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CPS OPERATIONAL REQUIREMENTS MANUAL (ORM)

The following exceptions are not considered to be CORE ALTERATIONS:

Suspension of CORE ALTERATIONS shall not preclude completion of movement of a component to a safe position.

FUNCTIONALITY does not apply to specified safety functions, but does apply to the ability of non-TS SSCs to perform other specified functions that have a necessary support function.

LOGIC SYSTEM FUNCTIONAL TEST 1.1.8A LOGIC SYSTEM FUNCTIONAL TEST shall be a test of all logic components required for FUNCTIONALITY of a logic circuit, from as close to the sensor as practicable up to, but not including, the actuated device, to verify FUNCTIONALITY. The LOGIC SYSTEM FUNCTIONAL TEST may be performed by means of any series of sequential, overlapping, or total system steps so that the entire logic system is tested.

CPS OPERATIONAL REQUIREMENTS MANUAL (ORM)

RATED THERMAL POWER 1.1.11 RATED THERMAL POWER (RTP) shall be a total reactor core heat transfer rate to the reactor coolant of 3473 MWt.

SELF TEST SYSTEM 1.1.12 The SELF TEST SYSTEM (STS) shall be that automatic test system designed to continually monitor the solid state nuclear system protection system (NSPS) functional circuitry by injecting short-duration pulses into circuits and verifying proper circuit response to various input combinations. The SELF TEST SYSTEM is designed to maintain surveillance over all NSPS cabinet circuitry essential to the Reactor Protection System, Emergency Core Cooling Systems, Reactor Core Isolation Cooling System, and the Nuclear Steam Supply Shutoff System on a continuous cyclic basis.

The SELF TEST SYSTEM may be used to perform various surveillance testing functions to satisfy technical specifications requirements for those components it is designed to monitor. The STS may be used to augment conventional testing methods to perform CHANNEL CHECKS, CHANNEL FUNCTIONAL TESTS, CHANNEL CALIBRATIONS, RESPONSE TIME TESTS and LOGIC SYSTEM FUNCTIONAL TESTS provided that FUNCTIONALITY of the STS has first been verified.

SITE BOUNDARY 1.1.13 The SITE BOUNDARY shall be that line beyond which the land is neither owned, nor leased, nor otherwise controlled by the licensee.

Exceptions to this requirement are stated in the individual Operational Requirements.

Where corrective measures are completed that permit operation in accordance with the Operational Requirement or ACTIONS, completion of the actions required by this requirement is not required.

This requirement is only applicable in MODES 1, 2, and 3.

This requirement shall not prevent changes in MODES or other specified conditions in the Applicability that are required to comply with ACTIONS or that are part of a shutdown of the unit.

This is an exception to Operational Requirement 1.2.2 for the system returned to service under administrative control to perform the testing required to demonstrate FUNCTIONALITY.

For Frequencies specified as "once," the above interval extension does not apply.

Exceptions to this Testing Requirement are stated in the individual Operational Requirements.

If the Testing Requirement is not performed within the delay period, the Operational Requirement must immediately be declared not met, and the applicable ACTIONS must be entered.

When the Testing Requirement is performed within the delay period and the Testing Requirement is not met, the Operational Requirement must immediately be declared not met, and the applicable ACTION(s) must be entered.

This provision shall not prevent entry into MODES or other specified conditions in the Applicability that are required to comply with ACTIONS or that are part of a shutdown of the unit.

For Category 'D' welds, BWR Owner's Group Vessel Internal Project (VIP) document BWRVIP-75 schedule shall be utilized.

* A channel may be placed in a non-functional status for up to 6 hours for required surveillance provided at least one other FUNCTIONAL channel in the same trip function is monitoring that parameter.

ACTION 3.2.1 With the number of FUNCTIONAL Channels:

: a. One less than required by the minimum FUNCTIONAL channels per trip function requirement, restore the non-functional channel to FUNCTIONAL status within 7 days or place the non-functional channel in the tripped condition within the next hour.

: a. Flow Biased Upscale

: 1) During two recirculation loop operation:

: 2) During single recirculation loop operation:

TESTING REQUIREMENTS 4.2.1.1 Deleted.

