV618)

(C5)

ST-C Q

SI Check Valve Leakage Control Valve PI 2Y 2-SI-621-CV 2

B Passive 1

GTV AO 62731 SH 2 C

C C

PI 2Y (G3)

SI Tank Fill Valve 2-SI-622-CV N

A Active 1

GTV AO 62731 SH 2 O/C C

C FS Q

(2CV622)

(F5)

ST-C Q

SI Tank Nitrogen Supply Valve LJ-C APPJ PI 2Y

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME: Safety Injection/Containment Spray SYSTEM NUMBER:

SI Active I Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-SI-623-CV 2

B Passive 1

GLV AO 62731 SH 2 C

C PI 2Y (F3)

SI Tank Vent Valve 2-SI-624-MOV 2

B Passive 12 GLV MO 62731 SH 2 0

0 PI 2Y (2MOV624)

(H4)

SI Tank Outlet Isolation Valve 2-SI-625-MOV 2

B Active 6

GLV MO 62731 SH 2 C

O/C DIAG OMN1 (2MOV625)

(H3)

FSE 2Y LPSI Header Isolation Valve 2-SI-626-MOV 2

B Active 2

GLV MO 62731 SH 1 C

0 FSE 0

(2MOV626)

(E3)

DIAG OMN1 Main HPSI Header Isolation Valve 2-SI-627-MOV 2

B Active 2

GLV MO 62731 SH 1 C

O/C FSE 0

(2MOV627)

(E3)

DIAG OMN1 Auxiliary HPSI Header Isolation Valve 2-SI-628-CV 2

B Active 1

GLV AO 62731 SH 2 O/C C

C FS Q

(2CV628)

(G5)

ST-C Q

SI Check Valve Leakage Control Valve PI 2Y 2-SI-6302-RV 2

C Active

.75 REV SE 62731 SH 1 C

0 RT 10Y-S GV-RR- 01 (C6)

Auxiliary High Pressure Safety Injection Pump 21 Discharge Header Relief Valve 2-SI-631-CV 2

B Passive 1

GTV AO 62731 SH 2 C

C C

PI 2Y (D9)

SI Tank Fill Valve 2-SI-632-CV N

A Active 1

GTV AO 62731 SH 2 O/C C

C FS Q

(2CV632)

(B111)

ST-C Q

SI Tank Nitrogen Supply Valve U-C APPJ PI 2Y

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Safety Injection/Containment Spray SYSTEM NUMBER:

SI Active I Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-SI-633-CV 2

B Passive 1

GLV AO 62731 SH 2 C

C PI 2Y (B8)

SI Tank Vent Valve 2-SI-634-MOV 2

B Passive 12 GLV MO 62731 SH 2 0

0 P1 2Y (2MOV634)

(D8)

SI Tank Outlet Isolation Valve 2-SI-635-MOV 2

B Active 6

GLV MO 62731 SH 2 C

O/C DIAG OMN1 (2MOV635)

(D9)

FSE 2Y LPSI Header Isolation Valve 2-SI-636-MOV 2

B Active 2

GLV MO 62731 SH 1 C

0 FSE 0

(2MOV636)

(F3)

DIAG OMN1 Main HPSI Header Isolation Valve 2-SI-637-MOV 2

B Active 2

GLV MO 62731 SH 1 C

O/C FSE Q

(2MOV637)

(F3)

DIAG OMN1 Auxiliary HPSI Header Isolation Valve 2-SI-638-CV 2

B Active 1

GLV AO 62731 SH 2 O/C C

C FS Q

(2CV638)

(C7)

ST-C a

SI Check Valve Leakage Control Valve P1 2Y 2-SI-641-CV 2

B Passive 1

GTV AO 62731 SH 2 C

C C

PI 2Y (G9)

SI Tank Fill Valve 2-SI-642-CV N

A Active I

GTV AO 62731 SH 2 O/C C

C FS 0

(2CV642)

(F7)

ST-C Q

SI Tank Nitrogen Supply Valve LJ-C APPJ PI 2Y 2-Sl-643-CV 2

B Passive 1

GLV AO 62731 SH 2 C

C P1 2Y (F10)

SI Tank Vent Valve

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Safety Injection/Containment Spray SYSTEM NUMBER:

SI Active /

Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-SI-644-MOV 2

S Passive 12 GLV MO 62731 SH 2 0

0 P1 2Y (2MOV644)

(H8)

SI Tank Outlet Isolation Valve 2-SI-645-MOV 2

B Active 6

GLV MO 62731 SH 2 C

O/C DIAG OMNI (2MOV645)

(H9)

FSE 2Y LPSI Header Isolation Valve 2-SI-646-MOV 2

B Active 2

GLV MO 62731 SH 1 C

0 FSE

.0 (2MOV646)

(H3)

DIAG OMNI Main HPSI Header Isolation Valve 2-SI-647-MOV 2

B Active 2

GLV MO 62731 SH 1 C

O/C FSE Q

(2MOV647)

(G3)

DIAG OMNI Auxiliary HPSI Header Isolation Valve 2-SI-648-CV 2

B Active 1

GLV AO 62731 SH 2 O/C C

C FS Q

(2CV648)

(G7)

ST-C

/

0 SI Check Valve Leakage Control Valve PI 2Y 2-SI-651-MOV 1

A Active 12 GTV MO 62731 SH 2 C

O/C DIAG OMNI (2MOV651)

(17)

FSE CS Shutdown Cooling Return Header Isolation Valve LJ-C APPJ 2-SI-652-MOV 1

A Active 12 GTV MO 62731 SH 2 C

O/C DIAG OMNI (2MOV652)

