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{{#Wiki_filter:SDM B 3.1.1 B 3.1 REACTIVITY CONTROL SYSTEMS B 3.1.1 SHUTDOWN MARGIN (SDM)  
{{#Wiki_filter:SDM B 3.1.1 B 3.1   REACTIVITY CONTROL SYSTEMS B 3.1.1   SHUTDOWN MARGIN (SDM)
BASES BACKGROUND        The reactivity control systems must be redundant and capable of holding the reactor core subcritical when shut down under cold conditions, in accordance with Reference 1, Appendix 1C, Criteria 27, 29, and 30. Maintenance of the SDM ensures that postulated reactivity events will not damage the fuel. SHUTDOWN MARGIN requirements provide sufficient reactivity margin to ensure that acceptable fuel design limits will not be exceeded for normal shutdown and anticipated operational occurrences (AOOs). As such, the SDM defines the degree of subcriticality that would be obtained immediately following the insertion of all control element assemblies (CEAs), assuming the single CEA of highest reactivity worth is fully withdrawn.
The system design requires that two independent reactivity control systems be provided, and that one of these systems be capable of maintaining the core subcritical under cold conditions. These requirements are provided by the use of movable CEAs and soluble boric acid in the Reactor Coolant System (RCS). The CEA System provides the SDM during power operation and is capable of making the core subcritical rapidly enough to prevent exceeding acceptable fuel damage limits, assuming that the CEA of highest reactivity worth remains fully withdrawn.
The soluble boron system can compensate for fuel depletion during operation and all xenon burnout reactivity changes, and maintain the reactor subcritical under cold conditions.
During power operation, SDM control is ensured by operating with the shutdown CEAs fully withdrawn and the regulating CEAs within the limits of Limiting Condition for Operation (LCO) 3.1.6. When the unit is in the shutdown and refueling MODEs, the SDM requirements are met by means of adjustments to the RCS boron concentration.
APPLICABLE        The minimum required SDM is assumed as an initial condition SAFETY ANALYSIS    in safety analysis. The safety analysis (Reference 1, Section 3.4) establishes a SDM that ensures specified acceptable fuel design limits (SAFDLs) are not exceeded for CALVERT CLIFFS - UNITS 1 & 2        B 3.1.1-1                        Revision 2


BASES  CALVERT CLIFFS - UNITS 1 & 2 B 3.1.1-1 Revision 2 BACKGROUND The reactivity control systems must be redundant and capable of holding the reactor core subcritical when shut down under cold conditions, in accordance with Reference 1, Appendix 1C, Criteria 27, 29, and 30
SDM B 3.1.1 BASES normal operation and AOOs, with the assumption of the highest worth CEA stuck out following a reactor trip. For MODE 5, the primary safety analysis that relies on the SDM limit is the boron dilution analysis.
. Maintenance of the SDM ensures that postulated reactivity events will not  
The acceptance criteria for the SDM requirements are that SAFDLs are maintained. This is done by ensuring that:
: a. The reactor can be made subcritical from all operating conditions, transients, and Design Basis Events;
: b. The reactivity transients associated with postulated accident conditions are controllable within acceptable limits (departure from nucleate boiling ratio [DNBR],
fuel centerline temperature limit AOOs, and an acceptable energy deposition for the CEA ejection accident [Reference 1, Chapter 14]); and
: c. The reactor will be maintained sufficiently subcritical to preclude inadvertent criticality in the shutdown condition.
The most limiting accident for the SDM requirements are based on a main steam line break (MSLB) or an Excess Load event (with failure of an MSIV to close), as described in the accident analysis (Reference 1, Chapter 14). The increased steam flow causes an increased energy removal from the affected steam generator, and consequently the RCS.
This results in a reduction of the reactor coolant temperature. The resultant coolant shrinkage causes a reduction in pressure. In the presence of a negative moderator temperature coefficient (MTC), this cooldown causes an increase in core reactivity. As RCS temperature decreases, the severity of the event decreases. The most limiting MSLB, with respect to potential fuel damage before a reactor trip occurs, is a guillotine break of a main steam line outside containment, initiated at the end of core life.
Following the MSLB or Excess Load event, a post-trip return to power may occur; however, no fuel damage occurs as a result of the post-trip return to power, and THERMAL POWER does not violate the Safety Limit (SL) requirement of SL 2.1.1. The limiting Excess Load event with respect to potential return-to-power after reactor trip is the opening of all steam dump and bypass valves at full power with failure of an MSIV to close.
CALVERT CLIFFS - UNITS 1 & 2      B 3.1.1-2                      Revision 43


damage the fuel. SHUTDOWN MARGIN requirements provide
SDM B 3.1.1 BASES In addition to the limiting MSLB transient, the SDM requirement for MODEs 3 and 4 must also protect against an uncontrolled CEA withdrawal from a hot zero power or low power condition, and a CEA ejection.
In the boron dilution analysis, the required SDM defines the reactivity difference between an initial subcritical boron concentration and the corresponding critical boron concentration. These values, in conjunction with the configuration of the RCS and the assumed dilution flow rate, directly affect the results of the analysis. This event is most limiting at the beginning of core life when critical boron concentrations are highest.
The withdrawal of CEAs from hot zero power or low power conditions adds reactivity to the reactor core, causing both the core power level and heat flux to increase with corresponding increases in reactor coolant temperatures and pressure. The withdrawal of CEAs also produces a time-dependent redistribution of core power.
The uncontrolled CEA withdrawal transient is terminated by the Variable High Power Trip. In all cases, power level, RCS pressure, linear heat rate (LHR), and the DNBR do not exceed allowable limits.
SHUTDOWN MARGIN satisfies 10 CFR 50.36(c)(2)(ii),
Criterion 2.
LCO              The MSLB (or the Excess Load event) and the boron dilution accidents (Reference 1, Chapter 14) are the most limiting analyses that establish the SDM value of the LCO. For MSLB accidents (or the Excess Load event), if the LCO is violated, there is a potential to exceed the DNBR limit and to exceed the acceptance criteria given in Reference 1, Chapter 14. For the boron dilution accident, if the LCO is violated, the minimum required time assumed for operator action to terminate dilution may no longer be applicable.
Because both initial RCS level and the dilution flow rate also significantly impact the boron dilution event in MODE 5 with pressurizer level < 90 inches from the bottom of the CALVERT CLIFFS - UNITS 1 & 2      B 3.1.1-3                        Revision 43


sufficient reactivity margin to ensure that acceptable fuel
SDM B 3.1.1 BASES pressurizer, the LCO also includes limits for these parameters during these conditions.
SHUTDOWN MARGIN is a core physics design condition that can be ensured through CEA positioning (regulating and shutdown CEA) in MODEs 1 and 2 and through the soluble boron concentration in all other MODEs.
APPLICABILITY    In MODEs 3, 4, and 5, the SDM requirements are applicable to provide sufficient negative reactivity to meet the assumptions of the safety analyses discussed above. In MODEs 1 and 2, SDM is ensured by complying with LCOs 3.1.5 and 3.1.6. In MODE 6, the shutdown reactivity requirements are given in LCO 3.9.1.
ACTIONS          A.1, A.2, and A.3 With non-borated water sources of > 88 gpm available, while the unit is in MODE 5 with the pressurizer level
                  < 90 inches, the consequences of a boron dilution event may exceed the analysis results. Therefore, action must be initiated immediately to reduce the potential for such an event. To accomplish this, Required Action A.1 requires immediate suspension of positive reactivity additions.
However, since Required Action A.1 only reduces the potential for the event and does not eliminate it, immediate action must also be initiated to increase the SDM to compensate for the non-borated water sources (Required Action A.2). Finally, Required Action A.3 requires periodic verification, once per 12 hours, that the SDM increase is maintained sufficient to compensate for the additional sources of non-borated water. Required Action A.1 is modified by a Note indicating that the suspension of positive reactivity additions is not required if SDM has been sufficiently increased to compensate for the additional sources of non-borated water. The immediate Completion Time reflects the urgency of the corrective actions. The periodic Completion Time of 12 hours is considered reasonable, based on other administrative controls available and operating experience.
CALVERT CLIFFS - UNITS 1 & 2      B 3.1.1-4                      Revision 43


design limits will not be exceeded for normal shutdown and
SDM B 3.1.1 BASES B.1 and B.2 With the RCS level at or below the bottom of the hot leg nozzles, while the unit is in MODE 5 with the pressurizer level < 90 inches, the consequences of a boron dilution event may exceed the analysis results. Therefore, action must be initiated immediately to reduce the potential for such an event. To accomplish this, Required Action B.1 requires immediate suspension of operations involving positive reactivity additions that could result in loss of the required SDM. Suspending positive reactivity additions that could result in failure to meet the minimum SDM limit is required to assure continued safe operation.
 
anticipated operational occurrences (AOOs). As such, the
 
SDM defines the degree of subcriticality that would be
 
obtained immediately following the insertion of all control
 
element assemblies (CEAs), assuming the single CEA of
 
highest reactivity worth is fully withdrawn.
 
The system design requires that two independent reactivity control systems be provided, and that one of these systems
 
be capable of maintaining the core subcritical under cold
 
conditions. These requirements are provided by the use of
 
movable CEAs and soluble boric acid in the Reactor Coolant
 
System (RCS). The CEA System provides the SDM during power
 
operation and is capable of making the core subcritical
 
rapidly enough to prevent exceeding acceptable fuel damage
 
limits, assuming that the CEA of highest reactivity worth
 
remains fully withdrawn.
 
The soluble boron system can compensate for fuel depletion during operation and all xenon burnout reactivity changes, and maintain the reactor subcritical under cold conditions.
 
During power operation, SDM control is ensured by operating with the shutdown CEAs fully withdrawn and the regulating
 
CEAs within the limits of Limiting Condition for Operation (LCO) 3.1.6. When the unit is in the shutdown and refueling MODEs, the SDM requirements are met by means of adjustments to the RCS boron concentration.
APPLICABLE The minimum required SDM is assumed as an initial condition SAFETY ANALYSIS in safety analysis. The safety analysis (Reference 1, Section 3.4) establishes a SDM that ensures specified acceptable fuel design limits (SAFDLs) are not exceeded for SDM B 3.1.1 BASES CALVERT CLIFFS - UNITS 1 & 2 B 3.1.1-2 Revision 43 normal operation and AOOs, with the assumption of the highest worth CEA stuck out following a reactor trip. For
 
MODE 5, the primary safety analysis that relies on the SDM
 
limit is the boron dilution analysis.
 
The acceptance criteria for the SDM requirements are that SAFDLs are maintained. This is done by ensuring that:  a. The reactor can be made subcritical from all operating conditions, transients, and Design Basis Events;  b. The reactivity transients associated with postulated accident conditions are controllable within acceptable
 
limits (departure from nucleate boiling ratio [DNBR],
fuel centerline temperature limit AOOs, and an
 
acceptable energy deposition for the CEA ejection
 
accident [Reference 1, Chapter 14]); and  c. The reactor will be maintained sufficiently subcritical to preclude inadvertent criticality in the shutdown
 
condition.
 
The most limiting accident for the SDM requirements are based on a main steam line break (MSLB) or an Excess Load event (with failure of an MSIV to close), as described in the accident analysis (Reference 1, Chapter 14). The
 
increased steam flow causes an increased energy removal from the affected steam generator, and consequently the RCS. 
 
This results in a reduction of the reactor coolant
 
temperature. The resultant coolant shrinkage causes a
 
reduction in pressure. In the presence of a negative
 
moderator temperature coefficient (MTC), this cooldown
 
causes an increase in core reactivity. As RCS temperature
 
decreases, the severity of the event decreases. The most limiting MSLB, with respect to potential fuel damage before
 
a reactor trip occurs, is a guillotine break of a main steam
 
line out side containment, initiated at the end of core life.
Following the MSLB or Excess Load event , a post-trip return to power may occur; however, no fuel damage occurs as a
 
result of the post-trip return to power, and THERMAL POWER
 
does not violate the Safety Limit (SL) requirement of
 
SL 2.1.1. The limiting Excess Load event with respect to potential return-to-power after reactor trip is the opening of all steam dump and bypass valves at full power with failure of an MSIV to close.
 
SDM B 3.1.1 BASES  CALVERT CLIFFS - UNITS 1 & 2 B 3.1.1-3 Revision 43 In addition to the limiting MSLB transient, the SDM requirement for MODEs 3 and 4 must also protect against an
 
uncontrolled CEA withdrawal from a hot zero power or low
 
power condition, and a CEA ejection.
In the boron dilution analysis, the required SDM defines the
 
reactivity difference between an initial subcritical boron
 
concentration and the corresponding critical boron
 
concentration. These values, in conjunction with the
 
configuration of the RCS and the assumed dilution flow rate, directly affect the results of the analysis. This event is
 
most limiting at the beginning of core life when critical
 
boron concentrations are highest.
 
The withdrawal of CEAs from hot zero power or low power conditions adds reactivity to the reactor core, causing both
 
the core power level and heat flux to increase with
 
corresponding increases in reactor coolant temperatures and
 
pressure. The withdrawal of CEAs also produces a time-
 
dependent redistribution of core power.
 
The uncontrolled CEA withdrawal transient is terminated by the Variable High Power Trip.
In all cases, power level, RCS pressure, linear heat rate (LHR), and the DNBR do not
 
exceed allowable limits.
 
SHUTDOWN MARGIN satisfies 10 CFR 50.36(c)(2)(ii), Criterion 2.
LCO The MSLB (or the Excess Load event) and the boron dilution accidents (Reference 1, Chapter 14) are the most limiting analyses that establish the SDM value of the LCO. For MSLB
 
accidents (or the Excess Load event), if the LCO is violated, there is a potential to exceed the DNBR limit and
 
to exceed the acceptance criteria given in Reference 1, Chapter 14. For the boron dilution accident, if the LCO is
 
violated, the minimum required time assumed for operator
 
action to terminate dilution may no longer be applicable. 
 
Because both initial RCS level and the dilution flow rate
 
also significantly impact the boron dilution event in MODE 5
 
with pressurizer level < 90 inches from the bottom of the SDM B 3.1.1 BASES  CALVERT CLIFFS - UNITS 1 & 2 B 3.1.1-4 Revision 43 pressurizer, the LCO also includes limits for these parameters during these conditions.
 
SHUTDOWN MARGIN is a core physics design condition that can be ensured through CEA positioning (regulating and shutdown
 
CEA) in MODEs 1 and 2 and through the soluble boron concentration in all other MODEs.
APPLICABILITY In MODEs 3, 4, and 5, the SDM requirements are applicable to provide sufficient negative reactivity to meet the
 
assumptions of the safety analyses discussed above. In
 
MODEs 1 and 2, SDM is ensured by complying with LCOs 3.1.5
 
and 3.1.6. In MODE 6, the shutdown reactivity requirements are given in LCO 3.9.1.
ACTIONS A.1, A.2, and A.3 With non-borated water sources of > 88 gpm available, while
 
the unit is in MODE 5 with the pressurizer level
 
< 90 inches, the consequences of a boron dilution event may
 
exceed the analysis results. Therefore, action must be
 
initiated immediately to reduce the potential for such an
 
event. To accomplish this, Required Action A.1 requires
 
immediate suspension of positive reactivity additions. 
 
However, since Required Action A.1 only reduces the
 
potential for the event and does not eliminate it, immediate action must also be initiated to increase the SDM to compensate for the non-borated water sources (Required
 
Action A.2). Finally, Required Action A.3 requires periodic
 
verification, once per 12 hours, that the SDM increase is
 
maintained sufficient to compensate for the additional
 
sources of non-borated water. Required Action A.1 is
 
modified by a Note indicating that the suspension of
 
positive reactivity additions is not required if SDM has
 
been sufficiently increased to compensate for the additional
 
sources of non-borated water. The immediate Completion Time
 
reflects the urgency of the corrective actions. The
 
periodic Completion Time of 12 hours is considered
 
reasonable, based on other administrative controls available
 
and operating experience.
 
SDM B 3.1.1 BASES  CALVERT CLIFFS - UNITS 1 & 2 B 3.1.1-5 Revision 27 B.1 and B.2 With the RCS level at or below the bottom of the hot leg nozzles, while the unit is in MODE 5 with the pressurizer  
 
level < 90 inches, the consequences of a boron dilution  
 
event may exceed the analysis results. Therefore, action  
 
must be initiated immediately to reduce the potential for such an event. To accomplish this, Required Action B.1 requires immediate suspension of operations involving positive reactivity additions that could result in loss of the required SDM. Suspending positive reactivity additions that could result in failure to meet the minimum SDM limit is required to assure continued safe operation.
Introduction of coolant inventory must be from sources that have boron concentration greater than that required in the RCS for the minimum SDM. This may result in an overall reduction in RCS boron concentration, but provides an acceptable margin to maintaining subcritical operation.
Introduction of coolant inventory must be from sources that have boron concentration greater than that required in the RCS for the minimum SDM. This may result in an overall reduction in RCS boron concentration, but provides an acceptable margin to maintaining subcritical operation.
Introduction of temperature changes including temperature increases when operating with a positive MTC must also be evaluated to ensure they do not result in a loss of the required SDM. However, since Required Action B.1 only reduces the potential for the event and does not eliminate  
Introduction of temperature changes including temperature increases when operating with a positive MTC must also be evaluated to ensure they do not result in a loss of the required SDM. However, since Required Action B.1 only reduces the potential for the event and does not eliminate it, immediate action must also be initiated to increase the RCS level to above the bottom of the hot leg nozzles (Required Action B.2). The immediate Completion Time reflects the urgency of the corrective actions.
 
C.1 If the SDM requirements are not met for reasons other than addressed in Condition A or B, boration must be initiated promptly. A Completion Time of immediately is required to meet the assumptions of the safety analysis. It is assumed that boration will be continued until the SDM requirements are met.
it, immediate action must also be initiated to increase the  
In the determination of the required combination of boration flow rate and boron concentration, there is no unique requirement that must be satisfied. Since it is imperative to raise the boron concentration of the RCS as soon as possible, the boron concentration should be a highly concentrated solution, such as that normally found in the boric acid storage tank or the refueling water tank. The CALVERT CLIFFS - UNITS 1 & 2      B 3.1.1-5                      Revision 27
 
RCS level to above the bottom of the hot leg nozzles (Required Action B.2). The immediate Completion Time  
 
reflects the urgency of the corrective actions.  
 
C.1 If the SDM requirements are not met for reasons other than  


addressed in Condition A or B, boration must be initiated
SDM B 3.1.1 BASES operator should borate with the best source available for the plant conditions. However, as a minimum, the boration flow rate shall be  40 gpm and the boron concentration shall be  2300 ppm boric acid solution or equivalent.
 
Assuming that a value of 1% k/k must be recovered and a boration flow rate of 40 gpm from the boric acid storage tank, it is possible to increase the boron concentration of the RCS by 100 ppm in approximately 15 minutes. If an inverse boron worth of 100 ppm/% k/k is assumed, this combination of parameters will increase the SDM by 1% k/k.
promptly. A Completion Time of immediately is required to
These boration parameters of 40 gpm and 100 ppm represent typical values and are provided for the purpose of offering a specific example.
 
SURVEILLANCE     SR 3.1.1.1 REQUIREMENTS SHUTDOWN MARGIN is verified by performing a reactivity balance calculation, considering the listed reactivity effects:
meet the assumptions of the safety analysis. It is assumed
: a. RCS boron concentration;
 
: b. CEA positions;
that boration will be continued until the SDM requirements
: c. RCS average temperature;
 
are met.
In the determination of the required combination of boration flow rate and boron concentration, there is no unique
 
requirement that must be satisfied. Since it is imperative
 
to raise the boron concentration of the RCS as soon as
 
possible, the boron concentration should be a highly
 
concentrated solution, such as that normally found in the
 
boric acid storage tank or the refueling water tank. The SDM B 3.1.1 BASES CALVERT CLIFFS - UNITS 1 & 2 B 3.1.1-6 Revision 27 operator should borate with the best source available for the plant conditions. However, as a minimum, the boration flow rate shall be  40 gpm and the boron concentration shall be  2300 ppm boric acid solution or equivalent.  
 
Assuming that a value of 1% k/k must be recovered and a boration flow rate of 40 gpm from the boric acid storage tank, it is possible to increase the boron concentration of  
 
the RCS by 100 ppm in approximately 15 minutes. If an inverse boron worth of 100 ppm/% k/k is assumed, this combination of parameters will increase the SDM by 1% k/k. These boration parameters of 40 gpm and 100 ppm represent typical values and are provided for the purpose of offering a specific example.
SURVEILLANCE SR 3.1.1.1 REQUIREMENTS SHUTDOWN MARGIN is verified by performing a reactivity balance calculation, considering the listed reactivity  
 
effects: a. RCS boron concentration; b. CEA positions; c. RCS average temperature;
: d. Fuel burnup based on gross thermal energy generation;
: d. Fuel burnup based on gross thermal energy generation;
: e. Xenon concentration;
: e. Xenon concentration;
: f. Samarium concentration; and
: f. Samarium concentration; and
: g. Isothermal temperature coefficient.  
: g. Isothermal temperature coefficient.
 
Using the isothermal temperature coefficient accounts for Doppler reactivity in this calculation because the reactor is subcritical and the fuel temperature will be changing at the same rate as the RCS.
Using the isothermal temperature coefficient accounts for Doppler reactivity in this calculation because the reactor is subcritical and the fuel temperature will be changing at the same rate as the RCS.  
The Frequency of 24 hours is based on the generally slow change in required boron concentration, and also allows sufficient time for the operator to collect the required data, which includes performing a boron concentration analysis, and complete the calculation.
 
CALVERT CLIFFS - UNITS 1 & 2      B 3.1.1-6                      Revision 27
The Frequency of 24 hours is based on the generally slow change in required boron concentration, and also allows  
 
sufficient time for the operator to collect the required  


data, which includes performing a boron concentration
SDM B 3.1.1 BASES SR 3.1.1.2 and SR 3.1.1.3 These Surveillance Requirements (SRs) periodically verify the significant assumptions of a boron dilution event are maintained. A non-borated water source of  88 gpm allows for only one charging pump to be capable of injection during these conditions since each charging pump is capable of an injection rate of 46 gpm. Each SR is modified by a Note indicating that it is only required when the unit is in MODE 5 with the pressurizer level < 90 inches. Since the applicable conditions for the SR may be attained while already in MODE 5, each SR is provided with a Frequency of once within 1 hour after achieving MODE 5 with pressurizer level < 90 inches. This provides a short period of time to verify compliance after the conditions are attained.
Additionally, each SR must be completed once each 12 hours after the initial verification. The Frequency of 12 hours is considered reasonable, in view of other administrative controls available and operating experience.
REFERENCES        1. Updated Final Safety Analysis Report (UFSAR)
CALVERT CLIFFS - UNITS 1 & 2      B 3.1.1-7                        Revision 27


analysis, and complete the calculation.  
Reactivity Balance B 3.1.2 B 3.1  REACTIVITY CONTROL SYSTEMS B 3.1.2  Reactivity Balance BASES BACKGROUND        According to Reference 1, Appendix 1C, Criteria 27, 29, and 30, reactivity shall be controllable, such that, subcriticality is maintained under cold conditions, and acceptable fuel design limits are not exceeded during normal operation and AOOs. Therefore, reactivity balance is used as a measure of the predicted versus measured core reactivity during power operation. The periodic confirmation of core reactivity is necessary to ensure that Design Basis Accident (DBA) and transient safety analyses remain valid. A large reactivity difference could be the result of unanticipated changes in fuel, CEA worth, or operation at conditions not consistent with those assumed in the predictions of core reactivity, and could potentially result in a loss of SDM or violation of acceptable fuel design limits. Comparing predicted versus measured core reactivity validates the nuclear methods used in the safety analysis and supports the SDM demonstrations (LCO 3.1.1) in ensuring the reactor can be brought safely to cold, subcritical conditions.
When the reactor core is critical or in normal power operation, a reactivity balance exists and the net reactivity is zero. A comparison of predicted and measured reactivity is convenient under such a balance, since parameters are being maintained relatively stable under steady state power conditions. The positive reactivity inherent in the core design is balanced by the negative reactivity of the control components, thermal feedback, neutron leakage, and materials in the core that absorb neutrons, such as burnable absorbers producing zero net reactivity. Excess reactivity can be inferred from the critical boron curve, which provides an indication of the soluble boron concentration in the RCS versus cycle burnup.
Periodic measurement of the RCS boron concentration for comparison with the predicted value with other variables fixed (such as CEA height, temperature, pressure, and power) provides a convenient method of ensuring that core reactivity is within design expectations, and that the calculational models used to generate the safety analysis are adequate.
CALVERT CLIFFS - UNITS 1 & 2        B 3.1.2-1                        Revision 2


SDM B 3.1.1 BASES CALVERT CLIFFS - UNITS 1 & 2 B 3.1.1-7 Revision 27 SR 3.1.1.2 and SR 3.1.1.3 These Surveillance Requirements (SRs) periodically verify the significant assumptions of a boron dilution event are maintained. A non-borated water source of 88 gpm allows for only one charging pump to be capable of injection during these conditions since each charging pump is capable of an injection rate of 46 gpm. Each SR is modified by a Note indicating that it is only required when the unit is in
Reactivity Balance B 3.1.2 BASES In order to achieve the required fuel cycle energy output, the uranium enrichment in the new fuel loading and in the fuel remaining from the previous cycle provides excess positive reactivity beyond that required to sustain steady state operation throughout the cycle. When the reactor is critical at hot full power, the excess positive reactivity is compensated by burnable absorbers (if any), CEAs, whatever neutron poisons (mainly xenon and samarium) are present in the fuel, and the RCS boron concentration.
When the core is producing THERMAL POWER, the fuel is being depleted and excess reactivity is decreasing. As the fuel depletes, the RCS boron concentration is reduced to decrease negative reactivity and maintain constant THERMAL POWER.
The critical boron curve is based on steady state operation at RATED THERMAL POWER (RTP). Therefore, deviations from the predicted critical boron curve may indicate deficiencies in the design analysis, deficiencies in the calculational models, or abnormal core conditions, and must be evaluated.
APPLICABLE        Accurate prediction of core reactivity is either an explicit SAFETY ANALYSES  or implicit assumption in the accident analysis evaluations.
Most accident evaluations (Reference 1, Section 14.1) are, therefore, dependent upon accurate evaluation of core reactivity. In particular, SDM and reactivity transients, such as CEA withdrawal accidents or CEA ejection accidents, are very sensitive to accurate prediction of core reactivity. These accident analysis evaluations rely on computer codes that have been qualified against available test data, operating plant data, and analytical benchmarks.
Monitoring reactivity balance additionally ensures that the nuclear methods provide an accurate representation of the core reactivity.
Design calculations and safety analyses are performed for each fuel cycle for the purpose of predetermining reactivity behavior and the RCS boron concentration requirements for reactivity control during fuel depletion.
The comparison between measured and predicted initial core reactivity provides a normalization for calculational models used to predict core reactivity. If the measured and CALVERT CLIFFS - UNITS 1 & 2      B 3.1.2-2                        Revision 2


MODE 5 with the pressurizer level < 90 inches. Since the  
Reactivity Balance B 3.1.2 BASES predicted RCS boron concentrations for identical core conditions at beginning-of-cycle (BOC) do not agree, the assumptions used in the reload cycle design analysis or the calculational models used to predict soluble boron requirements may not be accurate. If reasonable agreement between measured and predicted core reactivity exists at BOC, the prediction may be normalized to the measured boron concentration. Thereafter, any significant deviations in the measured boron concentration from the predicted critical boron curve that develop during fuel depletion may be an indication that the calculational model is not adequate for core burnups beyond BOC, or that an unexpected change in core conditions has occurred.
The normalization of predicted RCS boron concentration to the measured value is typically performed after reaching RTP following startup from a refueling outage, with the CEAs in their normal positions for power operation. The normalization is performed at BOC conditions, so that core reactivity relative to predicted values can be continually monitored and evaluated as core conditions change during the cycle.
The reactivity balance satisfies 10 CFR 50.36(c)(2)(ii),
Criterion 2.
LCO              The reactivity balance limit is established to ensure plant operation is maintained within the assumptions of the safety analyses. Large differences between actual and predicted core reactivity may indicate that the assumptions of the DBA and transient analyses are no longer valid, or that the uncertainties in the nuclear design methodology are larger than expected. A limit on the reactivity balance of
                  +/- 1% k/k has been established, based on engineering judgment. A 1% deviation in reactivity from that predicted is larger than expected for normal operation and should, therefore, be evaluated.
When measured core reactivity is within 1% k/k of the predicted value at steady state thermal conditions, the core is considered to be operating within acceptable design limits. Since deviations from the limit are normally detected by comparing predicted and measured steady state CALVERT CLIFFS - UNITS 1 & 2      B 3.1.2-3                        Revision 2


applicable conditions for the SR may be attained while
Reactivity Balance B 3.1.2 BASES RCS critical boron concentrations, the difference between measured and predicted values would be approximately 100 ppm (depending on the boron worth) before the limit is reached.
These values are well within the uncertainty limits for analysis of boron concentration samples, so that spurious violations of the limit due to uncertainty in measuring the RCS boron concentration are unlikely.
APPLICABILITY    The limits on core reactivity must be maintained during MODE 1 because a reactivity balance must exist when the reactor is critical or producing THERMAL POWER. As the fuel depletes, core conditions are changing, and confirmation of the reactivity balance ensures the core is operating as designed. This Specification does not apply in MODE 2 because enough operating margin exists to limit the effects of a reactivity anomaly, and THERMAL POWER is low enough
( 5% RTP) such that reactivity anomalies are unlikely to occur. This Specification does not apply in MODEs 3, 4, and 5 because the reactor is shut down and the reactivity balance is not changing.
In MODE 6, fuel loading results in a continually changing core reactivity. Boron concentration requirements (LCO 3.9.1) ensure that fuel movements are performed within the bounds of the safety analysis. A SDM demonstration is required during the first startup following operations that could have altered core reactivity (e.g., fuel movement, or CEA replacement, or shuffling).
ACTIONS          A.1 and A.2 Should an anomaly develop between measured and predicted core reactivity, an evaluation of the core design and safety analysis must be performed. Core conditions are evaluated to determine their consistency with input to design calculations. Measured core and process parameters are evaluated to determine that they are within the bounds of the safety analysis, and safety analysis calculational models are reviewed to verify that they are adequate for representation of the core conditions. The required Completion Time of 7 days is based on the low probability of a DBA occurring during this period, and allows sufficient CALVERT CLIFFS - UNITS 1 & 2      B 3.1.2-4                        Revision 2


already in MODE 5, each SR is provided with a Frequency of  
Reactivity Balance B 3.1.2 BASES time to assess the physical condition of the reactor and to complete the evaluation of the core design and safety analysis.
Following evaluations of the core design and safety analysis, the cause of the reactivity anomaly may be resolved. If the cause of the reactivity anomaly is a mismatch in core conditions at the time of RCS boron concentration sampling, a recalculation of the RCS boron concentration requirements may be performed to demonstrate that core reactivity is behaving as expected. If an unexpected physical change in the condition of the core has occurred, it must be evaluated and corrected, if possible.
If the cause of the reactivity anomaly is in the calculation technique, the calculational models must be revised to provide more accurate predictions. If any of these results are demonstrated, and it is concluded that the reactor core is acceptable for continued operation, the boron letdown curve may be renormalized, and power operation may continue.
If operational restrictions or additional SRs are necessary to ensure the reactor core is acceptable for continued operation, they must be defined.
The required Completion Time of 7 days is adequate for preparing whatever operating restrictions or SRs may be required to allow continued reactor operation.
B.1 If the core reactivity cannot be restored to within the 1% k/k limit, the plant must be brought to a MODE in which the LCO does not apply. To achieve this status, the plant must be brought to at least MODE 2 within 6 hours. The allowed Completion Time is reasonable, based on operating experience, for reaching MODE 2 from full power conditions in an orderly manner and without challenging plant systems.
SURVEILLANCE      SR 3.1.2.1 REQUIREMENTS Core reactivity is verified by periodic comparisons of measured and predicted RCS boron concentrations. The comparison is made considering that other core conditions are fixed or stable, including CEA position, moderator CALVERT CLIFFS - UNITS 1 & 2      B 3.1.2-5                        Revision 2


once within 1 hour after achieving MODE 5 with pressurizer
Reactivity Balance B 3.1.2 BASES temperature, fuel temperature, fuel depletion, xenon concentration, and samarium concentration. The SR is performed prior to entering MODE 1 as an initial check on core conditions and design calculations at BOC and every 31 days after 60 effective full power days (EFPD). The SR is modified by two Notes. The Note in the SR column indicates that the normalization of predicted core reactivity to the measured value may take place within the first 60 EFPD after each fuel loading. This allows sufficient time for core conditions to reach steady state, but prevents operation for a large fraction of the fuel cycle without establishing a benchmark for the design calculations. The required subsequent Frequency of 31 EFPD following the initial 60 EFPD, after entering MODE 1, is acceptable, based on the slow rate of core changes due to fuel depletion and the presence of other indicators (e.g., quadrant power tilt ratio, etc.) for prompt indication of an anomaly. The Frequency Note, "only required after 60 EFPD after each fuel loading," is added to the Frequency column to allow this.
 