4.2.1.2 Perform a CHANNEL FUNCTIONAL TEST every 184 days for the following trip functions:

ACTIONS 3.2.2 With the number of FUNCTIONAL Channels:

ACTIONS 3.2.3 With the number of FUNCTIONAL Channels:

TESTING REQUIREMENTS 4.2.4.1 Perform a CHANNEL CHECK on the instruments listed in Table 2.2.4-1 every 12 hours.

4.2.4.3 Perform a CHANNEL CALIBRATION on the instruments listed in Table 4.2.4-1 every 92 days for the Analog Trip Module.

4.2.4.4 Perform a CHANNEL CALIBRATION on the instruments listed in Table 2.2.4-1 every 24 months.

CONTROL ROD BLOCK INSTRUMENTATION OPERATIONAL REQUIREMENT The Reactor Coolant System Recirculation Flow control rod block instrumentation channels in Table 2.2.5-1 shall be FUNCTIONAL with their trip setpoints set consistent with the values specified in Table 3.2.5-1.

ACTION:

3.2.6.2 With the required monitor non-functional, perform area surveys of the monitored area with portable monitoring instrumentation at least once per 24 hours.

TESTING REQUIREMENTS 4.2.6.1 Perform a CHANNEL CHECK on the instruments listed in Table 2.2.6-1 every 12 hours.

4.2.6.2 Perform a CHANNEL FUNCTIONAL TEST on the instruments listed in Table 2.2.6-1 every 31 days.

APPLICABILITY At all times ACTION 3.2.7

: 1. Triaxial Accelerometers

: 2. Triaxial Peak Accelerographs (Passive)

: 4. Recorders

: 2. Triaxial Peak Accelerographs (Passive)

: 4. Recorders

APPLICABILITY At all times ACTION 3.2.8

: 2. Wind Direction

With one or more meteorological monitoring instrumentation channels non-functional for more than seven (7) days, the required Issue Report must include the following: (1)

: a. Three movable detectors, drives and readout equipment to map the core, and

: b. Indexing equipment to allow three detectors to be calibrated in a common location.

: a. Recalibration of the LPRM detectors, and

: b. Monitoring the APLHGR, LHGR, or MCPR.*

TESTING REQUIREMENTS 4.2.9.1 The traversing in-core probe system shall be demonstrated FUNCTIONAL by normalizing each of the above required detector outputs within 72 hours prior to use when required for the LPRM or calibration functions.

APPLICABILITY During operation of the main condenser air ejector.

ACTION 3.2.11

TESTING REQUIREMENTS 4.2.11.1 Perform a CHANNEL CHECK of the main condenser offgas treatment system explosive gas monitoring instrumentation every 24 hours.

4.2.11.2 Perform a CHANNEL FUNCTIONAL TEST of the main condenser offgas treatment system explosive gas monitoring instrumentation every 31 days.

4.2.11.3 Perform a CHANNEL CALIBRATION* of the main condenser offgas treatment system explosive gas monitoring instrumentation every 92 days.

The intent of the

* note attached to the CHANNEL CALIBRATION requirement is to specify that the CHANNEL CALIBRATION is to be performed using at least two separate gas samples of different, specific hydrogen concentrations appropriate for the sensor range. The balance of the sample gas mixture (normally nitrogen) is not necessarily restricted purely to nitrogen but must be in accordance with the requirements or recommendations provided by the manufacturer of the explosive gas monitoring instrumentation.

high, level 8, instrumentation FUNCTIONAL.

APPLICABILITY Mode 1 ACTION 3.2.12

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

A Channel may be placed in a non-functional status for up to 6 hours for required surveillance without placing the Channel in the tripped condition provided at least one other FUNCTIONAL Channel is monitoring that parameter.