(15)

FSE CS Shutdown Cooling Return Header Isolation Valve LJ-C APPJ 2-SI-653-MOV 2

B Active 4

GLV MO 62731 SH 1 C

O/C DIAG OMN1 (2MOV653)

(F5)

FSE 2Y HPSI Header Cross-Connect Valve 2-SI-654-MOV 2

B Passive 6

GTV MO 62731 SH 1 0

0 PI 2Y (F5)

HPSI Main and Auxiliary Header Isolation Valve

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Safety Injection/Containment Spray SYSTEM NUMBER:

SI Active I Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-SI-655-MOV 2

B Active 4

GLV MO 62731 SH 1 0

O/C DIAG OMN1 (2MOV655)

(E5)

FSE 2Y HPSI Header Cross-Connect Valve 2-SI-656-MOV 2

B Passive 6

GTV MO 62731 SH 1 0

0 PI 2Y (D5)

HPSI Main and Auxiliary Header Isolation Valve 2-SI-657-CV 2

B Active 12 GLV AO 62731 SH 3 C

0 C

ST-O Q

(2CV657)

(E4)

PI 2Y Shutdown Cooling Temperature/Flow Control Valve 2-SI-658-MOV 2

B Active 12 GTV MO 62731 SH 3 C

0 DIAG OMN1 (2MOV658)

(E7)

FSE 2Y LPSI Inlet to Shutdown Cooling Heat Exchanger 2-SI-659-MOV 2

A Active 4

GTV MO 62731 SH 1 0

O/C DIAG OMN1 (2MOV659)

(89)

FSE CS SI Pump Minimum-Flow Return to RWT Isolation Valve LK 2Y, 2-SI-660-MOV 2

A Active 4

GTV MO 62731 SH 1 0

O/C DIAG OMN1 (2MOV660)

(C9)

FSE CS SI Pump Minimum-Flow Return to RWT Isolation Valve LK 2Y 2-SI-661-CV 2

B Active I

GLV AO 62731 SH 2 O/C C

C FS a

(2CV661)

(87)

ST-C Q

SI Tank Drain/Test Line Leak-off to RCDT PI 2Y 2-SI-662-MOV 2

B Passive 4

GTV MO 62731 SH 3 C

C PI 2Y (G9)

LPSI to HPSI pump suction isolation valve 2-SI-663-MOV 2

B Passive 4

GTV MO 62731 SH 3 C

C PI 2Y (D9)

LPSI to HPSI pump suction isolation valve

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Service Water SYSTEM NUMBER:

SRW Active /

Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-SRW-117 3

B Active 14 BFV MAN 62706 SH 2 O/C O/C FSE 2Y (G2)

Service Water Pump 23 Suction Alignment Valve 2-SRW-118 3

B Active 14 BFV MAN 62706 SH 2 O/C O/C FSE 2Y (G2)

Service Water Pump 23 Suction Alignment Valve 2-SRW-119 3

B Active 14 BFV MAN 62706 SH 2 O/C O/C FSE 2Y (G2)

Service Water Pump 23 Suction Alignment Valve 2-SRW-120 3

B Active 14 BFV MAN 62706 SH 2 O/C O/C FSE 2Y (G2)

Service Water Pump 23 Suction Alignment Valve 2-SRW-121 3

B Active 14 BFV MAN 62706 SH 2 O/C O/C FSE 2Y (G3)

Service Water Pump 23 Discharge Alignment Valve 2-SRW-122 3

B Active 14 BFV MAN 62706 SH 2 O/C O/C FSE 2Y (G3)

Service Water Pump 23 Discharge Alignment Valve 2-SRW-123 3

B Active 14 BFV MAN 62706 SH 2 O/C O/C FSE 2Y (G3)

Service Water Pump 23 Discharge Alignment Valve 2-SRW-124 3

B Active 14 BFV MAN 62706 SH 2 O/C 0/C FSE 2Y (G3)

Service Water Pump 23 Discharge Alignment Valve 2-SRW-1575-RV 3

C Active 1

REV SE 62706 SH 2 C

0 aT 1 Y-S GV-RR - 01 (BI) 21A Service Water Heat Exchanger Relief Valve 2-SRW-1576-RV 3

C Active 1

REV SE 62706 SH 2 C

0 RT 10Y-S GV-RR - 01 (B3) 21 B Service Water Heat Exchanger Relief Valve

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Service Water SYSTEM NUMBER:

SRW Active I Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-SRW-1577-RV 3

C Active 1

REV SE 62706 SH 2 C

0 RT 10Y-S GV-RR - 01 (B4) 22A Service Water Heat Exchanger Relief Valve 2-SRW-1578-RV 3

C Active 1

REV SE 62706 SH 2 C

0 RT I0Y-S GV-RR - 01 (B5) 22B Service Water Heat Exchanger Relief Valve 2-SRW-1581-CV 3

B Active 8

BFV AO 62706 SH 2 0

T/O 0

FS 0

(2CV1581)

(F5)

ST-C Q

SRW Supply to Containment Cooling Units Isolation Valve ST-0 Q

PI 2Y 2-SRW-1 582-CV 3

B Active 8

BFV AO 62706 SH 2 C

0 0

FS Q

(2CV1582)

(E7)

ST-O Q

Containment Cooling Unit SRW Emergency Discharge Control Valve PI 2Y 2-SRW-1582-RV 3

