{{#Wiki_filter:UNITED STATES NUCLEAR REGULATORY COMMISSION WASHINGTON, 0.C. 20555-0001 October 30, 2018 Mr. Bryan C. Hanson Senior Vice President Exelon Generation Company, LLC President and Chief Nuclear Officer Exelon Nuclear 4300 Winfield Road Warrenville, IL 60555  

CALVERT CLIFFS NUCLEAR POWER PLANT, UNITS 1 AND 2-ISSUANCE OF AMENDMENT NOS. 326 AND 304 TO ADD RISK-INFORMED COMPLETION TIME PROGRAM (EPID L-2016-LLA-0001)  

The U.S. Nuclear Regulatory Commission (the Commission) has issued the enclosed Amendment No. 326 to Renewed Facility Operating License No. DPR-53 and Amendment No. 304 to Renewed Facility Operating License No. DPR-69 for the Calvert Cliffs Nuclear Power Plant (Calvert Cliffs), Units 1 and 2, respectively.

These amendments consist of changes to the Technical Specifications (TSs) in response to your application dated February 25, 2016, as supplemented by letters dated April 3, 2017, and January 11, January 18, June 21, and August 27, 2018. Publicly-available versions are in the Agencywide Documents Access and Management System under Accession Nos. ML 16060A223, ML 17094A591, ML 18011A665, ML 180186340, ML 18172A145, and ML 18239A260, respectively.

B. Hanson A copy of the related safety evaluation is enclosed.

A notice of issuance will be included in the Commission's biweekly Federal Register notice. Docket Nos. 50-317 and 50-318  

: 1. Amendment No. 326 to DPR-53 2. Amendment No. 304 to DPR-69 3. Safety Evaluation cc: Listserv Sincerely, Michael L. Marshall, Jr., Senior Project Manager Plant Licensing Branch I Division of Operating Reactor Licensing Office of Nuclear Reactor Regulation UNITED STATES NUCLEAR REGULATORY COMMISSION WASHINGTON, D.C. 20555-0001 EXELON GENERATION COMPANY, LLC DOCKET NO. 50-317 CALVERT CLIFFS NUCLEAR POWER PLANT, UNIT 1 AMENDMENT TO RENEWED FACILITY OPERATING LICENSE Amendment No. 326 Renewed License No. DPR-53 1. The U.S. Nuclear Regulatory Commission (the Commission) has found that: A. The application for amendment by Exelon Generation Company, LLC (Exelon, the licensee) dated February 25, 2016, as supplemented by letters dated April 3, 2017, and January 11, January 18, June 21, and August 27, 2018, complies with the standards and requirements of the Atomic Energy Act of 1954, as amended (the Act) and the Commission's rules and regulations set forth in 10 CFR Chapter I; B. The facility will operate in conformity with the application, the provisions of the Act, and the rules and regulations of the Commission; C. There is reasonable assurance (i) that the activities authorized by this amendment can be conducted without endangering the health and safety of the public, and (ii) that such activities will be conducted in compliance with the Commission's regulations; D. The issuance of this amendment will not be inimical to the common defense and security or to the health and safety of the public; and E. The issuance of this amendment is in accordance with 10 CFR Part 51 of the Commission's regulations and all applicable requirements have been satisfied.

Enclosure 1   2. Accordingly, the license is amended by changes to the Technical Specifications as indicated in the attachment to this license amendment, and paragraph 2.C.2. of Renewed Facility Operating License No. DPR-53 is hereby amended to read as follows: 2. Technical Specifications The Technical Specifications contained in Appendices A and B, as revised through Amendment No. 326, are hereby incorporated into this license. Exelon Generation shall operate the facility in accordance with the Technical Specifications.

: 3. This license amendment is effective as of the date of its issuance and shall be implemented within 180 days.  

Changes to the Renewed Facility Operating License and Technical Specifications Date of Issuance:

October 3 O, 2 O 1 8 FOR THE NUCLEAR REGULATORY COMMISSION Ja es G. Danna, Chief Plant Licensing Branch I Division of Operating Reactor Licensing Office of Nuclear Reactor Regulation ATTACHMENT TO LICENSE AMENDMENT NO. 326 CALVERT CLIFFS NUCLEAR POWER PLANT, UNIT 1 RENEWED FACILITY OPERATING LICENSE NO. DPR-53 DOCKET NO. 50-317 Replace the following page of the Renewed Facility Operating License with the attached revised page. The revised page is identified by amendment number and contains a marginal line indicating the area of change. Remove Page 3 Insert Page 3 Replace the following pages of the Appendix A Technical Specifications with the attached revised pages. The revised pages are identified by amendment number and contain marginal lines indicating the areas of change. Remove Pages 1.3-14 3.3.1-1 3.3.1-2 3.3.1-3 3.3.1-4 3.3.3-1 3.3.4-1 3.3.4-2 3.3.4-3 3.3.5-1 3.3.5-2 3.3.6-1 3.3.6-2 3.3.6-3 3.5.2-1 3.6.2-4 3.6.2-5 3.6.3-2 3.6.3-4 3.6.6-1 3.6.6-2 3.7.3-1 3.7.3-2 3.7.3-3 3.7.3-4 3.7.3-5 Insert Pages 1.3-14 1.3-15 3.3.1-1 3.3.1-2 3.3.1-3 3.3.1-4 3.3.3-1 3.3.4-1 3.3.4-2 3.3.4-3 3.3.5-1 3.3.5-2 3.3.6-1 3.3.6-2 3.3.6-3 3.3.6-4 3.5.2-1 3.6.2-4 3.6.2-5 3.6.2-6 3.6.3-2 3.6.3-4 3.6.6-1 3.6.6-2 3.7.3-1 3.7.3-2 3.7.3-3 3.7.3-4 3.7.3-5 3.7.3-6 Remove Pages 3.7.5-1 3.7.6-1 3.7.6-2 3.7.6-3 3.7.7-1 3.7.7-2 3.7.18-1 3.8.1-2 3.8.1-4 3.8.1-8 3.8.1-9 3.8.1-10 3.8.1-11 3.8.1-12 3.8.1-13 3.8.1-14 3.8.1-15 3.8.1-16 3.8.1-17 3.8.4-1 3.8.7-1 3.8.9-1 3.8.9-2 5.5-19 Insert Pages 3.7.5-1 3.7.6-1 3.7.6-2 3.7.6-3 3.7.7-1 3.7.7-2 3.7.7-3 3.7.18-1 3.8.1-2 3.8.1-4 3.8.1-8 3.8.1-9 3.8.1-10 3.8.1-11 3.8.1-12 3.8.1-13 3.8.1-14 3.8.1-15 3.8.1-16 3.8.1-17 3.8.1-18 3.8.4-1 3.8.7-1 3.8.9-1 3.8.9-2 5.5-19 5.5-20   (4) Exelon Generation pursuant to the Act and 10 CFR Parts 30, 40, and 70, to receive, possess, and use, in amounts as required, any byproduct, source, and special nuclear material without restriction to chemical or physical form, for sample analysis or instrument calibration or associated with radioactive apparatus or components; and (5) Exelon Generation pursuant to the Act and 10 CFR Parts 30 and 70 to possess, but not separate, such byproduct and special nuclear materials as may be produced by the operation of the facility.

C. This license is deemed to contain and is subject to the conditions set forth in 10 CFR Chapter I and is subject to all applicable provisions of the Act, and the rules, regulations, and orders of the Commission, now or hereafter applicable; and is subject to the additional conditions specified and incorporated below: (1) (2) Maximum Power Level Exelon Generation is authorized to operate the facility at steady-state reactor core power levels not in excess of 2737 megawatts-thermal in accordance with the conditions specified herein. Technical Specifications The Technical Specifications contained in Appendices A and B, as revised through Amendment No. 326, are hereby incorporated into this license. Exelon Generation shall operate the facility in accordance with the Technical Specifications. (a) For Surveillance Requirements (SRs) that are new, in Amendment 227 to Facility Operating License No. DPR-53, the first performance is due at the end of the first surveillance interval that begins at implementation of Amendment 227. For SRs that existed prior to Amendment 227, including SRs with modified acceptance criteria and SRs whose frequency of performance is being extended, the first performance is due at the end of the first surveillance interval that begins on the date the Surveillance was last performed prior to implementation of Amendment 227. (3) Additional Conditions The Additional Conditions contained in Appendix C as revised through Amendment No. 318 are hereby incorporated into this license. Exelon Generation shall operate the facility in accordance with the Additional Conditions. ( 4) Secondary Water Chemistry Monitoring Program Exelon Generation shall implement a secondary water chemistry monitoring program to inhibit steam generator tube degradation.

This program shall include: Amendment No. 326 1.3 Completion Times Completion Times 1.3 The Completion Time clock for Condition A does not stop after Condition Bis entered, but continues from the time Condition A was initially entered. If Required Action A.1 is met after Condition Bis entered, Condition Bis exited and operation may continue in accordance with Condition A, provided the Completion Time for Required Action A.2 has not expired. EXAMPLE 1.3-8-ACTIONS CONDITION A. One subsystem inoperable.

B. Required Action and associated Completion Time not met. A.1 B.1 AND B.2 REQUIRED ACTION COMPLETION TIME Restore subsystem 7 days to OPERABLE status. OR In accordance with the Risk Informed Completion Time Program Be in MODE 3. 6 hours Be in MODE 5. 36 hours When a subsystem is declared inoperable, Condition A is entered. The 7 day Completion Time may be applied as discussed in Example 1.3-2. However, the licensee may elect to apply the Risk Informed Completion Time Program which permits calculation of a Risk Informed Completion Time (RICT) that may be used to complete the required Action beyond the 7 day Completion Time. The RICT cannot exceed CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 1. 3-14 Amendment No. 326 Amendment No. 304 Completion Times 1.3 1.3 Completion Times IMMEDIATE COMPLETION TIME 30 days. After the 7 day Completion Time has expired, the subsystem must be restored to OPERABLE status within the RICT or Condition B must also be entered. The Risk Informed Completion Time Program requires recalculation of the RICT to reflect changing plant conditions.

For planned changes, the revised RICT must be determined prior to implementation of the change in configuration.

For emergent conditions, the revised RICT must be determined within the time limits of the Required Action Completion Time (i.e., not the RICT) or 12 hours after the plant configuration change, whichever is less. If the 7 day Completion Time clock of Condition A has expired and subsequent changes in plant condition result in exiting the applicability of the Risk Informed Completion Time Program without restoring the inoperable subsystem to OPERABLE status, Condition Bis also entered and the Completion Time clocks for Required Actions B.1 and B.2 start. If the RICT expires or is recalculated to be less than the elapsed time since the Condition was entered and the inoperable subsystem has not been restored to OPERABLE status, Condition Bis also entered and the Completion Time clocks for Required Actions B.1 and B.2 start. If the inoperable subsystems are restored to OPERABLE status after Condition Bis entered, Conditions A and Bare exited, and therefore, the Required Actions of Condition B may be terminated.

When 11 Immediately 11 is used as a Completion Time, the Required Action should be pursued without delay and in a controlled manner. CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 1.3-15 Amendment No. 326 Amendment No. 304 3.3 INSTRUMENTATION RPS Instrumentation-Operating 3.3.1 3.3.1 Reactor Protective System (RPS) Instrumentation-Operating LCO 3.3.1 Four RPS bistable trip units, associated measurement channels, and applicable automatic bypass removal features for each Function in Table 3.3.1-1 shall be OPERABLE.

APPLICABILITY:

According to Table 3.3.1-1: ACTIONS -------------------------------------NOTE-------------------------------------

CONDITION A. One or more Functions with -0ne RPS bistable trip unit or associated measurement channel inoperable except for Condition C (excore channel not calibrated with incore detectors).

CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 REQUIRED ACTION A. l Place affected bistable trip unit in bypass or trip. AND " A.2.1 Restore affected bistable trip unit and associated measurement channel to OPERABLE status. OR 3.3.1-1 COMPLETION TIME 1 hour 48 hours OR In accordance with the Risk Informed Completion Time Program Amendment No.326 Amendment No.304 ACTIONS (continued)

CONDITION A. (Continued)

: 8. One or more Functions with two RPS bistable trip units or associated measurement channels inoperable except for Condition C (excore channel not calibrated with incore detectors).

CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 A.2.2 8.1 AND 8.2 C.1 OR C.2 RPS Instrumentation-Operating 3.3.1 REQUIRED ACTION Place affected bistable trip unit in trip. Place one affected bistable trip unit in bypass and place the other affected bistable trip unit in trip. Restore one affected bistable trip unit and associated measurement channel to OPERABLE status. Perform SR 3.3.1.3. Restrict THERMAL POWER to< 90% RTP. 3.3.1-2 COMPLETION TIME 48 hours OR In accordance with the Risk Informed Completion Time Program 1 hour 48 hours OR In accordance with the Risk Informed Completion Time Program 24 hours 24 hours Amendment No.326 Amendment No. 304 ACTIONS {continued)

CONDITION RPS Instrumentation-Operating 3.3.1 REQUIRED ACTION COMPLETION TIME D. One or more Functions D.1 with one automatic Disable bypass channel. 1 hour bypass removal feature inoperable.

OR CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 D.2.1 Place affected bistable trip units in bypass or trip. D.2.2.1 Restore automatic bypass removal feature and affected bistable trip unit to OPERABLE status. OR 1 hour 48 hours In accordance with the Risk Informed Completion Time Program D.2.2.2 Place affected 48 hours bistable trip unit in trip. OR 3.3.1-3 In accordance with the Risk Informed Completion Time Program Amendment No. 326 Amendment No. 304 ACTIONS (continued)

CONDITION E. One or more Functions with two automatic bypass removal feature channels inoperable. " -CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 E.1 OR E.2.1 E.2.2 RPS Instrumentation-Operating 3.3.1 REQUIRED ACTION Disable bypass channels.

Place one affected bistable trip unit in bypass and place the other in trip for each affected t~ip Function.

AND Restore one automatic bypass removal feature and the affected bistable trip unit to OPERABLE status for each affected trip Function.

3.3.1-4 COMPLETION TIME 1 hour 1 hour 48 hours OR In accordance with the Risk Informed Completion Time Program Amendment No. 326 Amendment No. 304 3.3 INSTRUMENTATION RPS Logic and Trip Initiation 3.3.3 3.3.3 Reactor Protective System (RPS) Logic and Trip Initiation LCO 3.3.3 Six channels of RPS Matrix Logic, four channels of RPS Trip Path Logic, four channels of reactor trip circuit breakers (RTCBs), and four channels of Manual Trip shall be OPERABLE.

APPLICABILITY:

MODES 1 and 2, MODES 3, 4, and 5, with any RTCBs closed and any control element assemblies capable of being withdrawn.

ACTIONS CONDITION A. One Matrix Logic channel inoperable.

B. One channel of Manual Trip, RTCBs, or Trip Path Logic inoperable in MODE 1 or 2. C. One channel of Manual Trip, RTCBs, or Trip Path Logic inoperable in MODE 3, 4, or 5. CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 A.1 B.1 C.1 REQUIRED ACTION Restore Matrix Logic channel to OPERABLE status. Open the affected RTCBs. Open all RTCBs. 3.3.3-1 COMPLETION TIME 48 hours OR In accordance with the Risk Informed Completion Time Program 1 hour 48 hours Amendment No. 326 Amendment No. 304 3.3 INSTRUMENTATION ESFAS Instrumentation 3.3.4 3.3.4 Engineered Safety Features Actuation System (ESFAS) Instrumentation LCO 3.3.4 Four ESFAS sensor modules, associated measurement channels, and applicable automatic block removal features for each Function in Table 3.3.4-1 shall be OPERABLE.

APPLICABILITY:

MODES 1, 2, and 3. ACTIONS -------------------------------------NOTE-------------------------------------

CONDITION A. One or more Functions with one ESFAS sensor module or associated measurement channel inoperable.

CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 A.1 AND A.2.1 REQUIRED ACTION Place affected sensor module in bypass or trip. Restore affected sensor module and associated measurement channel to OPERABLE status. OR 3.3.4-1 COMPLETION TIME 1 hour 48 hours OR In accordance with the Risk Informed Completion Time Program Amendment No. 326 Amendment No. 304 ACTIONS (continued)

CONDITION REQUIRED ACTION ESFAS Instrumentation 3.3.4 COMPLETION TIME A. (continued)

A. 2. 2 Pl ace affected sensor 48 hours module in trip. B. One or more Functions B.1 with two ESFAS sensor modules or associated measurement channels inoperable.

Place one sensor module in bypass and place the other sensor module in trip. OR In accordance with the Risk Informed Completion Time Program 1 hour B.2 Restore one sensor 48 hours module and associated C. One or more Functions C.1 with the automatic block removal feature of one sensor block module inoperable.

OR measurement channel to OPERABLE status. Disable affected sensor block module. OR In accordance with the Risk Informed Completion Time Program 1 hour C.2 Place affected sensor 1 hour block module in CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 bypass. 3.3.4-2 Amendment No. 326 Amendment No. 304 ACTIONS (continued)

CONDITION D. One or more Functions with the automatic block removal feature of two sensor block modules inoperable.

E. Required Action and associated Completion Time not met. CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 D.1 OR D.2.1 REQUIRED ACTION Disable affected ESFAS Instrumentation 3.3.4 COMPLETION TIME 1 hour sensor block modules. Place one affected 1 hour sensor block module in bypass and disable the other for each affected ESFAS Function.

AND D.2.2 Restore one automatic.

block removal feature and the associated sensor block module to OPERABLE status for each affected ESFAS Function.

E.1 Be in MODE 3. AND E.2 Be in MODE 4. 3.3.4-3 48 hours OR In accordance with the Risk Informed Completion Time Program 6 hours 12 hours Amendment No. 326 Amendment No. 304 3.3 INSTRUMENTATION ESFAS Logic and Manual Actuation 3.3.5 3.3.5 Engineered Safety Features Actuation System (ESFAS) Logic and Manual Actuation LCO 3.3.5 Two ESFAS Manual Actuation or Start channels and two ESFAS Actuation Logic channels shall be OPERABLE for each ESFAS Function specified in Table 3.3.5-1. APPLICABILITY:

According to Table 3.3.5-1. ACTIONS -------------------------------------NOTE-------------------------------------

CONDITION A. One Auxiliary Feedwater Actuation System Manual Start channel or Actuation Logic channel inoperable.