4.2.12.2 Perform a CHANNEL FUNCTIONAL TEST every 184 days.

4.2.12.3 Perform a CHANNEL CALIBRATION every 24 months. The trip setpoint shall be 52.0 inches.

CPS OPERATIONAL REQUIREMENTS MANUAL (ORM)

APPLICABILITY MODES 1, 2*, and 3*

* Not required when reactor steam dome pressure is less than or equal to 150 psig ACTION 3.2.13.1 With an ADS accumulator low pressure alarm system instrumentation channel(s) non-functional:

: c. The provisions of Operational Requirement 1.2.4 are not applicable.

TESTING REQUIREMENTS 4.2.13.1 At least once per 31 days, performing a CHANNEL FUNCTIONAL TEST of the accumulator low pressure alarm system.

CPS OPERATIONAL REQUIREMENTS MANUAL (ORM)

APPLICABILITY MODES 1, 2, 3, 4, and 5.

ACTION 3.2.14.1 With the STS not operating in the required mode, i.e., in the fully automatic mode or being operated in a manual or partially automatic mode such that all required tests are performed at least once per 7 days during Modes 1, 2, and 3; or at least once per 90 days during Modes 4 and 5.

TESTING REQUIREMENTS 4.2.14.1 Status indications of the STS shall be obtained at least once per 24 hours, whenever the STS is operating in the fully or partially automatic mode.

The Self Test System (STS) is an overlay testing and surveillance subsystem which provides the capability to continuously and automatically perform testing of all active circuitry within the NSPS panels, essential to the safe shutdown of the reactor. The primary purpose of the STS is to enhance the availability of the NSPS by optimizing the time to detect and determine the location of a failure in the functional system. Each of the four NSPS cabinets, with one cabinet associated with each of the four Class IE powered NSPS divisions, contains its own controller. The STS may be used for post-maintenance testing and to augment conventional testing methods which include CHANNEL CHECKS, CHANNEL FUNCTIONAL TESTS, CHANNEL CALIBRATIONS, RESPONSE TIME TESTS and LOGIC SYSTEM FUNCTIONAL TESTS.

Under the provision of the ACTION statement, with the STS non-functional or not operating in the required mode of operation, 30 days is allowed to restore the STS to the required mode during MODES 1, 2, 3; 90 days is allowed during MODES 4, 5.

==Reference:==

EAS-67-1089, "Proposed Improved Technical Specification for Clinton Nuclear Power Station Nuclear Systems Protection System (NSPS) Self Test System (STS)"). Maintaining the STS in a partially automatic mode as much as possible (whenever it is not operating in the fully automatic mode) provides further enhancement of the NSPS availability.

93° F.

APPLICABILITY MODES 1, 2, and 3 ACTION 3.2.15.1 With fewer than 16 suppression pool water temperature indicators FUNCTIONAL, within 4 hours of indicator non-functionality verify at least one temperature indicator FUNCTIONAL in each of eight suppression pool sectors.

TESTING REQUIREMENTS 4.2.15.1 Perform a CHANNEL CHECK of the suppression pool water temperature indicators, at least once per 24 hours.

4.2.15.2 Perform a CHANNEL FUNCTIONAL TEST of the suppression pool water temperature indicators, at least once per 31 days.

INSTRUMENTATION OPERATIONAL REQUIREMENT The Main Steam Line Radiation Monitoring (MSLRM) Instrumentation shown in Table 3.2.16-1 shall be FUNCTIONAL with their alarm/trip setpoints set consistent with the values specified in Table 3.2.16-1.

APPLICABILITY See Table 3.2.16-1 ACTIONS 3.2.16.1

: 1. MECHANICAL VACUUM PUMP

INSTRUMENTATION (continued)

TESTING REQUIREMENTS 4.2.16.1 Perform a CHANNEL CHECK every 12 hours for the MSLRM instrumentation.

4.2.16.3 Perform a CHANNEL CALIBRATION every 24 months for the MSLRM instrumentation.

4.2.16.4 LOGIC SYSTEM FUNCTIONAL TESTS shall be performed at least once per 24 months.

Isolation signals generated from the MSLRs are not credited for any design basis event.