C Active

.75 REV SE 62706 SH 2 C

0 RT 10Y-S GV-RR - 01 (E6) 21 Containment Air Cooler Service Water Discharge/Return Relief Valve 2-SRW-1584-CV 3

B Active 8

BFV AO 62706 SH 2 0

T/O 0

FS Q

(2CV1584)

(F8)

ST-C Q

SRW Supply to Containment Cooling Units Isolation Valve ST-0 Q

PI 2Y 2-SRW-1585-CV 3

B Active 8

BFV AO 62706 SH 2 C

0 0

FS Q

(2CV1 585)

(E12)

ST-0 Q

Containment Cooling Unit SRW Emergency Discharge Control Valve PI 2Y 2-SRW-1585-RV 3

C Active

.75 REV SE 62706 SH 2 C

0 RT 10Y-S GV-RR - 01 (D1l1) 22 Containment Air Cooler Service Water Discharge/Return Relief Valve 2-SRW-1 587-CV 3

B Active 6

BFV AO 60727 SH 3 C

T (12)

Diesel Cooler 28, 18, 2A SRW Inlet Control Valve

Constellation Energy (CCNPP Unit 2)1IST Program VALVE TABLE SYSTEM NAME:

Service Water Active/

Size Valve Ac Valve ID / Name Class Cat.

Passive (in.)

Type I

2-SRW-1 587-RV 3

C Active 1.5 REV 1 B, 2A, & 28 Diesel Generator Service Water Supply/Inlet Relief Valve SYSTEM NUMBER:

SRW tuator gype SE Drawing

& Coord 60727 SH 3 (14)

Normal C

Position Safety Fail-Safe 0

Required Test RT Frequency 10y-S Code Dev.

GV-RR -01 Remarks 2-SRW-1588-CV 3

B Active 6

BFV AO 60727 SH 1 C

T 0

ST-0 SKID (12)

Diesel Cooler 28 SRW Inlet Control Valve 2-SRW-1588-RV 3

C Active 1.5 REV SE 60727 SH 1 C

0 RT 10Y-S GV-RR - 01 (14) 2B Diesel Generator Service Water Supply/Inlet Relief Valve 2-SRW-1589-CV 3

B Active 8

BFV AO 62706 SH 2 0

T/O 0

FS 0

(2CV1589)

(14).

ST-C Q

SRW Supply to Containment Cooling Units Isolation Valve ST-0 Q

PI 2Y 2-SRW-1590-CV 3

8 Active 8

BFV AO 62706 SH 2 C

0 0

FS Q

(2CV1590).

(H6)

ST-0 0

Containment Cooling Unit SRW Emergency Discharge Control Valve PI 2Y 2-SRW-1590-RV 3

C Active

.75 REV SE 62706 SH-2 C

0

- RT 10Y-S GV-RR - 01 (H5) 23 Containment Air Cooler Service Water Discharge/Return Relief Valve 2-SRW-1592-CV 3

B Active 8

BFV AO 62706 SH 2 0

T/O 0

FS Q

(2CV1592)

(G8)

ST-C 0

SRW Supply to Containment Cooling Units Isolation Valve ST-O 0

PI 2Y 2-SRW-1593-CV 3

B Active 8

8FV AO 62706 SH 2 C

0 0

FS 0

(2CV1 593)

(G1i1)

ST-0 0

Containment Cooling Unit SRW Emergency Discharge Control Valve PI 2Y 2-SRW-1593-RV 3

C Active

.75 REV SE 62706 SH 2 C

0 RT laY-S GV-RR - 01 (H1i0) 24 Containment Air Cooler Service Water Discharge/Return Relief Valve

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Service Water SYSTEM NUMBER:

SRW Active /

Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-SRW-1598-CV 3

8 Active 8

BFV AO 62706 SH 2 0

C C

FS 0

(2CV1598)

(C8)

ST-C Q

SFP Cooler SRW Inlet & Discharge Control Valve PI 2Y 2-SRW-1 598-RV 3

C Active

.50 REV SE 62706 SH 2 C

0 RT 1oy-S GV-RR - 01 (C8) 12 Spent Fuel Pool Cooler Service Water Relief Valve 2-SRW-1599-CV 3

B Active 8

BFV AO 62706 SH 2 0

C C

FS 0

(2CV1599)

(D9)

ST-C Q

SFP Cooler SRW Inlet & Discharge Control Valves PI 2Y 2-SRW-1600-CV 3

B Active 14 BFV AO 62706 SH 2 0

C C

FS CS (2CV1600)

(B11)

ST-C CS SRW-CSJ - 02 Turbine Building SRW Isolation Valve PI 2Y 2-SRW-1 637-CV 3

B Active 10 BFV AO 62706 SH 2 0

C C

FS CS (2CV1637)

(Cl11)

ST-C CS SRW-CSJ - 02 Turbine Building SRW Isolation Valve PI 2Y 2-SRW-1638-CV N

B Active 14 BFV AO 62706 SH 2 0

C C

FS CS (2CV1638)

(812)

ST-C CS SRW-CSJ - 02 Turbine Building SRW Isolation Valve PI 2Y 2-SRW-1639-CV N

B Active 10 BFV AO 62706 SH 2 0

C C

FS CS (2CV1639)

(C12)

ST-C CS SRW-CSJ - 02 Turbine Building SRW Isolation Valve P1 2Y 2-SRW-1640-CV 3

B Active 10 BFV AO 62706 SH 2 0

C C

FS Q

(2CV1640)

(Al 0)

ST-C Q

Blowdown Recovery Heat Exchanger SRW Isolation Valve PI 2Y 2-SRW-314 3

C Active 14 CHV SE 62706 SH 2 0/C O/C FE-F Q

(E3)