B. Required Action and associated Completion Time of Condition A not met. CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 REQUIRED ACTION A.1 Restore affected Auxiliary Feedwater Actuation System Manual Start channel and Actuation Logic channel to OPERABLE status. B.1 Be in MODE 3. AND B.2 Be in MODE 4. 3.3.5-1 COMPLETION TIME 48 hours OR In accordance with the Risk Informed Completion Time Program 6 hours 12 hours Amendment No. 326 Amendment No.304 ACTIONS (continued)

CONDITION C. One or more Functions with one Manual Actuation channel or Actuation Logic channel inoperable except Auxiliary Feedwater Actuation System. D. Required Action and associated Completion Time of Condition C not met for one Manual Actuation channel. E. Required Action and associated Completion Time of Condition C not met for one Actuation Logic channel. CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 C.1 D.1 AND D.2 E.1 AND E.2 ESFAS Logic and Manual Actuation 3.3.5 REQUIRED ACTION Restore affected Manual Actuation channel and Actuation Logic channel to OPERABLE status. Be in MODE 3. Be in MODE 5. Be in MODE 3. Be in Mode 4. 3.3.5-2 COMPLETION TIME 48 hours OR In accordance with the Risk Informed Completion Time Program 6 hours 36 hours 6 hours 12 hours Amendment No. 326 Amendment No. 304 3.3 INSTRUMENTATION 3.3.6 Diesel Generator (DG)-Loss of Voltage Start (LOVS) DG-LOVS 3.3.6 LCO 3.3.6 Four sensor modules and measurement channels per DG for the Loss of Voltage Function, four sensor modules and measurement channels per DG for the Transient Degraded Voltage Function, and four sensor modules and measurement channels per DG for the Steady State Degraded Voltage Function shall be OPERABLE.

APPLICABILITY:

MODES 1, 2, 3, and 4. ACTIONS -------------------------------------NOTE-------------------------------------

CONDITION A. One or more Functions with one sensor module or associated measurement channel per DG inoperable.

CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 A.1 AND A.2.1 REQUIRED ACTION Place sensor module in bypass or trip. Restore sensor module and associated measurement channel to OPERABLE status. OR 3.3.6-1 COMPLETION TIME 1 hour 48 hours OR In accordance with the Risk Informed Completion Time Program Amendment No. 326 Amendment No. 304 ACTIONS (continued)

CONDITION A. (Continued)

B. One or more Functions with two sensor modules or associated measurement channels per DG inoperable.

CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 REQUIRED ACTION A.2.2 Place the sensor module in trip. B.1 Enter applicable Conditions and Required Actions for the associated DG made inoperable by DG-LOVS instrumentation.

OR B.2.1 Place one sensor module in bypass and the other sensor module in trip. AND B.2.2 Restore one sensor module and associated measurement channel to OPERABLE status. 3.3.6-2 DG-LOVS 3.3.6 COMPLETION TIME 48 hours OR In accordance with the Risk Informed Completion Time Program 1 hour 1 hour 48 hours OR In accordance with the Risk Informed Completion Time Program Amendment No. 326 Amendment No. 304 ACTIONS {continued)

CONDITION REQUIRED ACTION C. One or more Functions C.1 Restore at least two with more than two sensor modules and sensor modules or associated associated measurement channels measurement channels to OPERABLE status. inoperable.

D. Required Action and D.1 Enter applicable associated Completion Conditions and Time not met. Required Actions for the associated DG made inoperable by DG-LOVS instrumentation.

SURVEILLANCE REQUIREMENTS SURVEILLANCE SR 3.3.6.1 Perform CHANNEL FUNCTIONAL TEST. CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 3.3.6-3 DG-LOVS 3.3.6 COMPLETION TIME 1 hour Immediately FREQUENCY In accordance with the Surveillance Frequency Control Program Amendment No.326 Amendment No.304 '

SR 3.3.6.2 SURVEILLANCE Perform CHANNEL CALIBRATION with setpoi nt Allowable Values as follows: 1. Transient Degraded Voltage Function 3630 V and~ 3790 V; Time Delay: 7.6 seconds and 8.4 seconds; 2. Steady State Degraded Voltage Function 3820 V and~ 3980 V Time Delay: 97.5 seconds and 104.5 seconds; and 3. Loss of voltage Function~

2345 V and 2555 V Time Delay: 1.8 seconds and 2.2 seconds at 2450 V. CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 3.3.6-4 DG-LOVS 3.3.6 FREQUENCY In accordance with the Surveillance Frequency Control Program Amendment No. 326 Amendment No. 304 3.5 EMERGENCY CORE COOLING SYSTEM (ECCS) 3.5.2 ECCS -Operating LCO 3.5.2 Two ECCS trains shall be OPERABLE.

APPLICABILITY:

MODES 1 and 2, ECCS -Operating 3.5.2 MODE 3 with pressurizer pressure~

1750 psia. ACTIONS CONDITION A. One or more trains inoperable.

AND At least 100% of the ECCS flow equivalent to a single OPERABLE ECCS train available.

B. Required Action and associated Completion Time not met. CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 A.1 B.1 AND B.2 REQUIRED ACTION Restore train(s) to OPERABLE status. Be in MODE 3. Reduce pressurizer pressure to < 1750 psia. 3.5.2-1 COMPLETION TIME 72 hours OR In accordance with the Risk Informed Completion Time Program 6 hours 12 hours Amendment No. 326 Amendment No. 304 ACTIONS (continued)

CONDITION B. (continued)

C. One or more containment air locks i noperab 1 e for reasons other than Condition A or B. CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 B.2 AND B.3 C.1 AND C.2 AND Containment Air Locks 3.6.2 REQUIRED ACTION Lock an OPERABLE door closed in the affected air lock. --------NOTE-------

Air lock doors in high radiation areas may be verified 1 ocked closed by administrative means. --------------------

Verify an OPERABLE door is locked closed in the affected air lock. Initiate action to evaluate overall containment leakage rate per LCO 3.6.1. Verify a door is closed in the affected air lock. 3.6.2-4 COMPLETION TIME 24 hours Once per 31 days Immediately 1 hour Amendment No. 326 Amendment No. 304 Containment Air Locks 3.6.2 ACTIONS (continued)

CONDITION REQUIRED ACTION C. (continued)

C.3 Restore air lock to OPERABLE status. D. Required Action and D.1 Be in MODE 3. associated Completion Time not met. AND D.2 Be in MODE 5. SURVEILLANCE REQUIREMENTS SR 3.6.2.1 SURVEILLANCE

------------------NOTES------------------

: 1. An inoperable air lock door does not invalidate the previous successful performance of the overall air lock 1 eakage test. 2. Results shall be evaluated against acceptance criteria applicable to SR 3.6.1.1. Perform required air lock leakage rate testing in accordance with the Containment Leakage Rate Testing Program. CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 3.6.2-5 COMPLETION TIME 24 hours OR In accordance with the Risk Informed Completion Time Program 6 hours 36 hours FREQUENCY In accordance with the Containment Leakage Rate Testing Program Amendment No. 326 Amendment No. 304 Containment Air Locks 3.6.2 SURVEILLANCE REQUIREMENTS (continued)

SR 3.6.2.2 SURVEILLANCE FREQUENCY Verify only one door in the air lock can be In accordance opened at a time. with the Surveillance Frequency Control Program CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 3.6.2-6 Amendment No.326 Amendment No. 304 ACTIONS (continued)

CONDITION A. --------NOTE--------

A.1 Only applicable to pen et ration fl ow paths with two containment isolation valves and not a closed system. One or more pen et ration fl ow paths with one containment isolation valve inoperable.

CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 AND A.2 Containment Isolation Valves 3.6.3 REQUIRED ACTION COMPLETION TIME I sol ate the affected 4 hours penetration flow path by use of at least one closed and de-activated automatic valve, closed manual valve, blind flange, or check valve with flow through the valve secured. --------NOTE-------

Isolation devices in high radiation areas may be verified by use of administrative means. Verify the affected penetration flow path is isolated.

3.6.3-2 In accordance with the Risk Informed Completion Time Program Once per 31 days following isolation for isolation devices outside containment AND Prior to entering MODE 4 from MODE 5 if not performed within the previous 92 days for isolation devices inside containment Amendment No.326 Amendment No. 304 ACTIONS (continued)

CONDITION C. --------NOTE --------Only applicable to penetration fl ow paths with one or more containment isolation valves and a closed system. ---------------------

One or more penetration flow paths with one or more containment isolation valves inoperable.

D. Required Action and associated Completion Time not met. CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 C.1 AND C.2 D.1 AND D.2 Containment Isolation Valves 3.6.3 REQUIRED ACTION Isolate the affected penetration flow path by use of at least one closed and de-activated automatic valve, closed manual valve, or blind flange. --------NOTE-------

Isolation devices in high radiation areas may be verified by use of administrative means. --------------------

Be in MODE 3. Be in MODE 5. 3.6.3-4 COMPLETION TIME 72 hours OR In accordance with the Risk Informed Completion Time Program Once per 31 days following isolation 6 hours 36 hours Amendment No. 326 Amendment No. 304 3.6 CONTAINMENT SYSTEMS Containment Spray and Cooling Systems 3.6.6 3.6.6 Containment Spray and Cooling Systems LCO 3.6.6 Two containment spray trains and two containment cooling trains shall be OPERABLE.

MODES 1 and 2. MODE 3, except containment spray is not required to be OPERABLE when pressurizer pressure is< 1750 psia. ACTIONS CONDITION A. One containment spray train inoperable.

B. One containment cooling train inoperable.

CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 A.1 B.1 REQUIRED ACTION Restore containment spray train to OPERABLE status. Restore containment cooling train to OPERABLE status. 3.6.6-1 COMPLETION TIME 72 hours OR In accordance with the Risk Informed Completion Time Program 7 days OR In accordance with the Risk Informed Completion Time Program Amendment No.326 Amendment No.304 ACTIONS (continued)

CONDITION C. --------NOTE --------Not applicable when second containment spray train intentionally made inoperable.  

---------------------

Two containment spray trains inoperable.

D. Two containment cooling trains inoperable.

E. Required Action and associated Completion Time not met. F. Any combination of three or more trains inoperable.

CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 C.1 AND C.2 D.1 E.1 AND E.2 F.1 Containment Spray and Cooling Systems 3.6.6 REQUIRED ACTION Verify LCO 3.7.8, "CREVS," is met. Restore at least one containment spray train to OPERABLE status. Restore one containment cooling train to OPERABLE status. Be in MODE 3. Be in MODE 4. Enter LCO 3.0.3. 3.6.6-2 COMPLETION TIME 1 hour 24 hours 72 hours 6 hours 12 hours Immediately Amendment No. 326 Amendment No. 304 3.7 PLANT SYSTEMS AFW System 3.7.3 3.7.3 Auxiliary Feedwater (AFW) System LCO 3.7.3 Two AFW trains shall be OPERABLE.

----------------------------NOTE----------------------------

MODES 1, 2, and 3. ACTIONS -------------------------------------NOTE-------------------------------------

CONDITION A. One steam-driven AFW A. 1 pump inoperable.

REQUIRED ACTION COMPLETION TIME Align remaining 72 hours OPERABLE steam-driven pump to automatic initiating status. A.2 Restore steam-driven 7 days pump to OPERABLE CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 status. OR 3.7.3-1 In accordance with the Risk Informed Completion Time Program Amendment No.326 Amendment No.304 ACTIONS (continued)

CONDITION B. One motor-driven AFW pump inoperable.

CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 B.1 AND B.2 C.1 AND C.2 AND C.3 AND REQUIRED ACTION Align standby steam-driven pump to automatic initiating status. Restore motor-driven pump to OPERABLE status. Align remaining OPERABLE pump to automatic initiating status. Verify the other unit 1 s motor-driven AFW pump is OPERABLE.

Verify, by administrative means, the cross-tie valve to the opposite unit is OPERABLE.

3.7.3-2 AFW System 3.7.3 COMPLETION TIME 72 hours 7 days OR In accordance with the Risk Informed Completion Time Program 1 hour 1 hour 1 hour Amendment No. 326 Amendment No. 304 ACTIONS (continued)

D. One AFW train inoperable for reasons other than Condition A, B, or C. E. Required Action and associated Completion Time of Condition A, B, C, or D not met. CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 C.4 D. l E. l AND E.2 REQUIRED ACTION Restore one AFW pump to OPERABLE status. Restore AFW train to OPERABLE status. Be in MODE 3. Be in MODE 4. 3.7.3-3 AFW System 3.7.3 COMPLETION TIME 72 hours OR In accordance with the Risk Informed Completion Time Program 72 hours OR In accordance with the Risk Informed Completion Time Program 6 hours 12 hours Amendment No.326 Amendment No. 304 ACTIONS (continued)

CONDITION REQUIRED ACTION F. Two AFW trains inoperable.

F.1 --------NOTE-------

LCO 3.0.3 and all other LCO Required Actions requiring . MODE changes are suspended until one AFW train is restored to OPERABLE status. --------------------

Initiate action to restore one AFW train to OPERABLE status. SURVEILLANCE REQUIREMENTS SR 3.7.3.1 SR 3.7.3.2 SURVEILLANCE Verify each AFW manual, power-operated, and automatic valve in each water flow path and in both steam supply flow paths to the steam turbine-driven pumps, that is not locked, sealed, or otherwise secured in position, is in the correct position.

Cycle each testable, remote-operated valve that is not in its operating position.

CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 3.7.3-4 AFW System 3.7.3 COMPLETION TIME Immediately FREQUENCY In accordance with the Surveillance Frequency Control Program In accordance with the INSERVICE TES TI NG PROGRAM Amendment No. 326 Amendment No. 304 I -

SURVEILLANCE REQUIREMENTS (continued)

SR 3.7.3.3 SR 3.7.3.4 SR 3.7.3.5 SURVEILLANCE

-------------------NOTE-------------------

Verify the developed head of each AFW pump at the flow test point is greater than or equal to the required developed head. -------------------NOTE-------------------

Verify each AFW automatic valve that is not locked, sealed, or otherwise secured in position, actuates to the correct position on an actual or simulated actuation signal. -------------------NOTE-------------------

Verify each AFW pump starts automatically on an actual or simulated actuation signal. CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 3.7.3-5 AFW System 3.7.3 FREQUENCY In accordance with the* INSERVICE TESTING PROGRAM In accordance with the Surveillance Frequency Control Program In accordance with the Surveillance Frequency Control Program Amendment No. 326 Amendment No. 304 SURVEILLANCE REQUIREMENTS (continued)

SR 3.7.3.6 SR 3.7.3.7 SURVEILLANCE

-------------------NOTE-------------------

Verify the AFW system is capable of providing a minimum of 300 gpm nominal flow to each flow leg. Verify the proper alignment of the required AFW flow paths by verifying flow from the condensate storage tank to each steam generator.

CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 3.7.3-6 AFW System 3.7.3 FREQUENCY In accordance with the Surveillance Frequency Control Program Prior to entering MODE 2 whenever unit has been in MODE 5 or 6 for > 30 days Amendment No. 326 Amendment No. 304 3.7 PLANT SYSTEMS 3.7.5 Component Cooling (CC) System LCO 3.7.5 Two CC loops shall be OPERABLE.

APPLICABILITY:

MODES 1, 2, 3, and 4. ACTIONS CONDITION A. One CC loop inoperable.

B. Required Action and associated Completion Time of Condition A not met. CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 REQUIRED ACTION A.1 --------NOTE  

-------Enter applicable Conditions and Required Actions of LCO 3.4.6, 11 RCS Loops--MODE 4, 11 for shutdown cooling made inoperable by CC. --------------------

Restore CC loop to OPERABLE status. B.1 Be in MODE 3. AND B.2 Be in MODE 5. 3.7.5-1 CC System 3.7.5 COMPLETION TIME 72 hours OR In accordance with the Risk Informed Completion Time Program 6 hours 36 hours Amendment No. 326 Amendment No. 304 3.7 PLANT SYSTEMS 3.7.6 Service Water (SRW) System LCO 3.7.6 Two SRW subsystems shall be OPERABLE.

APPLICABILITY:

MODES 1, 2, 3, and 4. ACTIONS CONDITION A. One SRW heat exchanger inoperable.

CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 A. l REQUIRED ACTION Isolate flow to one of the associated containment cooling units. --------NOTE Enter applicable Conditions and Required Actions of LCO 3.6.6, "Containment Spray and Cooling Systems," for one containment cooling train made inoperable by the heat exchanger.

3.7.6-1 SRW 3.7.6 COMPLETION TIME 1 hour Amendment No. 326 Amendment No. 304 ACTIONS (continued)

CONDITION A. (continued)

C. Required Action and associated Completion Time of Condition A or B not met. CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 A.2 B.1 C.1 AND C.2 REQUIRED ACTION Restore heat exchanger to operable status. --------NOTE-------

Enter applicable Conditions and Required Actions of LCO 3.8.1, 11 AC Sources--Operating, 11 for diesel generator made inoperable by SRW. --------------------

Restore SRW subsystem to OPERABLE status. Be in MODE 3. Be in MODE 5. 3.7.6-2 SRW 3.7.6 COMPLETION TIME 7 days OR In accordance with the Risk Informed Completion Time Program 72 hours OR In accordance with the Risk Informed Completion Time Program 6 hours 36 hours Amendment No.326 Amendment No. 304 SURVEILLANCE REQUIREMENTS SR 3.7.6.1 SR 3.7.6.2 SR 3.7.6.3 SURVEILLANCE

-------------------NOTE-------------------

Verify each SRW manual, power-operated, and automatic valve in the flow path servicing safety-related equipment, that is not locked, sealed, or otherwise secured in position, is in the correct position.

Verify each SRW automatic valve in the flow path that is not locked, sealed, or otherwise secured in position, actuates to the correct position on an actual or simulated actuation signal. Verify each SRW pump starts automatically on an actual or simulated actuation signal. CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 3.7.6-3 SRW 3.7.6 FREQUENCY In accordance with the Surveillance Frequency Control Program In accordance with the Surveillance Frequency Control Program In accordance with the Surveillance Frequency Control Program Amendment No.326 Amendment No. 304 3.7 PLANT SYSTEMS 3.7.7 Saltwater (SW) System LCO 3.7.7 Two SW subsystems shall be OPERABLE.

APPLICABILITY:

MODES 1, 2, 3, and 4. ACTIONS CONDITION A. One SW subsystem inoperable.

CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 A.1 REQUIRED ACTION -------NOTES-------

: 1. Enter applicable Conditions and Required Actions of LCO 3.8.1, "AC Operating," for emergency diesel generator made inoperable by SW System. 2. Enter application Conditions and Required Actions of LCO 3.4.6, "RCS Loops-MODE 4," for shutdown cooling made inoperable by SW System. 3.7.7-1 SW 3.7.7 COMPLETION TIME Amendment No. 326 Amendment No. 304 ACTIONS (continued)

CONDITION REQUIRED ACTION A. (continued)

Restore SW subsystem to OPERABLE status. B. Required Action and B.1 Be in MODE 3. associated Completion Time of Condition A AND not met. B.2 Be in MODE 5. SURVEILLANCE REQUIREMENTS SR 3.7.7.1 SURVEILLANCE

------------------

NOTE-------------------

Verify each SW System manual, operated, and automatic valve in the flow path servicing safety-related equipment, that is not locked, sealed, or otherwise secured in position, is in the correct position.

CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 3.7.7-2 SW 3.7.7 COMPLETION TIME 72 hours OR In accordance with the Risk Informed Completion Time Program 6 hours 36 hours FREQUENCY In accordance with the Surveillance Frequency Control Program Amendment No. 326 Amendment No. 304 SURVEILLANCE REQUIREMENTS (continued)

SR 3.7.7.2 SR 3.7.7.3 SURVEILLANCE Verify each SW System automatic valve in the flow path that is not locked, sealed, or otherwise secured in position, actuates to the correct position on an actual or simulated actuation signal. Verify each SW System pump starts automatically on an actual or simulated actuation signal. SW 3.7.7 FREQUENCY In accordance with the Surveillance Frequency Control Program In accordance with the Surveillance Frequency Control Program CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 3.7.7-3 Amendment No.326 -Amendment No. 304 3.7 PLANT SYSTEMS 3.7.18 Atmospheric Dump Valves (ADVs) LCO 3.7.18 Two ADV lines shall be OPERABLE.

APPLICABILITY:

MODES 1, 2, and 3, ADVs 3.7.18 MODE 4 when steam generator is being relied upon for heat removal. ACTIONS CONDITION A. One required ADV 1 i ne inoperable.

B. Two ADV lines inoperable.

C. Required Action and associated Completion Time not met. CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 A.1 B.1 C.1 AND C.2 REQUIRED ACTION Restore ADV line to OPERABLE status. Restore one ADV line to OPERABLE status. Be in MODE 3. Be in MODE 4 without reliance upon steam generator for heat removal. 3.7.18-1 COMPLETION TIME 48 hours OR In accordance with the Risk Informed Completion Time Program 1 hour 6 hours 24 hours Amendment No. 326 Amendment No. 304 AC Sources-Operating 3.8.1 ACTIONS -------------------------------------NOTE-------------------------------------

LCO 3.0.4.b is not applicable to DGs. CONDITION REQUIRED ACTION A. One required A.1 Perform SR 3.8.1.1 or LCO 3.8.1.a offsite SR 3.8.1.2 for circuit inoperable.

required OPERABLE offsite circuits.

AND A.2 Declare required feature(s) with no offsite power available inoperable when its redundant required feature(s) is inoperable.

AND A.3 Restore required offsite circuit to OPERABLE status. CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 3.8.1-2 COMPLETION TIME 1 hour AND Once per 8 hours thereafter 24 hours from discovery of no offsite power to one train concurrent with inoperability of redundant required feature(s) 72 hours OR In accordance with the Risk Informed Completion Time Program Amendment No. 326 Amendment No. 304 ACTIONS (continued)

CONDITION B. (continued)

C. Required Action and associated Completion Time of Required Action B.1 not met. CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 B.4.2 AND B.5 C .1.1 C.1.2 REQUIRED ACTION Perform SR 3.8.1.3 for OPERABLE DG(s). Restore DG to OPERABLE status. Restore both DGs on the other unit to OPERABLE status and QC DG to available status. OR Restore DG to OPERABLE status. 3.8.1-4 AC Sources-Operating 3.8.1 COMPLETION TIME 24 hours 14 days OR In accordance with the Risk Informed Completion Time Program 72 hours Amendment No.326 Amendment No.304 ACTIONS (continued)

CONDITION G. Two required LCO 3.8.1.a offsite circuits inoperable.

OR One required LCO 3.8.1.a offsite circuit that provides power to the CREVS and CRETS inoperable and the required LCO 3.8.1.c offsite circuit inoperable.

H. One required LCO 3.8.1.a offsite circuit inoperable.

AND G.2 Restore one required offsite circuit to OPERABLE status. -----------

NOTE------------

Enter applicable Conditions and Required Actions of LCO 3.8.9, when Condition H is entered with no AC power source to any train. ----------------------------

H.1 Restore required offsite circuit to OPERABLE status. OR 3 .8.1-8 Condition G concurrent with inoperability of redundant required feature(s) 24 hours OR In accordance with the Risk Informed Completion Time Program 12 hours OR In accordance with the Risk Informed Completion Time Program Amendment No. 326 Amendment No. 304 ACTIONS (continued)

CONDITION H. (continued)

I. Two LCO 3.8.1.b DGs inoperable.

CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 H.2 1.1 REQUIRED ACTION Restore DG to OPERABLE status. Restore one DG to OPERABLE status. 3.8.1-9 AC Sources-Operating 3 .8.1 COMPLETION TIME 12 hours OR In accordance with the Risk Informed Completion Time Program 2 hours Amendment No.326 Amendment No. 304 ACTIONS (continued)

CONDITION J. Required Action and associated Completion Time of Condition A, C, F, G, H, or I not met. OR Required Action and associated Completion Time of Required Action B.2, B.3, B.4.1, B.4.2, or B.5 not met. OR Required Action and associated Completion Time of Required Action E.2, E.3, E.4.1, E.4.2, or E.5 not met. K. Three or more required LCO 3.8.1.a and LCO 3.8.1.b AC sources inoperable.

CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 REQUIRED ACTION J.1 Be in MODE 3. AND J.2 Be in MODE 5. K.1 Enter LCO 3.0.3. 3.8.1-10 AC Sources-Operating 3.8.1 COMPLETION TIME 6 hours 36 hours Immediately Amendment No. 326 Amendment No. 304 L AC Sources-Operating 3 .8.1 SURVEILLANCE REQUIREMENTS  

-------------------------------------NOTE-------------------------------------

SR 3.8.1.1 through SR 3.8.1.15 are only applicable to LCO 3.8.1.a and LCO 3.8.1.b AC sources. SR 3.8.1.16 is only applicable to LCO 3.8.1.c AC sources. SR 3.8.1.1 SR 3.8.1.2 SURVEILLANCE

-------------------NOTE-------------------

Only required to be performed when SMECO is being credited for an offsite source. Verify correct breaker alignment and indicated power availability for the 69 kV SMECO offsite circuit. Verify correct breaker alignment and indicated power availability for each required 500 kV offsite circuit. CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 3.8.1-11 FREQUENCY Once within 1 hour after substitution for a 500 kV off site circuit In accordance with the Surveillance Frequency Control Program In accordance with the Surveillance Frequency Control Program Amendment No. 326 Amendment No. 304 AC Sources-Operating 3.8.1 SURVEILLANCE REQUIREMENTS (continued)

SR 3.8.1.3 SURVEILLANCE

------------------NOTES------------------

: 2. All DG starts may be preceded by an engine prelube period and followed by a warmup period prior to loading. 3. A modified DG start involving idling and gradual acceleration to synchronous speed may be used for this Surveillance Requirement as recommended by the. manufacturer.

When modified start procedures are not used, the voltage and frequency tolerances of SR 3.8.1.9 must be met. Verify each DG starts and achieves steady state voltage~ 4060 V ands 4400 V, and frequency~

58.8 Hz ands 61.2 Hz. CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 3.8.1-12 FREQUENCY In accordance with the Surveillance Frequency Control Program Amendment No. 326 Amendment No. 304 AC Sources-Operating 3 .8.1 SURVEILLANCE REQUIREMENTS (continued)

SR 3.8.1.4 SR 3.8.1.5 SR 3.8.1.6 SURVEILLANCE

------------------NOTES------------------

: 2. Momentary transients below the load limit do not invalidate this test. 3. This Surveillance shall be conducted on only one DG at a time. 4. This Surveillance Requirement shall be preceded by and immediately follow without shutdown a successful performance of SR 3.8.1.3 or SR 3 .8.1. 9. Verify each DG is synchronized and loaded, and operates for~ 60 minutes at a load 4000 kW for DG IA and~ 2700 kW for DGs 18, 2A, and 28. Verify each day tank contains~

a one hour supply. Check for and remove accumulated water from each day tank. CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 3.8.1-13 FREQUENCY In accordance with the Surveillance Frequency Control Program In accordance with the Surveillance Frequency Control Program In accordance with the Surveillance Frequency Control Program Amendment No. 326 Amendment No. 304 AC Sources-Operating 3.8.1 SURVEILLANCE REQUIREMENTS (continued)

SR 3.8.1. 7 SURVEILLANCE Verify the fuel oil transfer system operates to automatically transfer fuel oil from storage tank[s] to the day tank. FREQUENCY In acGordance with the Surveillance Frequency Control Program SR 3.8.1.8 Verify interval between each sequenced load In accordance block is within+/- 10% of design interval for with the each emergency and shutdown load sequencer.

Surveillance SR 3.8.1.9 -------------------NOTE-------------------

All DG starts may be preceded by an engine prelube period. Verify each DG starts from standby condition and achieves, in~ 10 seconds, voltage > 4060 V and frequency>

58.8 Hz, and after steady state conditions are reached, maintains voltage~ 4060 V and~ 4400 V and frequency of> 58.8 Hz and~ 61.2 Hz. SR 3.8.1.10 Verify manual transfer of AC power sources from the normal offsite circuit to the alternate offsite circuit. CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 3.8.1-14 Frequency Control Program In accordance with the .Surveillance Frequency Control Program In accordance with the Surveillance Frequency Control Program Amendment No. 326 Amendment No. 304 l AC Sources-Operating 3 .8.1 SURVEILLANCE REQUIREMENTS (continued)

SR 3.8.1.11 SURVEILLANCE

-------------------NOTE-------------------

: 1. Momentary transients outside the load and power factor limits do not invalidate this test. 2. If performed with the DG synchronized with offsite power, the surveillance test shall be performed at the required power factor. However, if grid conditions do not permit, the power factor limit is not required to be met. Under this condition, the power factor shall be maintained as close to the limit as practicable.

Verify each DG, operating at a frequency 58.8 Hz and~ 61.2 Hz, and an appropriate accident load power factor operates for 4 hours while loaded to~ 4000 kW for DG IA and~ 3000 kW for DGs IB, 2A, and 28. SR 3.8.1.12 Verify each DG rejects a load~ 500 hp without tripping.

CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 3.8.1-15 FREQUENCY In accordance with the Surveillance Frequency Control Program In accordance with the Surveillance Frequency Control Program Amendment No. 326 Amendment No. 304 _\ .

AC Sources-Operating 3 .8.1 SURVEILLANCE REQUIREMENTS (continued)

SR 3.8.1.13 SURVEILLANCE Verify that automatically bypassed DG trips are automatically bypassed on an actual or simulated required actuation signal. SR 3.8.1.14 Verify each DG: a. Synchronizes with offsite power source while loaded upon a simulated restoration of offsite power; b. Manually transfers loads to offsite power source; and c. Returns to ready-to-load operation.

CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 3.8.1-16 FREQUENCY In accordance with the Surveillance Frequency Control Program In accordance with the Surveillance Frequency Control Program Amendment No. 326 Amendment No. 304 AC Sources-Operating 3 .8.1 SURVEILLANCE REQUIREMENTS (continued)

SR 3.8.1.15 SURVEILLANCE

-------------------NOTE-------------------

All DG starts may be preceded by an engine prelube period. Verify on an actual or simulated loss of offsite power signal in conjunction with an actual or simulated Engineered Safety Feature actuation signal: a. De-energization of emergency buses; b. Load shedding from emergency buses; c. DG auto-starts from standby condition and: 1. energizes permanently connected loads in~ 10 seconds, 2. energizes auto-connected emergency loads through load sequencer, 3. maintains steady state voltage 4060 V and~ 4400 V, 4. maintains steady state frequency of~ 58.8 Hz and~ 61.2 Hz, and 5. supplies permanently connected and auto-connected emergency loads for 5 minutes. CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 3.8.1-17 FREQUENCY In accordance with the Surveillance Frequency Control Program Amendment No. 326 Amendment No. 304 \.

SURVEILLANCE REQUIREMENTS (continued)

SURVEILLANCE SR 3.8.1.16 For the LCO 3.8.1.c AC electrical sources, SR 3.8.1.1, SR 3.8.1.2, SR 3.8.1.3, SR 3.8.1.17 SR 3.8.1.5, SR 3.8.1.6, and SR 3.8.1.7 are required to be performed.  

-------------------NOTE-------------------

Momentary transients outside the load and power factor limits do not invalidate this test. Verify each DG operates for~ 24 hours: a. For~ 2 hours of the test loaded to 4200 kW for DG IA, and~ 3150 kW and 3300 kW for DGs 18, 2A, and 28, and b. For the remaining hours of the test loaded to~ 3600 kW for DG IA, and AC Sources-Operating 3.8.1 FREQUENCY In accordance with applicable Surveillance Requirements In accordance with the Surveillance Frequency Control Program 2700 kW and~ 3000 kW for DGs 18, 2A, and 28. CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 3.8.1-18 Amendment No. 326 Amendment No. 304 3.8 ELECTRICAL POWER SYSTEMS 3.8.4 DC Sources-Operating DC Sources-Operating 3.8.4 LCO 3.8.4 Four channels of DC electrical sources shall be OPERABLE.

APPLICABILITY:

MODES 1, 2, 3, and 4. ACTIONS CONDITION A. One DC channel inoperable due to an inoperable battery and the reserve battery available.

B. One DC channel inoperable for reasons other than Condition A. C. Required Action and associated Completion Time not met. CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 REQUIRED ACTION A.1 Replace inoperable battery with reserve battery. B.1 Restore DC channel to OPERABLE status. C.1 Be in MODE 3. AND C.2 Be in MODE 5. 3.8.4-1 COMPLETION TIME 4 hours OR In accordance with the Risk Informed Completion Time Program 2 hours OR In accordance with the Risk Informed Completion Time Program 6 hours 36 hours Amendment No.326 Amendment No.304 3.8 ELECTRICAL POWER SYSTEMS 3.8.7 Inverters-Operating LCO 3.8.7 Four inverters shall be OPERABLE.

MODES 1, 2, 3, and 4. ACTIONS CONDITION REQUIRED ACTION A. One required inverter A.1 --------NOTE-------

Enter applicable Conditions and Required Actions of LCO 3.8.9, Inverters-Operating 3.8.7 COMPLETION TIME "Distribution Systems-B. Required Action and associated Completion Time not met. CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 B.1 AND B.2 Operating" with any vital bus de-energized.  

Restore inverter to OPERABLE status. Be in MODE 3. Be in MODE 5. 3.8.7-1 24 hours OR In accordance with the Risk Informed Completion Time Program 6 hours 36 hours Amendment No. 326 Amendment No. 304 3.8 ELECTRICAL POWER SYSTEMS 3.8.9 Distribution Systems-Operating Distribution Systems-Operating 3.8.9 LCO 3.8.9 The AC. DC. and AC vital bus electrical power distribution subsystems shall be OPERABLE.

MODES 1. 2. 3. and 4. ACTIONS CONDITION A. One or more AC electrical power distribution subsystems inoperable.

B. One or more AC vital bus subsystem(s) inoperable.

CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 REQUIRED ACTION A.1 Restore AC electrical power distribution subsystems to OPERABLE status. B.1 Restore AC vital bus subsystems to OPERABLE status. 3.8.9-1 COMPLETION TIME 8 hours OR In accordance with the Risk Informed Completion Time Program 2 hours OR In accordance with the Risk Informed Completion Time Program Amendment No. 326 Amendment No. 304 Distribution Systems-Operating 3.8.9 ACTIONS (continued)

CONDITION REQUIRED ACTION C. One DC electrical C.1 Restore DC electrical power distribution power distribution subsystem inoperable.

subsystem to OPERABLE status. D. Required Action and D.1 Be in MODE 3. associated Completion Time not met. AND D.2 Be in MODE 5. E. Two or more E.1 Enter LCO 3.0.3. electrical power distribution subsystems inoperable that result in a loss of function.

SURVEILLANCE REQUIREMENTS SURVEILLANCE SR 3.8.9.1 Verify correct breaker alignments and voltage to AC, DC, and AC vital bus electrical power distribution subsystems.

CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 3.8.9-2 COMPLETION TIME 2 hours OR In accordance with the Risk Informed Completion Time Program 6 hours 36 hours Immediately FREQUENCY In accordance with the Surveillance Frequency Control Program Amendment No.326 Amendment No.304 Programs and Manuals 5.5 5.5 Programs and Manuals 5.5.18 inleakage, and assessing the CRE boundary as required by paragraphs c and d respectively.

Risk Informed Completion Time Program This program provides controls to calculate a Risk Informed Completion Time (RICT) and must be implemented in accordance with NEI 06-09, Revision 0-A, "Risk-Managed Technical Specifications (RMTS) Guidelines." The program shall include the following:

: a. The RICT may not exceed 30 days; b. A RICT may only be utilized in MODE 1, and 2; c. When a RICT is being used, any change to the plant configuration, as defined in NEI 06-09, Revision 0-A, Appendix A, must be considered for the effect on the RICT. 1. For planned changes, the revised RICT must be determined prior to implementation of the change in configuration.

: 2. For emergent conditions, the revised RICT must be determined within the time limits of the Required Action Completion Time (i.e., not the RICT) or 12 hours after the plant configuration change, whichever is less. 3. Revising the RICT is not required if the plant configuration change would lower plant risk and would result in a longer RICT. d. If the extent of condition evaluation for inoperable structures, systems, or components (SSCs) is not complete prior to exceeding the Completion Time, the RICT shall account for the increased possibility of common cause failure (CCF) by either: 1. Numerically accounting for the increased possibility of CCF in the RICT calculation; or CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 5.5-19 Amendment No. 326 Amendment No. 304 Programs and Manuals 5.5 5.5 Programs and Manuals 5.5.19 2. Risk Management Actions (RMAs) not already credited in the RICT calculation shall be implemented that support redundant or diverse SSCs that perform the function(s) of the inoperable SSCs, and, if practicable, reduce the frequency of initiating events that challenge the function(s) performed by the inoperable SSCs. e. The risk assessment approaches and methods shall be acceptable to the NRC. The plant PRA shall be based on the as-built, as-operated, and maintained plant; and reflect the operating experience at the plant, as specified in Regulatory Guide 1.200, Revision 2. Methods to assess the risk from extending the completion times must be PRA methods used to support Amendment Nos. 326/304, or other methods approved by the NRC for generic use. Any change in the PRA methods to assess risk that are outside these approval boundaries require prior NRC approval.

Surveillance Frequency Control Program This program provides controls for Surveillance Frequencies.