The MSLR CRVICS isolation and RPS Scram functions were removed from the Technical Specifications based on the applicability of General Electric Topical Report NEDO-31400A, "Safety Evaluation for Eliminating the Boiling Water Reactor Main Steam Line Radiation Monitor," to CPS. This Topical Report provided the results of generic evaluations which indicated that the main steam line radiation monitors are unnecessary to ensure compliance with the radiation dose guidelines of 10 CFR 100.

With the elimination of the main steam line radiation monitor isolation function from the plant design the main control room alarm function and the automatic trip of the Mechanical Vacuum Pump are retained. The high radiation alarm alerts operators to consider other plant indications in determining the source of the increased radiation, such as the onset of leakage from a fuel pin(s). These actions will ensure that any significant increases in the levels of radioactivity in the main steam lines will be expeditiously controlled (by procedure) to limit both occupational doses and environmental releases.

CPS OPERATIONAL REQUIREMENTS MANUAL (ORM)

: b. With Action and Completion Time of 3.2.17.a not met, initiate an Issue Report, and identify an alternate means of monitoring hydrogen.

TESTING REQUIREMENTS 4.2.17.1 Perform a CHANNEL CHECK every 31 days.

4.2.17.2 Perform a CHANNEL CALIBRATION every 92 days.

APPLICABILITY At all times.

: b. With the conductivity, chloride concentration, or pH exceeding the limit specified in Table 3.3.1-1 for more than 72 hours during one continuous time interval or with the conductivity and chloride concentration exceeding the limit specified in Table 3.3.1-1, for more than 336 hours per year, be in at least MODE 2 within the next 6 hours.

: b. With the chloride concentration exceeding the limit specified in Table 3.3.1-1 restore the chloride concentration to within the limit within 24 hours, or perform an engineering evaluation to determine the effects of the out-of-limit condition on the structural integrity of the reactor coolant system. Determine that the structural integrity of the reactor coolant system remains acceptable for continued operation prior to proceeding to MODE 3.

The effect of chloride is not as great when the oxygen concentration in the coolant is low, thus the 0.2 ppm limit on chlorides is permitted during POWER OPERATION.

During shutdown and refueling operations, the temperature necessary for stress corrosion to occur is not present so a 0.5 ppm concentration of chlorides is not considered harmful during these periods.

The testing requirements provide adequate assurance that concentrations in excess of the limits will be detected in sufficient time to take corrective action.

During outage refueling with no available means to obtain an in-line conductivity measurement, dip sample conductivity may be obtained from the fuel pool when the reactor vessel head is removed and the reactor cavity is flooded.

APPLICABILITY MODES 1, 2, 3, 4, and 5.

: b. With the structural integrity of any ASME Code Class 2 component(s) not conforming to the above requirements, restore the structural integrity of the affected component(s) to within its limit or isolate the affected component(s) prior to increasing the Reactor Coolant System temperature above 200°F.

: d. The provisions of Operational Requirement 1.2.4 are not applicable.

Components of the reactor coolant system were designed to provide access to permit inservice inspections in accordance with Section XI of the ASME Boiler and Pressure Vessel Code 1975 Edition and Addenda through Winter 1975.

The inservice inspection program for ASME Code Class 1, 2 and 3 components will be performed in accordance with Section XI of the ASME Boiler and Pressure Vessel Code and applicable addenda as required by 10 CFR Part 50.55a(g) except where specific written relief has been granted by the NRC pursuant to 10 CFR Part 50.55a(g)(6)(i).

NOTE Any affected supported LCO(s) are not required to be declared not met solely when one or more required snubbers are unable to perform their associated support function(s) when the condition(s) in LCO 3.0.8 are met. Proper application of LCO 3.0.8 is described in the Tech Spec Bases for LCO 3.0.8.

APPLICABILITY MODES 1, 2, and 3.

MODES 4 and 5 for snubbers located on systems required FUNCTIONAL in those MODES.

AND

: b. Perform an engineering evaluation on the components to which the non-functional snubbers are attached. The purpose of this engineering evaluation shall be to determine if the components to which the non-functional snubbers are attached were adversely affected by the non-functionality of the snubbers in order to ensure that the component remains capable of meeting the designed service.