REFERENCES       1. UFSAR CALVERT CLIFFS - UNITS 1 & 2       B 3.1.2-6                        Revision 3
level < 90 inches. This provides a short period of time to
 
verify compliance after the conditions are attained. 
 
Additionally, each SR must be completed once each 12 hours
 
after the initial verification. The Frequency of 12 hours
 
is considered reasonable, in view of other administrative controls available and operating experience.
REFERENCES 1. Updated Final Safety Analysis Report (UFSAR)
 
Reactivity Balance B 3.1.2 B 3.1  REACTIVITY CONTROL SYSTEMS B 3.1.2  Reactivity Balance
 
BASES CALVERT CLIFFS - UNITS 1 & 2 B 3.1.2-1 Revision 2 BACKGROUND According to Reference 1 , Appendix 1C, Criteria 27, 29, and 30 , reactivity shall be controllable, such that, subcriticality is maintained under cold conditions, and acceptable fuel design limits are not exceeded during normal operation and AOOs. Therefore, reactivity balance is used as a measure of the predicted versus measured core reactivity during power operation. The periodic
 
confirmation of core reactivity is necessary to ensure that
 
Design Basis Accident (DBA) and transient safety analyses
 
remain valid. A large reactivity difference could be the
 
result of unanticipated changes in fuel, CEA worth, or operation at conditions not consistent with those assumed in
 
the predictions of core reactivity, and could potentially
 
result in a loss of SDM or violation of acceptable fuel
 
design limits. Comparing predicted versus measured core
 
reactivity validates the nuclear methods used in the safety
 
analysis and supports the SDM demonstrations (LCO 3.1.1
) in ensuring the reactor can be brought safely to cold, subcritical conditions.
 
When the reactor core is critical or in normal power
 
operation, a reactivity balance exists and the net
 
reactivity is zero. A comparison of predicted and measured
 
reactivity is convenient under such a balance, since
 
parameters are being maintained relatively stable under
 
steady state power conditions. The positive reactivity
 
inherent in the core design is balanced by the negative
 
reactivity of the control components, thermal feedback, neutron leakage, and materials in the core that absorb
 
neutrons, such as burnable absorbers producing zero net
 
reactivity. Excess reactivity can be inferred from the
 
critical boron curve, which provides an indication of the soluble boron concentration in the RCS versus cycle burnup.
Periodic measurement of the RCS boron concentration for comparison with the predicted value with other variables
 
fixed (such as CEA height, temperature, pressure, and power)
 
provides a convenient method of ensuring that core
 
reactivity is within design expectations, and that the
 
calculational models used to generate the safety analysis
 
are adequate.
Reactivity Balance B 3.1.2 BASES  CALVERT CLIFFS - UNITS 1 & 2 B 3.1.2-2 Revision 2 In order to achieve the required fuel cycle energy output, the uranium enrichment in the new fuel loading and in the
 
fuel remaining from the previous cycle provides excess positive reactivity beyond that required to sustain steady
 
state operation throughout the cycle. When the reactor is critical at hot full power, the excess positive reactivity is compensated by burnable absorbers (if any), CEAs, whatever neutron poisons (mainly xenon and samarium) are
 
present in the fuel, and the RCS boron concentration.
 
When the core is producing THERMAL POWER, the fuel is being
 
depleted and excess reactivity is decreasing. As the fuel
 
depletes, the RCS boron concentration is reduced to decrease
 
negative reactivity and maintain constant THERMAL POWER. 
 
The critical boron curve is based on steady state operation
 
at RATED THERMAL POWER (RTP). Therefore, deviations from the predicted critical boron curve may indicate deficiencies
 
in the design analysis, deficiencies in the calculational models, or abnormal core conditions, and must be evaluated.
APPLICABLE Accurate prediction of core reactivity is either an explicit SAFETY ANALYSES or implicit assumption in the accident analysis evaluations.
Most accident evaluations (Reference 1, Section 14.1) are, therefore, dependent upon accurate evaluation of core
 
reactivity. In particular, SDM and reactivity transients, such as CEA withdrawal accidents or CEA ejection accidents, are very sensitive to accurate prediction of core
 
reactivity. These accident analysis evaluations rely on
 
computer codes that have been qualified against available test data, operating plant data, and analytical benchmarks.
Monitoring reactivity balance additionally ensures that the
 
nuclear methods provide an accurate representation of the
 
core reactivity.
 
Design calculations and safety analyses are performed for
 
each fuel cycle for the purpose of predetermining reactivity
 
behavior and the RCS boron concentration requirements for
 
reactivity control during fuel depletion.
 
The comparison between measured and predicted initial core reactivity provides a normalization for calculational models
 
used to predict core reactivity. If the measured and Reactivity Balance B 3.1.2 BASES  CALVERT CLIFFS - UNITS 1 & 2 B 3.1.2-3 Revision 2 predicted RCS boron concentrations for identical core conditions at beginning
-of-cycle (BOC) do not agree, the assumptions used in the reload cycle design analysis or the
 
calculational models used to predict soluble boron
 
requirements may not be accurate. If reasonable agreement
 
between measured and predicted core reactivity exists at BOC, the prediction may be normalized to the measured boron concentration. Thereafter, any significant deviations in the measured boron concentration from the predicted critical
 
boron curve that develop during fuel depletion may be an
 
indication that the calculational model is not adequate for
 
core burnups beyond BOC, or that an unexpected change in
 
core conditions has occurred.
 
The normalization of predicted RCS boron concentration to the measured value is typically performed after reaching RTP
 
following startup from a refueling outage, with the CEAs in
 
their normal positions for power operation. The
 
normalization is performed at BOC conditions, so that core
 
reactivity relative to predicted values can be continually
 
monitored and evaluated as core conditions change during the
 
cycle.
The reactivity balance satisfies 10 CFR 50.36(c)(2)(ii), Criterion 2.
 
LCO The reactivity balance limit is established to ensure plant
 
operation is maintained within the assumptions of the safety
 
analyses. Large differences between actual and predicted
 
core reactivity may indicate that the assumptions of the DBA and transient analyses are no longer valid, or that the uncertainties in the nuclear design methodology are larger
 
than expected. A limit on the reactivity balance of
+/- 1% k/k has been established, based on engineering judgment. A 1% deviation in reactivity from that predicted is larger than expected for normal operation and should
, therefore , be evaluated.
When measured core reactivity is within 1% k/k of the predicted value at steady state thermal conditions, the core is considered to be operating within acceptable design
 
limits. Since deviations from the limit are normally
 
detected by comparing predicted and measured steady state Reactivity Balance B 3.1.2 BASES  CALVERT CLIFFS - UNITS 1 & 2 B 3.1.2-4 Revision 2 RCS critical boron concentrations, the difference between measured and predicted values would be approximately 100 ppm (depending on the boron worth) before the limit is reached.
 
These values are well within the uncertainty limits for
 
analysis of boron concentration samples, so that spurious violations of the limit due to uncertainty in measuring the
 
RCS boron concentration are unlikely.
APPLICABILITY The limits on core reactivity must be maintained during MODE 1 because a reactivity balance must exist when the
 
reactor is critical or producing THERMAL POWER. As the fuel
 
depletes, core conditions are changing, and confirmation of
 
the reactivity balance ensures the core is operating as
 
designed. This Specification does not apply in MODE 2
 
because enough operating margin exists to limit the effects
 
of a reactivity anomaly, and THERMAL POWER is low enough
( 5% RTP) such that reactivity anomalies are unlikely to occur. This Specification does not apply in MODEs 3, 4, and 5 because the reactor is shut down and the reactivity balance is not changing.
 
In MODE 6, fuel loading results in a continually changing
 
core reactivity. Boron concentration requirements (LCO 3.9.1
) ensure that fuel movements are performed within the bounds of the safety analysis. A SDM demonstration is
 
required during the first startup following operations that
 
could have altered core reactivity (e.g., fuel movement, or CEA replacement, or shuffling).
ACTIONS A.1 and A.2 Should an anomaly develop between measured and predicted
 
core reactivity, an evaluation of the core design and safety
 
analysis must be performed. Core conditions are evaluated
 
to determine their consistency with input to design
 
calculations. Measured core and process parameters are
 
evaluated to determine that they are within the bounds of
 
the safety analysis, and safety analysis calculational
 
models are reviewed to verify that they are adequate for
 
representation of the core conditions. The required
 
Completion Time of 7 days is based on the low probability of
 
a DBA occurring during this period, and allows sufficient Reactivity Balance B 3.1.2 BASES  CALVERT CLIFFS - UNITS 1 & 2 B 3.1.2-5 Revision 2 time to assess the physical condition of the reactor and to complete the evaluation of the core design and safety analysis.
 
Following evaluations of the core design and safety
 
analysis, the cause of the reactivity anomaly may be resolved. If the cause of the reactivity anomaly is a mismatch in core conditions at the time of RCS boron
 
concentration sampling, a recalculation of the RCS boron concentration requirements may be performed to demonstrate
 
that core reactivity is behaving as expected. If an
 
unexpected physical change in the condition of the core has
 
occurred, it must be evaluated and corrected, if possible. 
 
If the cause of the reactivity anomaly is in the calculation
 
technique, the calculational models must be revised to provide more accurate predictions. If any of these results
 
are demonstrated, and it is concluded that the reactor core
 
is acceptable for continued operation, the boron letdown curve may be renormalized, and power operation may continue. 
 
If operational restrictions or additional SRs are necessary
 
to ensure the reactor core is acceptable for continued
 
operation, they must be defined.
 
The required Completion Time of 7 days is adequate for
 
preparing whatever operating restrictions or SR s may be required to allow continued reactor operation.
 
B.1  If the core reactivity cannot be restored to within the 1% k/k limit, the plant must be brought to a MODE in which the LCO does not apply. To achieve this status, the plant must be brought to at least MODE 2 within 6 hours. The
 
allowed Completion Time is reasonable, based on operating
 
experience, for reaching MODE 2 from full power conditions in an orderly manner and without challenging plant systems.
SURVEILLANCE SR 3.1.2.1 REQUIREMENTS
 
Core reactivity is verified by periodic comparisons of
 
measured and predicted RCS boron concentrations. The
 
comparison is made considering that other core conditions are fixed or stable
, including CEA position, moderator Reactivity Balance B 3.1.2 BASES  CALVERT CLIFFS - UNITS 1 & 2 B 3.1.2-6 Revision 3 temperature, fuel temperature, fuel depletion, xenon concentration, and samarium concentration. The SR is  
 
performed prior to entering MODE 1 as an initial check on  
 
core conditions and design calculations at BOC and every  
 
31 days after 60 effective full power days (EFPD). The SR  
 
is modified by two Notes. The Note in the SR column indicates that the normalization of predicted core reactivity to the measured value may take place within the first 60 EFPD after each fuel loading. This allows  
 
sufficient time for core conditions to reach steady state, but prevents operation for a large fraction of the fuel  
 
cycle without establishing a benchmark for the design  
 
calculations. The required subsequent Frequency of 31 EFPD  
 
following the initial 60 EFPD, after entering MODE 1, is  
 
acceptable, based on the slow rate of core changes due to  
 
fuel depletion and the presence of other indicators (e.g., quadrant power tilt ratio, etc.) for prompt  
 
indication of an anomaly. The Frequency Note, "only  
 
required after 60 EFPD after each fuel loading," is added to the Frequency column to allow this.
REFERENCES 1. UFSAR  
 
MTC B 3.1.3 B 3.1  REACTIVITY CONTROL SYSTEMS B 3.1.3  Moderator Temperature Coefficient (MTC)
 
BASES  CALVERT CLIFFS - UNITS 1 & 2 B 3.1.3-1 Revision 29 BACKGROUND The MTC relates a change in core reactivity to a change in reactor coolant temperature. A positive MTC means that reactivity increases with increasing moderator temperature;
 
conversely, a negative MTC means that reactivity decreases with increasing moderator temperature. The reactor is designed to operate with a negative MTC over a large range
 
of fuel cycle operation. Therefore, a coolant temperature
 
increase will cause a reactivity decrease, so that the
 
coolant temperature tends to return toward its initial
 
value. Reactivity increases that cause a coolant
 
temperature increase will thus be self limiting, and stable
 
power operation will result.
 
Moderator temperature coefficient values are predicted at selected burnups during the safety evaluation analysis and
 
are confirmed to be acceptable by measurements.
R eload cores are designed so that the MTC is less positive than that allowed by the LCO. The actual value of the MTC is
 
dependent on core characteristics, such as fuel loading and
 
reactor coolant soluble boron concentration. The core
 
design may require additional fixed distributed poisons (burnable poison) to yield an MTC at the BOC within the
 
range analyzed in the plant accident analysis. The end-of-
 
cycle (EOC) MTC is also limited by the requirements of the
 
accident analysis. Fuel cycles that are designed to achieve
 
high burnups or that have changes to other characteristics
 
are evaluated to ensure that the MTC does not exceed the EOC limit. APPLICABLE The acceptance criteria for the specified MTC are:


MTC B 3.1.3 B 3.1  REACTIVITY CONTROL SYSTEMS B 3.1.3  Moderator Temperature Coefficient (MTC)
BASES BACKGROUND        The MTC relates a change in core reactivity to a change in reactor coolant temperature. A positive MTC means that reactivity increases with increasing moderator temperature; conversely, a negative MTC means that reactivity decreases with increasing moderator temperature. The reactor is designed to operate with a negative MTC over a large range of fuel cycle operation. Therefore, a coolant temperature increase will cause a reactivity decrease, so that the coolant temperature tends to return toward its initial value. Reactivity increases that cause a coolant temperature increase will thus be self limiting, and stable power operation will result.
Moderator temperature coefficient values are predicted at selected burnups during the safety evaluation analysis and are confirmed to be acceptable by measurements. Reload cores are designed so that the MTC is less positive than that allowed by the LCO. The actual value of the MTC is dependent on core characteristics, such as fuel loading and reactor coolant soluble boron concentration. The core design may require additional fixed distributed poisons (burnable poison) to yield an MTC at the BOC within the range analyzed in the plant accident analysis. The end-of-cycle (EOC) MTC is also limited by the requirements of the accident analysis. Fuel cycles that are designed to achieve high burnups or that have changes to other characteristics are evaluated to ensure that the MTC does not exceed the EOC limit.
APPLICABLE        The acceptance criteria for the specified MTC are:
SAFETY ANALYSES
SAFETY ANALYSES
: a. The MTC values must remain within the bounds of those used in the accident analysis (Reference 1, Section 14.2.2); and
: a. The MTC values must remain within the bounds of those used in the accident analysis (Reference 1, Section 14.2.2); and
: b. The MTC must be such that inherently stable power operations result during normal operation and during  
: b. The MTC must be such that inherently stable power operations result during normal operation and during accidents, such as overheating and overcooling events.
 
CALVERT CLIFFS - UNITS 1 & 2       B 3.1.3-1                      Revision 29
accidents, such as overheating and overcooling events.  
 
MTC B 3.1.3 BASES  CALVERT CLIFFS - UNITS 1 & 2 B 3.1.3-2 Revision 43 Reference 1, Section 14.1.2 contains analyses of accidents that result in both overheating and overcooling of the
 
reactor core. Moderator temperature coefficient is one of
 
the controlling parameters for core reactivity in these
 
accidents. Both the most positive value and most negative
 
value of the MTC are important to safety, and both values must be bounded. Values used in the analyses consider worst-case conditions, such as very large soluble boron
 
concentrations, to ensure the accident results are bounding.
 
Accidents that cause core overheating, either by decreased heat removal or increased power production, must be
 
evaluated for results when the MTC is positive. Reactivity
 
accidents that cause increased power production include the
 
CEA withdrawal and CEA ejection transient s from either zero or full THERMAL POWER. The limiting overheating event
 
relative to plant response is based on the maximum
 
difference between core power and steam generator heat
 
removal during a transient. The most limiting event with
 
respect to a positive MTC is a CEA ejection accident from full power (Reference 1, Section 14.
13).
Accidents that cause core overcooling must be evaluated for results when the MTC is most negative. The event that
 
produces the most rapid cooldown of the RCS, and is
 
therefore the most limiting event with respect to the
 
negative MTC, is a steam line break (SLB) event. Following
 
the reactor trip for the postulated EOC SLB event, the large
 
moderator temperature reduction combined with the large
 
negative MTC may produce reactivity increases that are as
 
much as the shutdown reactivity. When this occurs, a
 
substantial fraction of core power is produced with all CEAs
 
inserted, except the most reactive one, which is assumed
 
withdrawn. Even if the reactivity increase produces slightly subcritical conditions, a large fraction of core power may be produced through the effects of subcritical
 
neutron multiplication.
 
Moderator temperature coefficient values are bounded in reload safety evaluations assuming steady state conditions


at BOC, peak RCS boron, and EOC. A 2/3 core burnup MTC  
MTC B 3.1.3 BASES Reference 1, Section 14.1.2 contains analyses of accidents that result in both overheating and overcooling of the reactor core. Moderator temperature coefficient is one of the controlling parameters for core reactivity in these accidents. Both the most positive value and most negative value of the MTC are important to safety, and both values must be bounded. Values used in the analyses consider worst-case conditions, such as very large soluble boron concentrations, to ensure the accident results are bounding.
Accidents that cause core overheating, either by decreased heat removal or increased power production, must be evaluated for results when the MTC is positive. Reactivity accidents that cause increased power production include the CEA withdrawal and CEA ejection transients from either zero or full THERMAL POWER. The limiting overheating event relative to plant response is based on the maximum difference between core power and steam generator heat removal during a transient. The most limiting event with respect to a positive MTC is a CEA ejection accident from full power (Reference 1, Section 14.13).
Accidents that cause core overcooling must be evaluated for results when the MTC is most negative. The event that produces the most rapid cooldown of the RCS, and is therefore the most limiting event with respect to the negative MTC, is a steam line break (SLB) event. Following the reactor trip for the postulated EOC SLB event, the large moderator temperature reduction combined with the large negative MTC may produce reactivity increases that are as much as the shutdown reactivity. When this occurs, a substantial fraction of core power is produced with all CEAs inserted, except the most reactive one, which is assumed withdrawn. Even if the reactivity increase produces slightly subcritical conditions, a large fraction of core power may be produced through the effects of subcritical neutron multiplication.
Moderator temperature coefficient values are bounded in reload safety evaluations assuming steady state conditions at BOC, peak RCS boron, and EOC. A 2/3 core burnup MTC measurement is conducted and the measured value may be CALVERT CLIFFS - UNITS 1 & 2      B 3.1.3-2                      Revision 43


measurement is conducted and the measured value may be MTC B 3.1.3 BASES CALVERT CLIFFS - UNITS 1 & 2 B 3.1.3-3 Revision 29 extrapolated to project the EOC value, in order to confirm reload design predictions.
MTC B 3.1.3 BASES extrapolated to project the EOC value, in order to confirm reload design predictions.
The MTC satisfies 10 CFR 50.36(c)(2)(ii), Criterion 2.
The MTC satisfies 10 CFR 50.36(c)(2)(ii), Criterion 2.
LCO Limiting Condition for Operation 3.1.3 requires the MTC to be within specified limits of the Core Operating Limits  
LCO               Limiting Condition for Operation 3.1.3 requires the MTC to be within specified limits of the Core Operating Limits Report (COLR), with the maximum positive limit specified in Figure 3.1.3-1, to ensure the core operates within the assumptions of the accident analysis. During the reload core safety evaluation, the MTC is analyzed to determine that its values remain within the bounds of the original accident analysis during operation. The limit on a positive MTC ensures that core overheating accidents will not violate the accident analysis assumptions. The negative MTC limit for EOC specified in the COLR ensures that core overcooling accidents will not violate the accident analysis assumptions.
 
Moderator temperature coefficient is a core physics parameter determined by the fuel and fuel cycle design and cannot be easily controlled once the core design is fixed.
Report (COLR), with the maximum positive limit specified in  
During operation, therefore, the LCO can only be ensured through measurement. The surveillance checks at BOC and 2/3 core burnup provide confirmation that the MTC is behaving as anticipated, so that the acceptance criteria are met.
 
APPLICABILITY     In MODE 1, the limits on the MTC must be maintained to ensure that any accident initiated from THERMAL POWER operation will not violate the design assumptions of the accident analysis. In MODE 2, the limits must also be maintained to ensure startup accidents, such as the uncontrolled CEA or group withdrawal, will not violate the assumptions of the accident analysis. In MODEs 3, 4, 5, and 6, this LCO is not applicable, since no DBAs using the MTC as an analysis assumption are initiated from these MODEs. However, the variation of the MTC, with temperature in MODEs 3, 4, and 5 for DBAs initiated in MODEs 1 and 2, is accounted for in the accident analysis. The variation of the MTC, with temperature assumed in the safety analysis, is accepted as valid once the BOC and 2/3 core burnup measurements are used for normalization.
Figure 3.1.3-1, to ensure the core operates within the  
CALVERT CLIFFS - UNITS 1 & 2       B 3.1.3-3                       Revision 29
 
assumptions of the accident analysis. During the reload  
 
core safety evaluation, the MTC is analyzed to determine  
 
that its values remain within the bounds of the original  
 
accident analysis during operation. The limit on a positive  
 
MTC ensures that core overheating accidents will not violate  
 
the accident analysis assumptions. The negative MTC limit  
 
for EOC specified in the COLR ensures that core overcooling  
 
accidents will not violate the accident analysis  
 
assumptions.  
 
Moderator temperature coefficient is a core physics parameter determined by the fuel and fuel cycle design and  
 
cannot be easily controlled once the core design is fixed.
 
During operation, therefore, the LCO can only be ensured  
 
through measurement. The surveillance checks at BOC and  
 
2/3 core burnup provide confirmation that the MTC is behaving as anticipated, so that the acceptance criteria are met. APPLICABILITY In MODE 1, the limits on the MTC must be maintained to ensure that any accident initiated from THERMAL POWER  
 
operation will not violate the design assumptions of the  
 
accident analysis. In MODE 2, the limits must also be  
 
maintained to ensure startup accidents, such as the  
 
uncontrolled CEA or group withdrawal, will not violate the  
 
assumptions of the accident analysis. In MODEs 3, 4, 5, and 6, this LCO is not applicable, since no DBAs using the  
 
MTC as an analysis assumption are initiated from these  
 
MODEs. However, the variation of the MTC, with temperature  
 
in MODEs 3, 4, and 5 for DBAs initiated in MODEs 1 and 2, is  
 
accounted for in the accident analysis. The variation of  
 
the MTC, with temperature assumed in the safety analysis, is  
 
accepted as valid once the BOC and 2/3 core burnup measurements are used for normalization.
MTC B 3.1.3 BASES  CALVERT CLIFFS - UNITS 1 & 2 B 3.1.3-4 Revision 29 ACTIONS A.1 Moderator temperature coefficient is a function of the fuel
 
and fuel cycle designs, and cannot be controlled directly
 
once the designs have been implemented in the core. If MTC
 
exceeds its limits, the reactor must be placed in MODE 3.
This eliminates the potential for violation of the accident analysis bounds. The associated Completion Time of 6 hours
 
is reasonable, considering the probability of an accident
 
occurring during the time period that would require an MTC
 
value within the LCO limits, and the time for reaching
 
MODE 3 from full power conditions in an orderly manner and without challenging plant systems.
SURVEILLANCE SR 3.1.3.1 and SR 3.1.3.2 REQUIREMENTS The SRs for measurement of the MTC at the beginning and 2/3 core burnup of each fuel cycle provide for confirmation of the limiting MTC values. The MTC varies with boron concentration during fuel cycle operation. The MTC becomes more negative as the RCS boron concentration is reduced. The requirement for measurement prior to entering MODE 1 after each fuel loading satisfies the confirmatory check on the most positive (least negative) MTC value. The
 
requirement for measurement, within 7 EFPD of initially reaching an equilibrium condition with THERMAL POWER  90% RTP, and within 7 EFPD of reaching 2/3 core burnup, satisfies the confirmatory check of the most negative MTC value. The 2/3 core burnup measurement is performed at any THERMAL POWER, so that the projected EOC MTC may be evaluated before the reactor actually reaches the EOC condition. Moderator temperature coefficient values may be
 
extrapolated and compensated to permit direct comparison to
 
the specified MTC limits.
 
Surveillance Requirement 3.1.3.2 is modified by a Note, which indicates that if the extrapolated MTC is more
 
negative than the EOC COLR limit, the SR may be repeated, and that shutdown must occur prior to exceeding the minimum
 
allowable boron concentration at which MTC is projected to
 
exceed the lower limit. An engineering evaluation is MTC B 3.1.3 BASES  CALVERT CLIFFS - UNITS 1 & 2 B 3.1.3-5 Revision 29 performed if the extrapolated value of MTC exceeds the Specification limits.
REFERENCES 1. UFSAR
 
CEA Alignment B 3.1.4 B 3.1  REACTIVITY CONTROL SYSTEMS B 3.1.4  Control Element Assembly (CEA) Alignment
 
BASES  CALVERT CLIFFS - UNITS 1 & 2 B 3.1.4-1 Revision 2 BACKGROUND The OPERABILITY (e.g., trippability) of the shutdown and regulating CEAs is an initial assumption in all safety analyses that assume CEA insertion upon reactor trip.
The applicable criteria for these reactivity and power distribution design requirements are found in Reference 1 , Appendix 1C, Criteria 6, 27, 29, and 30, and Reference 2
. Mechanical or electrical failures may cause a CEA to become inoperable or to become misaligned from its group.
Control element assembly inoperability or misalignment may cause increased power peaking, due to the asymmetric reactivity
 
distribution and a reduction in the total available CEA
 
worth for reactor shutdown. Therefore, CEA alignment and
 
OPERABILITY are related to core operation in design power
 
peaking limits and the core design requirement of a minimum
 
SDM.
Limits on CEA alignment and OPERABILITY have been established, and all CEA positions are monitored and
 
controlled during power operation to ensure that the power
 
distribution and reactivity limits defined by the design
 
power peaking and SDM limits are preserved.
 
Control element assemblies are moved by their control element drive mechanisms (CEDMs). Each CEDM moves its CEA
 
one step (approximately 3/4
-inch) at a time.
 
The CEAs are arranged into groups that are radially symmetric. Therefore, movement of the CEA groups do not
 
introduce radial asymmetries in the core power distribution. 
 
The shutdown and regulating CEAs provide the required reactivity worth for immediate reactor shutdown upon a reactor trip. The regulating CEAs also provide reactivity (power level) control during normal operation and
 
transients.
 
The axial position of shutdown and regulating CEAs is indicated by two separate and independent systems, which are CEA Alignment B 3.1.4 BASES  CALVERT CLIFFS - UNITS 1 & 2 B 3.1.4-2 Revision 2 the Plant Computer CEA Position Indication System and the Reed Switch Position Indication System.
 
The Plant Computer CEA Position Indication System counts the commands sent to the CEA gripper coils from the CEDM Control
 
System that moves the CEAs. There is a one step counter for each CEA. Individual CEAs in a group all receive the same signal to move and should, therefore, all be at the same
 
position indicated by the group step counter for that group. 
 
Plant Computer CEA Position Indication System is considered
 
highly precise (+/- 1 step or +/- 3/4
-inch). If a CEA does not move one step for each command signal, the step counter will
 
still count the command and incorrectly reflect the position
 
of the CEA.
 
The Reed Switch Position Indication System provides a highly accurate indication of actual CEA position, but at a lower
 
precision than the step counters. This system is based on
 
inductive analog signals from a series of reed switches
 
spaced along a tube with a center
-to-center distance of 1.5 inches, which is two steps. To increase the reliability
 
of the system, there are redundant reed switches at each position.
APPLICABLE Control element assembly misalignment accidents are SAFETY ANALYSES analyzed in the safety analysis (Reference 1, Sections 14.2, 14.11, and 14.13
). The accident analysis defines CEA misoperation as any event, with the exception of sequential


group withdraws, which could result from a single
MTC B 3.1.3 BASES ACTIONS          A.1 Moderator temperature coefficient is a function of the fuel and fuel cycle designs, and cannot be controlled directly once the designs have been implemented in the core. If MTC exceeds its limits, the reactor must be placed in MODE 3.
This eliminates the potential for violation of the accident analysis bounds. The associated Completion Time of 6 hours is reasonable, considering the probability of an accident occurring during the time period that would require an MTC value within the LCO limits, and the time for reaching MODE 3 from full power conditions in an orderly manner and without challenging plant systems.
SURVEILLANCE      SR 3.1.3.1 and SR 3.1.3.2 REQUIREMENTS The SRs for measurement of the MTC at the beginning and 2/3 core burnup of each fuel cycle provide for confirmation of the limiting MTC values. The MTC varies with boron concentration during fuel cycle operation. The MTC becomes more negative as the RCS boron concentration is reduced.
The requirement for measurement prior to entering MODE 1 after each fuel loading satisfies the confirmatory check on the most positive (least negative) MTC value. The requirement for measurement, within 7 EFPD of initially reaching an equilibrium condition with THERMAL POWER  90%
RTP, and within 7 EFPD of reaching 2/3 core burnup, satisfies the confirmatory check of the most negative MTC value. The 2/3 core burnup measurement is performed at any THERMAL POWER, so that the projected EOC MTC may be evaluated before the reactor actually reaches the EOC condition. Moderator temperature coefficient values may be extrapolated and compensated to permit direct comparison to the specified MTC limits.
Surveillance Requirement 3.1.3.2 is modified by a Note, which indicates that if the extrapolated MTC is more negative than the EOC COLR limit, the SR may be repeated, and that shutdown must occur prior to exceeding the minimum allowable boron concentration at which MTC is projected to exceed the lower limit. An engineering evaluation is CALVERT CLIFFS - UNITS 1 & 2      B 3.1.3-4                      Revision 29


malfunction in the reactivity control systems. For example, CEA misalignment may be caused by a malfunction of the CEDM, CEDM Control System , or by operator error. A stuck CEA may be caused by mechanical jamming of the CEA fingers or of the  
MTC B 3.1.3 BASES performed if the extrapolated value of MTC exceeds the Specification limits.
REFERENCES        1. UFSAR CALVERT CLIFFS - UNITS 1 & 2      B 3.1.3-5                      Revision 29


gripper. A dropped CEA could be caused by an electrical  
CEA Alignment B 3.1.4 B 3.1  REACTIVITY CONTROL SYSTEMS B 3.1.4  Control Element Assembly (CEA) Alignment BASES BACKGROUND        The OPERABILITY (e.g., trippability) of the shutdown and regulating CEAs is an initial assumption in all safety analyses that assume CEA insertion upon reactor trip.
 