The program shall ensure that Surveillance Requirements specified in the Technical Specifications are performed at intervals sufficient to assure the associated Limiting Conditions for Operation are met. a. The Surveillance Frequency Control Program shall contain a list of Frequencies of those Surveillance Requirements for which the Frequency is controlled by the program. b. Changes to the Frequencies listed in the Surveillance Frequency Control Program shall be made in accordance with NEI 04-10, 11 Ri sk-Informed Technical Specifications Initiative 5b, Risk Informed Method for Control of Surveillance Frequencies, 11 Revision 1. c. The provisions of Surveillance Requirements 3.0.2 and 3.0.3 are applicable to the Frequencies established in the Surveillance Frequency Control Program. CALVERT CLIFFS -UNIT 1 CALVERT CLIFFS -UNIT 2 5.5-20 Amendment No. 326 Amendment No. 304 UNITED STATES NUCLEAR REGULATORY COMMISSION WASHINGTON, D.C. 20555-0001 EXELON GENERATION COMPANY, LLC DOCKET NO. 50-318 CALVERT CLIFFS NUCLEAR POWER PLANT, UNIT 2 AMENDMENT TO RENEWED FACILITY OPERATING LICENSE Amendment No. 304 Renewed License No. DPR-69 1. The U.S. Nuclear Regulatory Commission (the Commission) has found that: A. The application for amendment by Exelon Generation Company, LLC (Exelon, the licensee) dated February 25, 2016, as supplemented by letters dated April 3, 2017, and January 11, January 18, June 21, and August 27, 2018, complies with the standards and requirements of the Atomic Energy Act of 1954, as amended (the Act) and the Commission's rules and regulations set forth in 10 CFR Chapter I; B. The facility will operate in conformity with the application, the provisions of the Act, and the rules and regulations of the Commission; C. There is reasonable assurance (i) that the activities authorized by this amendment can be conducted without endangering the health and safety of the public, and (ii) that such activities will be conducted in compliance with the Commission's regulations; D. The issuance of this amendment will not be inimical to the common defense and security or to the health and safety of the public; and E. The issuance of this amendment is in accordance with 10 CFR Part 51 of the Commission's regulations and all applicable requirements have been satisfied.

Enclosure 2  2. Accordingly, the license is amended by changes to the Technical Specifications as indicated in the attachment to this license amendment, and paragraph 2.C.2. of Renewed Facility Operating License No. DPR-69 is hereby amended to read as follows: 2. Technical Specifications The Technical Specifications contained in Appendices A and B, as revised through Amendment No. 304, are hereby incorporated into this license. The licensee shall operate the facility in accordance with the Technical Specifications.

: 3. This license amendment is effective as of the date of its issuance and shall be implemented within 180 days.

Changes to the Renewed Facility Operating License and Technical Specifications Date of Issuance:

October 30, 2018 FOR THE NUCLEAR REGULATORY COMMISSION James G. Danna, Chief Plant Licensing Branch I Division of Operating Reactor Licensing Office of Nuclear Reactor Regulation ATTACHMENT TO LICENSE AMENDMENT NO. 304 CALVERT CLIFFS NUCLEAR POWER PLANT, UNIT 2 RENEWED FACILITY OPERATING LICENSE NO. DPR-69 DOCKET NO. 50-318 Replace the following page of the Renewed Facility Operating License with the attached revised page. The revised page is identified by amendment number and contains a marginal line indicating the area of change. Remove Page 3 Insert Page 3 Calvert Cliffs Nuclear Power Plant, Unit 2, uses the same Appendix A as Calvert Cliffs Nuclear Power Plant, Unit 1. Accordingly, the Unit 1 Renewed Facility Operating License has been updated with the following pages, which are applicable to both Units 1 and 2. Remove Pages 1.3-14 3.3.1-1 3.3.1-2 3.3.1-3 3.3.1-4 3.3.3-1 3.3.4-1 3.3.4-2 3.3.4-3 3.3.5-1 3.3.5-2 3.3.6-1 3.3.6-2 3.3.6-3 3.5.2-1 3.6.2-4 3.6.2-5 3.6.3-2 3.6.3-4 3.6.6-1 3.6.6-2 3.7.3-1 3.7.3-2 3.7.3-3 3.7.3-4 3.7.3-5 Insert Pages 1.3-14 1.3-15 3.3.1-1 3.3.1-2 3.3.1-3 3.3.1-4 3.3.3-1 3.3.4-1 3.3.4-2 3.3.4-3 3.3.5-1 3.3.5-2 3.3.6-1 3.3.6-2 3.3.6-3 3.3.6-4 3.5.2-1 3.6.2-4 3.6.2-5 3.6.2-6 3.6.3-2 3.6.3-4 3.6.6-1 3.6.6-2 3.7.3-1 3.7.3-2 3.7.3-3 3.7.3-4 3.7.3-5 3.7.3-6 Remove Pages 3.7.5-1 3.7.6-1 3.7.6-2 3.7.6-3 3.7.7-1 3.7.7-2 3.7.18-1 3.8.1-2 3.8.1-4 3.8.1-8 3.8.1-9 3.8.1-10 3.8.1-11 3.8.1-12 3.8.1-13 3.8.1-14 3.8.1-15 3.8.1-16 3.8.1-17 3.8.4-1 3.8.7-1 3.8.9-1 3.8.9-2 5.5-19 Insert Pages 3.7.5-1 3.7.6-1 3.7.6-2 3.7.6-3 3.7.7-1 3.7.7-2 3.7.7-3 3.7.18-1 3.8.1-2 3.8.1-4 3.8.1-8 3.8.1-9 3.8.1-10 3.8.1-11 3.8.1-12 3.8.1-13 3.8.1-14 3.8.1-15 3.8.1-16 3.8.1-17 3.8.1-18 3.8.4-1 3.8.7-1 3.8.9-1 3.8.9-2 5.5-19 5.5-20  ( 4) Exelon Generation pursuant to the Act and 1 O CFR Parts 30, 40, and 70, to receive, possess, and use, in amounts as required, any byproduct, source, and special nuclear material without restriction to chemical or physical form, for sample analysis or instrument calibration or associated with radioactive apparatus or components; and (5) Exelon Generation pursuant to the Act and 10 CFR Parts 30 and 70 to possess, but not separate, such byproduct and special nuclear materials as may be produced by the operation of the facility.

==1.0 INTRODUCTION==

By application dated February 25, 2016 (Reference 1 ), as supplemented by letters dated April 3, 2017 (Reference 2), and January 11 (Reference 3), January 18 (Reference 4), June 21 (Reference 5), and August 27, 2018 (Reference 7), Exelon Generation Company, LLC (Exelon, the licensee) submitted a request for changes to the Calvert Cliffs Nuclear Power Plant, Units 1 and 2 (Calvert Cliffs), Technical Specifications (TSs). The supplement dated August 27, 2018, provided additional information that clarified the application, did not expand the scope of the application as originally noticed, and did not change the U.S. Nuclear Regulatory Commission (NRC, the Commission) staff's original proposed no significant hazards consideration determination as published in the Federal Register on September 4, 2018 (83 FR 44920). The license amendment request (LAR) was originally noticed in the Federal Register on May'24, 2016 (81 FR 32806). The licensee originally proposed to adopt, with plant-specific variations, Technical Specifications Task Force (TSTF) Traveler TSTF-505, Revision 1, "Provide Risk-Informed Extended Completion Times -RITSTF [Risk-Informed TSTF] Initiative 4b" (Reference 31). By letter dated November 15, 2016 (Reference 8), the NRC suspended its approval of TSTF-505, Revision 1, because of concerns identified during the review of plant-specific LARs for adoption of TSTF-505, Revision 1. In its letter, the NRC staff stated that it would continue reviewing applications already received and site-specific proposals to address the NRC staff's concerns.

Although the scope of the amendment request has not changed, the bases for the amendments no longer rely on TSTF-505.

The proposed changes would revise the Calvert Cliffs TSs related to completion times (CTs) for required actions to provide the option to calculate longer risk-informed CTs. The proposed amendments would also add a new program, the "Risk-Informed Completion Time Program," to TS Section 5.5, "Programs and Manuals." The methodology for using the Risk-Informed Completion Time Program is described in Nuclear Energy Institute (NEI) topical report (TR) NEI 06-09, "Risk-Informed Technical Specifications Initiative 4b, Risk-Managed Technical Specifications (RMTS) Guidelines," Revision 0-A (Reference 32). NEI 06-09, Revision 0-A, Enclosure 3   provides a methodology for extending CTs and thereby delay exiting the operational mode of applicability or taking remedial actions if risk is assessed and managed within the limits and programmatic requirements established by a risk-informed completion time {RICT) program or a configuration risk management program. The NRC staff found NEI 06-09, Revision 0-A, acceptable for referencing by licensees proposing to amend their TSs to implement risk managed TSs as documented in the NRC staff's final safety evaluation (SE) for NEI TR NEl-06-09, enclosed with the staff's letter dated May 17, 2007 (Reference 11 ).  

==2.0 REGULATORY EVALUATION==

2.1. Description of Risk-Informed Completion Times TSs contain limiting conditions for operation (LCOs), which are the lowest functional capability or performance levels of equipm~nt required for safe operation of the facility.

When an LCO is not met, the licensee must shut down the reactor or follow any remedial or required action (e.g., testing, maintenance, or repair activity) permitted by the TSs until the condition can be met. The Calvert Cliffs TSs contain conditions that typically describe how the LCO can fail to be met. The licensee must take the specified required actions under designated conditions within specified completion times (CTs). Upon expiration of a CT, the TSs typically require the licensee to exit the TS operational mode of applicability or follow other prescribed remedial actions, such as shutting down the reactor. NEI 06-09, Revision 0-A, provides a risk-informed methodology for extending selected CTs and thereby delay exiting the operational mode of applicability or taking remedial actions if risk is assessed and managed within the limits and programmatic requirements established by an RICT program or a configuration risk management program. The licensee's use of the new CT requires risk to be assessed, monitored, and managed as measured by the configuration-specific core damage frequency (CDF) and large early release frequency (LERF) using processes and limits specified in NEI 06-09, Revision 0-A. Use of the new CT also requires compensatory measures, or risk management actions (RMAs), and quantitative evaluation of risk sources if probabilistic risk assessment (PRA) models are not available.

2.2 Description of Affected Systems 2.2.1 Reactor Protective System (RPS) and Engineered Safety Features Actuation System (ESFAS) Instrumentation Descriptions Chapter 7.2 of the Calvert Cliffs Updated Final Safety Analysis Report (UFSAR) (Reference

: 34) contains the following description of the RPS: The RPS consists of sensors, amplifiers, logic, and other equipment necessary to monitor selected Nuclear Steam Supply System (NSSS) conditions and to effect reliable and rapid reactor shutdown if anyone or a combination of conditions deviates from a preselected operating range. The system functions to protect the core and RCS [reactor coolant system] pressure boundary.

[ ... ]the RPS consists of four trip paths operating through the coincidence logic matrices to maintain power to, or remove it from, the control element drive mechanisms (CEDMs). Four independent measurement channels normally monitor each plant parameter which can initiate a reactor trip. Individual channel trips occur when the measurement reaches a preselected value. The channel   trips are combined in six two out of two logic matrices.

Each two out of two logic matrix provides trip signals to four one out of six logic units, each of which causes a trip of the breakers in the AC supply to the CEDM power supplies.

Chapter 7.3 of the UFSAR contains the following description of the ES FAS: The Engineered Safety Features Actuation Systems (ESFAS) initiate the start of equipment which protects the public and plant personnel from the accidental release of radioactive fission products in the unlikely event of a loss-of-coolant, main steam line break (MSLB), or loss of feedwater incident.

The safety features function to localize, control, mitigate, and terminate such incidents in order to minimize radiation exposure levels for the general public. The actuation system is divided into four sensor subsystems (sensor channels ZD, ZE, ZF, and ZG), two actuation subsystems (actuation channels ZA and ZB), and two logic subsystems for sequential loading of the diesel generators.

2.2.2 Electrical Systems Descriptions According to Calvert Cliffs UFSAR Chapter 8, "Electrical Systems," electrical (offsite) power from the 500 kilovolt (kV) network to the switchyard is supplied by three physically independent transmission lines. Two physically independent circuits supply offsite pow~r from the 500 kV switchyard to the onsite electrical distribution system via the 13 kV system. The two independent offsite power circuits from the switchyard to the engineered safety features (ESF) electrical system include two 500 kV lines and buses, two 500 kV/14kV plant service transformers, two 13 kV service buses 11 and 21, and 13.8 kV/4.16 kV unit service transformers.

The two 500 kV lines and buses, two 500 kV/14kV plant service transformers, and two 13 kV service buses 11 and 21 are shared between the two units. Each 500 kV/14 kV plant service transformer is capable of supplying the total (two units) plant auxiliary load. Offsite power can also be supplied from the 13 kV circuit from the Southern Maryland Electric Cooperative (SMECO) line. The 13 kV SMECO offsite circuit includes the 13 kV line, 13 kV service bus 23, 13 kV service bus 11 or 21, and 13.8 kV/4.16 kV unit service transformers.

The 13 kV SMECO line is capable of supplying the power required to maintain both units in a safe shutdown condition.

It may be substituted for one of the 500 kV/13 kV circuits as one of the two required, physically independent offsite circuits.

Upon loss of the switchyard power source, the SM ECO line can be used to supply any two 4.16 kV ESF buses ( one from each unit) through the 13 kV service bus 23 and either 13 kV service bus 11 or 21. Four safety-related emergency diesel generators (EDGs) are provided for the plant, two for each unit. Any combination of two of the di~sel generators (DGs) (one from each unit) is capable of supplying sufficient power ( 1) for the operation of necessary ESF loads during accident conditions in one unit and shutdown loads of the alternate unit concurrent with a loss-of-offsite power (LOOP), and (2) for the safe and orderly shutdown of both units under LOOP conditions.

The DGs start automatically on safety injection actuation signal or an undervoltage condition on the 4.16 kV ESF buses that supply vital loads, and are ready to accept loads within 10 seconds. Section 8.4, "Emergency Power Source," of the UFSAR states that the station blackout (SBO) DG is designed to provide a power source capable of starting and supplying the essential loads necessary to safely shut down one unit and maintain it in a safe shutdown condition during an SBO event. The SBO DG has the ability to supply any of the four ESF buses. The SBO diesel is started manually.

The SBO diesel is loaded onto a bus when it is determined that the EOG   dedicated to that bus is not available to supply the plant loads. The SBO diesel is capable of . supplying the same emergency plant loads as the EDGs. TS Basis 3.8.1 states that the SBO DG is available to power the inoperable DG bus loads in the event of an SBO or LOOP. TSs require the licensee to administratively verify both opposite-unit DGs are operable and the SBO DG is available within 1 hour and to continue this action once every 24 hours thereafter until restoration of the required DG is accomplished.

This verification provides assurance that both opposite-unit DGs and the SBO DG are capable of supplying the . onsite Class 1 E alternating current (AC) electrical power distribution system. The 125 volt (V) direct current (DC) and vital AC systems are designed to furnish continuous power to the plant's vital instrumentation and control (l&C) systems. The 125 V DC and 120 V vital AC systems for the plant are divided into four independent and isolated channels.

Each channel consists of one battery, two battery chargers, one 125 V DC bus, multiple DC unit control panels, and two dual inverters.

AC input for one battery charger is fed from Unit 1, and the second battery charger is fed from Unit 2. Each battery charger is fully rated and can recharge a discharged battery, while at the same time supplying the steady state power requirements of the system. During normal operation, all battery chargers are energized and maintain a constant voltage to supply the batteries with sufficient current to keep them fully charged and maintain the steady state load of DC instruments, control circuits, and inverters.

A reserve 125 V DC system, which consists of one battery, one battery charger, and associated DC switching equipment, is provided.

The reserve battery is capable of replacing any of the 125 V DC batteries, if required.

The reserve battery is connected to its own charger when it is not connected to a safety-related 125 V DC bus. Each dual inverter has two built-in independent inverters, one to serve as primary and the other as backup. In the dual inverter, 120 V AC power output can be manually switched from primary inverter to backup inverter.

The safety-related AC electrical distribution systems ( 4.16 kV, 480 V, and vital 120 V AC) supply power to the ESF systems during normal operation and under accident conditions.

The 4.16 kV and 480 V AC distribution systems for each unit include two 4.16 kV buses, four 480 V buses and load centers, and two motor control centers (MCCs). Each of the two 4.16 kV ESF buses is supplied from either an offsite power source or a DG. The 480 V ESF buses are supplied from the DGs through the 4.16 kV/480 V service transformers in case of failure of the preferred source of power to the 4.16 kV ESF buses. Each of the two MCC buses is supplied from separate EDGs via the 480 V unit load centers. The 120 V AC vital distribution system in each unit has four separate distribution panel boards/buses that provide power for four RPS channels and the four ESF and auxiliary feedwater (AFW) actuation systems (i.e., ESFAS) channels.

Each 120 V AC vital bus is normally supplied by a dual inverter with its own DC feeder from a separate battery and can be manually switched from the dual inverter to a 120 V AC bus fed from an ESF MCC through a regulating transformer.

The TSs require offsite power sources and DGs for the control room emergency ventilation system (CREVS) and control room emergency temperature system (CRETS). Calvert Cliffs UFSAR Section 9.8.2.3, "Auxiliary Building Ventilation Systems," describes the operation of the control room ventilation system. The CREVS provides a protected environment from which occupants can control the unit following an uncontrolled release of radioactivity, hazardous chemicals, or smoke. The CREVS also provides automatically actuated airborne radiological protection for the control room operations.

The CREVS is a shared system providing protection for both Units 1 and 2. The CRETS provides temperature control for the control room following isolation of the control room. The CRETS is a shared system that is supported by the CREVS, since the CREVS must be operating in the emergency recirculation mode for the CRETS to perform its safety function.

2.3 Description of Proposed Changes The licensee proposed to add a new program, "Risk-Informed Completion Time Program," in TS Section 5.5, "Programs and Manuals" of the TSs, which would require adherence to NEI 06-09, Revision 0-A, "Risk-Informed Technical Specifications Initiative 4b: Risk-Managed Technical Specificaitons (RMTS) Guidelines," dated October 2012 (Reference 12). The proposed new RICT program is applied to specific TS LCOs that do not represent a loss of specified safety function or inoperability of all trains of a system required to be operable.

The licensee's application for the changes proposed to use NEI 06-09, Revision 0-A, included documentation regarding the technical adequacy of the PRA models for the RICT program consistent with the guidance of Regulatory Guide (RG) 1.200, Revision 2, "An Approach for Determining the Technical Adequacy of Probabilistic Risk Assessment Results for Risk-Informed Activities," dated March 2009 (Reference 15). As proposd in the LAR, the following description of the RICT program would be added to the TSs: 5.5.18 Risk Informed Completion Time Program This program provides controls to calculate a Risk Informed Completion Time (RICT) and must be implemented in accordance with NEI 06-09, Revision 0-A, "Risk-Managed Technical Specifications (RMTS) Guidelines." The program shall include the following:

: a. The RICT may not exceed 30 days; b. An RICT may only be utilized in MODE 1, and 2; c. When a RICT is being used, any change to the plant configuration, as defined in NEI 06-09, Revision 0-A, Appendix A, must be considered for the effect on the RICT. 1. For planned changes, the revised RICT must be determined prior to implementation of the change in configuration.