FE-R Q

Service Water Pump Discharge Check Valve

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Service Water SYSTEM NUMBER:

SRW Active /

Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-SRW-315 3

C Active 14 CHV SE 62706 SH 2 O/C O/C FE-F 0

(F3)

FE-R Q

Service Water Pump Discharge Check Valve 2-SRW-316 3

C Active 14 CHV SE 62706 SH 2 O/C O/C FE-F Q

(H3)

FE-R 0

Service Water Pump Discharge Check Valve 2-SRW-317 3

C Active 8

CHV SE 62706 SH 2 O/C 0

BDT-C CMP Condition Monitoring Program component (G5)

FE-F CMP Containment Cooling Unit Inlet Check Valve 2-SRW-318 3

C Active 8

CHV SE 62706 SH 2 O/C 0

BDT-C CMP Condition Monitoring Program component (El0)

FE-F CMP Containment Cooling Unit Inlet Check Valve 2-SRW-319 3

C Active 8

CHV SE 62706 SH 2 O/C 0

BDT-C CMP Condition Monitoring Program component (J5)

FE-F CMP Containment Cooling Unit Inlet Check Valve 2-SRW-320 3

C Active 8

CHV SE 62706 SH 2 O/C 0

BDT-C CMP Condition Monitoring Program component (H9)

FE-F CMP Containment Cooling Unit Inlet Check Valve 2-SRW-323 3

C Active 18 CHV SE 62706 SH 2 0

C BDT-O CS Normal operation (Cl)

FE-R CS SRW-CSJ - 01 Turbine Building SRW Return Header Check Valve 2-SRW-324 3

C Active 18 CHV SE 62706 SH 2 0

C BDT-O CS Normal operation (D1)

FE-R CS SRW-CSJ - 01 Turbine Building SRW Return Header Check Valve 2-SRW-325 3

C Active 18 CHV SE 62706 SH 2 0

C BDT-O CS Normal operation (D1)

FE-R CS SRW-CSJ - 01 Turbine Building SRW Return Header Check Valve 2-SRW-4084-RV 3

C Active

.75 REV SE 62749 SH -

C 0

RT 1 OY-S GV-RR - 01 (H3) 22 Steam Generator Blowdown Heat Exchanger Relief Valve

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Saltwater SYSTEM NUMBER:

SW Active /

Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-SW-1 03 3

C Active 24 CHV SE 62708 SH 2 O/C O/C FE-F 0

(C6)

FE-R Q

21 Saltwater Pump Discharge Check Valve 2-SW-1 07 3

C Active 24 CHV SE 62708 SH 2 O/C O/C FE-F Q

(C8)

FE-R Q

22 Saltwater Pump Discharge Check Valve 2-SW-111 3

C Active 24 CHV SE 62708 SH 2 O/C O/C FE-F 0

(Cll)

FE-R Q

23 Saltwater Pump Discharge Check Valve 2-SW-112 3

B Active 30 BFV MAN 62708 SH 2 O/C 0

FSE 2Y (C6)

SW Pump 23 Discharge to 21 SW Header Back-Up Isolation Valve 2-SW-113 3

B Active 30 BFV MAN 62708 SH 2 O/C 0

FSE 2Y (C6)

SW Pump 23 Discharge to 21 SW Header Isolation Valve 2-SW-114 3

B Active 30 BFV MAN 62708 SH 2 O/C 0

FSE 2Y (C6)

SW Pump 23 Discharge to 22 SW Header Back-Up Isolation Valve 2-SW-115 3

B Active 30 BFV MAN 62708 SH 2 O/C 0

FSE 2Y (C6)

SW Pump 23 Discharge to 22 SW Header Isolation Valve 2-SW-5148A-CV 3

B Active 6

BLV AO 62708 SH 3 C

O/C ST-C SKID (2CV5148A)

(86)

ST-0 SKID SRW Heat Exchanger Saltwater Strainer Flushing Valve 2-SW-5148-CV 3

B Active 16 BFV AO 62708 SH 3 0

0/C ST-C SKID (2CV5148)

(B5)

ST-0 SKID SRW Heat Exchanger Saltwater Strainer Diverter Valve 2-SW-5149-CV 3

B Active 24 BFV AO 62708 SH 2 C

O/C C

ST-0 CS SW-CSJ - 01 (2CV5149)

Emergency Saltwater Discharge to Bay Valve (B8)

PI 2Y

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Saltwater SYSTEM NUMBER:

SW Active /

Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-SW-5150-CV 3

B Active 24 BFV AO 62708 SH 3 0

O/C ST-C Q

(2CV5150)

(C3)

PI 2Y SRW Heat Exchangers Saltwater Inlet Valve 2-SW-5151 A-CV 3

B Active 6

BLV AO 62708 SH 3 C

O/C ST-C SKID (2CV5151 A)

(D6)

ST-O SKID SRW Heat Exchanger Saltwater Strainer Flushing Valve 2-SW-5151-CV 3

B

. Active 16 BFV AO 62708 SH 3 0

0/C ST-C SKID (2CV5151)

(05)

ST-O SKID SRW Heat Exchanger Saltwater Strainer Diverter Valve 2-SW-5152-CV 3

B Passive 24 BFV AO 62708 SH 3 0

0 PI 2Y (13)

SRW Heat Exchangers Saltwater Inlet Valve 2-SW-5153-CV 3

B Active 24 BFV AO 62708 SH 3 0

O/C ST-C Q

(2CV5153)

(El 1)