The applicable criteria for these reactivity and power distribution design requirements are found in Reference 1, Appendix 1C, Criteria 6, 27, 29, and 30, and Reference 2.
failure in the CEA coil power programmers.  
Mechanical or electrical failures may cause a CEA to become inoperable or to become misaligned from its group. Control element assembly inoperability or misalignment may cause increased power peaking, due to the asymmetric reactivity distribution and a reduction in the total available CEA worth for reactor shutdown. Therefore, CEA alignment and OPERABILITY are related to core operation in design power peaking limits and the core design requirement of a minimum SDM.
Limits on CEA alignment and OPERABILITY have been established, and all CEA positions are monitored and controlled during power operation to ensure that the power distribution and reactivity limits defined by the design power peaking and SDM limits are preserved.
Control element assemblies are moved by their control element drive mechanisms (CEDMs). Each CEDM moves its CEA one step (approximately 3/4-inch) at a time.
The CEAs are arranged into groups that are radially symmetric. Therefore, movement of the CEA groups do not introduce radial asymmetries in the core power distribution.
The shutdown and regulating CEAs provide the required reactivity worth for immediate reactor shutdown upon a reactor trip. The regulating CEAs also provide reactivity (power level) control during normal operation and transients.
The axial position of shutdown and regulating CEAs is indicated by two separate and independent systems, which are CALVERT CLIFFS - UNITS 1 & 2        B 3.1.4-1                        Revision 2


CEA Alignment B 3.1.4 BASES the Plant Computer CEA Position Indication System and the Reed Switch Position Indication System.
The Plant Computer CEA Position Indication System counts the commands sent to the CEA gripper coils from the CEDM Control System that moves the CEAs. There is a one step counter for each CEA. Individual CEAs in a group all receive the same signal to move and should, therefore, all be at the same position indicated by the group step counter for that group.
Plant Computer CEA Position Indication System is considered highly precise (+/- 1 step or +/- 3/4-inch). If a CEA does not move one step for each command signal, the step counter will still count the command and incorrectly reflect the position of the CEA.
The Reed Switch Position Indication System provides a highly accurate indication of actual CEA position, but at a lower precision than the step counters. This system is based on inductive analog signals from a series of reed switches spaced along a tube with a center-to-center distance of 1.5 inches, which is two steps. To increase the reliability of the system, there are redundant reed switches at each position.
APPLICABLE        Control element assembly misalignment accidents are SAFETY ANALYSES  analyzed in the safety analysis (Reference 1, Sections 14.2, 14.11, and 14.13). The accident analysis defines CEA misoperation as any event, with the exception of sequential group withdraws, which could result from a single malfunction in the reactivity control systems. For example, CEA misalignment may be caused by a malfunction of the CEDM, CEDM Control System, or by operator error. A stuck CEA may be caused by mechanical jamming of the CEA fingers or of the gripper. A dropped CEA could be caused by an electrical failure in the CEA coil power programmers.
The acceptance criteria for addressing CEA inoperability/
The acceptance criteria for addressing CEA inoperability/
misalignment are that:
misalignment are that:
: a. There shall be no violations of:   1. SAFDLs , or   2. RCS pressure boundary integrity; and CEA Alignment B 3.1.4 BASES  CALVERT CLIFFS - UNITS 1 & 2 B 3.1.4-3 Revision 2
: a. There shall be no violations of:
: 1. SAFDLs, or
: 2. RCS pressure boundary integrity; and CALVERT CLIFFS - UNITS 1 & 2       B 3.1.4-2                        Revision 2
 
CEA Alignment B 3.1.4 BASES
: b. The core must remain subcritical after accidents or transients.
: b. The core must remain subcritical after accidents or transients.
Two types of misalignment are distinguished in the safety analysis (Reference 1 , Appendix 1C
Two types of misalignment are distinguished in the safety analysis (Reference 1, Appendix 1C). The first type of misalignment occurs if one CEA fails to insert upon a reactor trip and remains stuck fully withdrawn. This condition requires an evaluation to determine that sufficient reactivity worth is held in the remaining CEAs to meet the SDM requirement with the maximum worth CEA stuck fully withdrawn. If a CEA is stuck in the fully withdrawn position, its worth is added to the SDM requirement, since the safety analysis does not take two stuck CEAs into account. The second type of misalignment occurs when one CEA drops partially or fully into the reactor core. This event causes an initial power reduction followed by a return toward the original power, due to positive reactivity feedback from the negative MTC. Increased peaking during the power increase may result in excessive local LHRs (Reference 1, Section 14.14).
). The first type of misalignment occurs if one CEA fails to insert upon a reactor trip and remains stuck fully withdrawn. This condition requires an evaluation to determine that  
None of the above CEA misoperations will result in an automatic reactor trip. In the case of the full-length CEA drop, a prompt decrease in core average power and a distortion in radial power are initially produced, which, when conservatively coupled, result in a local power and heat flux increase, and a decrease in DNBR parameters.
 
The results of the CEA misoperation analysis show that, during the most limiting misoperation events, no violations of the SAFDLs, fuel centerline temperature, or RCS pressure occur.
sufficient reactivity worth is held in the remaining CEAs to  
Control element assembly alignment satisfies 10 CFR 50.36(c)(2)(ii), Criteria 2 and 3.
 
LCO               The limits on shutdown and regulating CEA alignments ensure that the assumptions in the safety analysis will remain valid. The requirements on OPERABILITY ensure that upon reactor trip, the CEAs will be available and will be inserted to provide enough negative reactivity to shut down the reactor. The OPERABILITY requirements also ensure that CALVERT CLIFFS - UNITS 1 & 2       B 3.1.4-3                        Revision 2
meet the SDM requirement with the maximum worth CEA stuck  
 
fully withdrawn. If a CEA is stuck in the fully withdrawn  
 
position, its worth is added to the SDM requirement, since  
 
the safety analysis does not take two stuck CEAs into  
 
account. The second type of misalignment occurs when one  
 
CEA drops partially or fully into the reactor core. This  
 
event causes an initial power reduction followed by a return  
 
toward the original power, due to positive reactivity feedback from the negative MTC. Increased peaking during the power increase may result in excessive local LHRs (Reference 1, Section 14.14
).
None of the above CEA misoperations will result in an automatic reactor trip. In the case of the full
-length CEA drop, a prompt decrease in core average power and a  
 
distortion in radial power are initially produced, which, when conservatively coupled, result in a local power and  
 
heat flux increase, and a decrease in DNBR parameters.  
 
The results of the CEA misoperation analysis show that
, during the most limiting misoperation events, no violations  
 
of the SAFDLs, fuel centerline temperature, or RCS pressure  
 
occur.
Control element assembly alignment satisfies 10 CFR 50.36(c)(2)(ii), Criteria 2 and 3.  
 
LCO The limits on shutdown and regulating CEA alignments ensure that the assumptions in the safety analysis will remain  
 
valid. The requirements on OPERABILITY ensure that upon  
 
reactor trip, the CEAs will be available and will be  
 
inserted to provide enough negative reactivity to shut down  
 
the reactor. The OPERABILITY requirements also ensure that CEA Alignment B 3.1.4 BASES  CALVERT CLIFFS - UNITS 1 & 2 B 3.1.4-4 Revision 43 the CEA banks maintain the correct power distribution and CEA alignment.


CEA Alignment B 3.1.4 BASES the CEA banks maintain the correct power distribution and CEA alignment.
The requirement is to maintain the CEA alignment to within 7.5 inches between any CEA and its group.
The requirement is to maintain the CEA alignment to within 7.5 inches between any CEA and its group.
Failure to meet the requirements of this LCO may produce unacceptable power peaking factors and LHRs, or unacceptable SDMs, all of which may constitute initial conditions inconsistent with the safety analysis.
Failure to meet the requirements of this LCO may produce unacceptable power peaking factors and LHRs, or unacceptable SDMs, all of which may constitute initial conditions inconsistent with the safety analysis.
APPLICABILITY The requirements on CEA OPERABILITY and alignment are applicable in MODEs 1 and 2 because these are the only MODEs  
APPLICABILITY     The requirements on CEA OPERABILITY and alignment are applicable in MODEs 1 and 2 because these are the only MODEs in which neutron (or fission) power is generated, and the OPERABILITY (e.g., trippability) and alignment of CEAs have the potential to affect the safety of the plant. In MODEs 3, 4, 5, and 6, the alignment limits do not apply because the CEAs are bottomed, and the reactor is shut down and not producing fission power. In the shutdown MODEs, the OPERABILITY of the shutdown and regulating CEAs has the potential to affect the required SDM, but this effect can be compensated for by an increase in the boron concentration of the RCS. See LCO 3.1.1 for SDM in MODEs 3, 4, and 5, and LCO 3.9.1 for boron concentration requirements during refueling.
 
ACTIONS           A.1 and B.1 A CEA may become misaligned, yet remain trippable. In this condition, the CEA can still perform its required function of adding negative reactivity should a reactor trip be necessary.
in which neutron (or fission) power is generated, and the  
If one or more regulating or shutdown CEAs are misaligned by
 
                  > 7.5 inches and  15 inches but trippable, or one CEA is misaligned by > 15 inches but trippable, continued operation in MODEs 1 and 2 may continue, provided CEA alignment is restored within 1 hour for CEAs misaligned  15 inches and within the time specified in the COLR for CEAs misaligned
OPERABILITY (e.g., trippability) and alignment of CEAs have  
                  > 15 inches. (The maximum time provided in the COLR is 2 hours.)
 
CALVERT CLIFFS - UNITS 1 & 2       B 3.1.4-4                      Revision 43
the potential to affect the safety of the plant. In  
 
MODEs 3, 4, 5, and 6, the alignment limits do not apply  
 
because the CEAs are bottomed, and the reactor is shut down  
 
and not producing fission power. In the shutdown MODEs, the  
 
OPERABILITY of the shutdown and regulating CEAs has the  
 
potential to affect the required SDM, but this effect can be  
 
compensated for by an increase in the boron concentration of  
 
the RCS. See LCO 3.1.1 for SDM in MODEs 3, 4, and 5, and  
 
LCO 3.9.1 for boron concentration requirements during refueling.
ACTIONS A.1 and B.1 A CEA may become misaligned, yet remain trippable. In this  
 
condition, the CEA can still perform its required function  
 
of adding negative reactivity should a reactor trip be  
 
necessary.  
 
If one or more regulating or shutdown CEAs are misaligned by  
> 7.5 inches and  15 inches but trippable, or one CEA is misaligned by > 15 inches but trippable, continued operation  
 
in MODEs 1 and 2 may continue, provided CEA alignment is restored within 1 hour for CEAs misaligned  15 inches and within the time specified in the COLR for CEAs misaligned  
 
> 15 inches. (The maximum time provided in the COLR is 2 hour s.)
CEA Alignment B 3.1.4 BASES  CALVERT CLIFFS - UNITS 1 & 2 B 3.1.4-5 Revision 43 Regulating and shutdown CEA alignment is restored by either aligning the misaligned CEA(s) to within 7.5 inches of its
 
group or aligning the misaligned CEAs group to within
 
7.5 inches of the misaligned CEA.
 
Xenon redistribution in the core starts to occur as soon as a CEA becomes misaligned. Restoring CEA alignment ensures
 
acceptable power distributions are maintained. For small misalignments ( 15 inches) of the CEAs, there is:  a. A small effect on the time-dependent, long-term power distributions relative to those used in generating LCOs and limiting safety system settings setpoints;  b. A negligible effect on the available SDM; and  c. A small effect on the ejected CEA worth used in the accident analysis.
With a large CEA misalignment (> 15 inches), however, this misalignment would cause distortion of the core power distribution. This distortion may, in turn, have a
 
significant effect on the time-dependent, long-term power
 
distributions relative to those used in generating LCOs and
 
limiting safety system settings setpoints.
 
The effect on the available SDM and the ejected CEA worth used in the accident analysis remains small.
 
Therefore, this condition is limited to a single CEA misalignment, while still allowing time for recovery.


CEA Alignment B 3.1.4 BASES Regulating and shutdown CEA alignment is restored by either aligning the misaligned CEA(s) to within 7.5 inches of its group or aligning the misaligned CEAs group to within 7.5 inches of the misaligned CEA.
Xenon redistribution in the core starts to occur as soon as a CEA becomes misaligned. Restoring CEA alignment ensures acceptable power distributions are maintained. For small misalignments ( 15 inches) of the CEAs, there is:
: a. A small effect on the time-dependent, long-term power distributions relative to those used in generating LCOs and limiting safety system settings setpoints;
: b. A negligible effect on the available SDM; and
: c. A small effect on the ejected CEA worth used in the accident analysis.
With a large CEA misalignment (> 15 inches), however, this misalignment would cause distortion of the core power distribution. This distortion may, in turn, have a significant effect on the time-dependent, long-term power distributions relative to those used in generating LCOs and limiting safety system settings setpoints.
The effect on the available SDM and the ejected CEA worth used in the accident analysis remains small.
Therefore, this condition is limited to a single CEA misalignment, while still allowing time for recovery.
In both cases, the allowed time period is sufficient to:
In both cases, the allowed time period is sufficient to:
: a. Identify cause of a misaligned CEA;
: a. Identify cause of a misaligned CEA;
: b. Take appropriate corrective action to realign the CEAs; and c. Minimize the effects of xenon redistribution.
: b. Take appropriate corrective action to realign the CEAs; and
If a CEA is untrippable, it is not available for reactivity insertion during a reactor trip. With an untrippable CEA, meeting the insertion limits of LCOs 3.1.5 and 3.1.6 does  
: c. Minimize the effects of xenon redistribution.
 
If a CEA is untrippable, it is not available for reactivity insertion during a reactor trip. With an untrippable CEA, meeting the insertion limits of LCOs 3.1.5 and 3.1.6 does not ensure that adequate SDM exists. Condition F must be entered.
not ensure that adequate SDM exists. Condition F must be  
CALVERT CLIFFS - UNITS 1 & 2       B 3.1.4-5                       Revision 43
 
entered.
CEA Alignment B 3.1.4 BASES  CALVERT CLIFFS - UNITS 1 & 2 B 3.1.4-6 Revision 37 C.1 and C.2 If any CEA is not restored to within its alignment limits within the Completion Time provided in Required Action A.1
 
or B.1, an additional 2 hours is allowed to restore CEA alignment, provided THERMAL POWER is reduced  70% RTP.
Prompt action must be taken to reduce THERMAL POWER, and the reduction must be completed within 1 hour. Reducing THERMAL POWER ensures acceptable power distributions are maintained
 
during the additional time provided to restore alignment. 
 
The Completion Times are acceptable based on the reasons
 
provided in the Bases for Required Actions A.1 and B.1.
 
D.1, D.2.1, and D.2.2 The CEA motion inhibit permits CEA motion within the
 
requirements of LCO 3.1.6, and prevents regulating CEAs from
 
being misaligned from other CEAs in the group.
 
Performing SR 3.1.4.1 within 1 hour and every 4 hours thereafter is considered acceptable, in view of other
 
information continuously available to the operator in the
 
Control Room.
 
With the CEA motion inhibit inoperable, a Completion Time of 6 hours is allowed for restoring the CEA motion inhibit to
 
OPERABLE status, or fully withdrawing the CEAs in groups 3
 
and 4, and withdrawing all CEAs in group 5 to < 5%
 
insertion.
 
Withdrawal of the CEAs to the positions required in Required Action D.2.2 provides additional assurance that core
 
perturbations in local burnup, peaking factors, and SDM will
 
not be more adverse than the Conditions assumed in the
 
safety analyses and LCO setpoint determination (Reference 1, Chapter 14).
The 6-hour Completion Time takes into account Required Action D.1, the protection afforded by the CEA deviation circuits, and other information continuously available to 
 
the operator in the Control Room, so that during actual CEA
 
motion, deviations can be detected.
 
CEA Alignment B 3.1.4 BASES  CALVERT CLIFFS - UNITS 1 & 2 B 3.1.4-7 Revision 37 Required Action D.2.2 is modified by a Note indicating that performing this Required Action is not required when in
 
conflict with Required Actions A.1, B.1, C.2, or E.1.
 
E.1  When the CEA deviation circuit is inoperable, performing SR 3.1.4.1 within 1 hour and every 4 hours thereafter ensures improper CEA alignments are identified before
 
unacceptable flux distributions occur. The specified
 
Completion Times take into account other information
 
continuously available to the operator in the Control Room, so that during CEA movement, deviations can be detected, and
 
the protection provided by the CEA inhibit and deviation
 
circuit is not required.
 
F.1  If any Required Action and associated Completion Time of
 
Condition C, Condition D, or Condition E is not met, one or
 
more regulating or shutdown CEAs are untrippable, two or
 
more CEAs are misaligned by > 15 inches, the unit is
 
required to be brought to MODE 3. By being brought to
 
MODE 3, the unit is brought outside the MODE of
 
applicability. Continued operation is not allowed in the
 
case of more than one CEA misaligned from any other CEA in
 
its group by > 15 inches, or one or more CEAs untrippable. 
 
This is because these cases could result in a loss of SDM
 
and power distribution and a loss of safety function, respectively.
 
When a Required Action cannot be completed within the required Completion Time, a controlled shutdown should be
 
commenced. The allowed Completion Time of 6 hours is
 
reasonable, based on operating experience, for reaching
 
MODE 3 from full power conditions in an orderly manner and without challenging plant systems.
SURVEILLANCE SR 3.1.4.1 REQUIREMENTS Verification that individual CEA positions are within 7.5 inches (indicated reed switch positions) of all other
 
CEAs in the group are performed at Frequencies of within 1 hour of any CEA movement of
> 7.5 inches and every CEA Alignment B 3.1.4 BASES  CALVERT CLIFFS - UNITS 1 & 2 B 3.1.4-8 Revision 37 12 hours. The CEA position verification after each movement of > 7.5 inches ensure that the CEAs in that group are properly aligned at the time when CEA misalignments are most likely to have occurred. The 12-hour Frequency allows the
 
operator to detect a CEA that is beginning to deviate from
 
its expected position. The specified Frequency takes into account other CEA position information that is continuously available to the operator in the Control Room, so that
 
during CEA movement, deviations can be detected, and
 
protection can be provided by the CEA motion inhibit and
 
deviation circuits.
 
SR 3.1.4.2 Demonstrating the CEA motion inhibit OPERABLE verifies that
 
the CEA motion inhibit is functional, even if it is not
 
regularly operated. The verification shall ensure that the
 
motion inhibit circuit maintains the CEA group overlap and
 
sequencing requirements of LCO 3.1.6, and prevents any
 
regulating CEA from being misaligned from all other CEAs in its group by
> 7.5 inches (indicated position). The 31-day Frequency takes into account other information continuously available to the operator in the Control Room, so that
 
during CEA movement, deviations can be detected, and
 
protection can be provided by the CEA deviation circuits.
 
SR 3.1.4.3 Demonstrating the CEA deviation circuit is OPERABLE verifies
 
the circuit is functional. The 31-day Frequency takes into
 
account other information continuously available to the
 
operator in the Control Room, so that during CEA movement, deviations can be detected, and protection can be provided
 
by the CEA motion inhibit.
 
SR 3.1.4.4 Verifying each CEA is trippable would require that each CEA be tripped. In MODEs 1 and 2, tripping each CEA would result in radial or axial power tilts or oscillations. 
 
Therefore, individual CEAs are exercised every 92 days to
 
provide increased confidence that all CEAs continue to be
 
trippable, even if they are not regularly tripped. A
 
movement of 7.5 inches is adequate to demonstrate motion
 
without exceeding the alignment limit when only one CEA is CEA Alignment B 3.1.4 BASES  CALVERT CLIFFS - UNITS 1 & 2 B 3.1.4-9 Revision 37 being moved. For the purposes of performing the CEA operability test, if the CEA has an inoperable position
 
indicator channel, the alternate indication system (pulse
 
counter or voltage dividing network) will be used to monitor
 
position. The 92-day Frequency takes into consideration
 
other information available to the operator in the Control Room and other SRs being performed more frequently, which add to the determination of OPERABILITY of the CEAs. 
 
Between required performances of SR 3.1.4.5, if a CEA(s)is
 
discovered to be immovable, but remains trippable and
 
aligned, the CEA is considered to be OPERABLE. At any time, if a CEA(s) is immovable, a determination of the
 
trippability (OPERABILITY) of the CEA(s) must be made, and
 
appropriate action taken.
 
SR 3.1.4.5 Performance of a CHANNEL FUNCTIONAL TEST of each reed switch
 
position transmitter channel ensures the channel is OPERABLE
 
and capable of indicating CEA position over the entire
 
length of the CEA's travel. A successful test of the
 
required contact(s) of a channel relay may be performed by
 
the verification of the change of state of a single contact
 
of the relay. This clarifies what is an acceptable CHANNEL
 
FUNCTIONAL TEST of a relay. This is acceptable because all
 
of the other required contacts of the relay are verified by
 
other Technical Specification tests at least once per
 
refueling interval with applicable extensions. Since this
 
SR must be performed when the reactor is shut down, a


24-month Frequency to be coincident with refueling outages
CEA Alignment B 3.1.4 BASES C.1 and C.2 If any CEA is not restored to within its alignment limits within the Completion Time provided in Required Action A.1 or B.1, an additional 2 hours is allowed to restore CEA alignment, provided THERMAL POWER is reduced  70% RTP.
Prompt action must be taken to reduce THERMAL POWER, and the reduction must be completed within 1 hour. Reducing THERMAL POWER ensures acceptable power distributions are maintained during the additional time provided to restore alignment.
The Completion Times are acceptable based on the reasons provided in the Bases for Required Actions A.1 and B.1.
D.1, D.2.1, and D.2.2 The CEA motion inhibit permits CEA motion within the requirements of LCO 3.1.6, and prevents regulating CEAs from being misaligned from other CEAs in the group.
Performing SR 3.1.4.1 within 1 hour and every 4 hours thereafter is considered acceptable, in view of other information continuously available to the operator in the Control Room.
With the CEA motion inhibit inoperable, a Completion Time of 6 hours is allowed for restoring the CEA motion inhibit to OPERABLE status, or fully withdrawing the CEAs in groups 3 and 4, and withdrawing all CEAs in group 5 to < 5%
insertion.
Withdrawal of the CEAs to the positions required in Required Action D.2.2 provides additional assurance that core perturbations in local burnup, peaking factors, and SDM will not be more adverse than the Conditions assumed in the safety analyses and LCO setpoint determination (Reference 1, Chapter 14).
The 6-hour Completion Time takes into account Required Action D.1, the protection afforded by the CEA deviation circuits, and other information continuously available to the operator in the Control Room, so that during actual CEA motion, deviations can be detected.
CALVERT CLIFFS - UNITS 1 & 2      B 3.1.4-6                      Revision 37


was selected. Operating experience has shown that these
CEA Alignment B 3.1.4 BASES Required Action D.2.2 is modified by a Note indicating that performing this Required Action is not required when in conflict with Required Actions A.1, B.1, C.2, or E.1.
E.1 When the CEA deviation circuit is inoperable, performing SR 3.1.4.1 within 1 hour and every 4 hours thereafter ensures improper CEA alignments are identified before unacceptable flux distributions occur. The specified Completion Times take into account other information continuously available to the operator in the Control Room, so that during CEA movement, deviations can be detected, and the protection provided by the CEA inhibit and deviation circuit is not required.
F.1 If any Required Action and associated Completion Time of Condition C, Condition D, or Condition E is not met, one or more regulating or shutdown CEAs are untrippable, two or more CEAs are misaligned by > 15 inches, the unit is required to be brought to MODE 3. By being brought to MODE 3, the unit is brought outside the MODE of applicability. Continued operation is not allowed in the case of more than one CEA misaligned from any other CEA in its group by > 15 inches, or one or more CEAs untrippable.
This is because these cases could result in a loss of SDM and power distribution and a loss of safety function, respectively.
When a Required Action cannot be completed within the required Completion Time, a controlled shutdown should be commenced. The allowed Completion Time of 6 hours is reasonable, based on operating experience, for reaching MODE 3 from full power conditions in an orderly manner and without challenging plant systems.
SURVEILLANCE      SR 3.1.4.1 REQUIREMENTS Verification that individual CEA positions are within 7.5 inches (indicated reed switch positions) of all other CEAs in the group are performed at Frequencies of within 1 hour of any CEA movement of > 7.5 inches and every CALVERT CLIFFS - UNITS 1 & 2      B 3.1.4-7                        Revision 37


components usually pass this SR when performed at a
CEA Alignment B 3.1.4 BASES 12 hours. The CEA position verification after each movement of > 7.5 inches ensure that the CEAs in that group are properly aligned at the time when CEA misalignments are most likely to have occurred. The 12-hour Frequency allows the operator to detect a CEA that is beginning to deviate from its expected position. The specified Frequency takes into account other CEA position information that is continuously available to the operator in the Control Room, so that during CEA movement, deviations can be detected, and protection can be provided by the CEA motion inhibit and deviation circuits.
SR 3.1.4.2 Demonstrating the CEA motion inhibit OPERABLE verifies that the CEA motion inhibit is functional, even if it is not regularly operated. The verification shall ensure that the motion inhibit circuit maintains the CEA group overlap and sequencing requirements of LCO 3.1.6, and prevents any regulating CEA from being misaligned from all other CEAs in its group by > 7.5 inches (indicated position). The 31-day Frequency takes into account other information continuously available to the operator in the Control Room, so that during CEA movement, deviations can be detected, and protection can be provided by the CEA deviation circuits.
SR 3.1.4.3 Demonstrating the CEA deviation circuit is OPERABLE verifies the circuit is functional. The 31-day Frequency takes into account other information continuously available to the operator in the Control Room, so that during CEA movement, deviations can be detected, and protection can be provided by the CEA motion inhibit.
SR 3.1.4.4 Verifying each CEA is trippable would require that each CEA be tripped. In MODEs 1 and 2, tripping each CEA would result in radial or axial power tilts or oscillations.
Therefore, individual CEAs are exercised every 92 days to provide increased confidence that all CEAs continue to be trippable, even if they are not regularly tripped. A movement of 7.5 inches is adequate to demonstrate motion without exceeding the alignment limit when only one CEA is CALVERT CLIFFS - UNITS 1 & 2      B 3.1.4-8                      Revision 37


Frequency of once every 24 months. Furthermore, the  
CEA Alignment B 3.1.4 BASES being moved. For the purposes of performing the CEA operability test, if the CEA has an inoperable position indicator channel, the alternate indication system (pulse counter or voltage dividing network) will be used to monitor position. The 92-day Frequency takes into consideration other information available to the operator in the Control Room and other SRs being performed more frequently, which add to the determination of OPERABILITY of the CEAs.
Between required performances of SR 3.1.4.5, if a CEA(s)is discovered to be immovable, but remains trippable and aligned, the CEA is considered to be OPERABLE. At any time, if a CEA(s) is immovable, a determination of the trippability (OPERABILITY) of the CEA(s) must be made, and appropriate action taken.
SR 3.1.4.5 Performance of a CHANNEL FUNCTIONAL TEST of each reed switch position transmitter channel ensures the channel is OPERABLE and capable of indicating CEA position over the entire length of the CEA's travel. A successful test of the required contact(s) of a channel relay may be performed by the verification of the change of state of a single contact of the relay. This clarifies what is an acceptable CHANNEL FUNCTIONAL TEST of a relay. This is acceptable because all of the other required contacts of the relay are verified by other Technical Specification tests at least once per refueling interval with applicable extensions. Since this SR must be performed when the reactor is shut down, a 24-month Frequency to be coincident with refueling outages was selected. Operating experience has shown that these components usually pass this SR when performed at a Frequency of once every 24 months. Furthermore, the Frequency takes into account other SRs being performed at shorter Frequencies, which determine the OPERABILITY of the CEA Reed Switch Indication System.
SR 3.1.4.6 Verification of CEA drop times determined that the maximum CEA drop time permitted is consistent with the assumed drop time used in that safety analysis (Reference 1, Chapter 14).
Control element assembly drop time is measured from the time when electrical power is interrupted to the CEDM until the CALVERT CLIFFS - UNITS 1 & 2      B 3.1.4-9                      Revision 37


Frequency takes into account other SRs being performed at  
CEA Alignment B 3.1.4 BASES CEA reaches its 90% insertion position, from a fully withdrawn position, with Tave  515&deg;F and all reactor coolant pumps operating. Measuring drop times prior to reactor criticality, after reactor vessel head removal, ensures that reactor internals and CEDM will not interfere with CEA motion or drop time, and that no degradation in these systems has occurred that would adversely affect CEA motion or drop time. Individual CEAs whose drop times are greater than safety analysis assumptions are not OPERABLE. This SR is performed prior to criticality, based on the need to perform this SR under the conditions that apply during a unit outage and because of the potential for an unplanned unit transient if the SR were performed with the reactor at power.
REFERENCES        1. UFSAR
: 2. 10 CFR 50.46, "Acceptance Criteria for Emergency Core Cooling Systems for Light Water Nuclear Power Plants" CALVERT CLIFFS - UNITS 1 & 2      B 3.1.4-10                        Revision 37


shorter Frequencies, which determine the OPERABILITY of the CEA Reed Switch Indication System.
Shutdown CEA Insertion Limits B 3.1.5 B 3.1  REACTIVITY CONTROL SYSTEMS B 3.1.5  Shutdown Control Element Assembly (CEA) Insertion Limits BASES BACKGROUND        The insertion limits of the shutdown CEAs are initial assumptions in all safety analyses that assume CEA insertion upon reactor trip. The insertion limits directly affect core power distributions and assumptions of available SDM, ejected CEA worth, and initial reactivity insertion rate.
SR 3.1.4.6 Verification of CEA drop times determined that the maximum
The applicable criteria for these reactivity and power distribution design requirements are in Reference 1, Appendix 1C, Criteria 6, 27, 28, 29, and 30, and Reference 2. Limits on shutdown CEA insertion have been established, and all CEA positions are monitored and controlled during power operation to ensure that the reactivity limits, ejected CEA worth, and SDM limits are preserved.
The shutdown CEAs are arranged into groups that are radially symmetric. Therefore, movement of the shutdown CEAs does not introduce radial asymmetries in the core power distribution. The shutdown and regulating CEAs provide the required reactivity worth for immediate reactor shutdown upon a reactor trip.
The design calculations are performed with the assumption that the shutdown CEAs are withdrawn prior to the regulating CEAs. The shutdown CEAs can be fully withdrawn without the core going critical. The shutdown CEAs are controlled manually by the Control Room operator. During normal unit operation, the shutdown CEAs are fully withdrawn. The shutdown CEAs must be completely withdrawn from the core prior to withdrawing any regulating CEAs during an approach to criticality. The shutdown CEAs are left in this position until the reactor is shut down. They affect core power, burnup distribution, and add negative reactivity to shut down the reactor upon receipt of a reactor trip signal.
CALVERT CLIFFS - UNITS 1 & 2        B 3.1.5-1                        Revision 2


CEA drop time permitted is consistent with the assumed drop
Shutdown CEA Insertion Limits B 3.1.5 BASES APPLICABLE       Accident analysis assumes that the shutdown CEAs are fully SAFETY ANALYSES   withdrawn any time the reactor is critical. This ensures that:
 
: a. The minimum SDM is maintained; and
time used in that safety analysis (Reference 1, Chapter 14). 
: b. The potential effects of a CEA ejection accident are limited to acceptable limits.
 
Control element assemblies are considered fully withdrawn at 129 inches.
Control element assembly drop time is measured from the time
 
when electrical power is interrupted to the CEDM until the CEA Alignment B 3.1.4 BASES  CALVERT CLIFFS - UNITS 1 & 2 B 3.1.4-10 Revision 37 CEA reaches its 90% insertion position, from a fully withdrawn position, with Tave  515&deg;F and all reactor coolant pumps operating. Measuring drop times prior to reactor criticality, after reactor vessel head removal, ensures that
 
reactor internals and CEDM will not interfere with CEA
 
motion or drop time, and that no degradation in these systems has occurred that would adversely affect CEA motion or drop time. Individual CEAs whose drop times are greater
 
than safety analysis assumptions are not OPERABLE. This SR
 
is performed prior to criticality, based on the need to
 
perform this SR under the conditions that apply during a
 
unit outage and because of the potential for an unplanned
 
unit transient if the SR were performed with the reactor at power. REFERENCES 1. UFSAR
: 2. 10 CFR 50.46, "Acceptance Criteria for Emergency Core Cooling Systems for Light Water Nuclear Power Plants" Shutdown CEA Insertion Limits B 3.1.5 B 3.1  REACTIVITY CONTROL SYSTEMS B 3.1.5  Shutdown Control Element Assembly (CEA) Insertion Limits
 
BASES CALVERT CLIFFS - UNITS 1 & 2 B 3.1.5-1 Revision 2 BACKGROUND The insertion limits of the shutdown CEAs are initial assumptions in all safety analyses that assume CEA insertion upon reactor trip. The insertion limits directly affect
 
core power distributions and assumptions of available SDM, ejected CEA worth, and initial reactivity insertion rate.
The applicable criteria for these reactivity and power
 
distribution design requirements are in Reference 1, Appendix 1C, Criteria 6, 27, 28, 29, and 30
, and Reference 2
. Limits on shutdown CEA insertion have been established, and all CEA positions are monitored and
 
controlled during power operation to ensure that the
 
reactivity limits, ejected CEA worth, and SDM limits are
 
preserved.
 