: 2. For emergent conditions, the revised RICT must be determined within the time limits of the Required Action Completion Time (i.e., not the RICT) or 12 hours after the plant configuration change, whichever is less. 3. Revising the RICT is not required if the plant configuration change would lower plant risk and would result in a longer RICT. d. If the extent of condition evaluation for inoperable structures, systems, or components (SSCs) is not complete prior to exceeding the Completion Time, the RICT shall account for the increased possibility of common cause failure (CCF) by either:   1. Numerically accounting for the increased possibility of CCF in the RICT calculation; or 2. Risk Management Actions (RMAs) not already credited in the RICT calculation shall be implemented that support redundant or diverse SSCs that perform the function(s) of the inoperable SSCs, and, if practicable, reduce the frequency of initiating events that challenge the function(s) performed by the inoperable SSCs. e. The risk assessment approaches and methods shall be acceptable to the NRC. The plant PRA shall be based on the as-built, as-operated, and maintained plant; and reflect the operating experience at the plant, as specified in Regulatory Guide 1.200, Revision 2. Methods* to assess the risk from extending the completion times must be PRA methods used to support Amendment Nos. 326/304, or other methods approved by the NRC for generic use. Any change in the PRA methods to assess risk that are outside these approval boundaries require prior NRC approval.

* TS 3.3.1 Condition A -One or more functions with one RPS bistable trip unit or associated measurement channel inoperable except for Condition C (excore channel not calibrated with incore detectors), Required Actions A.2.1 and A.2.2.

* TS 3.3.1 Condition 8 -One or more functions with two RPS bistable trip units or associated measurement channels inoperable except for Condition C (excore channel not calibrated with incore detectors), Required Action 8.2.

* TS 3.3.1 Condition D -One or more functions with one automatic bypass removal feature inoperable, Required Actions D.2.2.1 and D.2.2.2.

* TS 3.3.1 Condition E -One or more functions with two automatic bypass removal feature channels inoperable, Required Action E.2.2.

* TS 3.3.3 Condition A -One matrix logic channel inoperable, Required Action A.1.

* TS 3.3.4 Condition A-One or more functions with one ESFAS sensor module or associated measurement channel inoperable, Required Actions A.2.1 and A.2.2.

* TS 3.3.4 Condition 8 -One or more functions with two ESFAS sensor modules or associated measurement channels inoperable, Required Action 8.2.

* TS 3.3.4 Condition D -One or more functions with the automatic block removal feature of two sensor block modules inoperable, Required Action D.2.2.

* TS 3.3.5 Condition A -One AFW actuation system manual start channel or actuation logic channel inoperable, Required Action A.1.

* TS 3.3.5 Condition C -One or more functions with one manual actuation channel or actuation logic channel inoperable except AFW actuation system, Required Action C.1.

* TS 3.3.6 Condition A -One or more functions with one sensor module or associated measurement channel per DG inoperable, Required Actions A.2.1 and A.2.2.

* TS 3.3.6 Condition B -One or more functions with two sensor modules or associated measurement channels per DG inoperable, Required Action B.2.2.

* TS 3.5.2 Condition A -One or more trains Inoperable and at least 100 percent of the emergency core cooling system flow equivalent to a single operable emergency core cooling system train available, Required Action A.1.

* TS 3.5.2 Condition C -One or more containment air locks inoperable for reasons other than Conditions A or B, Required Action C.3.

* TS 3.6.3 Condition A -One or more penetration flow paths with one containment isolation valve inoperable. (Only applicable to penetration flow paths with two containment isolation valves and not a closed system.) Required Action A.1.

* TS 3.6.3 Condition C -One or more penetration flow paths with one or more containment isolation valves inoperable, Required Action C.1 . *

* TS 3.6.6 Condition A -One containment spray train inoperable, Required Action A.1.

* TS 3.6.6 Condition B -One containment cooling train inoperable, Required Action B.1.

* TS 3.7.3 Condition A-One steam-driven AFW pump inoperable, Required Action A.2. *

* TS 3.7.3 Condition B -One motor-driven AFW pump inoperable, Required Action B.2.

* TS 3.7.3 Condition D -One AFW train inoperable for reasons other than Conditions A, B, or C, Required Action D.1.

* TS 3.7.5 Condition A -One component cooling (CC) LOOP inoperable, Required Action A.1.

* TS 3.7.6 Condition A-One service water heat exchanger inoperable, Required Action A.2.

* TS 3.7.6 Condition B -One service water subsystem inoperable, Required Action B.1.

* TS 3. 7. 7 Condition A -One saltwater subsystem inoperable, Required Action A.1.

* TS 3. 7 .18 Condition A -One required atmospheric dump valve (ADV) line inoperable, Required Action A.1.

* TS 3.8.1 Condition A -One required LCO 3.8.1.a offsite circuit inoperable, Required Action A.3.

* TS 3.8.1 Condition B -One LCO 3.8.1.b DG inoperable, Required Action B.5.

* TS 3.8.1 Condition G -Two required LCO 3.8.1.a offsite circuits inoperable.

OR One required LCO 3.8.1.a offsite circuit that provides power to the CREVS and CRETS inoperable and the required LCO 3.8.1.c offsite circuit inoperable, Required Action G.2.

* TS 3.8.1 Condition H -One required LCO 3.8.1.a offsite circuit inoperable AND One LCO 3.8.1.b DG inoperable, Required Action H.1 and H.2.

* TS 3.8.4 Condition A -One DC channel A.1 inoperable due to an inoperable battery and the reserve battery available, Required Action A.1. *

* TS 3.8.4 Condition B -One DC channel inoperab1 e for reasons other than Condition A, Required Action B.1.

* TS 3.8. 7 Condition A -One required inverter inoperable, Required Action A.1.

* TS 3.8.9 Condition A -One or more AC electrical power distribution subsystems inoperable.

* TS 3.8.9 Condition B -One or more AC vital bus subsystem(s) inoperable, Required Action B.1.

* TS 3.8.9 Condition C -One DC electrical power distribution subsystem inoperable, Required Action C.1. Also, the licensee proposed to add the following example to the TSs as Example 1.3-8: ACTIONS CONDITION REQUIRED ACTION COMPLETION TIME A. One subsystem A.1 Restore subsystem 7 days inoperable.

to OPERABLE status. OR In accordance with the Risk Informed Completion Time Program B. Required Action B.1 Be in MODE 3. 6 hours and associated Completion Time AND not met. B.2 Be in MODE 5. 36 hours   When a subsystem is declared inoperable, Condition A is entered. The 7 day Completion Time may be applied as discussed in Example 1.3-2. However, the licensee may elect to apply the Risk-Informed Completion Time Program which permits calculation of a Risk Informed Completion Time (RICT) that may be used to complete the Required Action beyond the 7 day Completion Time. The RICT cannot exceed 30 days. After the 7 day Completion Time has expired, the subsystem must be restored to OPERABLE status within the RICT or Condition B must also be entered. The Risk-Informed Completion Time Program requires recalculation of the RICT to reflect changing plant conditions.

For planned changes, the revised RICT must be determined prior to implementation of the change in configuration.

For emergent conditions, the revised RICT must be determined within the time limits of the Required Action Completion Time (i.e., not the RICT) or 12 hours after the plant configuration change, whichever is less. If the 7 day Completion Time clock of Condition A has expired and subsequent changes in plant condition result in exiting the applicability of the Risk Informed Completion Time Program without restoring the inoperable subsystem to OPERABLE status, Condition B is also entered and the Completion Time clocks for Required Actions B.1 and B.2 start. If the RICT expires or is recalculated to be less than the elapsed time since the Condition was entered and the inoperable subsystem has not been restored to OPERABLE status, Condition B is also entered and the Completion Time clocks for Required Actions B.1 and B.2 start. If the inoperable subsystems are restored to OPERABLE status after Condition B is entered, Conditions A and Bare exited, and therefore, the Required Actions of Condition B may be terminated.

2.4 Applicable Requirements and Guidance 2.4.1 Regulatory Requirements 2.4.1.1 Technical Specifications The regulatory requirements related to the content of the TSs are contained in Title 10 of the Code of Federal Regulations (10 CFR) Section 50.36, "Technical specifications." Section 50.36 of 10 CFR requires TSs to include the following categories related to station operation:

(1) safety limits, limiting safety systems settings, and control settings; (2) LCOs; (3) surveillance requirements; (4) design features; (5) administrative controls; (6) decommissioning; (7) initial notification; and (8) written reports. Section 50.36(c)(2)(i) of 10 CFR states: Limiting conditions for operation are the lowest functional capability or performance levels of equipment required for safe operation of the facility.

When a limiting condition for operation of a nuclear reactor is not met, the licensee shall   shut down the reactor or follow any remedial action permitted by the technical specifications until the condition can be met. Section 50.36(c)(2) of 10 CFR does not describe any specific safety standard for the remedial actions permitted by the TSs. However, both the common standards for licenses in 10 CFR 50.40(a) and those specifically for issuance of operating licenses in 10 CFR 50.57(a)(3) provide that there must be "reasonable assurance" that the activities at issue will not endanger the health and safety of the public. Section 50.36(c)(5) of 10 CFR states, in part, "Administrative controls are the provisions relating to organization and management, procedures, recordkeeping, review and audit, and reporting necessary to assure operation of the facility in a safe manner." The regulation in 10 CFR 50.36(c)(5) does not provide prescriptive requirements for the content of administrative control programs.

2.4.1.2 Instrumentation and Control Systems The regulations in 10 CFR 50.55a(h) require, for nuclear power plants with construction permits issued before January 1, 1971, that protection systems must be consistent with "their plant-specific licensing basis or may meet the requirements of IEEE Std. 603-1991 and the correction sheet dated January 30, 1995." The plant-specific licensing basis for Calvert Cliffs, Units 1 and 2, is described in Section 7.1, "Introduction," and Section 7.2.2, "Design Basis," of the Calvert Cliffs UFSAR. Section 7.1 states: All protection systems that actuate reactor trip, ESFs, and AFW components are designed to conform to the criteria of Institute of Electrical and Electronic Engineers (IEEE) 279 and those sections that are relevant from the Commission's proposed General Design Criteria, as published February 20, 1971. Section 7.2.2 of the Calvert Cliffs, Units 1 and 2, UFSAR, further states that, "Instrumentation conforms to the provisions of the proposed IEEE, Criteria for Nuclear Power Plant Protection Systems (IEEE 279, August 1968)." IEEE 279-1968 thus established the plant-specific licensing basis to which Calvert Cliffs must conform. Clause 4.2, "Single Failure Criterion," of IEEE 279-1968 requires that: Any single failure within the protection system shall not prevent proper protection system action when required.

Clause 4.11, "Channel Bypass or Removal from Operation," of IEEE 279-1968 requires that: The system shall be designed to permit any one channel to be maintained, and when required, tested or calibrated during power operation without initiating a protective action at the systems level. During such operation the active parts of the system shall of themselves continue to meet the single failure criterion.

However, the single failure criterion is allowed to be violated by the exception specified in this clause:   Exception: "One out of two" systems are permitted to violate the single failure criterion during channel bypass provided that acceptable reliability of operation can be otherwise demonstrated.

Appendix A, "General Design Criteria for Nuclear Power Plants" (GDC), to Part 50 of 1 O CFR, GDC-22, "Protection system independence," provides, in part, that, "Design techniques, such as functional diversity or diversity in component design and principles of operation, shall be used to the extent practical to prevent loss of the protection function." 2.4.1.3 Electrical Power Systems Calvert Cliffs UFSAR Appendix 1 C states, in part, "Calvert Cliffs was designed and constructed to meet the intent of the draft (proposed)

GDC for Nuclear Power Plants, which was published by the Atomic Energy Commission in July 1967. Modifications to the facility are evaluated in accordance with 10 CFR 50.59 to assess consistency with the current licensing basis (including the draft GDC, as applicable)." The following draft GDC 24 and 39 are applicable to the Calvert Cliffs electrical power systems. Draft GDC 24, "Emergency Power for Protection Systems," states, "In the event of loss of all offsite power, sufficient alternate sources of power shall be provided to permit the required functioning of the protection systems." Draft GDC 39, "Emergency Power for Engineered Safety Features," states, "An alternate power system shall be provided and designed with adequate independency, redundancy, capacity, and testability to permit the functioning required of the ESFs. As a minimum, the onsite power system and the offsite power system shall each, independently, provide this capacity, assuming a failure of a single active component in each power system." Calvert Cliffs UFSAR Appendix 1C states that a new safety-related DG (EDG 1A) was installed at Calvert Cliffs in 1996. The new EDG 1A, its support systems, and the building which houses it, were designed to the final GDC in Appendix A to 10 CFR Part 50. Appendix A to 10 CFR Part 50, GDC 17, "Electric power systems," requires, in part, that an onsite electric power system and an offsite electric power system be provided to permit functioning of SSCs important to safety. The safety function for each system (assuming the other system is not functioning) shall be to provide sufficient capacity and capability to assure that (1) specified acceptable fuel design limits and design conditions of the reactor coolant pressure boundary are not exceeded as a result of anticipated operational occurrences, and (2) the core is cooled and containment integrity and other vital functions are maintained in the event of postulated accidents.

The onsite electric power supplies, including the batteries and the onsite electric distribution system, shall have sufficient independence, redundancy, and testability to perform their safety functions, assuming a single failure. 2.4.2 Policy Statements In the Commission's "Final Policy Statement:

Technical Specifications for Nuclear Power Plants," dated July 22, 1993 (58 FR 39132), the Commission addressed the use of probabilistic   safety analysis (PSA), (currently referred to as PRA) in the Standard Technical Specifications).

In this 1993 publication, the Commission stated, in part: The Commission believes that it would be inappropriate at this time to allow requirements which meet one or more of the first three criteria [of Title 1 O of the Code of Federal Regulations (10 CFR), Section 50.36] to be deleted from Technical Specifications based solely on PSA (Criterion 4). However, if the results of PSA indicate that Technical Specifications can be relaxed or removed, a deterministic review will be performed.

The Commission Policy in this regard is consistent with its Policy Statement on "Safety Goals for the Operation of Nuclear Power Plants," 51 FR 30028, published on August 21, 1986. The Policy Statement on Safety Goals states in part, "[ ... ] probabilistic results should also be reasonably balanced and supported through use of deterministic arguments.

In this way, judgments can be made[ ... ] about the degree of confidence to be given these [probabilistic]

estimates and assumptions.

This is a key part of the process for determining the degree of regulatory conservatism that may be warranted for particular decisions.

This defense-in-depth approach is expected to continue to ensure the protection of public health and safety." The Commission will continue to use PSA, consistent with its policy on Safety Goals, as a tool in evaluating specific line-item improvements to Technical Specifications, new requirements, and industry proposals for risk-based Technical Specification changes. Approximately 2 years later, the Commission provided additional detail concerning the use of PRA in the "Final Policy Statement:

Use of Probabilistic Risk Assessment in Nuclear Regulatory Activities," dated August 16, 1995 (60 FR 42622). In this publication, the Commission stated: The Commission believes that an overall policy on the use of PRA methods in nuclear regulatory activities should be established so that the many potential applications of PRA can be implemented in a consistent and predictable manner that would promote regulatory stability and efficiency.

In addition, the Commission believes that the use of PRA technology in NRC regulatory activities should be increased to the extent supported by the state-of-the-art in PRA methods and data and in a manner that complements the NRC's deterministic approach.

[ ... ] PRA addresses a broad spectrum of initiating events by assessing the event frequency.

Mitigating system reliability is then assessed, including the potential for multiple and common cause failures.

The treatment therefore goes beyond the single failure requirements in the deterministic approach.

The probabilistic approach to regulation is, therefore, considered an extension and enhancement of traditional regulation by considering risk in a more coherent and complete manner. [ ... ] Therefore, the Commission believes that an overall policy on the use of PRA in nuclear regulatory activities should be established so that the many potential applications of PRA can be implemented in a consistent and predictable manner   that promotes regulatory stability and efficiency.

This policy statement sets forth the Commission's intention to encourage the use of PRA and to expand the scope of PRA applications in all nuclear regulatory matters to the extent supported by the state-of-the-art in terms of methods and data. [ ... ] Therefore, the Commission adopts the following policy statement regarding the expanded NRC use of PRA: ( 1) The use of PRA technology should be increased in all regulatory matters to the extent supported by the state-of-the-art in PRA methods and data and in a manner that complements the NRC's deterministic approach and supports the NRC's traditional defense-in-depth philosophy.

(2) PRA and associated analyses (e.g., sensitivity studies, uncertainty analyses, and importance measures) should be used in regulatory matters, where practical within the bounds of the state-of-the-art, to reduce unnecessary conservatism associated with current regulatory requirements, regulatory guides, license commitments, and staff practices.

Where appropriate, PRA should be used to support the proposal for additional regulatory requirements in accordance with 10 CFR 50.109 (Backfit Rule). Appropriate procedures for including PRA in the process for changing regulatory requirements should be developed and followed.

It is, of course, understood that the intent of this policy is that existing rules and regulations shall be complied with unless these rules and regulations are revised. (3) PRA evaluations in support of regulatory decisions should be as realistic as practicable and appropriate supporting data should be publicly available for review. ( 4) The Commission's safety goals for nuclear power plants and subsidiary numerical objectives are to be used with appropriate consideration of uncertainties in making regulatory judgments on the need for proposing and backfitting new generic requirements on nuclear power plant licensees.

2.4.3 Regulatory Guidance RG 1.17 4, Revision 3, "An Approach for Using Probabilistic Risk Assessment in Risk-Informed Decisions on Plant-Specific Changes to the Licensing Basis" (Reference 13), describes an acceptable risk-informed approach for assessing the nature and impact of proposed permanent licensing basis changes by considering engineering issues and applying risk insights.

This RG also provides risk acceptance guidelines for evaluating the results of such evaluations.

RG 1.177, Revision 1, "An Approach for Plant-Specific, Risk-Informed Decision making: Technical Specifications" (Reference 14), describes an acceptable risk-informed approach specifically for assessing proposed TS changes. Both RGs list the same set of principles of risk-informed integrated (or plant-specific) decisionmaking that are expected to be addressed when implementing risk-informed TS changes. RG 1.177 provides guidance specifically for risk-informed TS changes consistent with, but more detailed than, the generally applicable guidance given in RG 1.17 4. The principles, which are also referred to as key principles, are:   1. The proposed change meets the current regulations unless it is explicitly related to a requested exemption.

: 3. The proposed change maintains sufficient safety margins. 4. When proposed changes result in an increase in core damage frequency (CDF) or risk, the increases should be small and consistent with the intent of the Commission's Safety Goal Pc,licy Statement.