If any snubber selected for functional testing either fails to lock up or fails to move, i.e., frozen-in-place, the cause will be evaluated and if caused by manufacturer or design deficiency all snubbers of the same type subject to the same defect shall be functionally tested. This testing requirement shall be independent of the requirements stated in Testing Requirement 4.4.1.e for snubbers not meeting the functional test acceptance criteria.

: b. Visual Inspection Acceptance Criteria Visual inspections shall verify that (1) the snubber has no visible indications of damage or impaired FUNCTIONALITY, (2) attachments to the foundation or supporting structure are functional, and (3) fasteners for the attachment of the snubber to the component and to the snubber anchorage are functional. Snubbers which appear non-functional as a result of visual inspections shall be classified as unacceptable and may be reclassified acceptable for the purpose of establishing the next visual inspection interval, provided that: (1) the cause of the rejection is clearly established and remedied for that particular snubber and for other snubbers, irrespective of type, that may be generically susceptible; and (2) the affected snubber is functionally tested in the as-found condition and determined FUNCTIONAL per Testing Requirement 4.4.1.f. All snubbers found connected to a non-functional common hydraulic fluid reservoir shall be counted as unacceptable for determining the next inspection interval. A review and evaluation shall be performed and documented to justify continued operation with an unacceptable snubber. If continued operation cannot be justified, the snubber shall be declared non-functional and the ACTION requirements shall be met.

: d. Functional Tests For the purpose of Functional Testing Snubbers, Defined Test Plan Groups (DTPGs) may be per the Inservice Inspection Program Plan. At least once per refueling outage, a representative sample of snubbers shall be tested using one of the sample plans identified in the ISI Program Plan for each DTPG. The sample plan shall be selected prior to the test period and cannot be changed during the test period. The NRC Regional Administrator shall be notified in writing of the sample plan selected prior to the test period or the sample plan used in the prior test period shall be implemented.

: 1. Activation (restraining action) is achieved within the specified range in both tension and compression;

: 2. Snubber bleed, or release rate where required, is present in both tension and compression, within the specified range;

: 4. For snubbers specifically required not to displace under continuous load, the ability of the snubber to withstand load without displacement.

Testing methods may be used to measure parameters indirectly or parameters other than those specified if those results can be correlated to the specified parameters through established methods.

For the purpose of Functional Testing, snubbers may be classified in accordance with ASME OM Code, Subsection ISTD. Snubbers may be classified as one population, or divided into the two categories of accessible and inaccessible, or grouped by design, manufacturer, size and type. For example, mechanical snubbers utilizing the same design features of the 2-kip, 10-kip, and 100-kip capacity manufactured by Company "A" are of the same type. The same design mechanical snubbers manufactured by Company "B" for the purposes of this Technical Specification would be of a different type, as would hydraulic snubbers from either Manufacturer.

When a snubber is found non-functional, an engineering evaluation is performed, in addition to the determination of the snubber mode of failure, in order to determine if any safety-related component or system has been adversely affected by the non-functionality of the snubber. The engineering evaluation shall determine whether or not the snubber mode of failure has imparted a significant effect or degradation on the supported component or system.

A representative sample of the installed snubbers will be functionally tested to establish operational readiness at least once per refueling interval. Observed failures of these sample snubbers will require functional testing of additional units. To provide further assurance of snubber functionality, snubbers are examined at the frequencies required in the ASME OM Code, Subsection ISTD and applicable Code Cases.

Hydraulic snubbers and mechanical snubbers may each be treated as a different entity for the above surveillance programs. The service life of a snubber is evaluated via manufacturer input and information through consideration of the snubber service conditions and associated installation and maintenance records, i.e., newly installed snubber, seal replaced, spring replaced, in high radiation area, in high temperature area, etc. The requirement to monitor the snubber service life is included to ensure that the snubbers periodically undergo a performance evaluation in view of their age and operating conditions. These records will provide statistical bases for future consideration of snubber service life. The requirements for the maintenance of records and the snubber service life review are not intended to affect plant operation.