The shutdown CEAs are arranged into groups that are radially
 
symmetric. Therefore, movement of the shutdown CEAs does
 
not introduce radial asymmetries in the core power
 
distribution. The shutdown and regulating CEAs provide the
 
required reactivity worth for immediate reactor shutdown
 
upon a reactor trip.
 
The design calculations are performed with the assumption that the shutdown CEAs are withdrawn prior to the regulating
 
CEAs. The shutdown CEAs can be fully withdrawn without the
 
core going critical. The shutdown CEAs are controlled
 
manually by the Control Room operator. During normal unit
 
operation, the shutdown CEAs are fully withdrawn. The
 
shutdown CEAs must be completely withdrawn from the core
 
prior to withdrawing any regulating CEAs during an approach
 
to criticality. The shutdown CEAs are left in this position until the reactor is shut down. They affect core power, burnup distribution, and add negative reactivity to shut
 
down the reactor upon receipt of a reactor trip signal.
 
Shutdown CEA Insertion Limits B 3.1.5 BASES  CALVERT CLIFFS - UNITS 1 & 2 B 3.1.5-2 Revision 38 APPLICABLE Accident analysis assumes that the shutdown CEAs are fully SAFETY ANALYSES withdrawn any time the reactor is critical. This ensures that: a. The minimum SDM is maintained; and
: b. The potential effects of a CEA ejection accident are limited to acceptable limits.  
 
Control element assemblies are considered fully withdrawn at  
 
129 inches.
On a reactor trip, all CEAs (shutdown and regulating),
On a reactor trip, all CEAs (shutdown and regulating),
except the most reactive CEA, are assumed to insert into the  
except the most reactive CEA, are assumed to insert into the core. The shutdown and regulating CEAs shall be at or above their insertion limits and available to insert the required amount of negative reactivity on a reactor trip signal. The regulating CEAs may be partially inserted in the core as allowed by LCO 3.1.6. The shutdown CEA insertion limit is established to ensure that a sufficient amount of negative reactivity is available to shut down the reactor and maintain the required SDM (see LCO 3.1.1) following a reactor trip from full power. The combination of regulating CEAs and shutdown CEAs (less the most reactive CEA, which is assumed to be fully withdrawn) is sufficient to take the reactor from full power conditions at rated temperature to zero power, and to maintain the required SDM at rated no load temperature (Reference 1, Sections 3.2 and 3.4). The shutdown CEA insertion limit also limits the reactivity worth of an ejected shutdown CEA.
 
The acceptance criteria for addressing shutdown CEA, as well as regulating CEA insertion limits and inoperability or misalignment, are that:
core. The shutdown and regulating CEAs shall be at or above  
: a. There be no violation of:
 
: 1. SAFDLs, or
their insertion limits and available to insert the required  
: 2. RCS pressure boundary damage; and
 
: b. The core remains subcritical after accident transients.
amount of negative reactivity on a reactor trip signal. The  
As such, the shutdown CEA insertion limits affect safety analyses involving core reactivity, ejected CEA worth, and SDM (Reference 1, Section 14.1.2).
 
CALVERT CLIFFS - UNITS 1 & 2      B 3.1.5-2                      Revision 38
regulating CEAs may be partially inserted in the core as  
 
allowed by LCO 3.1.6. The shutdown CEA insertion limit is  
 
established to ensure that a sufficient amount of negative  
 
reactivity is available to shut down the reactor and  
 
maintain the required SDM (see LCO 3.1.1) following a  


reactor trip from full power. The combination of regulating
Shutdown CEA Insertion Limits B 3.1.5 BASES The shutdown CEA insertion limits satisfy 10 CFR 50.36(c)(2)(ii), Criterion 2.
LCO              The shutdown CEAs must be within their insertion limits any time the reactor is critical or approaching criticality.
This ensures that a sufficient amount of negative reactivity is available to shut down the reactor and maintain the required SDM following a reactor trip.
APPLICABILITY    The shutdown CEAs must be within their insertion limits, with the reactor in MODEs 1 and 2. The Applicability in MODE 2 begins anytime any regulating CEA is not fully inserted. This ensures that a sufficient amount of negative reactivity is available to shut down the reactor and maintain the required SDM following a reactor trip. In MODE 3, 4, 5, or 6, the shutdown CEAs are fully inserted in the core and contribute to the SDM. Refer to LCO 3.1.1 for SDM requirements in MODEs 3, 4, and 5. Limiting Condition for Operation 3.9.1 ensures adequate SDM in MODE 6.
This LCO has been modified by a Note indicating the LCO requirement is suspended during SR 3.1.4.4. This SR verifies the freedom of the CEAs to move, and requires the shutdown CEAs to move below the LCO limits, which would normally violate the LCO.
ACTIONS          A.1 When one shutdown CEA is withdrawn  121.5 inches and
                  < 129 inches, the accumulated times the shutdown CEAs have been withdrawn within this range must be verified. The Completion Time for this action is once within 4 hours and 24 hours thereafter. Operation is allowed for 7 consecutive days and a total of 14 days per 365 days. The peaking factors may not be outside required limits when one shutdown CEA is misaligned; therefore, continued operation is allowed. Since the power distribution limits are being maintained via the LCOs of Technical Specification Section 3.2, any out-of-limit peaking factor conditions will require entry into the Actions of the appropriate Section 3.2 LCO(s). The limits on consecutive days and total days in this condition reflect that the core may be approaching the acceptable limits placed on operation with CALVERT CLIFFS - UNITS 1 & 2      B 3.1.5-3                        Revision 38


CEAs and shutdown CEAs (less the most reactive CEA, which is  
Shutdown CEA Insertion Limits B 3.1.5 BASES flux patterns outside those assumed in the long-term burnup assumptions. Therefore, operation in this condition cannot continue and the CEA is required to be restored per Action B. The accumulated times are required to be verified once within 4 hours to determine which accumulated time limit is more limiting. The periodic Completion Time of 24 hours after the initial completion within 4 hours is adequate to ensure that the accumulated time limits are not exceeded.
B.1 Prior to entering this condition, the shutdown CEAs were fully withdrawn or all but one shutdown CEA was withdrawn 129 inches. If one shutdown CEA is withdrawn 121.5 inches and < 129 inches for > 7 days per occurrence or > 14 days per 365 days, or one shutdown CEA withdrawn
                  < 121.5 inches, or two or more shutdown CEAs withdrawn
                  < 129 inches, the out-of-limit CEAs must be restored to within limits within 2 hours. The Completion Time of 2 hours reflects that the power distribution limits may be outside required limits and that the core may be approaching the acceptable limits placed on operation within flux patterns outside those assumed in the long-term burnup assumptions.
The CEA(s) must be restored to within limits within 2 hours.
The 2-hour total Completion Time allows the operator adequate time to adjust the CEA(s) in an orderly manner.
C.1 When Required Action A.1 or B.1 cannot be met or completed within the required Completion Time, a controlled shutdown should be commenced. The allowed Completion Time of 6 hours is reasonable, based on operating experience, for reaching MODE 3 from full power conditions in an orderly manner and without challenging plant systems.
SURVEILLANCE      SR 3.1.5.1 REQUIREMENTS Verification that the shutdown CEAs are within their insertion limits prior to an approach to criticality ensures that when the reactor is critical, or being taken critical, the shutdown CEAs will be available to shut down the CALVERT CLIFFS - UNITS 1 & 2      B 3.1.5-4                      Revision 38


assumed to be fully withdrawn) is sufficient to take the  
Shutdown CEA Insertion Limits B 3.1.5 BASES reactor, and the required SDM will be maintained following a reactor trip. This SR and Frequency ensure that the shutdown CEAs are withdrawn before the regulating CEAs are withdrawn during a unit startup.
Since the shutdown CEAs are positioned manually by the Control Room operator, verification of shutdown CEA position at a Frequency of 12 hours is adequate to ensure that the shutdown CEAs are within their insertion limits. Also, the 12-hour Frequency takes into account other information available to the operator in the Control Room for the purpose of monitoring the status of the shutdown CEAs.
REFERENCES        1. UFSAR
: 2. 10 CFR 50.46, "Acceptance Criteria for Emergency Core Cooling Systems for Light Water Nuclear Power Plants" CALVERT CLIFFS - UNITS 1 & 2      B 3.1.5-5                      Revision 38


reactor from full power conditions at rated temperature to  
Regulating CEA Insertion Limits B 3.1.6 B 3.1  REACTIVITY CONTROL SYSTEMS B 3.1.6  Regulating Control Element Assembly (CEA) Insertion Limits BASES BACKGROUND        The insertion limits of the regulating CEAs are initial assumptions in all safety analyses that assume CEA insertion upon reactor trip. The insertion limits directly affect core power distributions, assumptions of available SDM, and initial reactivity insertion rate. The applicable criteria for these reactivity and power distribution design requirements are Reference 1, Appendix 1C, Criteria 27, 29, 30, and 31, and Reference 2.
Limits on regulating CEA insertion have been established, and all CEA positions are monitored and controlled during power operation to ensure that the power distribution and reactivity limits defined by the design power peaking, ejected CEA worth, reactivity insertion rate, and SDM limits are preserved.
The regulating CEA groups operate with a predetermined amount of position overlap, in order to approximate a linear relation between CEA worth and CEA position (integral CEA worth). The regulating CEA groups are withdrawn and operate in a predetermined sequence. The group sequence and overlap limits are specified in the COLR. Regulating CEAs are considered to be fully withdrawn when withdrawn to at least 129.0 inches.
The regulating CEAs are used for precise reactivity control of the reactor. The positions of the regulating CEAs are manually controlled. They are capable of adding reactivity very quickly (compared to borating or diluting).
The power density at any point in the core must be limited to maintain SAFDLs, including limits that preserve the criteria specified in Reference 2. Together, LCOs 3.1.6, 3.2.4, and LCO 3.2.5 provide limits on control component operation and on monitored process variables to ensure the core operates within the LHR (LCO 3.2.1); and Total Integrated Radial Peaking Factor ( F Tr ) (LCO 3.2.3) limits in the COLR. Operation within the LHR limits given in the COLR prevents power peaks that would exceed the loss of coolant accident (LOCA) limits derived by the Emergency Core Cooling CALVERT CLIFFS - UNITS 1 & 2        B 3.1.6-1                          Revision 43


zero power, and to maintain the required SDM at rated no
Regulating CEA Insertion Limits B 3.1.6 BASES System analysis. Operation within the F Tr limit given in the COLR prevents departure from nucleate boiling (DNB) during a loss of forced reactor coolant flow accident. In addition to the LHR and F Tr limits, certain reactivity limits are preserved by regulating CEA insertion limits.
The regulating CEA insertion limits also restrict the ejected CEA worth to the values assumed in the safety analysis and preserve the minimum required SDM in MODEs 1 and 2.
The regulating CEA insertion and alignment limits are process variables that together characterize and control the three-dimensional power distribution of the reactor core.
Additionally, the regulating bank insertion limits control the reactivity that could be added in the event of a CEA ejection accident, and the shutdown and regulating bank insertion limits ensure the required SDM is maintained.
Operation within the subject LCO limits will prevent fuel cladding failures that would breach the primary fission product barrier and release fission products to the reactor coolant in the event of a LOCA, loss of flow, ejected CEA, or other accident requiring termination by a Reactor Protective System trip function.
APPLICABLE        The fuel cladding must not sustain damage as a result of SAFETY ANALYSES  normal operation (Condition I) and AOOs (Condition II). The acceptance criteria for the regulating CEA insertion, ASI, F Tr , LHR, and AZIMUTHAL POWER TILT (Tq) LCOs are such as to preclude core power distributions from occurring that would violate the following fuel design criteria:
: a. During a large break LOCA, the peak cladding temperature must not exceed a limit of 2200&deg;F (Reference 2);
: b. During a loss of forced reactor coolant flow accident, there must be at least a 95% probability at a 95%
confidence level (the 95/95 DNB criterion) that the hot fuel rod in the core does not experience a DNB condition; CALVERT CLIFFS - UNITS 1 & 2        B 3.1.6-2                        Revision 43


load temperature (Reference 1, Sections 3.2 and 3.4). The  
Regulating CEA Insertion Limits B 3.1.6 BASES
: c. During an ejected CEA accident, the energy input to the fuel must not exceed accepted limits (Reference 1, Section 14.3); and
: d. The CEAs must be capable of shutting down the reactor with a minimum required SDM, with the highest worth CEA stuck fully withdrawn, Reference 1, Appendix 1C, Criterion 29.
Regulating CEA position, ASI, F Tr , LHR, and Tq are process variables that together characterize and control the three-dimensional power distribution of the reactor core.
Fuel cladding damage does not normally occur when the core is operated outside these LCOs during normal operation.
However, fuel cladding damage could result if an accident or AOO occurs with simultaneous violation of one or more of these LCOs. Changes in the power distribution can cause increased power peaking and corresponding increased local LHRs.
The SDM requirement is ensured by limiting the regulating and shutdown CEA insertion limits, so that the allowable inserted worth of the CEAs is such that sufficient reactivity is available to shut down the reactor to hot zero power. SHUTDOWN MARGIN assumes the maximum worth CEA remains fully withdrawn upon trip (Reference 1, Section 3.4).
The most limiting SDM requirements for MODEs 1 and 2 conditions at BOC are determined by the requirements of several transients, e.g., Loss of Flow, Seized Rotor, Boron Dilution, etc. However, the most limiting SDM requirements for MODEs 1 and 2 at EOC come from the SLB and Excess Load transients. The requirements of the SLB and Excess Load events at EOC for both the full power and no load conditions are significantly larger than those of any other event at that time in cycle.
To verify that adequate SDMs are available throughout the cycle to satisfy the changing requirements, calculations are performed at both BOC and EOC. It has been determined that calculations at these two times in cycle a are sufficient since the differences between available SDMs and the CALVERT CLIFFS - UNITS 1 & 2      B 3.1.6-3                          Revision 43


shutdown CEA insertion limit also limits the reactivity  
Regulating CEA Insertion Limits B 3.1.6 BASES limiting SDM requirements are the smallest at these times in a cycle. The measurement of CEA bank worth performed as part of the Startup Testing Program demonstrates that the core has the expected shutdown capability. Consequently, adherence to LCOs 3.1.5 and 3.1.6 provides assurance that the available SDM at any time in a cycle will exceed the limiting SDM requirements at that time in a cycle.
Operation at the insertion limits or ASI limits may approach the maximum allowable linear heat generation rate or peaking factor, with the allowed Tq present. Operation at the insertion limit may also indicate the maximum ejected CEA worth could be equal to the limiting value in fuel cycles that have sufficiently high ejected CEA worths.
The regulating and shutdown CEA insertion limits ensure that safety analyses assumptions for reactivity insertion rate, SDM, ejected CEA worth, and power distribution peaking factors are preserved (Reference 1, Section 3.4).
The regulating CEA insertion limits satisfy 10 CFR 50.36(c)(2)(ii), Criterion 2.
LCO              The limits on regulating CEAs sequence, overlap, and physical insertion, as defined in the COLR, must be maintained because they serve the function of preserving power distribution, ensuring that the SDM is maintained, ensuring that ejected CEA worth is maintained, and ensuring adequate negative reactivity insertion on trip. The overlap between regulating banks provides more uniform rates of reactivity insertion and withdrawal and is imposed to maintain acceptable power peaking during regulating CEA motion.
The power-dependent insertion limit (PDIL) alarm circuit is required to be OPERABLE for notification that the CEAs are outside the required insertion limits. The PDIL alarm circuit required to be OPERABLE receives its signal from the reed switch position indication system. When the PDIL alarm circuit is inoperable, the verification of CEA positions is increased to ensure improper CEA alignment is identified before unacceptable flux distribution occurs.
CALVERT CLIFFS - UNITS 1 & 2      B 3.1.6-4                        Revision 43


worth of an ejected shutdown CEA.  
Regulating CEA Insertion Limits B 3.1.6 BASES APPLICABILITY    The regulating CEA sequence, overlap, and physical insertion limits shall be maintained with the reactor in MODEs 1 and 2. These limits must be maintained, since they preserve the assumed power distribution, ejected CEA worth, SDM, and reactivity rate insertion assumptions. Applicability in MODEs 3, 4, and 5 is not required, since neither the power distribution nor ejected CEA worth assumptions would be exceeded in these MODEs. SHUTDOWN MARGIN is preserved in MODEs 3, 4, and 5 by adjustments to the soluble boron concentration.
This LCO has been modified by a Note indicating the LCO requirement is suspended during SR 3.1.4.4. This SR verifies the freedom of the CEAs to move, and requires the regulating CEAs to move below the LCO limits, which would normally violate the LCO.
ACTIONS          A.1 and A.2 Operation beyond the transient insertion limit may result in a loss of SDM and excessive peaking factors. The transient insertion limit should not be violated during normal operation; this violation, however, may occur during transients when the operator is manually controlling the CEAs in response to changing plant conditions. When the regulating groups are inserted beyond the transient insertion limits, actions must be taken to either withdraw the regulating groups beyond the limits or to reduce THERMAL POWER to less than or equal to that allowed for the actual CEA insertion limit. Two hours provides a reasonable time to accomplish this, allowing the operator to deal with current plant conditions while limiting peaking factors to acceptable levels.
B.1 and B.2 If the CEAs are inserted between the long-term steady state insertion limits and the transient insertion limits for intervals > 4 hours per 24 hour period, and the short-term steady state insertions are exceeded, peaking factors can develop that are of immediate concern (Reference 1, Chapter 14).
CALVERT CLIFFS - UNITS 1 & 2      B 3.1.6-5                      Revision 43


The acceptance criteria for addressing shutdown CEA, as well as regulating CEA insertion limits and inoperability or  
Regulating CEA Insertion Limits B 3.1.6 BASES Verifying the short-term steady state insertion limits are not exceeded ensures that the peaking factors that do develop are within those allowed for continued operation.
Fifteen minutes provides adequate time for the operator to verify if the short-term steady state insertion limits are exceeded.
Experience has shown that rapid power increases in areas of the core, in which the flux has been depressed, can result in fuel damage, as the LHR in those areas rapidly increases.
Restricting the rate of THERMAL POWER increases to 5% RTP per hour, following CEA insertion beyond the long-term steady-state insertion limits, ensures the power transients experienced by the fuel will not result in fuel failure.
C.1 With the regulating CEAs inserted between the long-term steady state insertion limit and the transient insertion limit, and with the core approaching the 5 EFPD per 30 EFPD or 14 EFPD per 365 EFPD limits, the CEAs must be returned to within the long-term steady state insertion limits, or the core must be placed in a condition in which the abnormal fuel burnup cannot continue. A Completion Time of 2 hours is allotted to return the CEAs to within the long-term steady state insertion limits.
The required Completion Time of 2 hours from initial discovery of a regulating CEA group outside the limits until its restoration to within the long-term steady state limits, shown on the figures in the COLR, allows sufficient time for borated water to enter the RCS from the chemical addition and makeup systems, and to cause the regulating CEAs to withdraw to the acceptable region. It is reasonable to continue operation for 2 hours after it is discovered that the 5-day or 14-day EFPD limit has been exceeded. This Completion Time is based on limiting the potential xenon redistribution, the low probability of an accident, and the steps required to complete the action.
D.1 When the PDIL alarm circuit is inoperable, performing SR 3.1.6.1 within 1 hour and once per 4 hours thereafter CALVERT CLIFFS - UNITS 1 & 2      B 3.1.6-6                      Revision 43


misalignment, are that:  a. There be no violation of1. SAFDLs, or   2. RCS pressure boundary damage; and  b. The core remains subcritical after accident transients.  
Regulating CEA Insertion Limits B 3.1.6 BASES ensures improper CEA alignments are identified before unacceptable flux distributions occur.
E.1 When a Required Action cannot be completed within the required Completion Time, a controlled shutdown should be commenced. The allowed Completion Time of 6 hours is reasonable, based on operating experience, for reaching MODE 3 from full power conditions in an orderly manner and without challenging plant systems.
SURVEILLANCE      SR 3.1.6.1 REQUIREMENTS With the PDIL alarm circuit OPERABLE, verification of each regulating CEA group position every 12 hours is sufficient to detect CEA positions that may approach the acceptable limits, and to provide the operator with time to undertake the Required Action(s) should the sequence or insertion limits be found to be exceeded. The 12-hour Frequency also takes into account the indication provided by the PDIL alarm circuit and other information about CEA group positions available to the operator in the Control Room.
SR 3.1.6.2 Verification of the accumulated time of CEA group insertion between the long-term steady state insertion limits and the transient insertion limits ensures the cumulative time limits are not exceeded. The 24-hour Frequency ensures the operator identifies a time limit that is being approached before it is reached.
SR 3.1.6.3 Demonstrating the PDIL alarm circuit OPERABLE verifies that the PDIL alarm circuit is functional. The 31-day Frequency takes into account other SRs being performed at shorter Frequencies that identify improper CEA alignments.
REFERENCES        1. UFSAR
: 2. 10 CFR 50.46, "Acceptance Criteria for Emergency Core Cooling Systems for Light Water Nuclear Power Plants" 10 CFR 50.46 CALVERT CLIFFS - UNITS 1 & 2      B 3.1.6-7                      Revision 43


As such, the shutdown CEA insertion limits affect safety analyses involving core reactivity, ejected CEA worth, and
STE-SDM B 3.1.7 B 3.1   REACTIVITY CONTROL SYSTEMS B 3.1.7   Special Test Exception (STE)-SHUTDOWN MARGIN (SDM)
 
BASES BACKGROUND         The primary purpose of the SDM STE is to permit relaxation of existing LCOs to allow the performance of certain PHYSICS TESTS. These tests are constructed to determine the CEA worth.
SDM (Reference 1, Section 14.1.2).
Reference 1, Appendix B, Section XI requires that a test program be established to ensure that structures, systems, and components will perform satisfactorily in service. All functions necessary to ensure that specified design conditions are not exceeded during normal operation and AOOs must be tested. Testing is required as an integral part of the design, fabrication, construction, and operation of the power plant. Requirements for notification of the Nuclear Regulatory Commission, for the purpose of conducting tests and experiments, are specified in Reference 1, 10 CFR 50.59.
 
The key objectives of a test program (Reference 2) are to:
Shutdown CEA Insertion Limits B 3.1.5 BASES  CALVERT CLIFFS - UNITS 1 & 2 B 3.1.5-3 Revision 38 The shutdown CEA insertion limits satisfy 10 CFR 50.36(c)(2)(ii), Criterion 2.
: a. Ensure that the facility has been adequately designed;
LCO The shutdown CEAs must be within their insertion limits any
 
time the reactor is critical or approaching criticality. 
 
This ensures that a sufficient amount of negative reactivity
 
is available to shut down the reactor and maintain the required SDM following a reactor trip.
APPLICABILITY The shutdown CEAs must be within their insertion limits, with the reactor in MODEs 1 and 2. The Applicability in
 
MODE 2 begins anytime any regulating CEA is not fully
 
inserted. This ensures that a sufficient amount of negative
 
reactivity is available to shut down the reactor and
 
maintain the required SDM following a reactor trip. In
 
MODE 3, 4, 5, or 6, the shutdown CEAs are fully inserted in
 
the core and contribute to the SDM. Refer to LCO 3.1.1 for
 
SDM requirements in MODEs 3, 4, and 5. Limiting Condition
 
for Operation 3.9.1 ensures adequate SDM in MODE 6.
 
This LCO has been modified by a Note indicating the LCO requirement is suspended during SR 3.1.4.4. This SR
 
verifies the freedom of the CEAs to move, and requires the
 
shutdown CEAs to move below the LCO limits, which would normally violate the LCO.
ACTIONS A.1 When one shutdown CEA is withdrawn  121.5 inches and
< 129 inches, the accumulated times the shutdown CEAs have been withdrawn within this range must be verified. The
 
Completion Time for this action is once within 4 hours and
 
24 hours thereafter. Operation is allowed for 7 consecutive
 
days and a total of 14 days per 365 days. The peaking
 
factors may not be outside required limits when one shutdown
 
CEA is misaligned; therefore, continued operation is
 
allowed. Since the power distribution limits are being
 
maintained via the LCOs of Technical Specification
 
Section 3.2, any out-of-limit peaking factor conditions will
 
require entry into the Actions of the appropriate
 
Section 3.2 LCO(s). The limits on consecutive days and
 
total days in this condition reflect that the core may be
 
approaching the acceptable limits placed on operation with Shutdown CEA Insertion Limits B 3.1.5 BASES  CALVERT CLIFFS - UNITS 1 & 2 B 3.1.5-4 Revision 38 flux patterns outside those assumed in the long-term burnup assumptions. Therefore, operation in this condition cannot
 
continue and the CEA is required to be restored per Action
 
B. The accumulated times are required to be verified once
 
within 4 hours to determine which accumulated time limit is
 
more limiting. The periodic Completion Time of 24 hours after the initial completion within 4 hours is adequate to ensure that the accumulated time limits are not exceeded.
 
B.1  Prior to entering this condition, the shutdown CEAs were
 
fully withdrawn or all but one shutdown CEA was withdrawn  129 inches. If one shutdown CEA is withdrawn  121.5 inches and
< 129 inches for
> 7 days per occurrence or > 14 days per 365 days, or one shutdown CEA withdrawn
< 121.5 inches, or two or more shutdown CEAs withdrawn
< 129 inches, the out-of-limit CEAs must be restored to within limits within 2 hours. The Completion Time of 2 hours reflects that the power distribution limits may be
 
outside required limits and that the core may be approaching
 
the acceptable limits placed on operation within flux
 
patterns outside those assumed in the long-term burnup
 
assumptions.
 
The CEA(s) must be restored to within limits within 2 hours. 
 
The 2-hour total Completion Time allows the operator
 
adequate time to adjust the CEA(s) in an orderly manner.
 
C.1  When Required Action A.1 or B.1 cannot be met or completed
 
within the required Completion Time, a controlled shutdown
 
should be commenced. The allowed Completion Time of 6 hours
 
is reasonable, based on operating experience, for reaching
 
MODE 3 from full power conditions in an orderly manner and without challenging plant systems.
SURVEILLANCE SR 3.1.5.1 REQUIREMENTS
 
Verification that the shutdown CEAs are within their
 
insertion limits prior to an approach to criticality ensures
 
that when the reactor is critical, or being taken critical, the shutdown CEAs will be available to shut down the Shutdown CEA Insertion Limits B 3.1.5 BASES  CALVERT CLIFFS - UNITS 1 & 2 B 3.1.5-5 Revision 38 reactor, and the required SDM will be maintained following a reactor trip. This SR and Frequency ensure that the
 
shutdown CEAs are withdrawn before the regulating CEAs are
 
withdrawn during a unit startup.
 
Since the shutdown CEAs are positioned manually by the Control Room operator, verification of shutdown CEA position at a Frequency of 12 hours is adequate to ensure that the
 
shutdown CEAs are within their insertion limits. Also, the
 
12-hour Frequency takes into account other information
 
available to the operator in the Control Room for the purpose of monitoring the status of the shutdown CEAs.
REFERENCES 1. UFSAR
: 2. 10 CFR 50.46, "Acceptance Criteria for Emergency Core Cooling Systems for Light Water Nuclear Power Plants" Regulating CEA Insertion Limits B 3.1.6 B 3.1  REACTIVITY CONTROL SYSTEMS B 3.1.6  Regulating Control Element Assembly (CEA) Insertion Limits
 
BASES  CALVERT CLIFFS - UNITS 1 & 2 B 3.1.6-1 Revision 43 BACKGROUND The insertion limits of the regulating CEAs are initial assumptions in all safety analyses that assume CEA insertion upon reactor trip. The insertion limits directly affect
 
core power distributions, assumptions of available SDM, and initial reactivity insertion rate. The applicable criteria for these reactivity and power distribution design
 
requirements are Reference 1, Appendix 1C, Criteria 27, 29, 30, and 31, and Reference 2.
 
Limits on regulating CEA insertion have been established, and all CEA positions are monitored and controlled during
 
power operation to ensure that the power distribution and
 
reactivity limits defined by the design power peaking, ejected CEA worth, reactivity insertion rate, and SDM limits
 
are preserved.
 
The regulating CEA groups operate with a predetermined amount of position overlap, in order to approximate a linear
 
relation between CEA worth and CEA position (integral CEA
 
worth). The regulating CEA groups are withdrawn and operate
 
in a predetermined sequence. The group sequence and overlap
 
limits are specified in the COLR. Regulating CEAs are
 
considered to be fully withdrawn when withdrawn to at least
 
129.0 inches.
 
The regulating CEAs are used for precise reactivity control of the reactor. The positions of the regulating CEAs are
 
manually controlled. They are capable of adding reactivity
 
very quickly (compared to borating or diluting).
 
The power density at any point in the core must be limited to maintain SAFDLs, including limits that preserve the criteria specified in Reference 2. Together, LCOs 3.1.6, 3.2.4, and LCO 3.2.5 provide limits on control component
 
operation and on monitored process variables to ensure the
 
core operates within the LHR (LCO 3.2.1);
and Total Integrated Radial Peaking Factor (r T F) (LCO 3.2.3) limits in the COLR. Operation within the LHR limits given in the COLR
 
prevents power peaks that would exceed the loss of coolant
 
accident (LOCA) limits derived by the Emergency Core Cooling Regulating CEA Insertion Limits B 3.1.6 BASES  CALVERT CLIFFS - UNITS 1 & 2 B 3.1.6-2 Revision 43 System analysis. Operation within the r T F limit given in the COLR prevents departure from nucleate boiling (DNB) during a loss of forced reactor coolant flow accident. In addition to the LHR and r T F limits, certain reactivity limits are preserved by regulating CEA insertion limits.
The regulating CEA insertion limits also restrict the
 
ejected CEA worth to the values assumed in the safety
 
analysis and preserve the minimum required SDM in MODEs 1
 
and 2.
The regulating CEA insertion and alignment limits are process variables that together characterize and control the
 
three-dimensional power distribution of the reactor core. 
 
Additionally, the regulating bank insertion limits control
 
the reactivity that could be added in the event of a CEA
 
ejection accident, and the shutdown and regulating bank
 
insertion limits ensure the required SDM is maintained.
 
Operation within the subject LCO limits will prevent fuel cladding failures that would breach the primary fission
 
product barrier and release fission products to the reactor
 
coolant in the event of a LOCA, loss of flow, ejected CEA, or other accident requiring termination by a Reactor Protective System trip function.
APPLICABLE The fuel cladding must not sustain damage as a result of SAFETY ANALYSES normal operation (Condition I) and AOOs (Condition II). The acceptance criteria for the regulating CEA insertion, ASI, r T F , LHR, and AZIMUTHAL POWER TILT (T q) LCOs are such as to preclude core power distributions from occurring that would
 
violate the following fuel design criteria:  a. During a large break LOCA, the peak cladding temperature must not exceed a limit of 2200&deg;F (Reference 2);  b. During a loss of forced reactor coolant flow accident, there must be at least a 95% probability at a 95%
confidence level (the 95/95 DNB criterion) that the hot
 
fuel rod in the core does not experience a DNB
 
condition; Regulating CEA Insertion Limits B 3.1.6 BASES  CALVERT CLIFFS - UNITS 1 & 2 B 3.1.6-3 Revision 43
: c. During an ejected CEA accident, the energy input to the fuel must not exceed accepted limits (Reference 1, Section 14.3); and  d. The CEAs must be capable of shutting down the reactor with a minimum required SDM, with the highest worth CEA
 
stuck fully withdrawn, Reference 1, Appendix 1C, Criterion 29.
Regulating CEA position, ASI, r T F , LHR, and T q are process variables that together characterize and control the three-dimensional power distribution of the reactor core.
 