* Tier 1 assesses the risk impact of the proposed change in accordance with acceptance guidelines consistent with the Commission's Safety Goal Policy Statement, as documented in RG 1.17 4 and RG 1.177. The first tier assesses the impact on plant risk as expressed by the change in core damage frequency

(~CDF) and change in large early release frequency

(~LERF). It also evaluates plant risk while equipment covered by the proposed CT is out of service, as represented by incremental conditional core damage probability (ICCDP) and incremental conditional large early release probability (ICLERP).

Tier 1 also addresses PRA quality, including the technical adequacy of the licensee's plant-specific PRA for the subject application.

Cumulative risk of the proposed TS change is considered with uncertainty/sensitivity analysis with respect to the assumptions related to the proposed TS change.

* Tier 2 identifies and evaluates any potential risk-significant plant equipment outage configurations that could result if equipment, in addition to that associated with the proposed license amendment, is removed from service simultaneously, or if other risk-significant operational factors, su1ch as concurrent system or equipment testing, are also involved.

The purpose of this evaluation is to ensure that there are appropriate restrictions in place such that risk-significant plant equipment outage configurations will not occur when equipment associated with the proposed CT is implemented.

* Tier 3 addresses the licensee's configuration risk management program (CRMP) to ensure that adequate programs and procedures are in place for identifying risk-significant plant configurations resulting from maintenance or other operational activities and appropriate compensatory measures are taken to avoid risk-significant configurations that may not have been considered when the Tier 2 evaluation was performed.

Compared with Tier 2, Tier 3 provides additional coverage to ensure risk-significant plant equipment outage configurations are identified in a timely manner and that the risk impact of out-of-service equipment is appropriately evaluated prior to performing any maintenance activity over extended periods of plant operation.

Tier 3 guidance can be satisfied by the Maintenance Rule, which requires a licensee to assess and manage the increase in risk that may result from activities such as surveillance testing and corrective and preventive maintenance, subject to the guidance provided in RG 1.177, Section 2.3.7.1, and the adequacy of the licensee's program and PRA model   for this application.

The CRMP ensures that equipment removed from service prior to or during the proposed extended CT will be appropriately assessed from a risk perspective.

RG 1.200, Revision 2 (Reference 15), describes an acceptable approach for determining whether the quality of the PRA, in total, or the parts that are used to support an application, is sufficient to provide confidence in the results such that the PRA can be used in regulatory decisionmaking for light water-reactors.

RG 1.200 provides regulatory guidance for assessing the technical adequacy of a PRA. RG 1.200, Revision 2, endorses, with clarifications and qualifications, the use of the American Society of Mechanical Engineers (ASME)/American Nuclear Society (ANS) Standard, RA-Sa-2009, "Addenda to ASME RA-S-2008, "Standard for Level 1/Large Early Release Frequency Probabilistic Risk Assessment for Nuclear Power Plant Applications" (i.e., the "PRA standard") (Reference 16). NEI 06-09, Revision 0-A, provides a methodology for modifying selected required actions to provide an optional RICT. The optional RICT can be used to delay exiting the operational mode of applicability or taking remedial actions if risk is assessed and managed within the limits and programmatic requirements established by an RICT program or a configuration risk management program. The NRC staff found NEI 06-09, Revision 0-A, acceptable for referencing by licensees proposing to amend their TSs to implement risk managed TSs as documented in the staff's final SE for NEI TR NEl-06-09, enclosed with the staff's letter dated May 17, 2007 (Reference 11 ). 3.0 TECHNICAL EVALUATION The licensee proposed to add an RICT program to the administrative controls section of the TSs and modify selected TS required actions to p1~rmit extending CTs if risk is assessed and managed as described in NEI 06-09, Revision 0-A (Reference 12). In accordance with NEI 06-09, Revision 0-A, PRA methods are used to justify each extension to a required action CT based on the specific plant configuration that exists at the time of the applicability of the required action, and are updated when plant conditions change. The licensee's LAR included documentation regarding the technical adequacy of the PRA models used in the CRMP, consistent with the requirements of RG 1.200. Most TSs identify one or more conditions for which the LCO may not be met to permit a licensee to perform required testing, maintenance, or repair activities.

Each condition has an associated required action for restoration of the LCO, or for other actions, each with a fixed time interval referred to as the CT, which specifies the tii:ne interval permitted to complete the required action. Upon expiration of the CT, typically the licensee is required to exit operational mode of applicability or follow the required action(s) stated in the LCO. The RICT program provides administrative controls to permit extension of CTs and thereby delay reactor shutdown or completion of the required action(s) if risk is assessed and managed within specified limits and programmatic requirements.

The specified safety function or performance level of TS required equipment is unchanged, and the required action(s), including the requirement to shut down the reactor, are also unchanged.

Only the CTs for the required actions are extended by the RICT program. The NRC staff reviewed the licensee's PRA methods and models to determine if they are technically acceptable for use in the proposed risk-informed CT extensions.

The NRC staff also reviewed the licensee's proposed RICT program to determine if it provides the necessary administrative controls to permit CT extensions. 3.1 Review of Key Principles RG 1.177, Revision 1 (Reference 14 ), identifies five key safety principles to be applied to risk-informed changes to the TSs. The licensee in its LAR addresses each of these principles.

The NRC staff evaluated the licensee's propo,sed use of RICTs against these key safety principles as discussed below. 3.1.1 Key Principle 1: Compliance with Current Regulations As stated in 10 CFR 50.36(c)(2):

Limiting conditions for operation are the lowest functional capability or performance levels of equipment required for safe operation of the facility.

When a limiting condition for operation of a nuclear reactor is not met, the licensee shall shut down the reactor or follow any remedial action permitted by the TSs until the condition can be met, When the necessary redundancy is not maintained (e.g., one train of a two-train system is inoperable), the TSs permit a limited period of time to restore the inoperable train to operable status and/or take other remedial measures.

If these actions are not completed within the CT, the TSs normally require that the plant exit the mode of applicability for the LCO. With one train of a two-train system inoperable, the TS safety function is accomplished by the remaining operable train. In the current TSs, the CT is specified as a fixed time period. The addition of the option to determine the CT in accordance with the RICT program would allow an evaluation to determine an RICT. The evaluation would be done in accordance with the methodology prescribed in NEI 06-09, Revision 0-A, and TS 5.5.18. The RICT is limited to a maximum of 30 days, provided there is no loss of TS safety function.

The CTs in the current TSs were established using experiential data, risk insights, and engineering judgement.

The licensee proposed one change to the TSs that involves a change other than revising the CT to reflect the option of calculating an RICT. The licensee proposed that LCO 3.6.3, Containment Isolation Valves, Action A.2, also be revised. Currently, Condition A is applicable with one or more penetration flow paths with one containment isolation valve inoperable.

The required action is to isolate the affected penetration within 4 hours (Required Action A.1) and verify it is isolated once per 31 days (Required Action A.2). Required Action A.1 is being modified to reflect the incorporation of an RICT. Since Required Action A.1 will have a variable CT, it is necessary to make a conforming change to Required Action A.2 to require verification that the affected penetration flow path is isolated once per 31 days following isolation for isolation devices outside containment.

The NRC staff finds this conforming change acceptable because the verification that the penetration flow path is isolated will continue to be verified once per 31 days. 3.1. 1. 1 Evaluation of Electrical Power Systems Draft GDC 24 and 39, and 10 CFR Part 50, Appendix A, GDC 17 requirements are reflected, in part, in the electrical power systems TS LCOs, which require redundant electrical power sources/equipment to be operable (in operating modes). When a TS LCO is not met because an electrical power source or equipment required by a TS LCO is inoperable, the TSs require the licensee to follow any remedial actions permitted by the TSs until the LCO can be met or exit the mode of applicability for the LCO. The current Calvert Cliffs TSs permit entry in a TS condition to restore the inoperable power source or equipment to operable status within the CT. During the RICT program entry for the proposed electrical TS conditions, when the LCO is not met due to the inoperable electrical power source or equipment, the redundancy required by the TS LCO (in operating modes), as specified by draft GDC 24 and 39, and GDC 17, will not be maintained.

Therefore, the NRC staff finds that the requirements of draft GDC 24 and 39, and 10 CFR Part 50, Appendix A, GDC 17 are not temporarily met during the RICT program entry for the proposed electrical power systems TS conditions since the redundancy required by the GDC is not maintained.

The NRC staff also finds that operating the plant while remedial actions are being taken, during the period of time the redundancy required by the GDC and LCO is not maintained, is allowed by 10 CFR 50.36(c)(2), which states, 'When an LCO of a nuclear reactor is not met, the licensee shall shut down the reactor or follow any remedial action permitted by the technical specifications until the condition can be met." When the necessary redundancy is not maintained (e.g., one train of a two train system is inoperable), the TSs permit a limited period of time to restore the inoperable train to operable status and/or take other remedial measures.

If these actions are not completed within the CT, the TSs normally require that the plant exit the mode of applicability for the LCO. With one train of a two train system inoperable, the TS safety function is accomplished by the remaining operable train. In the current TSs, the CT is specified as a fixed time period. The addition of the option to determine the CT in accordance with the RICT program would allow an evaluation to determine a configuration-specific CT. The evaluation would be done in accordance with the methodology prescribed in NEI 06-09, Revision 0-A, and TS 5.5.18. The RICT is limited to a maximum of 30 days and can only be used when there is no TS or PRA loss of function.

The RICT program provides the necessary administrative controls to permit extension of CTs and thereby delay reactor shutdown or required actions if risk is assessed and managed appropriately within specified limits and programmatic requirements.

3.1.1.2 Evaluation of Instrumentation and Control Systems Calvert Cliffs TS 3.3, "Instrumentation," LCOs were developed to assure that the Calvert Cliffs facility maintains necessary redundancy and diversity, and complies with the "single failure" design criterion as defined in Clause 4.2 of IEEE 279-1968, ~dequate bypass redundancy requirement as defined in Clause 4.11 of IEEE 279-1968, and adequate diversity requirements as defined in GDC 22. The l&C safety functions identified in the LAR maintain the capability to perform their safety functions when a channel is placed out of service. Therefore, the l&C system diversity configuration remains unchanged.

Based on the discussion provided above, the NRC staff concludes that the proposed changes to TS 3.3 meet current diversity requirements as defined in GDC 22. Under certain TS conditions, the single failure criterion cannot be met until the affected channel is placed in trip position or restored to operable.

In accordance with the RICT program defined   in TS 5.5.18, the RICT program provides the necessary administrative controls to permit an extension of CTs, and thereby delay exiting the operational mode of applicability or required actions. If an RICT is calculated in accordance with the RICT program, the NRC staff finds that the affected system operation reliability remains acceptable and is consistent with overall system reliability and risk considerations.

3.1.1.3 Key Principle 1 Conclusions The NRC staff finds that the proposed changes are in compliance with the applicable regulations.

The NRC staff concludes that proposed TS 5.5.18 provides the necessary controls to assure operation of the facility in a safe manner. This satisfies 10 CFR 50.36( c)(2), because the minimum required performance levels of SSCs are not changed by the incorporation of the option to calculate an RICT and the remedial actions applicable when an LCO is not met are not changed by the incorporation of the RICT program. Therefore, the NRC staff concludes that the proposed TS changes continue to satisfy the requirements of 10 CFR 50.36(c)(2).

The NRC staff also concludes that operating the plant while remedial actions are being taken, during the period of time the redundancy required by the GDC and LCO is not maintained, is allowed by 10 CFR 50.36(c)(2), which states, "When an LCO of a nuclear reactor is not met, the licensee shall shut down the reactor or follow any remedial action permitted by the technical specifications until the condition can be met." Additionally, the NRC staff considers that the affected l&C systems' operation reliability remains acceptable and is consistent with overall system reliability and risk considerations.

Therefore, the NRC staff concludes that the proposed changes involving the affected l&C power systems meet the requirements defined in Clauses 4.2 and 4.11 of IEEE 279-1968.

3.1.2 Key Principle 2: Evaluation of Defense-in-Depth Defense-in-depth is an approach to designing and operating nuclear facilities that prevents and mitigates accidents that release radiation or hazardous materials.

The key is creating multiple independent and redundant layers of defense to compensate for potential human and mechanical failures so that no single layer, no matter how robust, is exclusively relied upon. Defense-in-depth includes the use of access controls, physical barriers, redundant and diverse key safety functions, and emergency response measures.

As discussed throughout RG 1.17 4 (Reference 13), consistency with the defense-in-depth (DID) philosophy is maintained by the following measures:

: 1. Preserve a reasonable balance among the layers of defense. 2. Preserve adequate capability of design features without an overreliance on programmatic activities as compensatory measures.

: 4. Preserve adequate defense against potential CCFs. 5. Maintain multiple fission product barriers. 6. Preserve sufficient defense against human errors. 7. Continue to meet the intent of the plant's design criteria.

The proposed change provides a technical approach that balances avoidance of core damage, avoidance of containment failure, and consequence mitigation.

The three-tiered approach to risk-informed TS CT changes in RG 1.177 provides additional assurance that DID will not be significantly impacted by such changes to the licensing basis. The licensee is proposing no changes to the design of the plant or any operating parameter, no new operating configurations, and no new changes to the design basis in the proposed changes to the TSs. An RICT may not be determined and used following a loss of TS safety function because the system has lost the capability to perform its safety function(s).

This restriction, to not apply an RICT to loss of a TS-specified safety function or inoperability of all required trains of a system, ensures that consistency with the DID philosophy is maintained by following existing guidance when the capability to perform a TS safety function(s) is lost. The proposed RICT program uses plant-specific operating experience for component reliability and availability data. Thus, the allowances permitted by the RICT program are directly reflective of actual component performance in conjunction with component risk significance.

In certain cases, the RICT program may use compensatory actions to reduce calculated risk in some configurations.

Where credited in the PRA, these actions are incorporated into station procedures or work instructions and have been modeled using appropriate human reliability considerations.

Application of the RICT program determines the risk significance of plant configurations.

It also permits the operator to identify the equipment that has the greatest effect on the existing configuration risk. With this information, the operator can manage the out-of-service duration and determine the consequences of removing additional equipment from service. 3.1.2.1 Use of Compensatory Measures to Retain Defense-in-Depth Application of the RICT program provides a structure to assist the operator in identifying effective compensatory actions for various plant maintenance configurations to maintain and manage acceptable risk levels. NEI 06-09, Revision 0-A, addresses potential compensatory actions and RMA measures by stating, in generic terms, that compensatory measures may include, but are not limited, to the following:

NEI 06-09, Revision 0-A, requires that compensatory measures be initiated when the PRA-calculated risk management action time (RMAT) is exceeded, or for preplanned maintenance for which the RMAT is expected to be exceeded, RMAs shall be implemented at the earliest appropriate time. Compensatory measures are developed to provide assurance that additional defenses are in place for specific plant configurations, as appropriate.

Therefore, the NRC staff finds that compensatory measures support the conclusion that the RICT program is consistent with the principle of DID. 3.1.2.2 Evaluation of Electrical Power Systems In the LAR, the licensee stated that the proposed amendments would modify the TS requirements related to CTs for various required actions to provide the option to calculate a longer risk-informed CT. The licensee is proposing to incorporate the RICT program into its TSs for applicability only during Modes 1 and 2. The RICT program has a maximum limit of 30 days for any required action. The NRC staff evaluated whether the plant would continue to have DID if the proposed RICT program relating to TS Section 3.8 is implemented.

The NRC staff reviewed the DID of the electrical power systems for the TS conditions that would be impacted by the RICT program. The DID philosophy is incorporated into the design of the electrical power systems by having multiple or redundant and independent layers of electrical power sources and subsystems to ensure power to equipment required to prevent and mitigate postulated design-basis accidents (DBAs), events, transients, and abnormal occurrences, assuming a single failure. The LCOs for the electrical power systems TSs require redundant electrical power sources or equipment that is capable of performing necessary safety functions, assuming a single failure, to be operable when a plant is in one of the operating modes. If an electrical power source or equipment required by a TS LCO is inoperable, the required redundancy (i.e., DID) will be reduced or lost, the LCO will not be met, and an applicable TS condition will be entered for remedial actions. For this review, the NRC staff evaluated the reduced DID in each proposed electrical TS condition to determine whether the reduced DID during the RICT program entry for the specific TS condition is consistent with the DID philosophy of having multiple layers of defense during plant operation to mitigate accidents, and the staff considered the attributes of the DID philosophy described in RGs 1.17 4 and 1.177. The NRC staff reviewed information pertaining to the proposed electrical power systems TS conditions in the application, UFSAR, and the applicable TS LCOs and Bases to identify supplemental safety or non-safety-related electrical power sources or equipment (not necessarily required by the LCOs) that is available at Calvert Cliffs and is capable of performing the same safety function of the inoperable electrical power source or equipment.

The following postulated DBAs identified in Calvert Cliffs UFSAR Chapter 14, "Safety Analysis," were considered for the review: control element assembly (CEA) ejection event, steam line break (SLB) event, steam generator tube rupture (SGTR) event, seized rotor event, loss-of-coolant accident {LOCA) event, and feedline break event. The CEA ejection, SGTR, and seized rotor events were analyzed with offsite power available.

The SLB, LOCA, and feedline break events analyses assumed a concurrent LOOP. The SLB and LOCA events also assumed a concurrent single failure. The CEA ejection, SLB, SGTR, and seized rotor events assumed radiological release into the control room. All postulated DBAs credited actuation of the RPS and/or ESFAS. The DBAs were assumed to occur at full power. For this review, the NRC staff grouped the postulated DBAs in two groups based on UFSAR Chapter 14 safety analyses:

DBAs with offsite power (i.e., accidents with offsite power available) and DBAs without offsite power (i.e., accidents concurrent with LOOP). The LOOP was assumed to be the loss of the electrical grid. For each electrical power systems TS condition affected by the RICT program, the licensee provided the Calvert Cliffs design-success criteria in Table E1-1, "In Scope TS/LCO Conditions   to Corresponding PRA Functions," of the letter dated January 11, 2018. Each TS condition design success criterion reflects the redundant or absolute minimum electrical power source or subsystem required to be operable by the LCOs to support the minimum safety functions necessary to mitigate postulated DBAs, safely shut down the reactor, and maintain the reactor in a safe shutdown condition.

The NRC staff notes that since the use of the RICT program is based on the plant configurations provided in this application, the NRC staff review of the DID of the electrical power systems was limited to only this set of plant configurations.

For p~rposes of this review, a single layer of DID is considered to be an electrical power source or equipment that is not necessarily required by the LCOs and can be either safety or non-safety-related.