PI 2Y SRW Heat Exchangers Saltwater Back-Up Outlet Valve 2-SW-5154-CV 3

B Active 18 BFV AO 62708 SH 3 O/C O/C FS Q

(2CV5154)

(B2)

ST-C Q

SRW Heat Exchangers Saltwater Bypass Valve PI 2Y 2-SW-5155-CV 3

B Active 30 BFV AO 62708 SH 3 C

O/C ST-O CS SW-CSJ - 02 (2CV5155)

(El0)

PI 2Y SRW Heat Exchangers Saltwater Auxiliary Outlet/Back-Up Outlet Valve 2-SW-5156-CV 3

B Active 30 BFV AO 62708 SH 3 C

O/C ST-O CS SW-CSJ - 02 (2CV5156)

(E9)

PI 2Y SRW Heat Exchangers Saltwater Auxiliary Outlet/Back-Up Outlet Valve 2-SW-5157-CV 3

B Active 18 BFV AO 62708 SH 3 O/C O/C FS Q

(2CV5157)

(J8)

ST-C Q

SRW Heat Exchangers Saltwater Bypass Valve P1 2Y 2-SW-51 58A-CV 3

B Active 6

BLV AO 62708 SH 3 C

O/C ST-C SKID (2CV5158A)

(F6)

ST-O SKID SRW Heat Exchanger Saltwater Strainer Flushing Valve

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Saltwater SYSTEM NUMBER:

SW Active I Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-SW-5158-CV 3

B Active 16 BFV AO 62708 SH 3 C

O/C ST-C SKID (2CV5158)

(F5)

ST-O SKID SRW Heat Exchanger S9ltwater Strainer Diverter Valve 2-SW-5159A-CV 3

B Active 6

BLV AO 62708 SH 3 C

O/C ST-C SKID (2CV5159A)

(H6)

ST-O SKID SRW Heat Exchanger Saltwater Strainer Flushing Valve 2-SW-5159-CV 3

B Active 16 BFV AO 62708 SH 3 0

O/C ST-C SKID (2CV5159)

(H5)

ST-O SKID SRW Heat Exchanger Saltwater Strainer Diverter Valve 2-SW-5160-CV 3

B Active 24 BFV AO 62708 SH 2 C

O/C ST-C Q

(2CV5160)

(E5)

PI 2Y 21 CC Heat Exchangers Saltwater Inlet Valve 2-SW-5162-CV 3

B Passive 24 BFV AO 62708 SH 2 C

C PI 2Y (2CV5162)

(G4) 22 CC Heat Exchanger Saltwater Inlet Valve 2-SW-5163-CV 3

B Active 12 BFV AO 62708 SH 2 C

O/C ST-C a

(2CV5163)

(16)

PI 2Y 22 CC Heat Exchangers Saltwater Normal Back-Up Outlet Valve 2-SW-5165-CV 3

B Active 18 BFV AO 62708 SH 2 C

O/C ST-O CS SW-CSJ -02 (2CV5165)

(G6)

PI 2Y 22 CC Heat Exchangers Saltwater Auxiliary Outlet/Back-Up Outlet Valve 2-SW-5166-CV 3

B Active 18 BFV AO 62708 SH 2 C

O/C ST-O CS SW-CSJ - 02 (2CV5166)

(F6)

PI 2Y 22 CC Heat Exchangers Saltwater Auxiliary Outlet/Back-Up Outlet Valve 2-SW-5170-CV 3

B Active 8

BFV AO 62708 SH 2 C

O/C FS C

(2CV5170)

(F3)

ST-C Q

21 ECCS Pump Room Air Cooler Saltwater Inlet Valve ST-C C

PI 2Y

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Saltwater SYSTEM NUMBER:

SW Active /

Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-SW-5171-CV 3

B Active 8

BFV AO 62708 SH 2 C

O/C FS 0

(2CV5171)

(G3)

ST-C 0

21 ECCS Pump Room Air Cooler Outlet Valve ST-0 a

PI 2Y 2-SW-5173-CV 3

B Active 8

BFV AO 62708 SH 2 C

0 FS Q

(2CV5173)

(E3)

ST-O Q

22 ECCS Pump Room Air Cooler Saltwater Inlet Valve PI 2Y 2-SW-5174-CV 3

B Active 8

BFV AO 62708 SH 2 0

O/C ST-C Q

(2CV5174).

(H2)

PI 2Y 22 ECCS Pump Room Air Cooler Saltwater Normal/ Normal Back-Up Outlet Valve 2-SW-5175-CV 3

B Active 8

BFV AO 62708 SH 2 0

O/C ST-C Q

(2CV5175)

(H2)

PI 2Y 22 ECCS Pump Room Air Cooler Saltwater Normal/ Normal Back-Up Outlet Valve 2-SW-5177-CV 3

B Active 1 8 BFV AO 62708 SH 2 C

O/C ST-O CS SW-CSJ - 02 (2CV5177)

(G2)

PI 2Y 22 ECCS Pump Room Air Coolers Saltwater Auxiliary Outlet/Back-Up Outlet Valve 2-SW-5178-CV 3

B Active 8

BFV AO 62708 SH 2 C

O/C ST-O CS SW-CSJ - 02 (2CV5178)

(F2)

PI 2Y 22 ECCS Pump Room Air Coolers Saltwater Auxiliary Outlet/Back-Up Outlet Valve 2-SW-5205-RV 3

C Active

.75 REV SE 62708 SH 2 C

0 RT IOY-S GV-RR - 01 (2RV5205)

(E2)