Fuel cladding damage does not normally occur when the core is operated outside these LCOs during normal operation. 
 
However, fuel cladding damage could result if an accident or
 
AOO occurs with simultaneous violation of one or more of these LCOs. Changes in the power distribution can cause increased power peaking and corresponding increased local
 
LHRs.
The SDM requirement is ensured by limiting the regulating and shutdown CEA insertion limits, so that the allowable
 
inserted worth of the CEAs is such that sufficient
 
reactivity is available to shut down the reactor to hot zero
 
power. SHUTDOWN MARGIN assumes the maximum worth CEA
 
remains fully withdrawn upon trip (Reference 1, Section 3.4).
 
The most limiting SDM requirements for MODEs 1 and 2 conditions at BOC are determined by the requirements of
 
several transients, e.g., Loss of Flow, Seized Rotor, Boron Dilution, etc. However, the most limiting SDM requirements for MODEs 1 and 2 at EOC come from the SLB and Excess Load transient s. The requirements of the SLB and Excess Load event s at EOC for both the full power and no load conditions are significantly larger than those of any other event at
 
that time in cycle.
T o verify that adequate SDMs are available throughout the cycle to satisfy the changing requirements, calculations are
 
performed at both BOC and EOC. It has been determined that
 
calculations at these two times in cycle a are sufficient
 
since the differences between available SDMs and the Regulating CEA Insertion Limits B 3.1.6 BASES  CALVERT CLIFFS - UNITS 1 & 2 B 3.1.6-4 Revision 43 limiting SDM requirements are the smallest at these times in a cycle. The measurement of CEA bank worth performed as
 
part of the Startup Testing Program demonstrates that the
 
core has the expected shutdown capability. Consequently, adherence to LCOs 3.1.5 and 3.1.6 provides assurance that
 
the available SDM at any time in a cycle will exceed the limiting SDM requirements at that time in a cycle.
Operation at the insertion limits or ASI limits may approach the maximum allowable linear heat generation rate or peaking
 
factor, with the allowed T q present. Operation at the insertion limit may also indicate the maximum ejected CEA
 
worth could be equal to the limiting value in fuel cycles
 
that have sufficiently high ejected CEA worths.
 
The regulating and shutdown CEA insertion limits ensure that safety analyses assumptions for reactivity insertion rate, SDM, ejected CEA worth, and power distribution peaking
 
factors are preserved (Reference 1, Section 3.4).
 
The regulating CEA insertion limits satisfy 10 CFR 50.36(c)(2)(ii), Criterion 2.
 
LCO The limits on regulating CEAs sequence, overlap, and physical insertion, as defined in the COLR, must be
 
maintained because they serve the function of preserving
 
power distribution, ensuring that the SDM is maintained, ensuring that ejected CEA worth is maintained, and ensuring
 
adequate negative reactivity insertion on trip. The overlap
 
between regulating banks provides more uniform rates of reactivity insertion and withdrawal and is imposed to maintain acceptable power peaking during regulating CEA
 
motion.
The power-dependent insertion limit (PDIL) alarm circuit is required to be OPERABLE for notification that the CEAs are
 
outside the required insertion limits. The PDIL alarm
 
circuit required to be OPERABLE receives its signal from the
 
reed switch position indication system. When the PDIL alarm
 
circuit is inoperable, the verification of CEA positions is
 
increased to ensure improper CEA alignment is identified before unacceptable flux distribution occurs.
 
Regulating CEA Insertion Limits B 3.1.6 BASES  CALVERT CLIFFS - UNITS 1 & 2 B 3.1.6-5 Revision 43 APPLICABILITY The regulating CEA sequence, overlap, and physical insertion limits shall be maintained with the reactor in MODEs 1 and 2. These limits must be maintained, since they preserve
 
the assumed power distribution, ejected CEA worth, SDM, and
 
reactivity rate insertion assumptions. Applicability in
 
MODEs 3, 4, and 5 is not required, since neither the power distribution nor ejected CEA worth assumptions would be exceeded in these MODEs. SHUTDOWN MARGIN is preserved in
 
MODEs 3, 4, and 5 by adjustments to the soluble boron
 
concentration.
 
This LCO has been modified by a Note indicating the LCO requirement is suspended during SR 3.1.4.4. This SR
 
verifies the freedom of the CEAs to move, and requires the
 
regulating CEAs to move below the LCO limits, which would
 
normally violate the LCO.
ACTIONS A.1 and A.2 Operation beyond the transient insertion limit may result in
 
a loss of SDM and excessive peaking factors. The transient
 
insertion limit should not be violated during normal
 
operation; this violation, however, may occur during
 
transients when the operator is manually controlling the
 
CEAs in response to changing plant conditions. When the
 
regulating groups are inserted beyond the transient
 
insertion limits, actions must be taken to either withdraw
 
the regulating groups beyond the limits or to reduce THERMAL
 
POWER to less than or equal to that allowed for the actual
 
CEA insertion limit. Two hours provides a reasonable time
 
to accomplish this, allowing the operator to deal with current plant conditions while limiting peaking factors to acceptable levels.
 
B.1 and B.2 If the CEAs are inserted between the long-term steady state
 
insertion limits and the transient insertion limits for
 
intervals > 4 hours per 24 hour period, and the short-term
 
steady state insertions are exceeded, peaking factors can
 
develop that are of immediate concern (Reference 1, Chapter 14).
 
Regulating CEA Insertion Limits B 3.1.6 BASES  CALVERT CLIFFS - UNITS 1 & 2 B 3.1.6-6 Revision 43 Verifying the short-term steady state insertion limits are not exceeded ensures that the peaking factors that do
 
develop are within those allowed for continued operation. 
 
Fifteen minutes provides adequate time for the operator to
 
verify if the short-term steady state insertion limits are
 
exceeded.
 
Experience has shown that rapid power increases in areas of the core, in which the flux has been depressed, can result
 
in fuel damage, as the LHR in those areas rapidly increases.
Restricting the rate of THERMAL POWER increases to 5% RTP per hour, following CEA insertion beyond the long-term steady-state insertion limits, ensures the power transients
 
experienced by the fuel will not result in fuel failure.
 
C.1  With the regulating CEAs inserted between the long-term
 
steady state insertion limit and the transient insertion
 
limit, and with the core approaching the 5 EFPD per 30 EFPD
 
or 14 EFPD per 365 EFPD limits, the CEAs must be returned to
 
within the long-term steady state insertion limits, or the
 
core must be placed in a condition in which the abnormal
 
fuel burnup cannot continue. A Completion Time of 2 hours
 
is allotted to return the CEAs to within the long-term
 
steady state insertion limits.
 
The required Completion Time of 2 hours from initial discovery of a regulating CEA group outside the limits until
 
its restoration to within the long-term steady state limits, shown on the figures in the COLR, allows sufficient time for
 
borated water to enter the RCS from the chemical addition
 
and makeup systems, and to cause the regulating CEAs to
 
withdraw to the acceptable region. It is reasonable to
 
continue operation for 2 hours after it is discovered that
 
the 5-day or 14-day EFPD limit has been exceeded. This Completion Time is based on limiting the potential xenon redistribution, the low probability of an accident, and the
 
steps required to complete the action.
 
D.1  When the PDIL alarm circuit is inoperable, performing
 
SR 3.1.6.1 within 1 hour and once per 4 hours thereafter Regulating CEA Insertion Limits B 3.1.6 BASES  CALVERT CLIFFS - UNITS 1 & 2 B 3.1.6-7 Revision 43 ensures improper CEA alignments are identified before unacceptable flux distributions occur.
 
E.1  When a Required Action cannot be completed within the
 
required Completion Time, a controlled shutdown should be commenced. The allowed Completion Time of 6 hours is reasonable, based on operating experience, for reaching
 
MODE 3 from full power conditions in an orderly manner and without challenging plant systems.
SURVEILLANCE SR 3.1.6.1 REQUIREMENTS With the PDIL alarm circuit OPERABLE, verification of each regulating CEA group position every 12 hours is sufficient
 
to detect CEA positions that may approach the acceptable
 
limits, and to provide the operator with time to undertake
 
the Required Action(s) should the sequence or insertion
 
limits be found to be exceeded. The 12-hour Frequency also
 
takes into account the indication provided by the PDIL alarm
 
circuit and other information about CEA group positions
 
available to the operator in the Control Room.
 
SR 3.1.6.2 Verification of the accumulated time of CEA group insertion
 
between the long-term steady state insertion limits and the
 
transient insertion limits ensures the cumulative time
 
limits are not exceeded. The 24-hour Frequency ensures the
 
operator identifies a time limit that is being approached
 
before it is reached.
 
SR 3.1.6.3 Demonstrating the PDIL alarm circuit OPERABLE verifies that
 
the PDIL alarm circuit is functional. The 31-day Frequency
 
takes into account other SRs being performed at shorter Frequencies that identify improper CEA alignments.
REFERENCES 1. UFSAR
: 2. 10 CFR 50.46, "Acceptance Criteria for Emergency Core Cooling Systems for Light Water Nuclear Power Plants" 10 CFR 50.46 STE-SDM B 3.1.7 B 3.1 REACTIVITY CONTROL SYSTEMS B 3.1.7 Special Test Exception (STE)-SHUTDOWN MARGIN (SDM)  
 
BASES CALVERT CLIFFS - UNITS 1 & 2 B 3.1.7-1 Revision 2 BACKGROUND The primary purpose of the SDM STE is to permit relaxation of existing LCOs to allow the performance of certain PHYSICS TESTS. These tests are constructed to determine the CEA worth.
R eference 1 , Appendix B, Section XI requires that a test program be established to ensure that structures, systems, and components will perform satisfactorily in service. All  
 
functions necessary to ensure that specified design  
 
conditions are not exceeded during normal operation and AOOs must be tested. Testing is required as an integral part of  
 
the design, fabrication, construction, and operation of the  
 
power plant. Requirements for notification of the Nuclear  
 
Regulatory Commission, for the purpose of conducting tests  
 
and experiments, are specified in Reference 1, 10 CFR 50.59.
The key objectives of a test program (Reference 2) are to: a. Ensure that the facility has been adequately designed;
: b. Validate the analytical models used in design and analysis;
: b. Validate the analytical models used in design and analysis;
: c. Verify assumptions used for predicting plant response;
: c. Verify assumptions used for predicting plant response;
: d. Ensure that installation of equipment in the facility has been accomplished in accordance with the design;  
: d. Ensure that installation of equipment in the facility has been accomplished in accordance with the design; and
 
: e. Verify that operating and emergency procedures are adequate.
and  e. Verify that operating and emergency procedures are adequate.  
To accomplish these objectives, testing is required prior to initial criticality, after each refueling shutdown, and during startup, low power operation, power ascension, and at power operation. The PHYSICS TESTS requirements for reload fuel cycles ensure that the operating characteristics of the core are consistent with the design predictions, and that the core can be operated as designed (Reference 3, Section 13.4).
 
PHYSICS TESTS procedures are written and approved in accordance with an established process. The procedures CALVERT CLIFFS - UNITS 1 & 2       B 3.1.7-1                        Revision 2
To accomplish these objectives, testing is required prior to initial criticality, after each refueling shutdown, and  
 
during startup, low power operation, power ascension, and at  
 
power operation. The PHYSICS TESTS requirements for reload  
 
fuel cycles ensure that the operating characteristics of the core are consistent with the design predictions, and that the core can be operated as designed (Reference 3, Section 13.4
).
PHYSICS TESTS' procedures are written and approved in accordance with an established process. The procedures STE-SDM B 3.1.7 BASES  CALVERT CLIFFS - UNITS 1 & 2 B 3.1.7-2 Revision 2 include all information necessary to permit a detailed execution of testing required to ensure that the design
 
intent is met. PHYSICS TESTS are performed in accordance
 
with these procedures, and test results are independently
 
reviewed prior to continued power escalation and long- term
 
power operation. Examples of PHYSICS TESTS include determination of critical boron concentration, CEA group worths, reactivity coefficients, flux symmetry, and core power distribution.
APPLICABLE It is acceptable to suspend certain LCOs for PHYSICS TESTS SAFETY ANALYSES because fuel damage criteria are not exceeded. Even if an accident occurs during PHYSICS TESTS with one or more LCOs
 
suspended, fuel damage criteria are preserved because
 
adequate limits on power distribution and shutdown
 
capability are maintained during PHYSICS TESTS.
 
Reference 2 defines the requirements for initial testing of the facility, including PHYSICS TESTS. Requirements for
 
reload fuel cycle PHYSICS TESTS are defined in the UFSAR Reference 3, Section 13.4. Although these PHYSICS TESTS are generally accomplished within the limits of all LCOs, conditions may occur when one or more LCOs must be suspended
 
to make completion of PHYSICS TESTS possible or practical. 
 
This is acceptable as long as the fuel design criteria are
 
not violated. As long as the LHR remains within its limit, fuel design criteria are preserved.
 
In this test, the following LCOs are suspended:  a. LCO 3.1.1
; and  b. LCO 3.1.6. Therefore, this LCO places limits on the minimum amount of CEA worth required to be available for reactivity control
 
when CEA worth measurements are performed.


STE-SDM B 3.1.7 BASES include all information necessary to permit a detailed execution of testing required to ensure that the design intent is met. PHYSICS TESTS are performed in accordance with these procedures, and test results are independently reviewed prior to continued power escalation and long- term power operation. Examples of PHYSICS TESTS include determination of critical boron concentration, CEA group worths, reactivity coefficients, flux symmetry, and core power distribution.
APPLICABLE        It is acceptable to suspend certain LCOs for PHYSICS TESTS SAFETY ANALYSES  because fuel damage criteria are not exceeded. Even if an accident occurs during PHYSICS TESTS with one or more LCOs suspended, fuel damage criteria are preserved because adequate limits on power distribution and shutdown capability are maintained during PHYSICS TESTS.
Reference 2 defines the requirements for initial testing of the facility, including PHYSICS TESTS. Requirements for reload fuel cycle PHYSICS TESTS are defined in the UFSAR Reference 3, Section 13.4. Although these PHYSICS TESTS are generally accomplished within the limits of all LCOs, conditions may occur when one or more LCOs must be suspended to make completion of PHYSICS TESTS possible or practical.
This is acceptable as long as the fuel design criteria are not violated. As long as the LHR remains within its limit, fuel design criteria are preserved.
In this test, the following LCOs are suspended:
: a. LCO 3.1.1; and
: b. LCO 3.1.6.
Therefore, this LCO places limits on the minimum amount of CEA worth required to be available for reactivity control when CEA worth measurements are performed.
The individual LCOs cited above govern SDM CEA group height, insertion, and alignment. Additionally, the LCOs governing RCS flow, reactor inlet temperature, and pressurizer pressure contribute to maintaining DNB parameter limits.
The individual LCOs cited above govern SDM CEA group height, insertion, and alignment. Additionally, the LCOs governing RCS flow, reactor inlet temperature, and pressurizer pressure contribute to maintaining DNB parameter limits.
The initial condition criteria for accidents sensitive to  
The initial condition criteria for accidents sensitive to core power distribution are preserved by the LHR and DNB CALVERT CLIFFS - UNITS 1 & 2       B 3.1.7-2                         Revision 2
 
core power distribution are preserved by the LHR and DNB STE-SDM B 3.1.7 BASES  CALVERT CLIFFS - UNITS 1 & 2 B 3.1.7-3 Revision 43 parameter limits. The criteria for the LOCA are specified in Reference 2, 10 CFR 50.46. The criteria for the loss of
 
forced reactor coolant flow accident are specified in
 
Reference 3, Chapter 14. Operation within the LHR limit
 
preserves the LOCA criteria; operation within the DNB
 
parameter limits preserves the loss of flow criteria.
 
Surveillance tests are conducted as necessary to ensure that LHR and DNB parameters remain within limits during PHYSICS
 
TESTS. Performance of these SRs allows PHYSICS TESTS to be
 
conducted without decreasing the margin of safety.
 
Requiring that shutdown reactivity equivalent to at least the highest estimated CEA worth (of those CEAs actually
 
withdrawn) be available for trip insertion from the OPERABLE
 
CEA provides a high degree of assurance that shutdown
 
capability is maintained for the most challenging postulated
 
accident, a stuck CEA. When LCO 3.1.1 is suspended, there
 
is not the same degree of assurance during this test that
 
the reactor would always be shut down if the highest worth
 
CEA was stuck out and calculational uncertainties or the
 
estimated highest CEA worth was not as expected (the single
 
failure criterion is not met). This situation is judged
 
acceptable, however, because SAFDLs are still met. The risk
 
of experiencing a stuck CEA and subsequent criticality is
 
reduced during this PHYSICS TESTS exception by the
 
Surveillance Requirements; and by ensuring that shutdown
 
reactivity is available, equivalent to the reactivity worth
 
of the estimated highest worth withdrawn CEA (Reference 3, Chapter 3).
 
PHYSICS TESTS include measurement of core parameters or exercise of control components that affect process
 
variables. Among the process variables involved are total integrated radial peaking factor, T q and ASI, which represent initial condition input (power peaking) to the
 
accident analysis. Also involved are the shutdown and
 
regulating CEAs, which affect power peaking and are required
 
for shut down of the reactor. The limits for these
 
variables are specified for each fuel cycle in the COLR.
 
As described in LCO 3.0.7, compliance with STE LCOs is optional and , therefore
, no criteria of 10 CFR STE-SDM B 3.1.7 BASES  CALVERT CLIFFS - UNITS 1 & 2 B 3.1.7-4 Revision 43 50.36(c)(2)(ii) apply. Special Test Exception LCOs provide flexibility to perform certain operations by appropriately
 
modifying requirements of other LCOs. A discussion of the
 
criteria satisfied for the other LCOs is provided in their respective Bases.
LCO This LCO provides that a minimum amount of CEA worth is immediately available for reactivity control when CEA worth
 
measurement tests are performed. The STE is required to
 
permit the periodic verification of the actual versus
 
predicted worth of the regulating and shutdown CEAs. The
 
SDM requirements of LCO 3.1.1, the shutdown CEA insertion


limits of LCO 3.1.5, and the regulating CEA insertion limits of LCO 3.1.6 may be suspended.
STE-SDM B 3.1.7 BASES parameter limits. The criteria for the LOCA are specified in Reference 2, 10 CFR 50.46. The criteria for the loss of forced reactor coolant flow accident are specified in Reference 3, Chapter 14. Operation within the LHR limit preserves the LOCA criteria; operation within the DNB parameter limits preserves the loss of flow criteria.
APPLICABILITY This LCO is applicable in MODEs 2 and 3. Although CEA worth testing is conducted in MODE 2, sufficient negative
Surveillance tests are conducted as necessary to ensure that LHR and DNB parameters remain within limits during PHYSICS TESTS. Performance of these SRs allows PHYSICS TESTS to be conducted without decreasing the margin of safety.
Requiring that shutdown reactivity equivalent to at least the highest estimated CEA worth (of those CEAs actually withdrawn) be available for trip insertion from the OPERABLE CEA provides a high degree of assurance that shutdown capability is maintained for the most challenging postulated accident, a stuck CEA. When LCO 3.1.1 is suspended, there is not the same degree of assurance during this test that the reactor would always be shut down if the highest worth CEA was stuck out and calculational uncertainties or the estimated highest CEA worth was not as expected (the single failure criterion is not met). This situation is judged acceptable, however, because SAFDLs are still met. The risk of experiencing a stuck CEA and subsequent criticality is reduced during this PHYSICS TESTS exception by the Surveillance Requirements; and by ensuring that shutdown reactivity is available, equivalent to the reactivity worth of the estimated highest worth withdrawn CEA (Reference 3, Chapter 3).
PHYSICS TESTS include measurement of core parameters or exercise of control components that affect process variables. Among the process variables involved are total integrated radial peaking factor, Tq and ASI, which represent initial condition input (power peaking) to the accident analysis. Also involved are the shutdown and regulating CEAs, which affect power peaking and are required for shut down of the reactor. The limits for these variables are specified for each fuel cycle in the COLR.
As described in LCO 3.0.7, compliance with STE LCOs is optional and, therefore, no criteria of 10 CFR CALVERT CLIFFS - UNITS 1 & 2       B 3.1.7-3                      Revision 43


reactivity is inserted during the performance of these tests  
STE-SDM B 3.1.7 BASES 50.36(c)(2)(ii) apply. Special Test Exception LCOs provide flexibility to perform certain operations by appropriately modifying requirements of other LCOs. A discussion of the criteria satisfied for the other LCOs is provided in their respective Bases.
 
LCO              This LCO provides that a minimum amount of CEA worth is immediately available for reactivity control when CEA worth measurement tests are performed. The STE is required to permit the periodic verification of the actual versus predicted worth of the regulating and shutdown CEAs. The SDM requirements of LCO 3.1.1, the shutdown CEA insertion limits of LCO 3.1.5, and the regulating CEA insertion limits of LCO 3.1.6 may be suspended.
to result in temporary entry into MODE 3. Because the  
APPLICABILITY    This LCO is applicable in MODEs 2 and 3. Although CEA worth testing is conducted in MODE 2, sufficient negative reactivity is inserted during the performance of these tests to result in temporary entry into MODE 3. Because the intent is to immediately return to MODE 2 to continue CEA worth measurements, the STE allows limited operation to 6 consecutive hours in MODE 3, as indicated by the Note, without having to borate to meet the SDM requirements of LCO 3.1.1.
 
ACTIONS           A.1 With any CEA not fully inserted and less than the minimum required reactivity equivalent available for insertion, or with all CEAs inserted and the reactor subcritical by less than the reactivity equivalent of the highest worth CEA, restoration of the minimum SDM requirements must be accomplished by increasing the RCS boron concentration. The boration flow rate shall be  40 gpm and the boron concentration shall be  2300 ppm boric acid solution or equivalent. The required Completion Time of immediately is required to meet the assumptions of the safety analysis. It is assumed that boration will be continued until the SDM requirements are met.
intent is to immediately return to MODE 2 to continue CEA  
CALVERT CLIFFS - UNITS 1 & 2       B 3.1.7-4                      Revision 43
 
worth measurements, the STE allows limited operation to  
 
6 consecutive hours in MODE 3, as indicated by the Note, without having to borate to meet the SDM requirements of LCO 3.1.1.
ACTIONS A.1 With any CEA not fully inserted and less than the minimum required reactivity equivalent available for insertion, or  
 
with all CEAs inserted and the reactor subcritical by less  
 
than the reactivity equivalent of the highest worth CEA, restoration of the minimum SDM requirements must be  
 
accomplished by increasing the RCS boron concentration. The boration flow rate shall be  40 gpm and the boron concentration shall be  2300 ppm boric acid solution or equivalent. The required Completion Time of immediately is required to meet the assumptions of the safety analysis. It  
 
is assumed that boration will be continued until the SDM requirements are met.
STE-SDM B 3.1.7 BASES  CALVERT CLIFFS - UNITS 1 & 2 B 3.1.7-5 Revision 11 SURVEILLANCE SR 3.1.7.1 REQUIREMENTS Verification of the position of each partially or fully withdrawn full-length or part-length CEA is necessary to
 
ensure that the minimum negative reactivity requirements for insertion on a trip are preserved. A 2-hour Frequency is sufficient for the operator to verify that each CEA position
 
is within the acceptance criteria.
 
SR 3.1.7.2 Prior demonstration that each CEA to be withdrawn from the
 
core during PHYSICS TESTS is capable of full insertion, when
 
tripped from at least a 50% withdrawn position, ensures that
 
the CEA will insert on a trip signal. The Frequency ensures
 
that the CEAs are OPERABLE prior to reducing SDM to less
 
than the limits of LCO 3.1.1.


STE-SDM B 3.1.7 BASES SURVEILLANCE      SR 3.1.7.1 REQUIREMENTS Verification of the position of each partially or fully withdrawn full-length or part-length CEA is necessary to ensure that the minimum negative reactivity requirements for insertion on a trip are preserved. A 2-hour Frequency is sufficient for the operator to verify that each CEA position is within the acceptance criteria.
SR 3.1.7.2 Prior demonstration that each CEA to be withdrawn from the core during PHYSICS TESTS is capable of full insertion, when tripped from at least a 50% withdrawn position, ensures that the CEA will insert on a trip signal. The Frequency ensures that the CEAs are OPERABLE prior to reducing SDM to less than the limits of LCO 3.1.1.
The SR is modified by a Note that allows the SR to not be performed during initial power escalation following a refueling outage if SR 3.1.4.6 has been met during that refueling outage. This allows the CEA drop time test, which also proves the CEAs are trippable, to be credited for this SR.
The SR is modified by a Note that allows the SR to not be performed during initial power escalation following a refueling outage if SR 3.1.4.6 has been met during that refueling outage. This allows the CEA drop time test, which also proves the CEAs are trippable, to be credited for this SR.
REFERENCES 1. 10 CFR Part 50
REFERENCES       1. 10 CFR Part 50
: 2. Regulatory Guide 1.68, Revision 2, "Initial Test Programs for Water-Cooled Nuclear Power Plants," August 1978 3. UFSAR  
: 2. Regulatory Guide 1.68, Revision 2, Initial Test Programs for Water-Cooled Nuclear Power Plants,"
August 1978
: 3. UFSAR CALVERT CLIFFS - UNITS 1 & 2      B 3.1.7-5                      Revision 11


STE-MODEs 1 and 2 B 3.1.8 B 3.1 REACTIVITY CONTROL SYSTEMS B 3.1.8 Special Test Exceptions (STE)-
STE-MODEs 1 and 2 B 3.1.8 B 3.1   REACTIVITY CONTROL SYSTEMS B 3.1.8   Special Test Exceptions (STE)-MODEs 1 and 2 BASES BACKGROUND         The primary purpose of these MODEs 1 and 2 STEs is to permit relaxation of existing LCOs to allow the performance of certain PHYSICS TESTS. These tests are conducted to determine specific reactor core characteristics.
MODEs 1 and 2 BASES CALVERT CLIFFS - UNITS 1 & 2 B 3.1.8-1 Revision 2 BACKGROUND The primary purpose of these MODEs 1 and 2 STEs is to permit relaxation of existing LCOs to allow the performance of certain PHYSICS TESTS. These tests are conducted to  
Reference 1, Appendix B, Section XI requires that a test program be established to ensure that structures, systems, and components will perform satisfactorily in service. All functions necessary to ensure that specified design conditions are not exceeded during normal operation and AOOs must be tested. Testing is required as an integral part of the design, fabrication, construction, and operation of the power plant. Requirements for notification of the Nuclear Regulatory Commission, for the purpose of conducting tests and experiments, are specified in Reference 1, 10 CFR 50.59.
 
The key objectives of a test program (Reference 2) are to:
determine specific reactor core characteristics.  
: a. Ensure that the facility has been adequately designed;
 
R eference 1 , Appendix B, Section XI requires that a test program be established to ensure that structures, systems, and components will perform satisfactorily in service. All  
 
functions necessary to ensure that specified design  
 
conditions are not exceeded during normal operation and AOOs must be tested. Testing is required as an integral part of  
 
the design, fabrication, construction, and operation of the  
 
power plant. Requirements for notification of the Nuclear  
 
Regulatory Commission, for the purpose of conducting tests  
 
and experiments, are specified in Reference 1, 10 CFR 50.59.
The key objectives of a test program (Reference 2) are to: a. Ensure that the facility has been adequately designed;
: b. Validate the analytical models used in design and analysis;
: b. Validate the analytical models used in design and analysis;
: c. Verify assumptions used for predicting plant response;
: c. Verify assumptions used for predicting plant response;
: d. Ensure that installation of equipment in the facility has been accomplished in accordance with design; and e. Verify that operating and emergency procedures are adequate.  
: d. Ensure that installation of equipment in the facility has been accomplished in accordance with design; and
 
: e. Verify that operating and emergency procedures are adequate.
To accomplish these objectives, testing is required prior to initial criticality, after each refueling shutdown, and  
To accomplish these objectives, testing is required prior to initial criticality, after each refueling shutdown, and during startup, low power operation, power ascension, and at power operation. The PHYSICS TESTS requirements for reload fuel cycles ensure that the operating characteristics of the core are consistent with the design predictions, and that the core can be operated as designed (Reference 3, Section 13.4).
 
PHYSICS TESTS procedures are written and approved in accordance with established formats. The procedures include all information necessary to permit a detailed execution of CALVERT CLIFFS - UNITS 1 & 2       B 3.1.8-1                        Revision 2
during startup, low power operation, power ascension, and at  
 
power operation. The PHYSICS TESTS requirements for reload  
 
fuel cycles ensure that the operating characteristics of the  
 
core are consistent with the design predictions, and that the core can be operated as designed (Reference 3, Section 13.4
). PHYSICS TESTS procedures are written and approved in accordance with established formats. The procedures include  
 
all information necessary to permit a detailed execution of STE-MODEs 1 and 2 B 3.1.8 BASES  CALVERT CLIFFS - UNITS 1 & 2 B 3.1.8-2 Revision 43 testing required to ensure that design intent is met.
PHYSICS TESTS are performed in accordance with these
 
procedures and test results are approved prior to continued
 
power escalation and long-term power operation.


STE-MODEs 1 and 2 B 3.1.8 BASES testing required to ensure that design intent is met.
PHYSICS TESTS are performed in accordance with these procedures and test results are approved prior to continued power escalation and long-term power operation.
Examples of PHYSICS TESTS include determination of critical boron concentration, CEA group worths, reactivity coefficients, flux symmetry, and core power distribution.
Examples of PHYSICS TESTS include determination of critical boron concentration, CEA group worths, reactivity coefficients, flux symmetry, and core power distribution.
APPLICABLE It is acceptable to suspend certain LCOs for PHYSICS TESTS SAFETY ANALYSES because fuel damage criteria are not exceeded. Even if an accident occurs during a PHYSICS TESTS with one or more LCOs  
APPLICABLE       It is acceptable to suspend certain LCOs for PHYSICS TESTS SAFETY ANALYSES   because fuel damage criteria are not exceeded. Even if an accident occurs during a PHYSICS TESTS with one or more LCOs suspended, fuel damage criteria are preserved because the limits on power distribution and shutdown capability are maintained during PHYSICS TESTS.
Reference 3, Section 13.4 defines the requirements for initial testing of the facility, including PHYSICS TESTS.
Although these PHYSICS TESTS are generally accomplished within the limits of all LCOs, conditions may occur when one or more LCO must be suspended to make completion of PHYSICS TESTS possible or practical. This is acceptable as long as the fuel design criteria are not violated. As long as the LHR remains within its limit, fuel design criteria are preserved.
In this test, the following LCOs are suspended: LCO 3.1.3; LCO 3.1.4; LCO 3.1.5; LCO 3.1.6; LCO 3.2.3; and LCO 3.2.4.
The safety analysis (Reference 3, Section 13.4) places limits on allowable THERMAL POWER during PHYSICS TESTS and requires the LHR and the DNB parameter to be maintained within limits.
The individual LCOs governing CEA group height, insertion and alignment, ASI, F Tr , and Tq preserve the LHR limits.
Additionally, the LCOs governing RCS flow, reactor inlet temperature (Tc), and pressurizer pressure contribute to maintaining DNB parameter limits. The initial condition criteria for accidents sensitive to core power distribution are preserved by the LHR and DNB parameter limits. The criteria for the LOCA are specified in Reference 1, 10 CFR 50.46. The criteria for the loss of forced reactor CALVERT CLIFFS - UNITS 1 & 2      B 3.1.8-2                          Revision 43


suspended, fuel damage criteria are preserved because the
STE-MODEs 1 and 2 B 3.1.8 BASES coolant flow accident are specified in Reference 1, 10 CFR 50.46. Operation within the LHR limit preserves the LOCA criteria; operation within the DNB parameter limits preserves the loss of flow criteria.
 