3.1.2.2.1 TS 3.8.1 -AC Sources-Operating During operation, TS LCO 3.8.1 requires the following AC electrical sources to be operable:

: a. Two qualified circuits between the offsite transmission network and the onsite Class 1 E AC Electrical Power Distribution System; b. Two DGs each capable of supplying one train of the onsite Class 1 E AC Electrical Power Distribution System; and c. One qualified circuit between the offsite transmission network and the other unit's onsite Class 1 E AC electrical power distribution subsystems needed to supply power to the CREVS and CRETS, and one DG from the other unit capable of supplying power to the CREVS and CRETS. Per TS Basis 3.8.1, the offsite power circuits are the two 13 kV buses 11 and 21, which can be powered by either (1) two 500 kV lines with associated two 500 kV buses and two plant P-13000 service transformers or (2) one 500 kV line with associated one 500 kV bus and one plant P-13000 service transformer and the 13 kV SMECO line. TS Basis 3.8.1 states that the LCO requires operability of two out of three qualified circuits between the transmission network and the onsite Class 1 E AC electrical power distribution system circuits.

These circuits consist of two 500 kV circuits and the 69 kV SMECO dedicated source. TS Basis 3.8.1 further states that when appropriate, the ESFAS loss-of-coolant incident and shutdown sequencer for the 4.16 kV bus will sequence loads on the bus after the 69 kV/13.8 kV SMECO line has been manually placed in service. According to Calvert Cliffs UFSAR Section 8.1.3, "Shared Electrical Equipment," the following components of the offsite power circuits are shared by Units 1 and 2: service transformers P-13000-1 and P-13000-2, 13 kV service bus 11 and bus 21, the 500 kV red bus, and the 500 kV black bus. Therefore, both units would enter their respective TS conditions if any of the common components of the offsite power circuits were inoperable.

Although the SBO DG in its normal operating condition cannot be started within 10 seconds upon receiving a start signal to support the assumptions of the design-basis LOCA analysis in the UFSAR, this DG has been credited in the Calvert Cliffs TSs as an emergency power source. TS 3.8.1 Conditions B, E, and F require the SBO DG to be in an available status (aligned with the safety buses) when one required DG is inoperable.

While in the above TS conditions, operator action (closing a breaker) from the control room will start and load this DG. TS 3.8.1 Condition A -One required LCO 3.8.1.a offsite circuit inoperable The licensee proposed the option to use the RICT program to extend the existing 72-hour CT up to a maximum of 30 days to restore the required offsite circuit to operable status (Required Action A.3) for TS 3.8.1 Condition A. The RICT estimate for TS 3.8.1 Condition A in Table E1-2 is 30 days. According to Table E1-1, the design-success criteria for TS 3.8.1 Condition A is "One qualified circuit between the offsite transmission network and the onsite [Class] 1 E AC Electrical Power Distribution System." Therefore, during an RICT program entry for TS 3.8.1 Condition A, the remaining required LCO 3.8.1.a offsite circuit and SMECO line, in addition to the two LCO 3.8.1.b DGs, will be capable of supplying power to the ESF systems required to mitigate DBAs with offsite power available; thus, the required design-success criteria is met. In case offsite power is lost concurrently with the DBAs, as assumed in the UFSAR Chapter 14 analysis, the two operable LCO 3.8.1.b DGs will have the capability to power the minimum ESF systems required to mitigate the DBAs. Based on the above discussion, the NRC staff finds that during the RICT program entry for TS 3.8.1 Condition A, the DID of the electrical power systems that ensures AC power to key safety-related equipment required to operate during DBAs is reduced (1) to four layers of defense (an LCO 3.8.1.a offsite circuit, the SMECO line, and two LCO 3.8.1.b DGs) for DBAs with offsite power, and (2) two layers of defense (two LCO 3.8.1.b DGs) for DBAs without offsite power. In addition, in the letter dated January 11, 2018, in response to an NRC staff request for additional information (RAI) dated November 13, 2017 (Reference 9), the licensee stated that it will implement RMAs when in TS 3.8.1 Condition A. The example RMA, if implemented, would:

* Evaluate weather forecasts prior to entering the LCO to ensure favorable conditions exist for the entire length of the expected CT. Considering that the design-success criteria will be met during operation with a TS RICT, and RMAs will be implemented during operation with a TS RICT, the NRC staff finds that the plant will continue to have adequate DID while in TS 3.8.1 Condition A. Therefore, the proposed changes to TS 3.8.1 Condition A are acceptable. TS 3.8.1 Condition B -One LCO 3.8.1.b diesel generator inoperable The licensee proposed the option to use the RICT program to extend the existing 14-day CT up to a maximum of 30 days to restore the DG to operable status (Required Action 8.5) for Condition B. The RICT estimate for TS 3.8.1 Condition Bin Table E1-2 is 30 days. As stated in Table E1-1, the design-success criterion for TS 3.8.1 Condition Bis "one of two DGs capable of supplying one train of the onsite Class 1 E AC Electrical Power Distribution System." Therefore, during an RICT program entry for TS 3.8.1 Condition B, the remaining LCO 3.8.1.b DG, in addition to the two required LCO 3.8.1.a qualified offsite circuits and the SMECO line, will be capable of supplying power to ESF systems required to mitigate DBAs with offsite power; thus, the required design-success criterion is met. In the event that offsite power is lost concurrent with the DBAs, as assumed in the UFSAR Chapter 14 analysis, the remaining LCO 3.8.1.b DG will be relied on to power the minimum ESF systems required to mitigate the DBAs. The NRC staff further reviewed the examples of RMAs associated with TS 3.8.9 Condition A. In the letter dated February 25, 2016, the licensee provided the following examples of RMAs associated with DGs. 1. Contact the Transmission System Operator to determine the reliability of offsite power supplies prior to entering a RICT, and implement RMAs during times of high grid stress conditions, such as during high demand conditions.

: 3. Defer elective maintenance in the switchyard, on the station electrical distribution systems, and on the main and auxiliary transformers associated with the unit. 4. Defer planned maintenance or testing that affects the reliability of the operable DGs and their associated support equipment.

Defer planned maintenance activities on SBO mitigating systems. Treat these as protected equipment.

: 6. Implement 10 CFR 50.65(a)(4) fire-specific RMAs associated with the affected DG. 7. Brief the on-shift operations crew concerning the unit activities, including any compensatory measures established, and review the appropriate emergency operating procedures for a LOOP. The NRC staff notes that the Calvert Cliffs protected equipment program identifies equipment that should be protected to ensure that the minimum required equipment remains available to support plant operation.

The actions specified above would provide additional assurance for the availability of the remaining equipment.

The NRC staff finds that the examples of the RMAs associated with TS 3.8.1 Condition B are reasonable.

Based on the above discussion, the NRC staff finds that during the RICT program entry for TS 3.8.1 Condition B, the DID of the electrical power systems that ensure AC power to key safety-related equipment required to operate during DBAs is reduced (1) to four layers of defense (the remaining LCO 3.8.1.b DG, two required LCO 3.8.1.a qualified offsite circuits, and the SM ECO line) for DBAs with offsite power, and (2) a single layer of defense ( one LCO 3.8.1.b DG) for DBAs without offsite power. The NRC staff reviewed the licensee's proposed TS changes and supporting documentation.

Based on the evaluations above, the NRC staff finds that the design-success criterion is met. While the redundancy is not maintained (a single layer of defense [one LCO 3.8.1.b DG] for DBAs without offsite power), CT extensions in accordance with the RICT program are acceptable because (a) the capability of the systems to perform their safety functions (assuming no additional failures) is maintained, and (b) the licensee's demonstration of identifying and implementing compensatory measures or RMAs in accordance with the RICT program are appropriate to monitor and control risk. Therefore, the NRC staff finds that the plant will continue to have adequate DID while in TS 3.8.1 Condition B, and the proposed change to TS 3.8.1 Condition B is acceptable.

TS 3.8.1 Condition G -Two required LCO 3.8.1.a offsite circuits inoperable OR One required LCO 3.8.1.a offsite circuit that provides power to the CREVS and CRETS inoperable and the required LCO 3.8.1.c offsite circuit inoperable The licensee proposed the option to use the RICT program to extend the existing 24-hour CT to restore one required offsite circuit to operable status (Required Action G.2) for TS 3.8.1 Condition G. The RICT estimate for TS 3.8.1 Condition Gin Table E1-2 is 16 days. The two required LCO 3.8.1.a offsite circuits are the 13 kV service buses 11 and 21 with associated transmission lines, 500 kV buses, plant P-13000 and unit U-4000 service transformers, 13.8 kV voltage regulators, and 4.16 kV circuit breakers.

The 13 kV service buses 11 and 21, 500 kV buses, and plant P-13000 service transformers are shared by both units. The first option of TS 3.8.1 Condition G is applicable when the two LCO 3.8.1.a offsite circuits are inoperable.

The second option of TS 3.8.1 Condition G is applicable when one LCO 3.8.1 offsite circuit and one qualified circuit between the offsite transmission network and the other unit's onsite electrical power distribution subsystem that supplies power to CREVS and CRETS is inoperable.

As stated in Table E1-1, the design-success criteria for TS 3.8.1 Condition G is "One qualified circuit between the offsite transmission network and the onsite 1 E AC Electrical Power Distribution System." Per Calvert Cliffs UFSAR Section 8, offsite power from the 500 kV lines and 13 kV SMECO line supplies power to both units' 4.16 kV ESF buses via the 13.8 kV service buses 11 and 21. The Condition G worst case scenario would be the failure of two required LCO 3.8. 1.a offsite circuits.

During an RICT program entry for the TS 3.8.1 Condition G (worst scenario), the SMECO line, two LCO 3.8.1.b DGs, and the SBO DG, will be capable of supplying power to the ESF equipment required to mitigate all DBAs; thus, the required design-success criteria is met. In case offsite power is lost concurrently with the DBAs, as assumed in the UFSAR Chapter 14 analysis, two LCO 3.8.1.b DGs would be capable of supplying power to the ESF equipment required to mitigate all DBAs. Based on the above discussion, the NRC staff finds that during the RICT program entry for TS 3.8.1 Condition G, the DID of the electrical power systems that ensures AC power to key safety-related equipment required to operate during all DBAs is reduced to (1) four layers of defense ( one qualified offsite circuit, two LCO 3.8.1.b DGs, and the SBO DG) with offsite power, and (2) two layers of defense (two LCO 3.8.1.b DGs) for DBAs without offsite power. In addition, in the letter dated January 11, 2018, in response to the NRC staff's RAls, the licensee stated that it will implement RMAs when in TS 3.8.1 Condition G. The licensee will   implement the same RMAs for TS 3.8.1 Condition A, protect the CRETS/CREVS train using OP-AA-108-117, and hold shift briefs. Considering that the design-success criteria will be met during a TS RICT, and RMAs will be implemented during a TS RICT, the NRC staff finds that the plant will continue to have adequate DID while in TS 3.8.1 Condition G~ Therefore, the proposed changes to TS 3.8.1 Condition G are acceptable.

TS 3.8.1 Condition H -One required LCO 3.8.1.a offsite circuit inoperable AND one LCO 3.8.1.b diesel generator inoperable The licensee proposed the option to use the RICT program to extend the existing 12-hour CT to restore either the offsite circuit (Required Action H.1) or the DG (Required Action H.2) to operable status for TS 3.8.1 Condition H. The RICT estimate for TS 3.8.1 Condition H in Table E1-2 is 10 days. As stated in Table E1-1, the design-success criteria for TS 3.8.1 Condition Hare "One qualified circuit between the offsite transmission network and the onsite 1 E AC Electrical Power Distribution System," and "one of two DGs capable of supplying one train of the onsite Class 1 E AC Electrical Power Distribution System." Therefore, during an RICT program entry for TS 3.8.1 Condition H, the remaining required LCO 3.8.1.a offsite circuit, the SMECO line, the remaining LCO 3.8.1.b DG, and the SBO DG will be capable of supplying power to the ESF systems (in both trains) to mitigate DBAs with offsite power; thus, the required design-success criteria are met. In case offsite power is lost concurrently with the DBAs, the remaining LCO 3.8.1.b DG will be relied on to power the minimum ESF systems required to mitigate the DBAs. The NRC staff further reviewed the examples of RMAs associated with TS 3.8.1 Condition H. In the letter dated January 11, 2018, the licensee provided the following examples of RMAs associated with TS 3.8.1 Condition H.

* Defer planned maintenance or testing that affects the reliability of the operable DGs and their associated support equipment.

Defer planned maintenance activities on station blackout mitigating systems.

* Brief the on-shift operations crew concerning the unit activities, including any compensatory measures established, and review the appropriate emergency operating procedures for a LOOP. The NRC staff notes that the Calvert Cliffs protected equipment program identifies equipment that should be protected to ensure that the minimum required equipment remains available to support plant operation.

The actions specified above would provide additional assurance for the availability of the remaining equipment.

The NRC staff finds that the examples of the RMAs associated with TS 3.8.1 Condition H are reasonable.

Based on the evaluations above, the NRC staff finds that the design-success criteria are met. While redundancy is not maintained (a single layer of defense [one LCO 3.8.1.b DG] for DBAs without offsite power), the CT extensions in accordance with the RICT program are acceptable because (a) the capability of the systems to perform their safety functions (assuming no additional failures) is maintained, and (b) the licensee's demonstration of identifying and implementing compensatory measures or RMAs in accordance with the RICT program are appropriate to monitor and control risk. Therefore, the NRC staff finds that the plant will continue to have adequate DID while in TS 3.8.1 Condition H, and the proposed change to TS 3.8.1 Condition H is acceptable.

3.1.2.2.2 TS 3.8.4 -DC Sources-Operating During plant operation, LCO 3.8.4 requires four channels of DC electrical sources to be operable.

According to Calvert Cliffs UFSAR Section 8.1.3, the primary batteries 11, 12, 21, and 22 of the DC channels are shared by Units 1 and 2. Therefore, both units would enter their respective TS conditions if any of the primary batteries were inoperable.

In addition, reserve battery 01 is shared by both units. TS 3.8.4 Condition A -One DC channel inoperable due to an inoperable battery and the reserve battery available The licensee proposed the option to use the RICT program to extend the existing 4-hour CT to replace the inoperable battery with the reserve battery (Required Action A.1) for TS 3.8.4 Condition A. The RICT estimate for TS 3.8.4 Condition A in Table E1-2 is 2 days. As stated in Table E1-1, the design-success criteria for TS 3.8.4 Condition A are "primary or reserve battery for each DC channel, three of four DC channels." The NRC staff notes that Calvert Cliffs has one reserve battery to replace one DC battery at a time. The reserve battery would not be available to the remaining three DC channels, should the reserve battery be used to replace a primary DC battery. The NRC staff also notes once the reserve battery is used to replace a primary DC battery as the required action for TS 3.8.4 Condition A, TS 3.8.4

* Condition A LCO will be exited since the required action would be met. Therefore, there will be four DC channels (batteries and chargers) available.

Because the required design-success   criteria are a DC battery for each channel, and three out of four channels available, and because there are four channels of DC batteries and a reserve battery capable of performing the required safety function, the staff finds there are two layers of defense that provide the minimum DC power necessary to mitigate postulated DBAs for Calvert Cliffs design success. During an RICT program entry for TS 3.8.4 Condition A, the remaining three DC channels (batteries and chargers) will be capable of supplying power to the DC loads required to mitigate DBAs with or without offsite power; thus, the required design-success criteria are met. In addition, the two chargers associated with the inoperable DC channel will supply power to the inoperable DC channel during DBAs with offsite power available.

In case offsite power is lost concurrently with the DBAs, the charger powered from the DG relying on the inoperable battery for field flashing would be nonfunctioning, but the charger fed from the other unit's DG would be reenergized to supply the inoperable DC channel's loads that are required to mitigate the DBAs. The charger fed from the other unit's DG will be sequenced onto the DG within 5 seconds of the DG breaker closure (UFSAR Table 8-7, "Load Sequencing").

TS 3.8.4 Condition B -One DC channel inoperable for reasons other than Condition A The licensee proposed the option to use the RICT program to extend the existing 2-hour CT for restoring a DC channel to operable status (Required Action 8.1) in TS 3.8.4 Condition B. The RICT estimate for TS 3.8.4 Condition Bin Table E1-2 is 15 hours. Table E1-1 identified the design-success criteria for TS 3.8.4 Condition Bas "One of two chargers for each channel. Primary or reserve battery for each channel. Three of four channels." Calvert Cliffs UFSAR Section 8.3.5, "125 Volt DC and 120 Volt AC systems," stated that all battery chargers are energized and maintain a constant voltage to supply the batteries and the steady state DC loads during normal operation.

The NRC staff notes that both chargers would have to be inoperable for the DC channel to be inoperable since both chargers are energized to supply the DC bus (battery and DC loads) and only one charger is required for an operable DC channel. The NRC staff also notes that the remaining three DC channels (batteries and chargers) will provide a single layer of defense since they are the minimum DC channels required to provide the minimum DC power necessary to mitigate Calvert Cliffs postulated DBAs, thus meeting the required design-success criteria.

When TS 3.8.4 Condition B is entered, the following are representative scenarios:

two inoperable chargers, two inoperable chargers and inoperable primary and reserve batteries, or inoperable primary and reserve batteries.

The NRC staff notes that Calvert Cliffs would enter TS 3.8.4 Condition B for Units 1 and 2 since each unit feeds one of the two chargers and both units share the batteries.

The primary and reserve batteries are sized to supply the DC and vital AC loads for a period of 2 hours per UFSAR Section 8.3.5, and the reserve battery can be   connected to the DC bus within 4 hours per current TS 3.8.4 Condition A. Since the primary battery is able to supply the load for 2 hours (a short period of time), the NRC staff notes that within 2 hours after the start of the OBA, the DID for the case of "two inoperable chargers" would be the same as that of "two inoperable chargers and inoperable primary and reserve batteries." Therefore, the NRC staff evaluated the case of two inoperable chargers, inoperable primary battery, and inoperable reserve battery as the worst case scenario for TS 3.8.4 Condition B. During an RICT program entry for the TS 3.8.4 Condition B worst case scenario, the remaining three DC channels will be capable of supplying power to the minimum DC loads required to mitigate DBAs with or without offsite power; thus, the required design-success criteria are met. The NRC staff further reviewed the examples of RMAs associated with TS 3.8.4 Condition B. In the letter dated January 11, 2018, the licensee provided the following examples of RMAs associated with TS 3.8.4 Condition B.

* Protect equipment as directed by OP-M-108-117.

This protection would include prohibiting all elective maintenance on any Vital AC or DC bus and its associated support equipment.

The NRC staff notes that the Calvert Cliffs protected equipment program identifies equipment that should be protected to ensure that the minimum required equipment remains available to support plant operation.

The actions specified above would provide additional assurance for the availability of the remaining equipment.

The NRC staff finds that the examples of the RMAs associated with TS 3.8.4 Condition B are reasonable.