ECCS Pump Room Air Coolers Saltwater Relief Valve 2-SW-5206-CV 3

B Active 12 BFV AO 62708 SH 2 O/C O/C 0

FS Q

(2CV5206)

(16)

ST-C Q

21 CC Heat Exchanger Saltwater Normal Outlet Valve ST-O Q

PI 2Y 2-SW-5206-RV 3

C Active 1.5 REV SE 62708 SH 2 C

0 RT laY-S GV-RR - 01 (2RV5206)

(F5)

CC Heat Exchangers Saltwater Relief Valve

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Saltwater SYSTEM NUMBER:

SW Active /

Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-SW-5207-RV 3

C Active

.75 REV SE 62708 SH 2 C

0 RT 10Y-S GV-RR - 01 (2RV5207)

(D2)

ECCS Pump Room Air Coolers Saltwater Relief Valve 2-SW-5208-CV 3

B Active 12 BFV AO 62708 SH 2 O/C O/C 0

ES 0

(2CV5208)

(14)

ST-C Q

22 CC Heat Exchanger Saltwater Normal Outlet Valve ST-0 Q

PI 2Y 2-SW-5208-RV 3

C Active 1.5 REV SE 62708 SH 2 C

0 RT 1 OY-S GV-RR - 01 (2RV5208)

(H5)

CC Heat Exchangers Saltwater Relief Valve 2-SW-5209-CV 3

B Active 18 BFV AO 62708 SH 3 OfT OfT 0

FS Q

(2CV5209)

(B110)

ST-C Q

SRW Heat Exchanger Saltwater Outlet Valve ST-O 0

PI 2Y 2-SW-5209-RV 3

C Active 1.5 REV SE 62708 SH 3 C

0 RT 1oY-S GV-RR - 01 (B6)

SRW Heat Exchangers Inlet Relief Valve 2-SW-5210-CV 3

8 Active 18 BFV AO 62708 SH 3 OfT OfT 0

FS Q

(2CV521 0)

(D10)

ST-C Q

SRW Heat Exchanger Saltwater Outlet Valve ST-0 Q

PI 2Y 2-SW-5210-RV 3

C Active 1.5 REV SE 62708 SH 3 C

0 RT 10Y-S GV-RR - 01 (C6)

SRW Heat Exchangers Inlet Relief Valve 2-SW-5211-CV 3

B Active 18 BFV AO 62708 SH 3 OfT OfT 0

FS Q

(2CV521 1)

(G10)

ST-C Q

SRW Heat Exchanger Saltwater Outlet Valve ST-O Q

PI 2Y

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Saltwater SYSTEM NUMBER:

SW Active /

Size Valve Actuator Drawing Position Required Code Valve ID ! Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-SW-5211.RV 3

C Active 1.5 REV SE 62708 SH 3 C

0 RT 10Y-S GV-RR -01 (F7)

SRW Heat Exchangers Inlet Relief Valve 2-SW-5212-CV 3

B Active 18 BFV AO 62708 SH 3 O/T O/T 0

FS Q

(2CV5212)

(H10)

ST-C Q

SRW Heat Exchanger Saltwater Outlet Valve ST-0 Q

PI 2Y 2-SW-5212-RV 3

C Active 1.5 REV SE 62708 SH 3 C

0 RT 1OY-S GV-RR - 01 (H6)

SRW Heat Exchangers Inlet Relief Valve

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Various SYSTEM NUMBER: arious Active I Size Valve Actuator Drawing Position Required Code Valve ID / Name

-Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks Various NA ST-O GA-RR - 01 ST-O GV-RR - 02 ST-O GV-RR - 03

Constellation Energy (CCNPP Unit 2) IST Program VALVE TABLE SYSTEM NAME:

Waste Gas SYSTEM NUMBER:

WGS Active /

Size Valve Actuator Drawing Position Required Code Valve ID / Name Class Cat.

Passive (in.)

Type Type

& Coord Normal Safety Fail-Safe Test Frequency Dev.

Remarks 2-WGS-2180-CV 2

A Active 2

GTV AO 60735 SH 1 O/C C

C FS 0

(2CV2180)

(E2)

ST-C 0

Waste Gas Outlet from Reactor Coolant Drain Tanks Containment Isolation Valve LJ-C APPJ PI 2Y 2-WGS-2181-CV 2

A Active 2

GTV AO 60735 SH 1 O/C C

C FS 0

(2CV2181)

(E2)

ST-C Q

Waste Gas Outlet from Reactor Coolant Drain Tanks Containment Isolation Valve LJ-C APPJ PI 2Y

Constellation Energy (CCNPP Unit 2) IST Program Pump Matrix SYSTEM: AFW - Auxiliary Feedwater Test Parameters Code Disc.

Code Component PID(Coord)

Class Group Press DP Flow VIB Speed Freg Dev.

Comments 21 TD-AFW 62583 SH 2 (ClO) 3 B

No Yes Yes Yes Yes 2Y Comprehensive Pump Test Turbine Driven Auxiliary Feedwater Pump 21 No No Yes No Yes Q

22 TD-AFW 62583 SH 2 (F1 0) 3 B

No Yes Yes Yes Yes 2Y Comprehensive Pump Test Turbine Driven Auxiliary Feedwater Pump 22 No No Yes No Yes Q

23 MD-AFW 62583 SH 2 (H9) 3 B

No Yes Yes Yes Yes 2Y Comprehensive Pump Test Motor Driven Auxiliary Feedwater Pump No No Yes No Yes a

Constellation Energy (CCNPP Unit 2) IST Program Pump Matrix SYSTEM: CC - Component Cooling Test Parameters Code Disc,.