During PHYSICS TESTS, one or more of the LCOs that normally preserve the LHR and DNB parameter limits may be suspended.
limits on power distribution and shutdown capability are
The results of the accident analysis are not adversely impacted, however, if LHR and DNB parameters are verified to be within their limits while the LCOs are suspended.
 
Therefore, SRs are placed as necessary to ensure that LHR and DNB parameters remain within limits during PHYSICS TESTS. Performance of these SRs allows PHYSICS TESTS to be conducted without decreasing the margin of safety.
maintained during PHYSICS TESTS.
PHYSICS TESTS include measurement of core parameters or exercise of control components that affect process variables. Among the process variables involved are F Tr , Tq, and ASI, which represent initial condition input (power peaking) to the accident analysis. Also involved are the shutdown and regulating CEAs, which affect power peaking and are required for shut down of the reactor. The limits for these variables are specified for each fuel cycle in the COLR.
 
As described in LCO 3.0.7, compliance with STE LCOs is optional and, therefore, no criteria of 10 CFR 50.36(c)(2)(ii) apply. Special Test Exception LCOs provide flexibility to perform certain operations by appropriately modifying requirements of other LCOs. A discussion of the criteria satisfied for the other LCOs is provided in their respective Bases.
Reference 3, Section 13.4 defines the requirements for initial testing of the facility, including PHYSICS TESTS. 
LCO              This LCO permits individual CEAs to be positioned outside of their normal group heights and insertion limits during the performance of PHYSICS TESTS, such as those required to:
 
: a. Measure CEA worth;
Although these PHYSICS TESTS are generally accomplished
: b. Determine the reactor stability index and damping factor under xenon oscillation conditions;
 
: c. Determine power distributions for nonnormal CEA configurations; CALVERT CLIFFS - UNITS 1 & 2      B 3.1.8-3                      Revision 43
within the limits of all LCOs, conditions may occur when one
 
or more LCO must be suspended to make completion of PHYSICS
 
TESTS possible or practical. This is acceptable as long as
 
the fuel design criteria are not violated. As long as the
 
LHR remains within its limit, fuel design criteria are
 
preserved.
 
In this test, the following LCOs are suspended:  LCO 3.1.3; LCO 3.1.4; LCO 3.1.5; LCO 3.1.6; LCO 3.2.3; and LCO 3.2.4.
 
The safety analysis (Reference 3, Section 13.4) places limits on allowable THERMAL POWER during PHYSICS TESTS and
 
requires the LHR and the DNB parameter to be maintained
 
within limits.
 
The individual LCOs governing CEA group height, insertion and alignment, ASI, r T F , and T q preserve the LHR limits.
Additionally, the LCOs governing RCS flow, reactor inlet
 
temperature (T c), and pressurizer pressure contribute to maintaining DNB parameter limits. The initial condition
 
criteria for accidents sensitive to core power distribution are preserved by the LHR and DNB parameter limits. The criteria for the LOCA are specified in Reference 1, 10 CFR 50.46. The criteria for the loss of forced reactor STE-MODEs 1 and 2 B 3.1.8 BASES CALVERT CLIFFS - UNITS 1 & 2 B 3.1.8-3 Revision 43 coolant flow accident are specified in Reference 1, 10 CFR 50.46. Operation within the LHR limit preserves the  
 
LOCA criteria; operation within the DNB parameter limits  
 
preserves the loss of flow criteria.  
 
During PHYSICS TESTS, one or more of the LCOs that normally preserve the LHR and DNB parameter limits may be suspended.
 
The results of the accident analysis are not adversely  
 
impacted, however, if LHR and DNB parameters are verified to  


be within their limits while the LCOs are suspended. 
STE-MODEs 1 and 2 B 3.1.8 BASES
 
Therefore, SRs are placed as necessary to ensure that LHR
 
and DNB parameters remain within limits during PHYSICS
 
TESTS. Performance of these SRs allows PHYSICS TESTS to be
 
conducted without decreasing the margin of safety.
 
PHYSICS TESTS include measurement of core parameters or exercise of control components that affect process variables. Among the process variables involved are r T F , T q , and ASI, which represent initial condition input (power peaking) to the accident analysis. Also involved are the
 
shutdown and regulating CEAs, which affect power peaking and
 
are required for shut down of the reactor. The limits for
 
these variables are specified for each fuel cycle in the
 
COLR.
As described in LCO 3.0.7, compliance with STE LCOs is optional and, therefore, no criteria of 10 CFR
 
50.36(c)(2)(ii) apply. Special Test Exception LCOs provide
 
flexibility to perform certain operations by appropriately
 
modifying requirements of other LCOs. A discussion of the
 
criteria satisfied for the other LCOs is provided in their respective Bases.
LCO This LCO permits individual CEAs to be positioned outside of their normal group heights and insertion limits during the
 
performance of PHYSICS TESTS, such as those required to:
: a. Measure CEA worth;
: b. Determine the reactor stability index and damping factor under xenon oscillation conditions;  c. Determine power distributions for nonnormal CEA configurations; STE-MODEs 1 and 2 B 3.1.8 BASES CALVERT CLIFFS - UNITS 1 & 2 B 3.1.8-4 Revision 43
: d. Measure rod shadowing factors; and
: d. Measure rod shadowing factors; and
: e. Measure temperature and power coefficients.
: e. Measure temperature and power coefficients.
The requirements of LCO 3.1.3, LCO 3.1.4, LCO 3.1.5, LCO 3.1.6, LCO 3.2.3, and LCO 3.2.4 may be suspended during the performance of PHYSICS TESTS, provided THERMAL POWER is restricted to test power plateau, which shall not exceed  
The requirements of LCO 3.1.3, LCO 3.1.4, LCO 3.1.5, LCO 3.1.6, LCO 3.2.3, and LCO 3.2.4 may be suspended during the performance of PHYSICS TESTS, provided THERMAL POWER is restricted to test power plateau, which shall not exceed 85% RTP.
 
APPLICABILITY     This LCO is applicable in MODEs 1 and 2 because the reactor must be critical at various THERMAL POWER levels to perform the PHYSICS TESTS described in the LCO section. Limiting the test power plateau to < 85% RTP ensures that LHRs are maintained within acceptable limits.
85% RTP. APPLICABILITY This LCO is applicable in MODEs 1 and 2 because the reactor must be critical at various THERMAL POWER levels to perform  
ACTIONS           A.1 If THERMAL POWER exceeds the test power plateau, THERMAL POWER must be reduced to restore the additional thermal margin provided by the reduction. The 15-minute Completion Time ensures that prompt action shall be taken to reduce THERMAL POWER to within acceptable limits.
 
B.1 and B.2 If Required Action A.1 cannot be completed within the required Completion Time, PHYSICS TESTS must be suspended within 1 hour, and the reactor must be brought to MODE 3.
the PHYSICS TESTS described in the LCO section. Limiting  
Allowing 1 hour for suspending PHYSICS TESTS allows the operator sufficient time to change any abnormal CEA configuration back to within the limits of LCO 3.1.4, LCO 3.1.5, and LCO 3.1.6. Bringing the reactor to MODE 3 within 6 hours increases thermal margin and is consistent with the Required Actions of the power distribution LCOs.
 
The required Completion Time of 6 hours is adequate for performing a controlled shutdown from full power conditions in an orderly manner and without challenging plant systems, and is consistent with power distribution LCO Completion Times.
the test power plateau to < 85% RTP ensures that LHRs are maintained within acceptable limits.
CALVERT CLIFFS - UNITS 1 & 2       B 3.1.8-4                      Revision 43
ACTIONS A.1 If THERMAL POWER exceeds the test power plateau, THERMAL  
 
POWER must be reduced to restore the additional thermal  
 
margin provided by the reduction. The 15-minute Completion  
 
Time ensures that prompt action shall be taken to reduce  
 
THERMAL POWER to within acceptable limits.  
 
B.1 and B.2 If Required Action A.1 cannot be completed within the  
 
required Completion Time, PHYSICS TESTS must be suspended within 1 hour, and the reactor must be brought to MODE 3.
Allowing 1 hour for suspending PHYSICS TESTS allows the  
 
operator sufficient time to change any abnormal CEA  
 
configuration back to within the limits of LCO 3.1.4, LCO 3.1.5, and LCO 3.1.6. Bringing the reactor to MODE 3  
 
within 6 hours increases thermal margin and is consistent  
 
with the Required Actions of the power distribution LCOs.
 
The required Completion Time of 6 hours is adequate for  
 
performing a controlled shutdown from full power conditions  
 
in an orderly manner and without challenging plant systems, and is consistent with power distribution LCO Completion Times.
STE-MODEs 1 and 2 B 3.1.8 BASES  CALVERT CLIFFS - UNITS 1 & 2 B 3.1.8-5 Revision 2 SURVEILLANCE SR 3.1.8.1 REQUIREMENTS  Verifying that THERMAL POWER is equal to or less than that allowed by the test power plateau, as specified in the


PHYSICS TESTS procedure and required by the safety analysis, ensures that adequate LHR and DNB parameter margins are maintained while LCOs are suspended. The 1
STE-MODEs 1 and 2 B 3.1.8 BASES SURVEILLANCE      SR 3.1.8.1 REQUIREMENTS Verifying that THERMAL POWER is equal to or less than that allowed by the test power plateau, as specified in the PHYSICS TESTS procedure and required by the safety analysis, ensures that adequate LHR and DNB parameter margins are maintained while LCOs are suspended. The 1- hour Frequency is sufficient, based on the slow rate of power change and increased operational controls in place during PHYSICS TESTS.
- hour Frequency is sufficient, based on the slow rate of power change and increased operational controls in place during PHYSICS TESTS. REFERENCES 1. 10 CFR Part 50
REFERENCES       1. 10 CFR Part 50
: 2. Regulatory Guide 1.68, Revision 2, "Initial Test Programs for Water-Cooled Nuclear Power Plants," August 1978
: 2. Regulatory Guide 1.68, Revision 2, Initial Test Programs for Water-Cooled Nuclear Power Plants,"
: 3. UFSAR}}
August 1978
: 3. UFSAR CALVERT CLIFFS - UNITS 1 & 2      B 3.1.8-5                        Revision 2}}

Latest revision as of 00:00, 4 November 2019

B 3.1.1-1, Reactivity Control Systems Through B 3.1.8-5, STE-Modes 1 and 2
ML14267A226
Person / Time
Site: Calvert Cliffs  Constellation icon.png
Issue date: 09/19/2014
From:
Calvert Cliffs, Exelon Generation Co
To:
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Download: ML14267A226 (50)


Text

SDM B 3.1.1 B 3.1 REACTIVITY CONTROL SYSTEMS B 3.1.1 SHUTDOWN MARGIN (SDM)

BASES BACKGROUND The reactivity control systems must be redundant and capable of holding the reactor core subcritical when shut down under cold conditions, in accordance with Reference 1, Appendix 1C, Criteria 27, 29, and 30. Maintenance of the SDM ensures that postulated reactivity events will not damage the fuel. SHUTDOWN MARGIN requirements provide sufficient reactivity margin to ensure that acceptable fuel design limits will not be exceeded for normal shutdown and anticipated operational occurrences (AOOs). As such, the SDM defines the degree of subcriticality that would be obtained immediately following the insertion of all control element assemblies (CEAs), assuming the single CEA of highest reactivity worth is fully withdrawn.

The system design requires that two independent reactivity control systems be provided, and that one of these systems be capable of maintaining the core subcritical under cold conditions. These requirements are provided by the use of movable CEAs and soluble boric acid in the Reactor Coolant System (RCS). The CEA System provides the SDM during power operation and is capable of making the core subcritical rapidly enough to prevent exceeding acceptable fuel damage limits, assuming that the CEA of highest reactivity worth remains fully withdrawn.

The soluble boron system can compensate for fuel depletion during operation and all xenon burnout reactivity changes, and maintain the reactor subcritical under cold conditions.

During power operation, SDM control is ensured by operating with the shutdown CEAs fully withdrawn and the regulating CEAs within the limits of Limiting Condition for Operation (LCO) 3.1.6. When the unit is in the shutdown and refueling MODEs, the SDM requirements are met by means of adjustments to the RCS boron concentration.

APPLICABLE The minimum required SDM is assumed as an initial condition SAFETY ANALYSIS in safety analysis. The safety analysis (Reference 1, Section 3.4) establishes a SDM that ensures specified acceptable fuel design limits (SAFDLs) are not exceeded for CALVERT CLIFFS - UNITS 1 & 2 B 3.1.1-1 Revision 2

SDM B 3.1.1 BASES normal operation and AOOs, with the assumption of the highest worth CEA stuck out following a reactor trip. For MODE 5, the primary safety analysis that relies on the SDM limit is the boron dilution analysis.

The acceptance criteria for the SDM requirements are that SAFDLs are maintained. This is done by ensuring that:

a. The reactor can be made subcritical from all operating conditions, transients, and Design Basis Events;
b. The reactivity transients associated with postulated accident conditions are controllable within acceptable limits (departure from nucleate boiling ratio [DNBR],

fuel centerline temperature limit AOOs, and an acceptable energy deposition for the CEA ejection accident [Reference 1, Chapter 14]); and

c. The reactor will be maintained sufficiently subcritical to preclude inadvertent criticality in the shutdown condition.

The most limiting accident for the SDM requirements are based on a main steam line break (MSLB) or an Excess Load event (with failure of an MSIV to close), as described in the accident analysis (Reference 1, Chapter 14). The increased steam flow causes an increased energy removal from the affected steam generator, and consequently the RCS.

This results in a reduction of the reactor coolant temperature. The resultant coolant shrinkage causes a reduction in pressure. In the presence of a negative moderator temperature coefficient (MTC), this cooldown causes an increase in core reactivity. As RCS temperature decreases, the severity of the event decreases. The most limiting MSLB, with respect to potential fuel damage before a reactor trip occurs, is a guillotine break of a main steam line outside containment, initiated at the end of core life.

Following the MSLB or Excess Load event, a post-trip return to power may occur; however, no fuel damage occurs as a result of the post-trip return to power, and THERMAL POWER does not violate the Safety Limit (SL) requirement of SL 2.1.1. The limiting Excess Load event with respect to potential return-to-power after reactor trip is the opening of all steam dump and bypass valves at full power with failure of an MSIV to close.

CALVERT CLIFFS - UNITS 1 & 2 B 3.1.1-2 Revision 43

SDM B 3.1.1 BASES In addition to the limiting MSLB transient, the SDM requirement for MODEs 3 and 4 must also protect against an uncontrolled CEA withdrawal from a hot zero power or low power condition, and a CEA ejection.

In the boron dilution analysis, the required SDM defines the reactivity difference between an initial subcritical boron concentration and the corresponding critical boron concentration. These values, in conjunction with the configuration of the RCS and the assumed dilution flow rate, directly affect the results of the analysis. This event is most limiting at the beginning of core life when critical boron concentrations are highest.

The withdrawal of CEAs from hot zero power or low power conditions adds reactivity to the reactor core, causing both the core power level and heat flux to increase with corresponding increases in reactor coolant temperatures and pressure. The withdrawal of CEAs also produces a time-dependent redistribution of core power.

The uncontrolled CEA withdrawal transient is terminated by the Variable High Power Trip. In all cases, power level, RCS pressure, linear heat rate (LHR), and the DNBR do not exceed allowable limits.

SHUTDOWN MARGIN satisfies 10 CFR 50.36(c)(2)(ii),

Criterion 2.

LCO The MSLB (or the Excess Load event) and the boron dilution accidents (Reference 1, Chapter 14) are the most limiting analyses that establish the SDM value of the LCO. For MSLB accidents (or the Excess Load event), if the LCO is violated, there is a potential to exceed the DNBR limit and to exceed the acceptance criteria given in Reference 1, Chapter 14. For the boron dilution accident, if the LCO is violated, the minimum required time assumed for operator action to terminate dilution may no longer be applicable.

Because both initial RCS level and the dilution flow rate also significantly impact the boron dilution event in MODE 5 with pressurizer level < 90 inches from the bottom of the CALVERT CLIFFS - UNITS 1 & 2 B 3.1.1-3 Revision 43

SDM B 3.1.1 BASES pressurizer, the LCO also includes limits for these parameters during these conditions.

SHUTDOWN MARGIN is a core physics design condition that can be ensured through CEA positioning (regulating and shutdown CEA) in MODEs 1 and 2 and through the soluble boron concentration in all other MODEs.

APPLICABILITY In MODEs 3, 4, and 5, the SDM requirements are applicable to provide sufficient negative reactivity to meet the assumptions of the safety analyses discussed above. In MODEs 1 and 2, SDM is ensured by complying with LCOs 3.1.5 and 3.1.6. In MODE 6, the shutdown reactivity requirements are given in LCO 3.9.1.

ACTIONS A.1, A.2, and A.3 With non-borated water sources of > 88 gpm available, while the unit is in MODE 5 with the pressurizer level

< 90 inches, the consequences of a boron dilution event may exceed the analysis results. Therefore, action must be initiated immediately to reduce the potential for such an event. To accomplish this, Required Action A.1 requires immediate suspension of positive reactivity additions.

However, since Required Action A.1 only reduces the potential for the event and does not eliminate it, immediate action must also be initiated to increase the SDM to compensate for the non-borated water sources (Required Action A.2). Finally, Required Action A.3 requires periodic verification, once per 12 hours1.388889e-4 days <br />0.00333 hours <br />1.984127e-5 weeks <br />4.566e-6 months <br />, that the SDM increase is maintained sufficient to compensate for the additional sources of non-borated water. Required Action A.1 is modified by a Note indicating that the suspension of positive reactivity additions is not required if SDM has been sufficiently increased to compensate for the additional sources of non-borated water. The immediate Completion Time reflects the urgency of the corrective actions. The periodic Completion Time of 12 hours1.388889e-4 days <br />0.00333 hours <br />1.984127e-5 weeks <br />4.566e-6 months <br /> is considered reasonable, based on other administrative controls available and operating experience.

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SDM B 3.1.1 BASES B.1 and B.2 With the RCS level at or below the bottom of the hot leg nozzles, while the unit is in MODE 5 with the pressurizer level < 90 inches, the consequences of a boron dilution event may exceed the analysis results. Therefore, action must be initiated immediately to reduce the potential for such an event. To accomplish this, Required Action B.1 requires immediate suspension of operations involving positive reactivity additions that could result in loss of the required SDM. Suspending positive reactivity additions that could result in failure to meet the minimum SDM limit is required to assure continued safe operation.

Introduction of coolant inventory must be from sources that have boron concentration greater than that required in the RCS for the minimum SDM. This may result in an overall reduction in RCS boron concentration, but provides an acceptable margin to maintaining subcritical operation.

Introduction of temperature changes including temperature increases when operating with a positive MTC must also be evaluated to ensure they do not result in a loss of the required SDM. However, since Required Action B.1 only reduces the potential for the event and does not eliminate it, immediate action must also be initiated to increase the RCS level to above the bottom of the hot leg nozzles (Required Action B.2). The immediate Completion Time reflects the urgency of the corrective actions.

C.1 If the SDM requirements are not met for reasons other than addressed in Condition A or B, boration must be initiated promptly. A Completion Time of immediately is required to meet the assumptions of the safety analysis. It is assumed that boration will be continued until the SDM requirements are met.

In the determination of the required combination of boration flow rate and boron concentration, there is no unique requirement that must be satisfied. Since it is imperative to raise the boron concentration of the RCS as soon as possible, the boron concentration should be a highly concentrated solution, such as that normally found in the boric acid storage tank or the refueling water tank. The CALVERT CLIFFS - UNITS 1 & 2 B 3.1.1-5 Revision 27

SDM B 3.1.1 BASES operator should borate with the best source available for the plant conditions. However, as a minimum, the boration flow rate shall be 40 gpm and the boron concentration shall be 2300 ppm boric acid solution or equivalent.

Assuming that a value of 1% k/k must be recovered and a boration flow rate of 40 gpm from the boric acid storage tank, it is possible to increase the boron concentration of the RCS by 100 ppm in approximately 15 minutes. If an inverse boron worth of 100 ppm/% k/k is assumed, this combination of parameters will increase the SDM by 1% k/k.

These boration parameters of 40 gpm and 100 ppm represent typical values and are provided for the purpose of offering a specific example.

SURVEILLANCE SR 3.1.1.1 REQUIREMENTS SHUTDOWN MARGIN is verified by performing a reactivity balance calculation, considering the listed reactivity effects:

a. RCS boron concentration;
b. CEA positions;
c. RCS average temperature;
d. Fuel burnup based on gross thermal energy generation;
e. Xenon concentration;
f. Samarium concentration; and
g. Isothermal temperature coefficient.

Using the isothermal temperature coefficient accounts for Doppler reactivity in this calculation because the reactor is subcritical and the fuel temperature will be changing at the same rate as the RCS.

The Frequency of 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> is based on the generally slow change in required boron concentration, and also allows sufficient time for the operator to collect the required data, which includes performing a boron concentration analysis, and complete the calculation.

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SDM B 3.1.1 BASES SR 3.1.1.2 and SR 3.1.1.3 These Surveillance Requirements (SRs) periodically verify the significant assumptions of a boron dilution event are maintained. A non-borated water source of 88 gpm allows for only one charging pump to be capable of injection during these conditions since each charging pump is capable of an injection rate of 46 gpm. Each SR is modified by a Note indicating that it is only required when the unit is in MODE 5 with the pressurizer level < 90 inches. Since the applicable conditions for the SR may be attained while already in MODE 5, each SR is provided with a Frequency of once within 1 hour1.157407e-5 days <br />2.777778e-4 hours <br />1.653439e-6 weeks <br />3.805e-7 months <br /> after achieving MODE 5 with pressurizer level < 90 inches. This provides a short period of time to verify compliance after the conditions are attained.

Additionally, each SR must be completed once each 12 hours1.388889e-4 days <br />0.00333 hours <br />1.984127e-5 weeks <br />4.566e-6 months <br /> after the initial verification. The Frequency of 12 hours1.388889e-4 days <br />0.00333 hours <br />1.984127e-5 weeks <br />4.566e-6 months <br /> is considered reasonable, in view of other administrative controls available and operating experience.

REFERENCES 1. Updated Final Safety Analysis Report (UFSAR)

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Reactivity Balance B 3.1.2 B 3.1 REACTIVITY CONTROL SYSTEMS B 3.1.2 Reactivity Balance BASES BACKGROUND According to Reference 1, Appendix 1C, Criteria 27, 29, and 30, reactivity shall be controllable, such that, subcriticality is maintained under cold conditions, and acceptable fuel design limits are not exceeded during normal operation and AOOs. Therefore, reactivity balance is used as a measure of the predicted versus measured core reactivity during power operation. The periodic confirmation of core reactivity is necessary to ensure that Design Basis Accident (DBA) and transient safety analyses remain valid. A large reactivity difference could be the result of unanticipated changes in fuel, CEA worth, or operation at conditions not consistent with those assumed in the predictions of core reactivity, and could potentially result in a loss of SDM or violation of acceptable fuel design limits. Comparing predicted versus measured core reactivity validates the nuclear methods used in the safety analysis and supports the SDM demonstrations (LCO 3.1.1) in ensuring the reactor can be brought safely to cold, subcritical conditions.

When the reactor core is critical or in normal power operation, a reactivity balance exists and the net reactivity is zero. A comparison of predicted and measured reactivity is convenient under such a balance, since parameters are being maintained relatively stable under steady state power conditions. The positive reactivity inherent in the core design is balanced by the negative reactivity of the control components, thermal feedback, neutron leakage, and materials in the core that absorb neutrons, such as burnable absorbers producing zero net reactivity. Excess reactivity can be inferred from the critical boron curve, which provides an indication of the soluble boron concentration in the RCS versus cycle burnup.

Periodic measurement of the RCS boron concentration for comparison with the predicted value with other variables fixed (such as CEA height, temperature, pressure, and power) provides a convenient method of ensuring that core reactivity is within design expectations, and that the calculational models used to generate the safety analysis are adequate.

CALVERT CLIFFS - UNITS 1 & 2 B 3.1.2-1 Revision 2

Reactivity Balance B 3.1.2 BASES In order to achieve the required fuel cycle energy output, the uranium enrichment in the new fuel loading and in the fuel remaining from the previous cycle provides excess positive reactivity beyond that required to sustain steady state operation throughout the cycle. When the reactor is critical at hot full power, the excess positive reactivity is compensated by burnable absorbers (if any), CEAs, whatever neutron poisons (mainly xenon and samarium) are present in the fuel, and the RCS boron concentration.

When the core is producing THERMAL POWER, the fuel is being depleted and excess reactivity is decreasing. As the fuel depletes, the RCS boron concentration is reduced to decrease negative reactivity and maintain constant THERMAL POWER.

The critical boron curve is based on steady state operation at RATED THERMAL POWER (RTP). Therefore, deviations from the predicted critical boron curve may indicate deficiencies in the design analysis, deficiencies in the calculational models, or abnormal core conditions, and must be evaluated.

APPLICABLE Accurate prediction of core reactivity is either an explicit SAFETY ANALYSES or implicit assumption in the accident analysis evaluations.

Most accident evaluations (Reference 1, Section 14.1) are, therefore, dependent upon accurate evaluation of core reactivity. In particular, SDM and reactivity transients, such as CEA withdrawal accidents or CEA ejection accidents, are very sensitive to accurate prediction of core reactivity. These accident analysis evaluations rely on computer codes that have been qualified against available test data, operating plant data, and analytical benchmarks.

Monitoring reactivity balance additionally ensures that the nuclear methods provide an accurate representation of the core reactivity.

Design calculations and safety analyses are performed for each fuel cycle for the purpose of predetermining reactivity behavior and the RCS boron concentration requirements for reactivity control during fuel depletion.

The comparison between measured and predicted initial core reactivity provides a normalization for calculational models used to predict core reactivity. If the measured and CALVERT CLIFFS - UNITS 1 & 2 B 3.1.2-2 Revision 2

Reactivity Balance B 3.1.2 BASES predicted RCS boron concentrations for identical core conditions at beginning-of-cycle (BOC) do not agree, the assumptions used in the reload cycle design analysis or the calculational models used to predict soluble boron requirements may not be accurate. If reasonable agreement between measured and predicted core reactivity exists at BOC, the prediction may be normalized to the measured boron concentration. Thereafter, any significant deviations in the measured boron concentration from the predicted critical boron curve that develop during fuel depletion may be an indication that the calculational model is not adequate for core burnups beyond BOC, or that an unexpected change in core conditions has occurred.

The normalization of predicted RCS boron concentration to the measured value is typically performed after reaching RTP following startup from a refueling outage, with the CEAs in their normal positions for power operation. The normalization is performed at BOC conditions, so that core reactivity relative to predicted values can be continually monitored and evaluated as core conditions change during the cycle.

The reactivity balance satisfies 10 CFR 50.36(c)(2)(ii),

Criterion 2.

LCO The reactivity balance limit is established to ensure plant operation is maintained within the assumptions of the safety analyses. Large differences between actual and predicted core reactivity may indicate that the assumptions of the DBA and transient analyses are no longer valid, or that the uncertainties in the nuclear design methodology are larger than expected. A limit on the reactivity balance of

+/- 1% k/k has been established, based on engineering judgment. A 1% deviation in reactivity from that predicted is larger than expected for normal operation and should, therefore, be evaluated.

When measured core reactivity is within 1% k/k of the predicted value at steady state thermal conditions, the core is considered to be operating within acceptable design limits. Since deviations from the limit are normally detected by comparing predicted and measured steady state CALVERT CLIFFS - UNITS 1 & 2 B 3.1.2-3 Revision 2

Reactivity Balance B 3.1.2 BASES RCS critical boron concentrations, the difference between measured and predicted values would be approximately 100 ppm (depending on the boron worth) before the limit is reached.

These values are well within the uncertainty limits for analysis of boron concentration samples, so that spurious violations of the limit due to uncertainty in measuring the RCS boron concentration are unlikely.

APPLICABILITY The limits on core reactivity must be maintained during MODE 1 because a reactivity balance must exist when the reactor is critical or producing THERMAL POWER. As the fuel depletes, core conditions are changing, and confirmation of the reactivity balance ensures the core is operating as designed. This Specification does not apply in MODE 2 because enough operating margin exists to limit the effects of a reactivity anomaly, and THERMAL POWER is low enough

( 5% RTP) such that reactivity anomalies are unlikely to occur. This Specification does not apply in MODEs 3, 4, and 5 because the reactor is shut down and the reactivity balance is not changing.

In MODE 6, fuel loading results in a continually changing core reactivity. Boron concentration requirements (LCO 3.9.1) ensure that fuel movements are performed within the bounds of the safety analysis. A SDM demonstration is required during the first startup following operations that could have altered core reactivity (e.g., fuel movement, or CEA replacement, or shuffling).

ACTIONS A.1 and A.2 Should an anomaly develop between measured and predicted core reactivity, an evaluation of the core design and safety analysis must be performed. Core conditions are evaluated to determine their consistency with input to design calculations. Measured core and process parameters are evaluated to determine that they are within the bounds of the safety analysis, and safety analysis calculational models are reviewed to verify that they are adequate for representation of the core conditions. The required Completion Time of 7 days is based on the low probability of a DBA occurring during this period, and allows sufficient CALVERT CLIFFS - UNITS 1 & 2 B 3.1.2-4 Revision 2

Reactivity Balance B 3.1.2 BASES time to assess the physical condition of the reactor and to complete the evaluation of the core design and safety analysis.

Following evaluations of the core design and safety analysis, the cause of the reactivity anomaly may be resolved. If the cause of the reactivity anomaly is a mismatch in core conditions at the time of RCS boron concentration sampling, a recalculation of the RCS boron concentration requirements may be performed to demonstrate that core reactivity is behaving as expected. If an unexpected physical change in the condition of the core has occurred, it must be evaluated and corrected, if possible.

If the cause of the reactivity anomaly is in the calculation technique, the calculational models must be revised to provide more accurate predictions. If any of these results are demonstrated, and it is concluded that the reactor core is acceptable for continued operation, the boron letdown curve may be renormalized, and power operation may continue.

If operational restrictions or additional SRs are necessary to ensure the reactor core is acceptable for continued operation, they must be defined.

The required Completion Time of 7 days is adequate for preparing whatever operating restrictions or SRs may be required to allow continued reactor operation.

B.1 If the core reactivity cannot be restored to within the 1% k/k limit, the plant must be brought to a MODE in which the LCO does not apply. To achieve this status, the plant must be brought to at least MODE 2 within 6 hours6.944444e-5 days <br />0.00167 hours <br />9.920635e-6 weeks <br />2.283e-6 months <br />. The allowed Completion Time is reasonable, based on operating experience, for reaching MODE 2 from full power conditions in an orderly manner and without challenging plant systems.

SURVEILLANCE SR 3.1.2.1 REQUIREMENTS Core reactivity is verified by periodic comparisons of measured and predicted RCS boron concentrations. The comparison is made considering that other core conditions are fixed or stable, including CEA position, moderator CALVERT CLIFFS - UNITS 1 & 2 B 3.1.2-5 Revision 2

Reactivity Balance B 3.1.2 BASES temperature, fuel temperature, fuel depletion, xenon concentration, and samarium concentration. The SR is performed prior to entering MODE 1 as an initial check on core conditions and design calculations at BOC and every 31 days after 60 effective full power days (EFPD). The SR is modified by two Notes. The Note in the SR column indicates that the normalization of predicted core reactivity to the measured value may take place within the first 60 EFPD after each fuel loading. This allows sufficient time for core conditions to reach steady state, but prevents operation for a large fraction of the fuel cycle without establishing a benchmark for the design calculations. The required subsequent Frequency of 31 EFPD following the initial 60 EFPD, after entering MODE 1, is acceptable, based on the slow rate of core changes due to fuel depletion and the presence of other indicators (e.g., quadrant power tilt ratio, etc.) for prompt indication of an anomaly. The Frequency Note, "only required after 60 EFPD after each fuel loading," is added to the Frequency column to allow this.