The isotope segments of the GE 14i Isotope Test Assembly program contain double encapsulated cobalt targets that have characteristics similar to the description of a sealed source. These isotope segments are not a sealed source and are not subject to the requirements of this section.

APPLICABILITY At all times.

: 1. Decontaminate and repair the sealed source, or

: 2. Dispose of the sealed source in accordance with Commission Regulations.

TESTING REQUIREMENTS 4.4.2.1 Test Requirements - Each sealed source shall be tested for leakage and/or contamination by:

The test method shall have a detection sensitivity of at least 0.005 microcuries per test sample.

4.4.2.3 Reports - A report shall be prepared and submitted to the Commission on an annual basis if sealed source or fission detector leakage tests reveal the presence of greater than or equal to 0.005 microcuries of removable contamination.

Restricting the quantity of radioactive material contained in each of the specified tanks provides assurance that in the event of an uncontrolled release of the contents from any of these tanks, the resulting concentrations would be less than the limits of 10 CFR Part 20, Appendix B, Table 2, Column 2, at the nearest potable water supply and the nearest surface water supply in an UNRESTRICTED AREA.

: b. The provisions of Operational Requirements 1.2.3 and 1.2.4 are not applicable.

APPLICABILITY MODES 1, 2, and 3.

ACTION 3.4.6 With the position indicator of one or more OPERABLE drywell post-LOCA vacuum relief valve(s) non-functional, verify at least one vacuum relief valve in each affected penetration to be closed** at least once per 24 hours, and initiate an issue report.

The provisions of Operational Requirement 1.2.3 and 1.2.4 are not applicable.

TESTING REQUIREMENTS 4.4.6.1 At least once per 31 days verify the position indicator FUNCTIONAL by observing expected valve movement during the cycling test.

4.4.6.2 At least once per 24 months verify the position indicator FUNCTIONAL by performance of a CHANNEL CALIBRATION.

APPLICABILITY Whenever irradiated fuel assemblies are in the spent fuel storage, cask storage or upper containment fuel pools.

BASES 5.4.8 The restrictions on minimum water level ensure that sufficient water depth is available to remove 99% of the assumed 10% iodine gap activity released from the rupture of an irradiated fuel assembly. This minimum water depth is consistent with the assumptions of the accident analysis.

With irradiated fuel assemblies in the cask storage pool, the gates between the cask storage pool and spent fuel pool must be open to ensure removal of decay heat from the cask storage pool.

Thus, water level in the cask storage pool is monitored via the spent fuel pool level indication.

APPLICABILITY When both divisions of hydrogen igniters are non-functional, requiring entry into TS 3.6.3.2, Condition B.

TESTING REQUIREMENTS 4.4.10.1 Perform a FUNCTIONAL TEST for the hydrogen recombiner, every 48 months.

4.4.10.2 Visually examine the Primary Containment Hydrogen Recombiner enclosure and verify there is no evidence of abnormal conditions, every 24 months.

4.4.10.3 Perform a resistance to ground test for each heater phase, every 24 months.

BASES 5.4.10.1 The revised 10CFR50.44 no longer defines a design-basis LOCA hydrogen release, and eliminated requirements for hydrogen control systems to mitigate such a release. The installation of hydrogen recombiners and/or vent and purge systems required by 10CFR50.44(b)(3) was intended to address the limited quantity and rate of hydrogen generation that was postulated from a design-basis LOCA. The NRC found that this hydrogen release is not risk-significant because the design-basis LOCA hydrogen release does not contribute to the conditional probability of a large release up to approximately 24 hours after the onset of core damage. In addition, these systems were ineffective at mitigating hydrogen releases from risk-significant beyond design-basis accidents. Therefore, the NRC eliminated the hydrogen release associated with a design-basis LOCA from 10CFR50.44 and the associated requirements that necessitated the need for the hydrogen recombiners and the backup hydrogen vent and purge systems. As a result, the NRC determined that the hydrogen recombiners no longer meet any of the four criteria in 10 CFR 50.36(c)(s)(ii) for retention in Technical Specifications and the existing TS requirements may, therefore, be eliminated for all plants.

APPLICABILITY MODES 1, 2, and 3.