Component PID(Coord)

Class Group Press DP Flow VIB Speed Freg 21 CC 62710 SH I (E5) 3 A

No Yes Yes Yes No 0

Component Cooling Pump 21 No Yes Yes Yes No 2Y 22 CC 62710 SH 1 (G5) 3 A

No Yes Yes Yes No a

Component Cooling Pump 22 No Yes Yes Yes No 2Y 23 CC 62710 SH 1 (H5) 3 A

No Yes Yes Yes No a

Component Cooling Pump 23 No Yes Yes Yes No 2Y Code Dev.

Comments Comprehensive Pump Test Comprehensive Pump Test Comprehensive Pump Test 2

Constellation Energy (CCNPP Unit 2) IST Program Pump Matrix SYSTEM: CVC - Chemical & Volume Control Test Parameters Code Disc.code Component PID(Coord)

Class Group Press DP Flow VIB Speed Freg Dev.

Comments 21 BA 62730 SH I (G9) 2 A

No Yes Yes Yes No 0

Boric Acid Transfer Pump 21 No Yes Yes Yes No 2Y Comprehensive Pump Test 22 BA 62730 SH 1 (H1l) 2 A

No Yes Yes Yes No a

Boric Acid Transfer Pump 22 No Yes Yes Yes No 2Y Comprehensive Pump Test 3

Constellation Energy (CCNPP Unit 2) IST Program Pump Matrix SYSTEM: RC - Reactor Coolant Test Parameters Code Disc.

Component PID(Coord)

Class Group Press DP Flow VIB Speed 21 RCS CHG 62731 SH 2 (F7) 2 A

Yes No Yes Yes No Chemical and Volume Control (Charging) Pump 21 Freg Q

Code Dev.

Comments CVC-R R - 01 Yes No Yes Yes No 2Y Comprehensive Pump Test 22 RCS CHG 62731 SH 2 (G7) 2 A

Yes No Yes Yes No Q

CVC-R Chemical and Volume Control (Charging) Pump 22 R -01 Yes No Yes Yes No 2Y Comprehensive Pump Test 23 RCS CHG 62731 SH 2 (H7) 2 A

Yes No Yes Yes No Q

CVC-R Chemical and Volume Control (Charging) Pump 23 R - 01 Yes No Yes Yes No 2Y Comprehensive Pump Test 4

Constellation Energy (CCNPP Unit 2) IST Program Pump Matrix SYSTEM: SI - Safety Injection/Containment Spray Test Parameters Code Disc.

Component PID(Coord)

Class Group Press DP Flow VIB Speed 21 CS 62731 SH 3 (69) 2 B

No Yes Yes Yes No Containment Spray Pump 21 No No Yes No No 21 HPSI 62731 SH 1 (D7) 2 B

No Yes Yes Yes No High Pressure Safety Injection Pump 21 No No Yes No No 21 LPSI 62731 SH 1 (B7) 2 A/B No Yes Yes Yes No Low Pressure Safety Injection Pump 21 No No Yes No No 22 CS 62731 SH 3 (F9) 2 B

No Yes Yes Yes No Containment Spray Pump 22 No No Yes No No 22 HPSI 62731 SH 1 (E7) 2 B

No Yes Yes Yes No High Pressure Safety Injection Pump 22 No No Yes No No 22 LPSI 62731 SH 1 (H7) 2 A/B No Yes Yes Yes No Low Pressure Safety Injection Pump 22 No No Yes No No 23 HPSI 62731 SH 1 (G7) 2 B

No Yes Yes Yes No High Pressure Safety Injection Pump 23 No No Yes No No Freg 2Y Q

2Y Q

2Y Q

2Y-Q 27Y Q

2Y Q

2Y Q

Code Dev.

Comments Comprehensive Pump Test Comprehensive Pump Test Comprehensive Pump Test Comprehensive Pump Test Comprehensive Pump Test Comprehensive Pump Test Comprehensive Pump Test 5

Constellation Energy (CCNPP Unit 2) IST Program Pump Matrix SYSTEM: SRW - Service Water Test Parameters Code Disc.

Component PID(Coord)

Class Group Press DP Flow VIB Speed Freg 21 SRW 62706 SH 2 (E2) 3 A

No Yes Yes Yes No a

Service Water Pump 21 No Yes Yes Yes No 2Y 22 SRW 62706 SH 2 (F2) 3 A

No Yes Yes Yes No a

Service Water Pump 22 No Yes Yes Yes No 2Y 23 SRW 62706 SH 2 (G2) 3 A

No Yes Yes Yes No Q

Service Water Pump 23 No Yes Yes Yes No 2Y Code Dev.

Comments Comprehensive Pump Test Comprehensive Pump Test Comprehensive Pump Test 6

Constellation Energy (CCNPP Unit 2) IST Program Pump Matrix SYSTEM: SW - Saltwater Component 21 SW Saltwater Pump 21 22 SW Saltwater Pump 22 23 SW Saltwater Pump 23 Test Parameters Code Disc.

PID(Coord)

Class Group Press DP Flow VIB Speed 62708 SH 2 (C10) 3 A

No Yes Yes Yes No No Yes Yes Yes No 62708 SH 2 (C8) 3 A

No Yes Yes Yes No No Yes Yes Yes No 62708 SH 2 (C5) 3 A

No Yes Yes Yes No No Yes Yes Yes No Freg Q

2Y Q

2Y 2Y Code Dev.