3.1.2.2.3 TS 3.8.7 -Inverters-Operating During plant operation, LCO 3.8. 7 requires four inverters to be operable.

TS 3.8. 7 Condition A -One required inverter inoperable The licensee proposed the option to use the RICT program to extend the existing 24-hour CT for restoring an inverter to operable status (Required Action A.1) in TS 3.8. 7 Condition A. The RICT estimate for TS 3.8.7 Condition A in Table E1-2 is 12 days. The note for Required Action A.1 requires entry into Condition B of TS LCO 3.8.9 with any AC vital bus deenergized.

As required by current TS 3.8.9 Condition B, the AC vital bus associated with the inoperable inverter will be manually reenergized within 2 hours from its alternate   120 V AC bus fed from an ESF MCC through a regulating transformer.

Therefore, the NRC staff assumed that the AC vital bus associated with the inoperable inverter would be reenergized within the current 24-hour CT for TS 3.8. 7 Condition A prior to entering the RICT for TS 3.8. 7 Condition A. Table E1-1 identified the design-success criterion for TS 3.8. 7 Condition A as three of four inverters.

The NRC staff notes that 3 inverters will provide a single layer of defense since they are the minimum number of inverters required to support the minimum safety functions necessary to mitigate the Calvert Cliffs postulated DBAs; thus, the required design-success criterion is met. During an RICT program entry for TS 3.8. 7 Condition A, the remaining 3 inverters would be capable of providing uninterruptible AC power to the AC vital buses required during DBAs with or without offsite power. In addition, the alternate 120 V AC bus fed from an ESF MCC through a regulating transformer will provide power to the AC vital bus associated with the inoperable inverter when offsite power is available.

In case offsite power is lost, the alternate 120 V AC bus would receive power from the DG associated with the ESF MCC through the regulating transformer and would, in turn, reenergize the affected AC vital bus with some time delay. Based on the above discussion, the NRC staff finds that during the RICT program entry for TS 3.8.7 Condition A, the DID of the electrical power systems that ensure AC power to the safety-related AC vital buses required to operate during DBAs with or without offsite power is reduced to two layers of defense (minimum required three inverters and the alternate 120 V AC bus fed via a regulating transformer).

In addition, in the letter dated January 11, 2018, in response to the NRC staff's RAls, the licensee stated that it may perform the following example RMAs: enter TS 3.8.9 Condition A, complete the RMAs for the Maintenance Rule fire actions, protect equipment using OP-AA-108-117, and perform shift briefs when in TS 3.8.7 Condition A. Considering that the design-success criteria will be met during TS RICT and RMAs will be implemented during TS RICT, the NRC staff finds that the plant will continue to have adequate DID while in TS 3.8.7 Condition A. Therefore, the proposed changes to TS 3.8.7 Condition A are acceptable.

3.1.2.2.4 TS 3.8.9 -Distribution Systems-Operating During plant operation, the LCO for TS 3.8.9 requires the AC, DC, and AC vital bus electrical power distribution subsystems to be operable.

TS 3.8.9 Condition A -One or more AC electrical power distribution subsystems inoperable The licensee proposed the option to use the RICT program to extend the existing 8-hour CT for restoring one or more AC power distribution subsystems to operable status (Required Action A.1) in TS 3.8.9 Condition A. The RICT estimate for TS 3.8.9 Condition A in Table E1-2 is 4 days. Per TS Basis 3.8.9, Condition A represents one or more required AC electrical power distribution subsystems inoperable with no loss of function.

According to Calvert Cliffs UFSAR Chapter 8, the safety-related AC distribution system, except the AC vital systems for each unit, includes a 4.16 kV ESF system and a 480 V ESF system. The 4.16 kV ESF system includes two redundant 4.16 kV buses, and the 480 V ESF system   includes four redundant 480 V unit buses, two 480 V MCC buses, and load centers. The 480 V buses are powered from the 4.16 kV buses. Based on TS Table B 3.8.9-1 footnote 1, each bus of the AC electrical power distribution system is a subsystem.

Per TS 3.8.9, operable AC electrical power distribution subsystems require the associated buses, load centers, MCCs, and distribution panels to be energized to their proper voltages.

The NRC staff notes that since the 480 V buses are fed from the 4.16 kV buses, an inoperable 4.16 kV bus ( or subsystem) would render the associated 480 V buses/subsystems, 480 V MCCs, and load centers inoperable (i.e., not energized to proper voltages).

In this case, the 4.16 kV and 480 V buses/subsystems, MCCs, and load centers included in the AC distribution system of one train would be inoperable.

Therefore, the TS 3.8.9 Condition A worst case scenario would be one train of AC distribution system ( 4.16 kV and 480 V subsystems, including MCCs and load centers) inoperable.

As identified in Table E1-1, the design-success criterion for TS 3.8.9 Condition A, is one of two AC distribution systems. The NRC staff notes that one AC distribution system (consisting of the AC distribution subsystems) in the redundant train will provide one layer of defense to mitigate postulated DBAs since one AC distribution system is required to support the minimum safety functions to mitigate Calvert Cliffs' postulated DBAs; thus, the required success design criterion is met. During an RICT program entry for the TS 3.8.9 Condition A worst case scenario, the remaining AC distribution system (4.16 kV and 480 V subsystems) in the redundant train will be capable of providing power to safety-related equipment required during DBAs with or without offsite power. The NRC staff further reviewed the examples of RMAs associated with TS 3.8.9 Condition A. In the letter dated January 11, 2018, the licensee provided the following examples of RMAs associated with TS 3.8.9 Condition A.

* Take the required actions per AOP for loss of AC distribution subsystem.

This would include the direction to cross tie buses as appropriate for risk-significant equipment.

* Pre-stage material for work activity and ensure parts availability for any contingent work. The staff notes that the Calvert Cliffs protected equipment program identifies equipment that should be protected to ensure that the minimum required equipment remains available to support plant operation.

The actions specified above would provide additional assurance for the availability of the remaining equipment.

The NRC staff finds that the examples of the RMAs associated with TS 3.8.9 Condition A are reasonable.

Based on the above discussion, the NRC staff finds that during the RICT program entry for TS 3.8.9 Condition A, the DID of the electrical power distribution systems that ensures AC power to the key safety-related equipment required to operate during DBAs with or without offsite power is reduced to a single layer of defense (minimum required AC electrical distribution system (including subsystems) in the redundant train). Although there is only a single layer of   DID for the TS 3.8.9 Condition A worst case scenario, the NRC staff finds that with the risk management actions in place during the timeframe of 4 days in Table E1-2 described in the RICT program, this is reasonable and acceptable.

Based on the evaluations above, the NRC staff finds that the design-success criterion is met. While redundancy is not maintained (a single layer of defense [one train of AC electrical distribution system (including subsystems)]

for DBAs without offsite power), the CT extensions in accordance with the RICT program are acceptable because (a) the capability of the systems to perform their safety functions (assuming no additional failures) is maintained, and (b) the licensee's demonstration of identifying and implementing compensatory measures or RMAs in accordance with the RICT program are appropriate to monitor and control risk. Therefore, the NRC staff finds that the plant will continue to have adequate DID while in TS 3.8.9 Condition A, and the proposed change to TS 3.8.9 Condition A is acceptable.

TS 3.8.9 Condition B-One or more AC vital bus subsystem{s) inoperable The licensee proposed the option to use the RICT program to extend the existing 2-hour CT to restore the AC vital bus subsystems to operable status (Required Action B.1) for TS 3.8.9 Condition B. The RICT estimate for TS 3.8.9 Condition Bin Table E1-2 is 12 days. Per TS 3.8.9, Condition B represents one or more required AC vital buses inoperable with no loss of function.

According to Calvert Cliffs UFSAR Chapter 8, the 120 V AC vital distribution system for each unit includes four independent 120 V AC panelboards/buses.

Per TS Table B 3.8.9-1 footnote 1, each bus of the 120 V AC vital electrical power distribution system is a subsystem.

During an RICT program entry for the TS 3.8.9 Condition B worst case scenario (two AC vital bus subsystems inoperable), the remaining two AC vital buses subsystems will be capable of providing power to the RPS and the ESFAS during DBAs with or without offsite power; thus, the required design-success criterion is met. The NRC staff further reviewed the examples of RMAs associated with TS 3.8.9 Condition B. In the letter dated January 11, 2018, the licensee provided the following examples of RMAs associated with TS 3.8.9 Condition B.

This would include the direction to cross tie buses as appropriate for significant equipment.

The NRC staff notes that the Calvert Cliffs protected equipment program identifies equipment that should be protected to ensure that the minimum required equipment remains available to support plant operation.

The actions specified above would provide additional assurance for the availability of the remaining equipment.

The NRC staff finds that the examples of the RMAs associated with TS 3.8.9 Condition Bare reasonable.

Based on the evaluations above, the NRC staff finds that the design-success criteria is met. While the redundancy is not maintained (a single layer of defense [two AC vital buses] for DBAs with or without offsite power), the CT extensions in accordance with the RICT program are acceptable because (a) the capability of the systems to perform their safety functions (assuming no additional failures) is maintained, and (b) the licensee's demonstration of identifying and implementing compensatory measures or RMAs in accordance with the RICT program are appropriate to monitor and control risk. Therefore, the NRC staff finds that the plant will continue to have adequate DID while in TS 3.8.9 Condition B, and the proposed change to TS 3.8.9 Condition B is acceptable.

TS 3.8.9 Condition C-One DC electrical power distribution subsystem inoperable The licensee proposed the option to use the RICT program to extend the existing 2-hour CT to restore the DC electrical power distribution subsystem to operable status (Required Action C.1) for TS 3.8.9 Condition C. The RICT estimate for TS 3.8.9 Condition C in Table E1-2 is 15 hours. Per Calvert Cliffs UFSAR Chapter 8, the safety-related 125 V DC distribution system includes four DC buses that are shared between the two units. Based on TS Table B 3.8.9-1 footnote 1, each bus of the DC electrical power distribution system is a subsystem.

The NRC staff notes that Calvert Cliffs would enter TS 3.8.9 Condition C for Units 1 and 2 since both units share the DC buses as stated in UFSAR Section 8.1.3. As identified in Table E1-1, the design-success criterion for TS 3.8.9 Condition C is three of four DC electrical power distribution subsystems.

The NRC staff notes that the remaining three DC electrical power distribution subsystems will provide one layer of defense to mitigate DBAs with   or without power since three DC electrical power distribution subsystems are required to provide the minimum DC power to mitigate the Calvert Cliffs postulated DBAs. During an RICT program entry for TS 3.8.9 Condition C, the remaining three DC electrical power distribution subsystems will be capable of providing the DC power for equipment required during DBAs; thus, the required design-success criterion is met. The NRC staff further reviewed the examples of RMAs associated with TS 3.8.9 Condition C. In the letter dated January 11, 2018, the licensee provided the following examples of RMAs associated with TS 3.8.9 Condition C.

This would include the direction to cross tie buses as appropriate for significant equipment.

The NRC staff notes that the Calvert Cliffs protected equipment program identifies equipment that should be protected to ensure that the minimum required equipment remains available to support plant operation.

The actions specified above would provide additional assurance for the availability of the remaining equipment.

The NRC staff finds that the examples of the RMAs associated with TS 3.8.9 Condition Care reasonable.

Based on the above discussion, the NRC staff finds that during the RICT program entry for TS 3.8.9 Condition C, the DID of the electrical power distribution systems that ensures DC power to key safety-related equipment required to operate during DBAs with or without offsite power is reduced to a single layer of defense (minimum required DC power distribution subsystem).

Although there is only a single layer of DID for the TS 3.8.9 Condition C worst case scenario, the NRC staff finds that with the risk management actions in place during the timeframe of 15 hours in Table E1-2 described in the RICT program, this is reasonable and acceptable.

Based on the evaluations above, the NRC staff finds that the design-success criterion is met. While redundancy is not maintained (a single layer of defense [one DC power distribution subsystem]

for DBAs with or without offsite power), the CT extensions in accordance with the RICT program are acceptable because (a) the capability of the systems to perform their safety functions (assuming no additional failures) is maintained, and (b) the licensee's demonstration of identifying and implementing compensatory measures or RMAs in accordance with the RICT program are appropriate to monitor and control risk. Therefore, the NRC staff finds that the plant will continue to have adequate DID while in TS 3.8.9 Condition C, and the proposed change to TS 3.8.9 Condition C is acceptable. 3.1.2.3 Evaluation of Instrumentation and Control Systems The NRC staff examined the design information from the Calvert Cliffs UFSAR and the risk-informed LCO conditions for the affected l&C functions.

Based on this information, the NRC staff confirmed that under any given OBA evaluated in the Calvert Cliffs UFSAR, the affected l&C protective features maintain adequate DID by either necessary redundancy (e.g., at least one redundant channel) and/or necessary diversity (e.g., at least one alternative safety feature).

The licensee confirmed in the LAR that the proposed changes do not alter the Calvert Cliffs l&C system designs. Consequently, the NRC staff concludes that the proposed changes do not alter the ways in which the Calvert Cliffs l&C systems fail, do not introduce new CCF modes, and system independence is maintained.

The NRC staff finds that some proposed changes reduce the level of redundancy of the affected l&C systems, and this reduction may reduce the level of defense against some CCFs; however, the NRC staff finds, as described below, that such reduction in redundancy and defense against CCFs are acceptable due to the existence of adequate diversity.

LCO 3.3.1 -"Reactor Protection System (RPS) Instrumentation-Operating LCO 3.3.1 requires "Four RPS bistable trip units, associated measurement channels, and applicable automatic bypass removal features for each Function in Table 3.3.1-1 shall be OPERABLE."

* Condition A, "One or more Functions with one RPS bistable trip unit or associated measurement channel inoperable except for Condition C (excore channel not calibrated with incore detectors)." Under Condition A Action A.1 is required to "[p]lace affected bistable trip unit in bypass or trip" within 1 hour. Action A.1 is followed by the risk-informed Action A.2.1 and Action A.2.2. Action A.2.1 is specified to "[r]estore affected bistable trip unit and associated measurement channel to OPERABLE status," and Action A.2.2 is specified to "[p]lace affected bistable trip unit in trip." Both CTs are risk-informed as "48 hours or in accordance with the Risk-Informed Completion Time Program." As specified in Chapter 7 of the Calvert Cliffs UFSAR and Calvert Cliffs TS LCO 3.3.1, each function in Table 3.3.1-1 has four bistable units and four associated measurement channels, and has a 2 out of 4 coincidence logic. Under Condition A, and following the completion of Action A.1 (bypass action is conservatively assumed in this analysis}, the coincidence logic of the affected function becomes 2 out of 3. In this situation, the protective functions are still fulfilled with one additional channel in redundancy.

The NRC staff concludes that the proposed RICT for inoperable instrumentation does not impede accomplishing their safety functions because the proposed RICT program requires, in part, that the redundant channels are operable.

The NRC staff finds these changes are consistent with the DID philosophy and are, therefore, acceptable.

* Condition B, "One or more Functions with two RPS bistable trip units or associated measurement channels inoperable except for Condition C (excore channel not calibrated with incore detectors)."   Under Condition B, Action B.1 is required to "[p] lace one affected bistable trip unit in bypass and place the other affected bistable trip unit in trip" within 1 hour. Action B.1 is followed by the risk-informed Action B.2. Action B.2 is specified to "[r]estore one affected bistable trip unit and associated measurement channel to OPERABLE status." The CT for this action is risk-informed as "48 hours or in accordance with the Risk-Informed Completion Time Program." As specified in Chapter 7 of the Calvert Cliffs UFSAR and TS LCO 3.3.1, each function in Table 3.3.1-1 has four bistable units and four associated measurement channels, and has a 2 out of 4 coincidence logic. Under Condition B, and following the completion of Action B.1, to place one channel in bypass and another one in trip, the coincidence logic of the affected function becomes 1 out of 2. In this situation, the protective functions are still fulfilled with one additional channel in redundancy.

The NRC staff concludes that the proposed RICT for inoperable instrumentation does not impede accomplishing their safety functions because the proposed RICT program requires, in part, that the redundant channels are operable.

The NRC staff finds these changes are consistent with the DID philosophy and are, therefore, acceptable.

* Condition D, "One or more Functions with one automatic bypass removal feature inoperable." Under Condition D, Action D.2.1 is required to "[p]lace affected bistable trip units in bypass or trip" within 1 hour. Action D.2.1 is followed by the risk-informed Action D.2.2.1 and Action D.2.2.2. Action D.2.2.1 is specified to "[r]estore automatic bypass removal feature and affected bistable trip unit to OPERABLE status," and Action D.2.2.2 is specified to "[p]lace bistable trip unit in trip." Both CTs are risk-informed as "48 hours or in accordance with the Risk-Informed Completion Time Program." As specified in Chapter 7 of the Calvert Cliffs UFSAR and TS LCO 3.3.1 each function in Table 3.3.1-1 has four operating bypass channels.

Under Condition D, and following the completion of Action D.2.1 (bypass action is conservatively assumed in this analysis), the coincidence logic of the affected automatic bypass removal function becomes 2 out of 3. In this condition, the protective functions are still fulfilled with one additional channel in redundancy.

The NRC staff concludes that the proposed RICT for inoperable instrumentation does not impede accomplishing their safety functions because the proposed RICT program requires, in part, that the redundant channels are operable.

The NRC staff finds these changes are consistent with the DID philosophy and are, therefore, acceptable.

* Condition E, "One or more Functions with two automatic bypass removal feature channels inoperable." Under Condition E, Action E.2.1 is required to "[p]lace one affected bistable trip unit in bypass and place the other in trip for each affected trip Function" within 1 hour. Action E.2.1 is followed by the risk-informed Action E.2.2. Action E.2.2 is specified to "[r]estore one affected bistable trip unit and associated measurement channel to OPERABLE status for each affected trip Function." Its CT is risk-informed as "48 hours or in accordance with the Risk-Informed Completion Time Program."   As specified in Chapter 7 of the Calvert Cliffs UFSAR and TS LCO 3.3.1 each function in Table 3.3.1-1 has four operating bypass channels.

Under Condition E, and following the completion of Action E.2.1, the coincidence logic of the affected automatic bypass removal function becomes 1 out of 2. In this condition, the protective functions are still fulfilled with one additional channel in redundancy.

The NRC staff concludes that the proposed RICT for inoperable instrumentation does not impede accomplishing their safety functions because the proposed RICT program requires, in part, that the redundant channels are operable.

The NRC staff finds these changes are consistent with the DID philosophy and are, therefore, acceptable.

LCO 3.3.3 -"Reactor Protective System (RPS) Logic and Trip Initiation" LCO 3.3.3 requires that "[s]ix channels of RPS Matrix Logic, four channels of RPS Trip Path Logic, four channels of reactor trip circuit breakers (RTCBs), and four channels of Manual Trip shall be OPERABLE."