: 1. For 6.9-kV circuit breakers, remove the 6.9-kV circuit(s) from service by racking out the breaker within 72 hours and verify the non-functional breaker(s) to be racked out at least once per 7 days thereafter.

: 2. For lower voltage circuit breakers (excluding the upper containment polar crane), de-energize the non-functional circuit by tripping and taking appropriate administrative controls for the associated redundant circuit breaker(s) for molded case circuit breakers [or by racking out the associated redundant circuit breaker(s) for unit substation circuit breakers] within 72 hours and verify the redundant circuit breaker to be tripped at least once per 7 days thereafter.

: 3. For the upper containment polar crane containment penetration conductor overcurrent protective devices (cubicle 7B C08 relays and trip circuit of breaker 3B of panel 1AP11E) or circuit breaker 7B of panel 1AP11E inoperable, declare the polar crane inoperable and de-energize the non-functional circuit by racking out circuit breaker 7B of panel 1AP11E within 72 hours, and verify circuit breaker 7B of panel 1AP11E to be racked out at least once per 7 days thereafter.

: 1. By verifying that all medium voltage 6.9-kV and polar crane circuit breakers are FUNCTIONAL by performing:

a) A CHANNEL CALIBRATION of the associated protective relays, and b) An integrated system functional test which includes simulated automatic actuation of the system and verifying that each relay and associated circuit breakers and overcurrent control circuits function as designed.

: 1. By selecting and functionally testing all low voltage molded case circuit breakers. Testing of these circuit breakers shall consist of injecting currents in excess of the breaker's nominal setpoint and measuring the response time of the long time delay and short time delay trip elements and setpoint of the instantaneous element where applicable. The measured response time shall be compared to the manufacturer's data to ensure that it is less than or equal to a value specified by the manufacturer.

: 2. By subjecting each low voltage molded case circuit breaker to an inspection and preventive maintenance in accordance with procedures prepared in conjunction with its manufacturer's recommendations.

APPLICABILITY Whenever the motor operated valve is required to be OPERABLE.

APPLICABILITY When the associated battery is required to be OPERABLE.

ACTIONS (NOTE: Separate condition entry is allowed for each battery.)

(b) Corrected for electrolyte temperature and level. However, level correction is not required when battery charging is < 2 amps when on float charge.

(c) A battery charging current of < 2 amps when on float charge is acceptable for meeting specific gravity limits following a battery recharge, for a maximum of 7 days. When charging current is used to satisfy specific gravity requirements, specific gravity of each connected cell shall be measured prior to expiration of the 7 day allowance.

APPLICABILITY MODE 5, during movement of irradiated fuel in the reactor pressure vessel.

APPLICABILITY MODE 5, during CORE ALTERATIONS*.

a) within the reactor pressure vessel, or b) during operations associated with the Inclined Fuel Transfer System (IFTS).

APPLICABILITY During handling of fuel assemblies or control rods, either:

a) within the reactor pressure vessel, or b) during operations associated with the IFTS.

REFUELING OPERATIONS OPERATIONAL REQUIREMENTS Loads in excess of 1000 pounds shall be prohibited from travel over fuel assemblies in the spent fuel storage racks in the spent fuel storage and cask storage pools, (including fuel seated in a spent fuel cask), upper containment fuel pool racks or new fuel storage vault racks EXCEPT loads required to perform dry cask storage operations. Loads in excess of 1000 pounds required to perform dry cask storage operations shall be allowed to travel over fuel assemblies in a spent fuel canister if performed in compliance with the requirements of the Control of Heavy Loads Program and using a single failure proof handling system.

APPLICABILITY With fuel assemblies in the spent fuel storage pool racks in the spent fuel storage and cask storage pools, (including fuel seated in a spent fuel cask), upper containment fuel pool racks, or the new fuel storage vault racks.

: b. At least once per 7 days while handling loads with the fuel building overhead crane.