Comments Comprehensive Pump Test Comprehensive Pump Test Comprehensive Pump Test 7

ENCLOSURE (2)

Unit 2 Drawings DOC ID REV #

DATE TITLE DATE 62437SH0001 0004 03/03/2005 FUEL OIL STORAGE & TRANSFER SYSTEM DG BLDG 1 62467SH0001 0003 11/04/2005 STARTING AIR SYSTEM DIESEL GENERATOR BUILDING 1 62467SH0002 0003 11/04/2005 STARTING AIR SYSTEM DIESEL GENERATOR BUILDING 1 62583SH0001 0056 04/17/2007 AUXILIARY FEEDWATER SYSTEM (STEAM) 62583SH0002 0000 02/23/2005 AUXILIARY FEEDWATER SYSTEM (CONDENSATE) 62700SH0001 0047 01/17/2006 MAIN STEAM AND REHEAT 62702SH0004 0045 08/25/2006 CONDENSATE & FEEDWATER SYSTEM SERVICE WATER COOLING SYS AUXILIARY BLDG 62706SH0002 0045 08/25/2006COTIMN CONTAINMENT 62708SH0002 0104 04/12/2007 CIRCULATING WATER COOLING SYSTEM 62708SH0003 0007 10/14/2003 CIRCULATING SALTWATER SYSTEM 62710SH0001 0038 05/14/1999 COMPONENT COOLING SYSTEM 62710SH0002 0024 01/10/2003 COMPONENT COOLING SYSTEM 62712SH0003 0110 06/20/2006 COMPRESSED AIR SYSTEM PLANT AND INSTRUMENT AIR 62729SH0001 0096 04/11/2007 REACTOR COOLANT SYSTEM 62730SH0001 0079 06/05/2007 CHEMICAL & VOLUME CONTROL SYSTEM 62730SH0002 0061 05/25/2006 CHEMICAL & VOLUME CONTROL SYSTEM 62730SH0003 0042 12/01/2005 CHEMICAL & VOLUME CONTROL SYSTEM 62731SH0001 0072 10/08/2004 SAFETY INJECTION AND CONTAINMENT SPRAY SYSTEMS 62731SH0002 0041 11/04/2005 SAFETY INJECTION AND CONTAINMENT SPRAY SYSTEMS 62731SH0003 0026 04/10/2007 SAFETY INJECTION AND CONTAINMENT SPRAY SYSTEMS DIAGRAM HYDRAULIC SCHEMATIC MAIN STEAM ISOLATION 62747 0028 04/17/2007 VLE 1&2 6 VALVES 21 & 22 62749 0034 12/19/2003 1STEAM GENERATOR BLOWDOWN RECOVERY SYSTEM

ENCLOSURE (2)

Unit 2 Drawings DOC ID REV#

ISSUE TITLE DATE 62437SH0001 0004 03/03/2005 FUEL OIL STORAGE & TRANSFER SYSTEM DG BLDG 1 62467SH0001 0003 11/04/2005 STARTING AIR SYSTEM DIESEL GENERATOR BUILDING 1 62467SH0002 0003.

11/04/2005 STARTING AIR SYSTEM DIESEL GENERATOR BUILDING 1 62583SH0001' 0056 04/17/2007 AUXILIARY FEEDWATER SYSTEM (STEAM) 62583SH0002 0000 02/23/2005 AUXILIARY FEEDWATER SYSTEM (CONDENSATE) 62700SH0001, 0047 01/17/2006 MAIN STEAM AND REHEAT 62702SH0004.

0045 08/25/2006 CONDENSATE & FEEDWATER SYSTEM SERVICE WATER COOLING SYS AUXILIARY BLDG 62706SH0002.

0045 08/25/2006 CNA MN CONTAINMENT 62708SH0002 0104 04/12/2007 CIRCULATING WATER COOLING SYSTEM 62708SH0003 0007 10/14/2003 CIRCULATING SALTWATER SYSTEM 62710SHO010 0038 05/14/1999 COMPONENT COOLING SYSTEM 62710SH0002 0024 01/10/2003 COMPONENT COOLING SYSTEM 62712SH0003 0110 06/20/2006 COMPRESSED AIR SYSTEM PLANT AND INSTRUMENT AIR 62729SH0001 0096 04/11/2007 REACTOR COOLANT SYSTEM 62730SH0001:

0079 06/05/2007 CHEMICAL & VOLUME CONTROL SYSTEM 62730SH0002 0061 05/25/2006 CHEMICAL & VOLUME CONTROL SYSTEM 62730SH0003, 0042 12/01/2005 CHEMICAL & VOLUME CONTROL SYSTEM 62731SHOO01 0072 10/08/2004 SAFETY INJECTION AND CONTAINMENT SPRAY SYSTEMS 62731 SH0002-0041 11/04/2005 SAFETY INJECTION AND CONTAINMENT SPRAY SYSTEMS 62731SH0003:

0026 04/10/2007 SAFETY INJECTION AND CONTAINMENT SPRAY SYSTEMS 62747 0028 04/17/2007 DIAGRAM HYDRAULIC SCHEMATIC MAIN STEAM ISOLATION VALVES 21 & 22 62749 0034 12/19/2003 STEAM GENERATOR BLOWDOWN RECOVERY SYSTEM

THE FOLLOWING IS A LISTING OF OVERSIZED DRAWINGS CONTAINED WITHIN THIS DOCUMENT.

TO VIEW A DRAWING, REFERENCE THE DRAWING NUMBER SPECIFIC TO THE DESIRED DRAWING (NOTED ON THE LIST) AND LOCATE IT WITHIN THIS PACKAGE OR, PERFORM A SEARCH USING THE DRAWING NUMBER