REFERENCES 1. UFSAR CALVERT CLIFFS - UNITS 1 & 2 B 3.1.2-6 Revision 3

MTC B 3.1.3 B 3.1 REACTIVITY CONTROL SYSTEMS B 3.1.3 Moderator Temperature Coefficient (MTC)

BASES BACKGROUND The MTC relates a change in core reactivity to a change in reactor coolant temperature. A positive MTC means that reactivity increases with increasing moderator temperature; conversely, a negative MTC means that reactivity decreases with increasing moderator temperature. The reactor is designed to operate with a negative MTC over a large range of fuel cycle operation. Therefore, a coolant temperature increase will cause a reactivity decrease, so that the coolant temperature tends to return toward its initial value. Reactivity increases that cause a coolant temperature increase will thus be self limiting, and stable power operation will result.

Moderator temperature coefficient values are predicted at selected burnups during the safety evaluation analysis and are confirmed to be acceptable by measurements. Reload cores are designed so that the MTC is less positive than that allowed by the LCO. The actual value of the MTC is dependent on core characteristics, such as fuel loading and reactor coolant soluble boron concentration. The core design may require additional fixed distributed poisons (burnable poison) to yield an MTC at the BOC within the range analyzed in the plant accident analysis. The end-of-cycle (EOC) MTC is also limited by the requirements of the accident analysis. Fuel cycles that are designed to achieve high burnups or that have changes to other characteristics are evaluated to ensure that the MTC does not exceed the EOC limit.

APPLICABLE The acceptance criteria for the specified MTC are:

SAFETY ANALYSES

a. The MTC values must remain within the bounds of those used in the accident analysis (Reference 1, Section 14.2.2); and
b. The MTC must be such that inherently stable power operations result during normal operation and during accidents, such as overheating and overcooling events.

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MTC B 3.1.3 BASES Reference 1, Section 14.1.2 contains analyses of accidents that result in both overheating and overcooling of the reactor core. Moderator temperature coefficient is one of the controlling parameters for core reactivity in these accidents. Both the most positive value and most negative value of the MTC are important to safety, and both values must be bounded. Values used in the analyses consider worst-case conditions, such as very large soluble boron concentrations, to ensure the accident results are bounding.

Accidents that cause core overheating, either by decreased heat removal or increased power production, must be evaluated for results when the MTC is positive. Reactivity accidents that cause increased power production include the CEA withdrawal and CEA ejection transients from either zero or full THERMAL POWER. The limiting overheating event relative to plant response is based on the maximum difference between core power and steam generator heat removal during a transient. The most limiting event with respect to a positive MTC is a CEA ejection accident from full power (Reference 1, Section 14.13).

Accidents that cause core overcooling must be evaluated for results when the MTC is most negative. The event that produces the most rapid cooldown of the RCS, and is therefore the most limiting event with respect to the negative MTC, is a steam line break (SLB) event. Following the reactor trip for the postulated EOC SLB event, the large moderator temperature reduction combined with the large negative MTC may produce reactivity increases that are as much as the shutdown reactivity. When this occurs, a substantial fraction of core power is produced with all CEAs inserted, except the most reactive one, which is assumed withdrawn. Even if the reactivity increase produces slightly subcritical conditions, a large fraction of core power may be produced through the effects of subcritical neutron multiplication.

Moderator temperature coefficient values are bounded in reload safety evaluations assuming steady state conditions at BOC, peak RCS boron, and EOC. A 2/3 core burnup MTC measurement is conducted and the measured value may be CALVERT CLIFFS - UNITS 1 & 2 B 3.1.3-2 Revision 43

MTC B 3.1.3 BASES extrapolated to project the EOC value, in order to confirm reload design predictions.

The MTC satisfies 10 CFR 50.36(c)(2)(ii), Criterion 2.

LCO Limiting Condition for Operation 3.1.3 requires the MTC to be within specified limits of the Core Operating Limits Report (COLR), with the maximum positive limit specified in Figure 3.1.3-1, to ensure the core operates within the assumptions of the accident analysis. During the reload core safety evaluation, the MTC is analyzed to determine that its values remain within the bounds of the original accident analysis during operation. The limit on a positive MTC ensures that core overheating accidents will not violate the accident analysis assumptions. The negative MTC limit for EOC specified in the COLR ensures that core overcooling accidents will not violate the accident analysis assumptions.

Moderator temperature coefficient is a core physics parameter determined by the fuel and fuel cycle design and cannot be easily controlled once the core design is fixed.

During operation, therefore, the LCO can only be ensured through measurement. The surveillance checks at BOC and 2/3 core burnup provide confirmation that the MTC is behaving as anticipated, so that the acceptance criteria are met.

APPLICABILITY In MODE 1, the limits on the MTC must be maintained to ensure that any accident initiated from THERMAL POWER operation will not violate the design assumptions of the accident analysis. In MODE 2, the limits must also be maintained to ensure startup accidents, such as the uncontrolled CEA or group withdrawal, will not violate the assumptions of the accident analysis. In MODEs 3, 4, 5, and 6, this LCO is not applicable, since no DBAs using the MTC as an analysis assumption are initiated from these MODEs. However, the variation of the MTC, with temperature in MODEs 3, 4, and 5 for DBAs initiated in MODEs 1 and 2, is accounted for in the accident analysis. The variation of the MTC, with temperature assumed in the safety analysis, is accepted as valid once the BOC and 2/3 core burnup measurements are used for normalization.

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MTC B 3.1.3 BASES ACTIONS A.1 Moderator temperature coefficient is a function of the fuel and fuel cycle designs, and cannot be controlled directly once the designs have been implemented in the core. If MTC exceeds its limits, the reactor must be placed in MODE 3.

This eliminates the potential for violation of the accident analysis bounds. The associated Completion Time of 6 hours6.944444e-5 days <br />0.00167 hours <br />9.920635e-6 weeks <br />2.283e-6 months <br /> is reasonable, considering the probability of an accident occurring during the time period that would require an MTC value within the LCO limits, and the time for reaching MODE 3 from full power conditions in an orderly manner and without challenging plant systems.

SURVEILLANCE SR 3.1.3.1 and SR 3.1.3.2 REQUIREMENTS The SRs for measurement of the MTC at the beginning and 2/3 core burnup of each fuel cycle provide for confirmation of the limiting MTC values. The MTC varies with boron concentration during fuel cycle operation. The MTC becomes more negative as the RCS boron concentration is reduced.

The requirement for measurement prior to entering MODE 1 after each fuel loading satisfies the confirmatory check on the most positive (least negative) MTC value. The requirement for measurement, within 7 EFPD of initially reaching an equilibrium condition with THERMAL POWER 90%

RTP, and within 7 EFPD of reaching 2/3 core burnup, satisfies the confirmatory check of the most negative MTC value. The 2/3 core burnup measurement is performed at any THERMAL POWER, so that the projected EOC MTC may be evaluated before the reactor actually reaches the EOC condition. Moderator temperature coefficient values may be extrapolated and compensated to permit direct comparison to the specified MTC limits.

Surveillance Requirement 3.1.3.2 is modified by a Note, which indicates that if the extrapolated MTC is more negative than the EOC COLR limit, the SR may be repeated, and that shutdown must occur prior to exceeding the minimum allowable boron concentration at which MTC is projected to exceed the lower limit. An engineering evaluation is CALVERT CLIFFS - UNITS 1 & 2 B 3.1.3-4 Revision 29

MTC B 3.1.3 BASES performed if the extrapolated value of MTC exceeds the Specification limits.

REFERENCES 1. UFSAR CALVERT CLIFFS - UNITS 1 & 2 B 3.1.3-5 Revision 29

CEA Alignment B 3.1.4 B 3.1 REACTIVITY CONTROL SYSTEMS B 3.1.4 Control Element Assembly (CEA) Alignment BASES BACKGROUND The OPERABILITY (e.g., trippability) of the shutdown and regulating CEAs is an initial assumption in all safety analyses that assume CEA insertion upon reactor trip.

The applicable criteria for these reactivity and power distribution design requirements are found in Reference 1, Appendix 1C, Criteria 6, 27, 29, and 30, and Reference 2.

Mechanical or electrical failures may cause a CEA to become inoperable or to become misaligned from its group. Control element assembly inoperability or misalignment may cause increased power peaking, due to the asymmetric reactivity distribution and a reduction in the total available CEA worth for reactor shutdown. Therefore, CEA alignment and OPERABILITY are related to core operation in design power peaking limits and the core design requirement of a minimum SDM.

Limits on CEA alignment and OPERABILITY have been established, and all CEA positions are monitored and controlled during power operation to ensure that the power distribution and reactivity limits defined by the design power peaking and SDM limits are preserved.

Control element assemblies are moved by their control element drive mechanisms (CEDMs). Each CEDM moves its CEA one step (approximately 3/4-inch) at a time.

The CEAs are arranged into groups that are radially symmetric. Therefore, movement of the CEA groups do not introduce radial asymmetries in the core power distribution.

The shutdown and regulating CEAs provide the required reactivity worth for immediate reactor shutdown upon a reactor trip. The regulating CEAs also provide reactivity (power level) control during normal operation and transients.

The axial position of shutdown and regulating CEAs is indicated by two separate and independent systems, which are CALVERT CLIFFS - UNITS 1 & 2 B 3.1.4-1 Revision 2

CEA Alignment B 3.1.4 BASES the Plant Computer CEA Position Indication System and the Reed Switch Position Indication System.

The Plant Computer CEA Position Indication System counts the commands sent to the CEA gripper coils from the CEDM Control System that moves the CEAs. There is a one step counter for each CEA. Individual CEAs in a group all receive the same signal to move and should, therefore, all be at the same position indicated by the group step counter for that group.

Plant Computer CEA Position Indication System is considered highly precise (+/- 1 step or +/- 3/4-inch). If a CEA does not move one step for each command signal, the step counter will still count the command and incorrectly reflect the position of the CEA.

The Reed Switch Position Indication System provides a highly accurate indication of actual CEA position, but at a lower precision than the step counters. This system is based on inductive analog signals from a series of reed switches spaced along a tube with a center-to-center distance of 1.5 inches, which is two steps. To increase the reliability of the system, there are redundant reed switches at each position.

APPLICABLE Control element assembly misalignment accidents are SAFETY ANALYSES analyzed in the safety analysis (Reference 1, Sections 14.2, 14.11, and 14.13). The accident analysis defines CEA misoperation as any event, with the exception of sequential group withdraws, which could result from a single malfunction in the reactivity control systems. For example, CEA misalignment may be caused by a malfunction of the CEDM, CEDM Control System, or by operator error. A stuck CEA may be caused by mechanical jamming of the CEA fingers or of the gripper. A dropped CEA could be caused by an electrical failure in the CEA coil power programmers.

The acceptance criteria for addressing CEA inoperability/

misalignment are that:

a. There shall be no violations of:
1. SAFDLs, or
2. RCS pressure boundary integrity; and CALVERT CLIFFS - UNITS 1 & 2 B 3.1.4-2 Revision 2

CEA Alignment B 3.1.4 BASES

b. The core must remain subcritical after accidents or transients.

Two types of misalignment are distinguished in the safety analysis (Reference 1, Appendix 1C). The first type of misalignment occurs if one CEA fails to insert upon a reactor trip and remains stuck fully withdrawn. This condition requires an evaluation to determine that sufficient reactivity worth is held in the remaining CEAs to meet the SDM requirement with the maximum worth CEA stuck fully withdrawn. If a CEA is stuck in the fully withdrawn position, its worth is added to the SDM requirement, since the safety analysis does not take two stuck CEAs into account. The second type of misalignment occurs when one CEA drops partially or fully into the reactor core. This event causes an initial power reduction followed by a return toward the original power, due to positive reactivity feedback from the negative MTC. Increased peaking during the power increase may result in excessive local LHRs (Reference 1, Section 14.14).

None of the above CEA misoperations will result in an automatic reactor trip. In the case of the full-length CEA drop, a prompt decrease in core average power and a distortion in radial power are initially produced, which, when conservatively coupled, result in a local power and heat flux increase, and a decrease in DNBR parameters.

The results of the CEA misoperation analysis show that, during the most limiting misoperation events, no violations of the SAFDLs, fuel centerline temperature, or RCS pressure occur.

Control element assembly alignment satisfies 10 CFR 50.36(c)(2)(ii), Criteria 2 and 3.

LCO The limits on shutdown and regulating CEA alignments ensure that the assumptions in the safety analysis will remain valid. The requirements on OPERABILITY ensure that upon reactor trip, the CEAs will be available and will be inserted to provide enough negative reactivity to shut down the reactor. The OPERABILITY requirements also ensure that CALVERT CLIFFS - UNITS 1 & 2 B 3.1.4-3 Revision 2

CEA Alignment B 3.1.4 BASES the CEA banks maintain the correct power distribution and CEA alignment.

The requirement is to maintain the CEA alignment to within 7.5 inches between any CEA and its group.

Failure to meet the requirements of this LCO may produce unacceptable power peaking factors and LHRs, or unacceptable SDMs, all of which may constitute initial conditions inconsistent with the safety analysis.

APPLICABILITY The requirements on CEA OPERABILITY and alignment are applicable in MODEs 1 and 2 because these are the only MODEs in which neutron (or fission) power is generated, and the OPERABILITY (e.g., trippability) and alignment of CEAs have the potential to affect the safety of the plant. In MODEs 3, 4, 5, and 6, the alignment limits do not apply because the CEAs are bottomed, and the reactor is shut down and not producing fission power. In the shutdown MODEs, the OPERABILITY of the shutdown and regulating CEAs has the potential to affect the required SDM, but this effect can be compensated for by an increase in the boron concentration of the RCS. See LCO 3.1.1 for SDM in MODEs 3, 4, and 5, and LCO 3.9.1 for boron concentration requirements during refueling.

ACTIONS A.1 and B.1 A CEA may become misaligned, yet remain trippable. In this condition, the CEA can still perform its required function of adding negative reactivity should a reactor trip be necessary.

If one or more regulating or shutdown CEAs are misaligned by

> 7.5 inches and 15 inches but trippable, or one CEA is misaligned by > 15 inches but trippable, continued operation in MODEs 1 and 2 may continue, provided CEA alignment is restored within 1 hour1.157407e-5 days <br />2.777778e-4 hours <br />1.653439e-6 weeks <br />3.805e-7 months <br /> for CEAs misaligned 15 inches and within the time specified in the COLR for CEAs misaligned

> 15 inches. (The maximum time provided in the COLR is 2 hours2.314815e-5 days <br />5.555556e-4 hours <br />3.306878e-6 weeks <br />7.61e-7 months <br />.)

CALVERT CLIFFS - UNITS 1 & 2 B 3.1.4-4 Revision 43

CEA Alignment B 3.1.4 BASES Regulating and shutdown CEA alignment is restored by either aligning the misaligned CEA(s) to within 7.5 inches of its group or aligning the misaligned CEAs group to within 7.5 inches of the misaligned CEA.

Xenon redistribution in the core starts to occur as soon as a CEA becomes misaligned. Restoring CEA alignment ensures acceptable power distributions are maintained. For small misalignments ( 15 inches) of the CEAs, there is:

a. A small effect on the time-dependent, long-term power distributions relative to those used in generating LCOs and limiting safety system settings setpoints;
b. A negligible effect on the available SDM; and
c. A small effect on the ejected CEA worth used in the accident analysis.

With a large CEA misalignment (> 15 inches), however, this misalignment would cause distortion of the core power distribution. This distortion may, in turn, have a significant effect on the time-dependent, long-term power distributions relative to those used in generating LCOs and limiting safety system settings setpoints.

The effect on the available SDM and the ejected CEA worth used in the accident analysis remains small.

Therefore, this condition is limited to a single CEA misalignment, while still allowing time for recovery.

In both cases, the allowed time period is sufficient to:

a. Identify cause of a misaligned CEA;
b. Take appropriate corrective action to realign the CEAs; and
c. Minimize the effects of xenon redistribution.

If a CEA is untrippable, it is not available for reactivity insertion during a reactor trip. With an untrippable CEA, meeting the insertion limits of LCOs 3.1.5 and 3.1.6 does not ensure that adequate SDM exists. Condition F must be entered.

CALVERT CLIFFS - UNITS 1 & 2 B 3.1.4-5 Revision 43

CEA Alignment B 3.1.4 BASES C.1 and C.2 If any CEA is not restored to within its alignment limits within the Completion Time provided in Required Action A.1 or B.1, an additional 2 hours2.314815e-5 days <br />5.555556e-4 hours <br />3.306878e-6 weeks <br />7.61e-7 months <br /> is allowed to restore CEA alignment, provided THERMAL POWER is reduced 70% RTP.

Prompt action must be taken to reduce THERMAL POWER, and the reduction must be completed within 1 hour1.157407e-5 days <br />2.777778e-4 hours <br />1.653439e-6 weeks <br />3.805e-7 months <br />. Reducing THERMAL POWER ensures acceptable power distributions are maintained during the additional time provided to restore alignment.

The Completion Times are acceptable based on the reasons provided in the Bases for Required Actions A.1 and B.1.

D.1, D.2.1, and D.2.2 The CEA motion inhibit permits CEA motion within the requirements of LCO 3.1.6, and prevents regulating CEAs from being misaligned from other CEAs in the group.

Performing SR 3.1.4.1 within 1 hour1.157407e-5 days <br />2.777778e-4 hours <br />1.653439e-6 weeks <br />3.805e-7 months <br /> and every 4 hours4.62963e-5 days <br />0.00111 hours <br />6.613757e-6 weeks <br />1.522e-6 months <br /> thereafter is considered acceptable, in view of other information continuously available to the operator in the Control Room.

With the CEA motion inhibit inoperable, a Completion Time of 6 hours6.944444e-5 days <br />0.00167 hours <br />9.920635e-6 weeks <br />2.283e-6 months <br /> is allowed for restoring the CEA motion inhibit to OPERABLE status, or fully withdrawing the CEAs in groups 3 and 4, and withdrawing all CEAs in group 5 to < 5%

insertion.

Withdrawal of the CEAs to the positions required in Required Action D.2.2 provides additional assurance that core perturbations in local burnup, peaking factors, and SDM will not be more adverse than the Conditions assumed in the safety analyses and LCO setpoint determination (Reference 1, Chapter 14).

The 6-hour Completion Time takes into account Required Action D.1, the protection afforded by the CEA deviation circuits, and other information continuously available to the operator in the Control Room, so that during actual CEA motion, deviations can be detected.

CALVERT CLIFFS - UNITS 1 & 2 B 3.1.4-6 Revision 37

CEA Alignment B 3.1.4 BASES Required Action D.2.2 is modified by a Note indicating that performing this Required Action is not required when in conflict with Required Actions A.1, B.1, C.2, or E.1.

E.1 When the CEA deviation circuit is inoperable, performing SR 3.1.4.1 within 1 hour1.157407e-5 days <br />2.777778e-4 hours <br />1.653439e-6 weeks <br />3.805e-7 months <br /> and every 4 hours4.62963e-5 days <br />0.00111 hours <br />6.613757e-6 weeks <br />1.522e-6 months <br /> thereafter ensures improper CEA alignments are identified before unacceptable flux distributions occur. The specified Completion Times take into account other information continuously available to the operator in the Control Room, so that during CEA movement, deviations can be detected, and the protection provided by the CEA inhibit and deviation circuit is not required.

F.1 If any Required Action and associated Completion Time of Condition C, Condition D, or Condition E is not met, one or more regulating or shutdown CEAs are untrippable, two or more CEAs are misaligned by > 15 inches, the unit is required to be brought to MODE 3. By being brought to MODE 3, the unit is brought outside the MODE of applicability. Continued operation is not allowed in the case of more than one CEA misaligned from any other CEA in its group by > 15 inches, or one or more CEAs untrippable.

This is because these cases could result in a loss of SDM and power distribution and a loss of safety function, respectively.

When a Required Action cannot be completed within the required Completion Time, a controlled shutdown should be commenced. The allowed Completion Time of 6 hours6.944444e-5 days <br />0.00167 hours <br />9.920635e-6 weeks <br />2.283e-6 months <br /> is reasonable, based on operating experience, for reaching MODE 3 from full power conditions in an orderly manner and without challenging plant systems.

SURVEILLANCE SR 3.1.4.1 REQUIREMENTS Verification that individual CEA positions are within 7.5 inches (indicated reed switch positions) of all other CEAs in the group are performed at Frequencies of within 1 hour1.157407e-5 days <br />2.777778e-4 hours <br />1.653439e-6 weeks <br />3.805e-7 months <br /> of any CEA movement of > 7.5 inches and every CALVERT CLIFFS - UNITS 1 & 2 B 3.1.4-7 Revision 37

CEA Alignment B 3.1.4 BASES 12 hours1.388889e-4 days <br />0.00333 hours <br />1.984127e-5 weeks <br />4.566e-6 months <br />. The CEA position verification after each movement of > 7.5 inches ensure that the CEAs in that group are properly aligned at the time when CEA misalignments are most likely to have occurred. The 12-hour Frequency allows the operator to detect a CEA that is beginning to deviate from its expected position. The specified Frequency takes into account other CEA position information that is continuously available to the operator in the Control Room, so that during CEA movement, deviations can be detected, and protection can be provided by the CEA motion inhibit and deviation circuits.

SR 3.1.4.2 Demonstrating the CEA motion inhibit OPERABLE verifies that the CEA motion inhibit is functional, even if it is not regularly operated. The verification shall ensure that the motion inhibit circuit maintains the CEA group overlap and sequencing requirements of LCO 3.1.6, and prevents any regulating CEA from being misaligned from all other CEAs in its group by > 7.5 inches (indicated position). The 31-day Frequency takes into account other information continuously available to the operator in the Control Room, so that during CEA movement, deviations can be detected, and protection can be provided by the CEA deviation circuits.

SR 3.1.4.3 Demonstrating the CEA deviation circuit is OPERABLE verifies the circuit is functional. The 31-day Frequency takes into account other information continuously available to the operator in the Control Room, so that during CEA movement, deviations can be detected, and protection can be provided by the CEA motion inhibit.

SR 3.1.4.4 Verifying each CEA is trippable would require that each CEA be tripped. In MODEs 1 and 2, tripping each CEA would result in radial or axial power tilts or oscillations.

Therefore, individual CEAs are exercised every 92 days to provide increased confidence that all CEAs continue to be trippable, even if they are not regularly tripped. A movement of 7.5 inches is adequate to demonstrate motion without exceeding the alignment limit when only one CEA is CALVERT CLIFFS - UNITS 1 & 2 B 3.1.4-8 Revision 37

CEA Alignment B 3.1.4 BASES being moved. For the purposes of performing the CEA operability test, if the CEA has an inoperable position indicator channel, the alternate indication system (pulse counter or voltage dividing network) will be used to monitor position. The 92-day Frequency takes into consideration other information available to the operator in the Control Room and other SRs being performed more frequently, which add to the determination of OPERABILITY of the CEAs.

Between required performances of SR 3.1.4.5, if a CEA(s)is discovered to be immovable, but remains trippable and aligned, the CEA is considered to be OPERABLE. At any time, if a CEA(s) is immovable, a determination of the trippability (OPERABILITY) of the CEA(s) must be made, and appropriate action taken.

SR 3.1.4.5 Performance of a CHANNEL FUNCTIONAL TEST of each reed switch position transmitter channel ensures the channel is OPERABLE and capable of indicating CEA position over the entire length of the CEA's travel. A successful test of the required contact(s) of a channel relay may be performed by the verification of the change of state of a single contact of the relay. This clarifies what is an acceptable CHANNEL FUNCTIONAL TEST of a relay. This is acceptable because all of the other required contacts of the relay are verified by other Technical Specification tests at least once per refueling interval with applicable extensions. Since this SR must be performed when the reactor is shut down, a 24-month Frequency to be coincident with refueling outages was selected. Operating experience has shown that these components usually pass this SR when performed at a Frequency of once every 24 months. Furthermore, the Frequency takes into account other SRs being performed at shorter Frequencies, which determine the OPERABILITY of the CEA Reed Switch Indication System.

SR 3.1.4.6 Verification of CEA drop times determined that the maximum CEA drop time permitted is consistent with the assumed drop time used in that safety analysis (Reference 1, Chapter 14).

Control element assembly drop time is measured from the time when electrical power is interrupted to the CEDM until the CALVERT CLIFFS - UNITS 1 & 2 B 3.1.4-9 Revision 37

CEA Alignment B 3.1.4 BASES CEA reaches its 90% insertion position, from a fully withdrawn position, with Tave 515°F and all reactor coolant pumps operating. Measuring drop times prior to reactor criticality, after reactor vessel head removal, ensures that reactor internals and CEDM will not interfere with CEA motion or drop time, and that no degradation in these systems has occurred that would adversely affect CEA motion or drop time. Individual CEAs whose drop times are greater than safety analysis assumptions are not OPERABLE. This SR is performed prior to criticality, based on the need to perform this SR under the conditions that apply during a unit outage and because of the potential for an unplanned unit transient if the SR were performed with the reactor at power.

REFERENCES 1. UFSAR

2. 10 CFR 50.46, "Acceptance Criteria for Emergency Core Cooling Systems for Light Water Nuclear Power Plants" CALVERT CLIFFS - UNITS 1 & 2 B 3.1.4-10 Revision 37

Shutdown CEA Insertion Limits B 3.1.5 B 3.1 REACTIVITY CONTROL SYSTEMS B 3.1.5 Shutdown Control Element Assembly (CEA) Insertion Limits BASES BACKGROUND The insertion limits of the shutdown CEAs are initial assumptions in all safety analyses that assume CEA insertion upon reactor trip. The insertion limits directly affect core power distributions and assumptions of available SDM, ejected CEA worth, and initial reactivity insertion rate.

The applicable criteria for these reactivity and power distribution design requirements are in Reference 1, Appendix 1C, Criteria 6, 27, 28, 29, and 30, and Reference 2. Limits on shutdown CEA insertion have been established, and all CEA positions are monitored and controlled during power operation to ensure that the reactivity limits, ejected CEA worth, and SDM limits are preserved.

The shutdown CEAs are arranged into groups that are radially symmetric. Therefore, movement of the shutdown CEAs does not introduce radial asymmetries in the core power distribution. The shutdown and regulating CEAs provide the required reactivity worth for immediate reactor shutdown upon a reactor trip.

The design calculations are performed with the assumption that the shutdown CEAs are withdrawn prior to the regulating CEAs. The shutdown CEAs can be fully withdrawn without the core going critical. The shutdown CEAs are controlled manually by the Control Room operator. During normal unit operation, the shutdown CEAs are fully withdrawn. The shutdown CEAs must be completely withdrawn from the core prior to withdrawing any regulating CEAs during an approach to criticality. The shutdown CEAs are left in this position until the reactor is shut down. They affect core power, burnup distribution, and add negative reactivity to shut down the reactor upon receipt of a reactor trip signal.

CALVERT CLIFFS - UNITS 1 & 2 B 3.1.5-1 Revision 2

Shutdown CEA Insertion Limits B 3.1.5 BASES APPLICABLE Accident analysis assumes that the shutdown CEAs are fully SAFETY ANALYSES withdrawn any time the reactor is critical. This ensures that:

a. The minimum SDM is maintained; and
b. The potential effects of a CEA ejection accident are limited to acceptable limits.

Control element assemblies are considered fully withdrawn at 129 inches.

On a reactor trip, all CEAs (shutdown and regulating),

except the most reactive CEA, are assumed to insert into the core. The shutdown and regulating CEAs shall be at or above their insertion limits and available to insert the required amount of negative reactivity on a reactor trip signal. The regulating CEAs may be partially inserted in the core as allowed by LCO 3.1.6. The shutdown CEA insertion limit is established to ensure that a sufficient amount of negative reactivity is available to shut down the reactor and maintain the required SDM (see LCO 3.1.1) following a reactor trip from full power. The combination of regulating CEAs and shutdown CEAs (less the most reactive CEA, which is assumed to be fully withdrawn) is sufficient to take the reactor from full power conditions at rated temperature to zero power, and to maintain the required SDM at rated no load temperature (Reference 1, Sections 3.2 and 3.4). The shutdown CEA insertion limit also limits the reactivity worth of an ejected shutdown CEA.

The acceptance criteria for addressing shutdown CEA, as well as regulating CEA insertion limits and inoperability or misalignment, are that:

a. There be no violation of:
1. SAFDLs, or
2. RCS pressure boundary damage; and
b. The core remains subcritical after accident transients.

As such, the shutdown CEA insertion limits affect safety analyses involving core reactivity, ejected CEA worth, and SDM (Reference 1, Section 14.1.2).

CALVERT CLIFFS - UNITS 1 & 2 B 3.1.5-2 Revision 38

Shutdown CEA Insertion Limits B 3.1.5 BASES The shutdown CEA insertion limits satisfy 10 CFR 50.36(c)(2)(ii), Criterion 2.

LCO The shutdown CEAs must be within their insertion limits any time the reactor is critical or approaching criticality.

This ensures that a sufficient amount of negative reactivity is available to shut down the reactor and maintain the required SDM following a reactor trip.

APPLICABILITY The shutdown CEAs must be within their insertion limits, with the reactor in MODEs 1 and 2. The Applicability in MODE 2 begins anytime any regulating CEA is not fully inserted. This ensures that a sufficient amount of negative reactivity is available to shut down the reactor and maintain the required SDM following a reactor trip. In MODE 3, 4, 5, or 6, the shutdown CEAs are fully inserted in the core and contribute to the SDM. Refer to LCO 3.1.1 for SDM requirements in MODEs 3, 4, and 5. Limiting Condition for Operation 3.9.1 ensures adequate SDM in MODE 6.

This LCO has been modified by a Note indicating the LCO requirement is suspended during SR 3.1.4.4. This SR verifies the freedom of the CEAs to move, and requires the shutdown CEAs to move below the LCO limits, which would normally violate the LCO.

ACTIONS A.1 When one shutdown CEA is withdrawn 121.5 inches and

< 129 inches, the accumulated times the shutdown CEAs have been withdrawn within this range must be verified. The Completion Time for this action is once within 4 hours4.62963e-5 days <br />0.00111 hours <br />6.613757e-6 weeks <br />1.522e-6 months <br /> and 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> thereafter. Operation is allowed for 7 consecutive days and a total of 14 days per 365 days. The peaking factors may not be outside required limits when one shutdown CEA is misaligned; therefore, continued operation is allowed. Since the power distribution limits are being maintained via the LCOs of Technical Specification Section 3.2, any out-of-limit peaking factor conditions will require entry into the Actions of the appropriate Section 3.2 LCO(s). The limits on consecutive days and total days in this condition reflect that the core may be approaching the acceptable limits placed on operation with CALVERT CLIFFS - UNITS 1 & 2 B 3.1.5-3 Revision 38

Shutdown CEA Insertion Limits B 3.1.5 BASES flux patterns outside those assumed in the long-term burnup assumptions. Therefore, operation in this condition cannot continue and the CEA is required to be restored per Action B. The accumulated times are required to be verified once within 4 hours4.62963e-5 days <br />0.00111 hours <br />6.613757e-6 weeks <br />1.522e-6 months <br /> to determine which accumulated time limit is more limiting. The periodic Completion Time of 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> after the initial completion within 4 hours4.62963e-5 days <br />0.00111 hours <br />6.613757e-6 weeks <br />1.522e-6 months <br /> is adequate to ensure that the accumulated time limits are not exceeded.

B.1 Prior to entering this condition, the shutdown CEAs were fully withdrawn or all but one shutdown CEA was withdrawn 129 inches. If one shutdown CEA is withdrawn 121.5 inches and < 129 inches for > 7 days per occurrence or > 14 days per 365 days, or one shutdown CEA withdrawn

< 121.5 inches, or two or more shutdown CEAs withdrawn

< 129 inches, the out-of-limit CEAs must be restored to within limits within 2 hours2.314815e-5 days <br />5.555556e-4 hours <br />3.306878e-6 weeks <br />7.61e-7 months <br />. The Completion Time of 2 hours2.314815e-5 days <br />5.555556e-4 hours <br />3.306878e-6 weeks <br />7.61e-7 months <br /> reflects that the power distribution limits may be outside required limits and that the core may be approaching the acceptable limits placed on operation within flux patterns outside those assumed in the long-term burnup assumptions.