REFUELING OPERATIONS (continued) safety analyses. The fuel building overhead crane physical stops preclude travel of the fuel building overhead crane over the fuel building spent fuel storage pool racks but do not prevent travel over the cask storage pool. The stops also ensure that handling of heavy loads is within the guidelines of NUREG-0612 which precludes dropping a heavy load onto safety-related equipment. Although weighing more than 1000 pounds itself, the fuel building overhead crane main hoist load block need not be considered a load because the main and auxiliary hoist are single failure proof. This will ensure that movement of the load block is in accordance with NUREG- 0612.

CPS/USAR Section 9.1.5.4 Control of Heavy Loads Program ensures compliance with NUREG-0612 and other requirements during the handling of heavy loads.

APPLICABILITY During IFTS operation.

: b. All access doors (including removable shields) to rooms through which the IFTS penetrates are closed and locked.

: b. The keylock switches which provide IFTS access or control-transfer system lockout are OPERABLE.

** When the contained water volume of the suppression pool is less than 98,700 ft3, which is equivalent to a suppression pool level of 12' 8", or Technical Specification 3.10.4 is being utilized.

Refer to USAR Section 13.4.1, "Plant Operations Review Committee."

Refer to Updated Safety Analysis Report section 13.4.2, Nuclear Safety Review Board.

: a. Each such procedure or procedure change shall be independently reviewed by an individual knowledgeable in the area affected other than the individual who prepared the procedure, or procedure change. The applicable Department Head/Designee shall approve all plant procedures and changes thereto, prior to implementation.

: b. Individuals responsible for reviews performed in accordance with Item 6.5.3.1.a above shall be designated by the Manager-Clinton Power Station or the responsible manager*. Each such review shall include a determination of whether or not additional, cross-disciplinary, review is necessary. If deemed necessary, such review shall be performed by the review personnel of the appropriate discipline.

: c. When a review pursuant to 10 CFR 50.59 is required, it shall be included in the procedure or the procedure change review. Pursuant to 10 CFR 50.59, NRC approval of items requiring NRC review shall be obtained prior to the Manager-Clinton Power Station approval for implementation.

: d. Written records of reviews performed in accordance with Item 6.5.3.1.a above, including recommendations for approval or disapproval, shall be prepared and maintained.

: a. The Commission shall be notified and a report submitted pursuant to the requirements of 10CFR50.73, and

: b. The reportable event shall be reviewed by the PORC.

: a. The CPS Site Vice President, Manager-Clinton Power Station, and the NSRB shall be notified within 24 hours.

: b. The Safety Limit Violation Report shall be reviewed by the PORC. This report shall describe: (1) applicable circumstances preceding the violation, (2) effects of the violation upon unit components, systems, or structures, and (3) corrective action taken to prevent recurrence.

: a. Refueling operations;

: b. Surveillance and test activities of safety-related equipment;

: f. Process Control Program implementation; and

: g. Offsite Dose Calculation Manual implementation.

: a. The intent of the original procedure is not altered;

: b. The change is approved by two members of the unit management staff, at least one of whom holds a Senior Operator license on the unit affected; and

: a. In-Plant Radiation Monitoring A program which will ensure the capability to accurately determine the airborne iodine concentration in vital areas under accident conditions.

This program shall include the following:

: 1. Monitoring, sampling, analysis, and reporting of radiation and radionuclides in the environment in accordance with the methodology and parameters in the ODCM;

: 2. A Land Use Census to ensure that changes in the use of areas at and beyond the SITE BOUNDARY are identified and that modifications to the monitoring program are made if required by the results of this census; and

The Process Control Program shall contain the current formula, sampling, analyses, tests, and determinations to be made to ensure that the processing and packaging of solid radioactive wastes based on demonstrated processing of actual or simulated wet solid wastes will be accomplished in such a way as to assure compliance with 10 CFR Part 20, 10 CFR Part 61, 10 CFR Part 71 and Federal and State regulations, burial ground requirements and other requirements governing the disposal of the radioactive waste.

Changes to the PCP:

: 1. Sufficient information to support the change together with the appropriate analyses or evaluations justifying the change(s), and

: 2. A determination that the change will maintain the overall conformance of the solidified waste product to existing requirements of Federal, State, or other applicable regulations.