The CEA(s) must be restored to within limits within 2 hours2.314815e-5 days <br />5.555556e-4 hours <br />3.306878e-6 weeks <br />7.61e-7 months <br />.

The 2-hour total Completion Time allows the operator adequate time to adjust the CEA(s) in an orderly manner.

C.1 When Required Action A.1 or B.1 cannot be met or completed within the required Completion Time, a controlled shutdown should be commenced. The allowed Completion Time of 6 hours6.944444e-5 days <br />0.00167 hours <br />9.920635e-6 weeks <br />2.283e-6 months <br /> is reasonable, based on operating experience, for reaching MODE 3 from full power conditions in an orderly manner and without challenging plant systems.

SURVEILLANCE SR 3.1.5.1 REQUIREMENTS Verification that the shutdown CEAs are within their insertion limits prior to an approach to criticality ensures that when the reactor is critical, or being taken critical, the shutdown CEAs will be available to shut down the CALVERT CLIFFS - UNITS 1 & 2 B 3.1.5-4 Revision 38

Shutdown CEA Insertion Limits B 3.1.5 BASES reactor, and the required SDM will be maintained following a reactor trip. This SR and Frequency ensure that the shutdown CEAs are withdrawn before the regulating CEAs are withdrawn during a unit startup.

Since the shutdown CEAs are positioned manually by the Control Room operator, verification of shutdown CEA position at a Frequency of 12 hours1.388889e-4 days <br />0.00333 hours <br />1.984127e-5 weeks <br />4.566e-6 months <br /> is adequate to ensure that the shutdown CEAs are within their insertion limits. Also, the 12-hour Frequency takes into account other information available to the operator in the Control Room for the purpose of monitoring the status of the shutdown CEAs.

REFERENCES 1. UFSAR

2. 10 CFR 50.46, "Acceptance Criteria for Emergency Core Cooling Systems for Light Water Nuclear Power Plants" CALVERT CLIFFS - UNITS 1 & 2 B 3.1.5-5 Revision 38

Regulating CEA Insertion Limits B 3.1.6 B 3.1 REACTIVITY CONTROL SYSTEMS B 3.1.6 Regulating Control Element Assembly (CEA) Insertion Limits BASES BACKGROUND The insertion limits of the regulating CEAs are initial assumptions in all safety analyses that assume CEA insertion upon reactor trip. The insertion limits directly affect core power distributions, assumptions of available SDM, and initial reactivity insertion rate. The applicable criteria for these reactivity and power distribution design requirements are Reference 1, Appendix 1C, Criteria 27, 29, 30, and 31, and Reference 2.

Limits on regulating CEA insertion have been established, and all CEA positions are monitored and controlled during power operation to ensure that the power distribution and reactivity limits defined by the design power peaking, ejected CEA worth, reactivity insertion rate, and SDM limits are preserved.

The regulating CEA groups operate with a predetermined amount of position overlap, in order to approximate a linear relation between CEA worth and CEA position (integral CEA worth). The regulating CEA groups are withdrawn and operate in a predetermined sequence. The group sequence and overlap limits are specified in the COLR. Regulating CEAs are considered to be fully withdrawn when withdrawn to at least 129.0 inches.

The regulating CEAs are used for precise reactivity control of the reactor. The positions of the regulating CEAs are manually controlled. They are capable of adding reactivity very quickly (compared to borating or diluting).

The power density at any point in the core must be limited to maintain SAFDLs, including limits that preserve the criteria specified in Reference 2. Together, LCOs 3.1.6, 3.2.4, and LCO 3.2.5 provide limits on control component operation and on monitored process variables to ensure the core operates within the LHR (LCO 3.2.1); and Total Integrated Radial Peaking Factor ( F Tr ) (LCO 3.2.3) limits in the COLR. Operation within the LHR limits given in the COLR prevents power peaks that would exceed the loss of coolant accident (LOCA) limits derived by the Emergency Core Cooling CALVERT CLIFFS - UNITS 1 & 2 B 3.1.6-1 Revision 43

Regulating CEA Insertion Limits B 3.1.6 BASES System analysis. Operation within the F Tr limit given in the COLR prevents departure from nucleate boiling (DNB) during a loss of forced reactor coolant flow accident. In addition to the LHR and F Tr limits, certain reactivity limits are preserved by regulating CEA insertion limits.

The regulating CEA insertion limits also restrict the ejected CEA worth to the values assumed in the safety analysis and preserve the minimum required SDM in MODEs 1 and 2.

The regulating CEA insertion and alignment limits are process variables that together characterize and control the three-dimensional power distribution of the reactor core.

Additionally, the regulating bank insertion limits control the reactivity that could be added in the event of a CEA ejection accident, and the shutdown and regulating bank insertion limits ensure the required SDM is maintained.

Operation within the subject LCO limits will prevent fuel cladding failures that would breach the primary fission product barrier and release fission products to the reactor coolant in the event of a LOCA, loss of flow, ejected CEA, or other accident requiring termination by a Reactor Protective System trip function.

APPLICABLE The fuel cladding must not sustain damage as a result of SAFETY ANALYSES normal operation (Condition I) and AOOs (Condition II). The acceptance criteria for the regulating CEA insertion, ASI, F Tr , LHR, and AZIMUTHAL POWER TILT (Tq) LCOs are such as to preclude core power distributions from occurring that would violate the following fuel design criteria:

a. During a large break LOCA, the peak cladding temperature must not exceed a limit of 2200°F (Reference 2);
b. During a loss of forced reactor coolant flow accident, there must be at least a 95% probability at a 95%

confidence level (the 95/95 DNB criterion) that the hot fuel rod in the core does not experience a DNB condition; CALVERT CLIFFS - UNITS 1 & 2 B 3.1.6-2 Revision 43

Regulating CEA Insertion Limits B 3.1.6 BASES

c. During an ejected CEA accident, the energy input to the fuel must not exceed accepted limits (Reference 1, Section 14.3); and
d. The CEAs must be capable of shutting down the reactor with a minimum required SDM, with the highest worth CEA stuck fully withdrawn, Reference 1, Appendix 1C, Criterion 29.

Regulating CEA position, ASI, F Tr , LHR, and Tq are process variables that together characterize and control the three-dimensional power distribution of the reactor core.

Fuel cladding damage does not normally occur when the core is operated outside these LCOs during normal operation.

However, fuel cladding damage could result if an accident or AOO occurs with simultaneous violation of one or more of these LCOs. Changes in the power distribution can cause increased power peaking and corresponding increased local LHRs.

The SDM requirement is ensured by limiting the regulating and shutdown CEA insertion limits, so that the allowable inserted worth of the CEAs is such that sufficient reactivity is available to shut down the reactor to hot zero power. SHUTDOWN MARGIN assumes the maximum worth CEA remains fully withdrawn upon trip (Reference 1, Section 3.4).

The most limiting SDM requirements for MODEs 1 and 2 conditions at BOC are determined by the requirements of several transients, e.g., Loss of Flow, Seized Rotor, Boron Dilution, etc. However, the most limiting SDM requirements for MODEs 1 and 2 at EOC come from the SLB and Excess Load transients. The requirements of the SLB and Excess Load events at EOC for both the full power and no load conditions are significantly larger than those of any other event at that time in cycle.

To verify that adequate SDMs are available throughout the cycle to satisfy the changing requirements, calculations are performed at both BOC and EOC. It has been determined that calculations at these two times in cycle a are sufficient since the differences between available SDMs and the CALVERT CLIFFS - UNITS 1 & 2 B 3.1.6-3 Revision 43

Regulating CEA Insertion Limits B 3.1.6 BASES limiting SDM requirements are the smallest at these times in a cycle. The measurement of CEA bank worth performed as part of the Startup Testing Program demonstrates that the core has the expected shutdown capability. Consequently, adherence to LCOs 3.1.5 and 3.1.6 provides assurance that the available SDM at any time in a cycle will exceed the limiting SDM requirements at that time in a cycle.

Operation at the insertion limits or ASI limits may approach the maximum allowable linear heat generation rate or peaking factor, with the allowed Tq present. Operation at the insertion limit may also indicate the maximum ejected CEA worth could be equal to the limiting value in fuel cycles that have sufficiently high ejected CEA worths.

The regulating and shutdown CEA insertion limits ensure that safety analyses assumptions for reactivity insertion rate, SDM, ejected CEA worth, and power distribution peaking factors are preserved (Reference 1, Section 3.4).

The regulating CEA insertion limits satisfy 10 CFR 50.36(c)(2)(ii), Criterion 2.

LCO The limits on regulating CEAs sequence, overlap, and physical insertion, as defined in the COLR, must be maintained because they serve the function of preserving power distribution, ensuring that the SDM is maintained, ensuring that ejected CEA worth is maintained, and ensuring adequate negative reactivity insertion on trip. The overlap between regulating banks provides more uniform rates of reactivity insertion and withdrawal and is imposed to maintain acceptable power peaking during regulating CEA motion.

The power-dependent insertion limit (PDIL) alarm circuit is required to be OPERABLE for notification that the CEAs are outside the required insertion limits. The PDIL alarm circuit required to be OPERABLE receives its signal from the reed switch position indication system. When the PDIL alarm circuit is inoperable, the verification of CEA positions is increased to ensure improper CEA alignment is identified before unacceptable flux distribution occurs.

CALVERT CLIFFS - UNITS 1 & 2 B 3.1.6-4 Revision 43

Regulating CEA Insertion Limits B 3.1.6 BASES APPLICABILITY The regulating CEA sequence, overlap, and physical insertion limits shall be maintained with the reactor in MODEs 1 and 2. These limits must be maintained, since they preserve the assumed power distribution, ejected CEA worth, SDM, and reactivity rate insertion assumptions. Applicability in MODEs 3, 4, and 5 is not required, since neither the power distribution nor ejected CEA worth assumptions would be exceeded in these MODEs. SHUTDOWN MARGIN is preserved in MODEs 3, 4, and 5 by adjustments to the soluble boron concentration.

This LCO has been modified by a Note indicating the LCO requirement is suspended during SR 3.1.4.4. This SR verifies the freedom of the CEAs to move, and requires the regulating CEAs to move below the LCO limits, which would normally violate the LCO.

ACTIONS A.1 and A.2 Operation beyond the transient insertion limit may result in a loss of SDM and excessive peaking factors. The transient insertion limit should not be violated during normal operation; this violation, however, may occur during transients when the operator is manually controlling the CEAs in response to changing plant conditions. When the regulating groups are inserted beyond the transient insertion limits, actions must be taken to either withdraw the regulating groups beyond the limits or to reduce THERMAL POWER to less than or equal to that allowed for the actual CEA insertion limit. Two hours provides a reasonable time to accomplish this, allowing the operator to deal with current plant conditions while limiting peaking factors to acceptable levels.

B.1 and B.2 If the CEAs are inserted between the long-term steady state insertion limits and the transient insertion limits for intervals > 4 hours4.62963e-5 days <br />0.00111 hours <br />6.613757e-6 weeks <br />1.522e-6 months <br /> per 24 hour2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> period, and the short-term steady state insertions are exceeded, peaking factors can develop that are of immediate concern (Reference 1, Chapter 14).

CALVERT CLIFFS - UNITS 1 & 2 B 3.1.6-5 Revision 43

Regulating CEA Insertion Limits B 3.1.6 BASES Verifying the short-term steady state insertion limits are not exceeded ensures that the peaking factors that do develop are within those allowed for continued operation.

Fifteen minutes provides adequate time for the operator to verify if the short-term steady state insertion limits are exceeded.

Experience has shown that rapid power increases in areas of the core, in which the flux has been depressed, can result in fuel damage, as the LHR in those areas rapidly increases.

Restricting the rate of THERMAL POWER increases to 5% RTP per hour, following CEA insertion beyond the long-term steady-state insertion limits, ensures the power transients experienced by the fuel will not result in fuel failure.

C.1 With the regulating CEAs inserted between the long-term steady state insertion limit and the transient insertion limit, and with the core approaching the 5 EFPD per 30 EFPD or 14 EFPD per 365 EFPD limits, the CEAs must be returned to within the long-term steady state insertion limits, or the core must be placed in a condition in which the abnormal fuel burnup cannot continue. A Completion Time of 2 hours2.314815e-5 days <br />5.555556e-4 hours <br />3.306878e-6 weeks <br />7.61e-7 months <br /> is allotted to return the CEAs to within the long-term steady state insertion limits.

The required Completion Time of 2 hours2.314815e-5 days <br />5.555556e-4 hours <br />3.306878e-6 weeks <br />7.61e-7 months <br /> from initial discovery of a regulating CEA group outside the limits until its restoration to within the long-term steady state limits, shown on the figures in the COLR, allows sufficient time for borated water to enter the RCS from the chemical addition and makeup systems, and to cause the regulating CEAs to withdraw to the acceptable region. It is reasonable to continue operation for 2 hours2.314815e-5 days <br />5.555556e-4 hours <br />3.306878e-6 weeks <br />7.61e-7 months <br /> after it is discovered that the 5-day or 14-day EFPD limit has been exceeded. This Completion Time is based on limiting the potential xenon redistribution, the low probability of an accident, and the steps required to complete the action.

D.1 When the PDIL alarm circuit is inoperable, performing SR 3.1.6.1 within 1 hour1.157407e-5 days <br />2.777778e-4 hours <br />1.653439e-6 weeks <br />3.805e-7 months <br /> and once per 4 hours4.62963e-5 days <br />0.00111 hours <br />6.613757e-6 weeks <br />1.522e-6 months <br /> thereafter CALVERT CLIFFS - UNITS 1 & 2 B 3.1.6-6 Revision 43

Regulating CEA Insertion Limits B 3.1.6 BASES ensures improper CEA alignments are identified before unacceptable flux distributions occur.

E.1 When a Required Action cannot be completed within the required Completion Time, a controlled shutdown should be commenced. The allowed Completion Time of 6 hours6.944444e-5 days <br />0.00167 hours <br />9.920635e-6 weeks <br />2.283e-6 months <br /> is reasonable, based on operating experience, for reaching MODE 3 from full power conditions in an orderly manner and without challenging plant systems.

SURVEILLANCE SR 3.1.6.1 REQUIREMENTS With the PDIL alarm circuit OPERABLE, verification of each regulating CEA group position every 12 hours1.388889e-4 days <br />0.00333 hours <br />1.984127e-5 weeks <br />4.566e-6 months <br /> is sufficient to detect CEA positions that may approach the acceptable limits, and to provide the operator with time to undertake the Required Action(s) should the sequence or insertion limits be found to be exceeded. The 12-hour Frequency also takes into account the indication provided by the PDIL alarm circuit and other information about CEA group positions available to the operator in the Control Room.

SR 3.1.6.2 Verification of the accumulated time of CEA group insertion between the long-term steady state insertion limits and the transient insertion limits ensures the cumulative time limits are not exceeded. The 24-hour Frequency ensures the operator identifies a time limit that is being approached before it is reached.

SR 3.1.6.3 Demonstrating the PDIL alarm circuit OPERABLE verifies that the PDIL alarm circuit is functional. The 31-day Frequency takes into account other SRs being performed at shorter Frequencies that identify improper CEA alignments.

REFERENCES 1. UFSAR

2. 10 CFR 50.46, "Acceptance Criteria for Emergency Core Cooling Systems for Light Water Nuclear Power Plants" 10 CFR 50.46 CALVERT CLIFFS - UNITS 1 & 2 B 3.1.6-7 Revision 43

STE-SDM B 3.1.7 B 3.1 REACTIVITY CONTROL SYSTEMS B 3.1.7 Special Test Exception (STE)-SHUTDOWN MARGIN (SDM)

BASES BACKGROUND The primary purpose of the SDM STE is to permit relaxation of existing LCOs to allow the performance of certain PHYSICS TESTS. These tests are constructed to determine the CEA worth.

Reference 1, Appendix B,Section XI requires that a test program be established to ensure that structures, systems, and components will perform satisfactorily in service. All functions necessary to ensure that specified design conditions are not exceeded during normal operation and AOOs must be tested. Testing is required as an integral part of the design, fabrication, construction, and operation of the power plant. Requirements for notification of the Nuclear Regulatory Commission, for the purpose of conducting tests and experiments, are specified in Reference 1, 10 CFR 50.59.

The key objectives of a test program (Reference 2) are to:

a. Ensure that the facility has been adequately designed;
b. Validate the analytical models used in design and analysis;
c. Verify assumptions used for predicting plant response;
d. Ensure that installation of equipment in the facility has been accomplished in accordance with the design; and
e. Verify that operating and emergency procedures are adequate.

To accomplish these objectives, testing is required prior to initial criticality, after each refueling shutdown, and during startup, low power operation, power ascension, and at power operation. The PHYSICS TESTS requirements for reload fuel cycles ensure that the operating characteristics of the core are consistent with the design predictions, and that the core can be operated as designed (Reference 3, Section 13.4).

PHYSICS TESTS procedures are written and approved in accordance with an established process. The procedures CALVERT CLIFFS - UNITS 1 & 2 B 3.1.7-1 Revision 2

STE-SDM B 3.1.7 BASES include all information necessary to permit a detailed execution of testing required to ensure that the design intent is met. PHYSICS TESTS are performed in accordance with these procedures, and test results are independently reviewed prior to continued power escalation and long- term power operation. Examples of PHYSICS TESTS include determination of critical boron concentration, CEA group worths, reactivity coefficients, flux symmetry, and core power distribution.

APPLICABLE It is acceptable to suspend certain LCOs for PHYSICS TESTS SAFETY ANALYSES because fuel damage criteria are not exceeded. Even if an accident occurs during PHYSICS TESTS with one or more LCOs suspended, fuel damage criteria are preserved because adequate limits on power distribution and shutdown capability are maintained during PHYSICS TESTS.

Reference 2 defines the requirements for initial testing of the facility, including PHYSICS TESTS. Requirements for reload fuel cycle PHYSICS TESTS are defined in the UFSAR Reference 3, Section 13.4. Although these PHYSICS TESTS are generally accomplished within the limits of all LCOs, conditions may occur when one or more LCOs must be suspended to make completion of PHYSICS TESTS possible or practical.

This is acceptable as long as the fuel design criteria are not violated. As long as the LHR remains within its limit, fuel design criteria are preserved.

In this test, the following LCOs are suspended:

a. LCO 3.1.1; and
b. LCO 3.1.6.

Therefore, this LCO places limits on the minimum amount of CEA worth required to be available for reactivity control when CEA worth measurements are performed.

The individual LCOs cited above govern SDM CEA group height, insertion, and alignment. Additionally, the LCOs governing RCS flow, reactor inlet temperature, and pressurizer pressure contribute to maintaining DNB parameter limits.

The initial condition criteria for accidents sensitive to core power distribution are preserved by the LHR and DNB CALVERT CLIFFS - UNITS 1 & 2 B 3.1.7-2 Revision 2

STE-SDM B 3.1.7 BASES parameter limits. The criteria for the LOCA are specified in Reference 2, 10 CFR 50.46. The criteria for the loss of forced reactor coolant flow accident are specified in Reference 3, Chapter 14. Operation within the LHR limit preserves the LOCA criteria; operation within the DNB parameter limits preserves the loss of flow criteria.

Surveillance tests are conducted as necessary to ensure that LHR and DNB parameters remain within limits during PHYSICS TESTS. Performance of these SRs allows PHYSICS TESTS to be conducted without decreasing the margin of safety.

Requiring that shutdown reactivity equivalent to at least the highest estimated CEA worth (of those CEAs actually withdrawn) be available for trip insertion from the OPERABLE CEA provides a high degree of assurance that shutdown capability is maintained for the most challenging postulated accident, a stuck CEA. When LCO 3.1.1 is suspended, there is not the same degree of assurance during this test that the reactor would always be shut down if the highest worth CEA was stuck out and calculational uncertainties or the estimated highest CEA worth was not as expected (the single failure criterion is not met). This situation is judged acceptable, however, because SAFDLs are still met. The risk of experiencing a stuck CEA and subsequent criticality is reduced during this PHYSICS TESTS exception by the Surveillance Requirements; and by ensuring that shutdown reactivity is available, equivalent to the reactivity worth of the estimated highest worth withdrawn CEA (Reference 3, Chapter 3).

PHYSICS TESTS include measurement of core parameters or exercise of control components that affect process variables. Among the process variables involved are total integrated radial peaking factor, Tq and ASI, which represent initial condition input (power peaking) to the accident analysis. Also involved are the shutdown and regulating CEAs, which affect power peaking and are required for shut down of the reactor. The limits for these variables are specified for each fuel cycle in the COLR.

As described in LCO 3.0.7, compliance with STE LCOs is optional and, therefore, no criteria of 10 CFR CALVERT CLIFFS - UNITS 1 & 2 B 3.1.7-3 Revision 43

STE-SDM B 3.1.7 BASES 50.36(c)(2)(ii) apply. Special Test Exception LCOs provide flexibility to perform certain operations by appropriately modifying requirements of other LCOs. A discussion of the criteria satisfied for the other LCOs is provided in their respective Bases.

LCO This LCO provides that a minimum amount of CEA worth is immediately available for reactivity control when CEA worth measurement tests are performed. The STE is required to permit the periodic verification of the actual versus predicted worth of the regulating and shutdown CEAs. The SDM requirements of LCO 3.1.1, the shutdown CEA insertion limits of LCO 3.1.5, and the regulating CEA insertion limits of LCO 3.1.6 may be suspended.

APPLICABILITY This LCO is applicable in MODEs 2 and 3. Although CEA worth testing is conducted in MODE 2, sufficient negative reactivity is inserted during the performance of these tests to result in temporary entry into MODE 3. Because the intent is to immediately return to MODE 2 to continue CEA worth measurements, the STE allows limited operation to 6 consecutive hours in MODE 3, as indicated by the Note, without having to borate to meet the SDM requirements of LCO 3.1.1.

ACTIONS A.1 With any CEA not fully inserted and less than the minimum required reactivity equivalent available for insertion, or with all CEAs inserted and the reactor subcritical by less than the reactivity equivalent of the highest worth CEA, restoration of the minimum SDM requirements must be accomplished by increasing the RCS boron concentration. The boration flow rate shall be 40 gpm and the boron concentration shall be 2300 ppm boric acid solution or equivalent. The required Completion Time of immediately is required to meet the assumptions of the safety analysis. It is assumed that boration will be continued until the SDM requirements are met.

CALVERT CLIFFS - UNITS 1 & 2 B 3.1.7-4 Revision 43

STE-SDM B 3.1.7 BASES SURVEILLANCE SR 3.1.7.1 REQUIREMENTS Verification of the position of each partially or fully withdrawn full-length or part-length CEA is necessary to ensure that the minimum negative reactivity requirements for insertion on a trip are preserved. A 2-hour Frequency is sufficient for the operator to verify that each CEA position is within the acceptance criteria.

SR 3.1.7.2 Prior demonstration that each CEA to be withdrawn from the core during PHYSICS TESTS is capable of full insertion, when tripped from at least a 50% withdrawn position, ensures that the CEA will insert on a trip signal. The Frequency ensures that the CEAs are OPERABLE prior to reducing SDM to less than the limits of LCO 3.1.1.

The SR is modified by a Note that allows the SR to not be performed during initial power escalation following a refueling outage if SR 3.1.4.6 has been met during that refueling outage. This allows the CEA drop time test, which also proves the CEAs are trippable, to be credited for this SR.

REFERENCES 1. 10 CFR Part 50

2. Regulatory Guide 1.68, Revision 2, Initial Test Programs for Water-Cooled Nuclear Power Plants,"

August 1978

3. UFSAR CALVERT CLIFFS - UNITS 1 & 2 B 3.1.7-5 Revision 11

STE-MODEs 1 and 2 B 3.1.8 B 3.1 REACTIVITY CONTROL SYSTEMS B 3.1.8 Special Test Exceptions (STE)-MODEs 1 and 2 BASES BACKGROUND The primary purpose of these MODEs 1 and 2 STEs is to permit relaxation of existing LCOs to allow the performance of certain PHYSICS TESTS. These tests are conducted to determine specific reactor core characteristics.

Reference 1, Appendix B,Section XI requires that a test program be established to ensure that structures, systems, and components will perform satisfactorily in service. All functions necessary to ensure that specified design conditions are not exceeded during normal operation and AOOs must be tested. Testing is required as an integral part of the design, fabrication, construction, and operation of the power plant. Requirements for notification of the Nuclear Regulatory Commission, for the purpose of conducting tests and experiments, are specified in Reference 1, 10 CFR 50.59.

The key objectives of a test program (Reference 2) are to:

a. Ensure that the facility has been adequately designed;
b. Validate the analytical models used in design and analysis;
c. Verify assumptions used for predicting plant response;
d. Ensure that installation of equipment in the facility has been accomplished in accordance with design; and
e. Verify that operating and emergency procedures are adequate.

To accomplish these objectives, testing is required prior to initial criticality, after each refueling shutdown, and during startup, low power operation, power ascension, and at power operation. The PHYSICS TESTS requirements for reload fuel cycles ensure that the operating characteristics of the core are consistent with the design predictions, and that the core can be operated as designed (Reference 3, Section 13.4).

PHYSICS TESTS procedures are written and approved in accordance with established formats. The procedures include all information necessary to permit a detailed execution of CALVERT CLIFFS - UNITS 1 & 2 B 3.1.8-1 Revision 2

STE-MODEs 1 and 2 B 3.1.8 BASES testing required to ensure that design intent is met.

PHYSICS TESTS are performed in accordance with these procedures and test results are approved prior to continued power escalation and long-term power operation.

Examples of PHYSICS TESTS include determination of critical boron concentration, CEA group worths, reactivity coefficients, flux symmetry, and core power distribution.

APPLICABLE It is acceptable to suspend certain LCOs for PHYSICS TESTS SAFETY ANALYSES because fuel damage criteria are not exceeded. Even if an accident occurs during a PHYSICS TESTS with one or more LCOs suspended, fuel damage criteria are preserved because the limits on power distribution and shutdown capability are maintained during PHYSICS TESTS.

Reference 3, Section 13.4 defines the requirements for initial testing of the facility, including PHYSICS TESTS.

Although these PHYSICS TESTS are generally accomplished within the limits of all LCOs, conditions may occur when one or more LCO must be suspended to make completion of PHYSICS TESTS possible or practical. This is acceptable as long as the fuel design criteria are not violated. As long as the LHR remains within its limit, fuel design criteria are preserved.

In this test, the following LCOs are suspended: LCO 3.1.3; LCO 3.1.4; LCO 3.1.5; LCO 3.1.6; LCO 3.2.3; and LCO 3.2.4.

The safety analysis (Reference 3, Section 13.4) places limits on allowable THERMAL POWER during PHYSICS TESTS and requires the LHR and the DNB parameter to be maintained within limits.

The individual LCOs governing CEA group height, insertion and alignment, ASI, F Tr , and Tq preserve the LHR limits.

Additionally, the LCOs governing RCS flow, reactor inlet temperature (Tc), and pressurizer pressure contribute to maintaining DNB parameter limits. The initial condition criteria for accidents sensitive to core power distribution are preserved by the LHR and DNB parameter limits. The criteria for the LOCA are specified in Reference 1, 10 CFR 50.46. The criteria for the loss of forced reactor CALVERT CLIFFS - UNITS 1 & 2 B 3.1.8-2 Revision 43

STE-MODEs 1 and 2 B 3.1.8 BASES coolant flow accident are specified in Reference 1, 10 CFR 50.46. Operation within the LHR limit preserves the LOCA criteria; operation within the DNB parameter limits preserves the loss of flow criteria.

During PHYSICS TESTS, one or more of the LCOs that normally preserve the LHR and DNB parameter limits may be suspended.

The results of the accident analysis are not adversely impacted, however, if LHR and DNB parameters are verified to be within their limits while the LCOs are suspended.

Therefore, SRs are placed as necessary to ensure that LHR and DNB parameters remain within limits during PHYSICS TESTS. Performance of these SRs allows PHYSICS TESTS to be conducted without decreasing the margin of safety.

PHYSICS TESTS include measurement of core parameters or exercise of control components that affect process variables. Among the process variables involved are F Tr , Tq, and ASI, which represent initial condition input (power peaking) to the accident analysis. Also involved are the shutdown and regulating CEAs, which affect power peaking and are required for shut down of the reactor. The limits for these variables are specified for each fuel cycle in the COLR.

As described in LCO 3.0.7, compliance with STE LCOs is optional and, therefore, no criteria of 10 CFR 50.36(c)(2)(ii) apply. Special Test Exception LCOs provide flexibility to perform certain operations by appropriately modifying requirements of other LCOs. A discussion of the criteria satisfied for the other LCOs is provided in their respective Bases.

LCO This LCO permits individual CEAs to be positioned outside of their normal group heights and insertion limits during the performance of PHYSICS TESTS, such as those required to:

a. Measure CEA worth;
b. Determine the reactor stability index and damping factor under xenon oscillation conditions;
c. Determine power distributions for nonnormal CEA configurations; CALVERT CLIFFS - UNITS 1 & 2 B 3.1.8-3 Revision 43

STE-MODEs 1 and 2 B 3.1.8 BASES

d. Measure rod shadowing factors; and
e. Measure temperature and power coefficients.

The requirements of LCO 3.1.3, LCO 3.1.4, LCO 3.1.5, LCO 3.1.6, LCO 3.2.3, and LCO 3.2.4 may be suspended during the performance of PHYSICS TESTS, provided THERMAL POWER is restricted to test power plateau, which shall not exceed 85% RTP.

APPLICABILITY This LCO is applicable in MODEs 1 and 2 because the reactor must be critical at various THERMAL POWER levels to perform the PHYSICS TESTS described in the LCO section. Limiting the test power plateau to < 85% RTP ensures that LHRs are maintained within acceptable limits.

ACTIONS A.1 If THERMAL POWER exceeds the test power plateau, THERMAL POWER must be reduced to restore the additional thermal margin provided by the reduction. The 15-minute Completion Time ensures that prompt action shall be taken to reduce THERMAL POWER to within acceptable limits.

B.1 and B.2 If Required Action A.1 cannot be completed within the required Completion Time, PHYSICS TESTS must be suspended within 1 hour1.157407e-5 days <br />2.777778e-4 hours <br />1.653439e-6 weeks <br />3.805e-7 months <br />, and the reactor must be brought to MODE 3.

Allowing 1 hour1.157407e-5 days <br />2.777778e-4 hours <br />1.653439e-6 weeks <br />3.805e-7 months <br /> for suspending PHYSICS TESTS allows the operator sufficient time to change any abnormal CEA configuration back to within the limits of LCO 3.1.4, LCO 3.1.5, and LCO 3.1.6. Bringing the reactor to MODE 3 within 6 hours6.944444e-5 days <br />0.00167 hours <br />9.920635e-6 weeks <br />2.283e-6 months <br /> increases thermal margin and is consistent with the Required Actions of the power distribution LCOs.

The required Completion Time of 6 hours6.944444e-5 days <br />0.00167 hours <br />9.920635e-6 weeks <br />2.283e-6 months <br /> is adequate for performing a controlled shutdown from full power conditions in an orderly manner and without challenging plant systems, and is consistent with power distribution LCO Completion Times.

CALVERT CLIFFS - UNITS 1 & 2 B 3.1.8-4 Revision 43

STE-MODEs 1 and 2 B 3.1.8 BASES SURVEILLANCE SR 3.1.8.1 REQUIREMENTS Verifying that THERMAL POWER is equal to or less than that allowed by the test power plateau, as specified in the PHYSICS TESTS procedure and required by the safety analysis, ensures that adequate LHR and DNB parameter margins are maintained while LCOs are suspended. The 1- hour Frequency is sufficient, based on the slow rate of power change and increased operational controls in place during PHYSICS TESTS.

REFERENCES 1. 10 CFR Part 50

2. Regulatory Guide 1.68, Revision 2, Initial Test Programs for Water-Cooled Nuclear Power Plants,"

August 1978

3. UFSAR CALVERT CLIFFS - UNITS 1 & 2 B 3.1.8-5 Revision 2