ML17117A588: Difference between revisions

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When pump flow is present in the system. For Slowdown, when the Slowdown Flow Control Valve is >0% open and the Slowdown line is not otherwise isolated.
When pump flow is present in the system. For Slowdown, when the Slowdown Flow Control Valve is >0% open and the Slowdown line is not otherwise isolated.
ACTIONS  
ACTIONS  
: 1. Separate Condition entry is allowed for each instrument channel.
: 1. Separate Condition entry is allowed for each instrument channel. CONDITION REQUIRED ACTION COMPLETION TIME A. One or more required A.1 Suspend the release of Immediately instrument channels radioactive liquid effluents inoperable due to its monitored by the alarm/trip setpoint less instrument channel. conservative than required.
CONDITION REQUIRED ACTION COMPLETION TIME A. One or more required A.1 Suspend the release of Immediately instrument channels radioactive liquid effluents inoperable due to its monitored by the alarm/trip setpoint less instrument channel.
OR A.2 Enter the Condition referenced Immediately in Table R12.2.1-1 forthe instrument channel. 8. One or more required 8.1 Enter the Condition referenced Immediately instrument channels In Table R12.2.1-1 forthe inoperable for reasons instrument channel. other than Condition A. (continued)
conservative than required.
OR A.2 Enter the Condition referenced Immediately in Table R12.2.1-1 forthe instrument channel.  
: 8. One or more required 8.1 Enter the Condition referenced Immediately instrument channels In Table R12.2.1-1 forthe inoperable for reasons instrument channel.
other than Condition A. (continued)
Page 1-12.2.1-1 ACTIONS CONDITION C. As required by Required C.1 Action A.2 or B.1 and referenced in Table R12.2.1-1.
Page 1-12.2.1-1 ACTIONS CONDITION C. As required by Required C.1 Action A.2 or B.1 and referenced in Table R12.2.1-1.
AND C.2 AND C.3 C.4 D. Required Action and D.1 associated Completion Time of Condition C not met. E. As required by Required E.1 Action A.2 or B.1 and referenced in Table R12.2.1-1.
AND C.2 AND C.3 C.4 D. Required Action and D.1 associated Completion Time of Condition C not met. E. As required by Required E.1 Action A.2 or B.1 and referenced in Table R12.2.1-1.
AND E.2 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls REQUIRED ACTION COMPLETION TIME Perform RSR 12.3.1.1 on at Prior to each release least two independent samples of the tanks contents.
AND E.2 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls REQUIRED ACTION COMPLETION TIME Perform RSR 12.3.1.1 on at Prior to each release least two independent samples of the tanks contents.
Verify the release rate Prior to each release calculations and discharge valve line-up independently with at least two qualified members of the technical staff. Return instrument channel to 30 days OPERABLE status. OR Place Administrative Control 30 days Clearance order to Lock-Closed OWF201, RW DSCH Tank River DSCH Valve, to remove the ability to conduct a Liquid Radwaste Discharge.
Verify the release rate Prior to each release calculations and discharge valve line-up independently with at least two qualified members of the technical staff. Return instrument channel to 30 days OPERABLE status. OR Place Administrative Control 30 days Clearance order to Lock-Closed OWF201, RW DSCH Tank River DSCH Valve, to remove the ability to conduct a Liquid Radwaste Discharge.
Suspend release of radioactive Immediately effluents via this pathway.
Suspend release of radioactive Immediately effluents via this pathway. Analyze affected effluent grab Once per 8 hours samples for principal gamma emitters and 1-131 at an LLD as specified in Table R12.3.1-2. Restore the instrument channel 30 days to OPERABLE status. Page 1-12.2.1-2 ACTIONS CONDITION F. As required by Required Action A.2 or 8.1 and referenced in Table R12.2.1-1.
Analyze affected effluent grab Once per 8 hours samples for principal gamma emitters and 1-131 at an LLD as specified in Table R12.3.1-2. Restore the instrument channel 30 days to OPERABLE status. Page 1-12.2.1-2 ACTIONS CONDITION F. As required by Required Action A.2 or 8.1 and referenced in Table R12.2.1-1.
G. -----------NOTE-------------
G. -----------NOTE-------------
Required Action G.1 shall be completed if this Condition is entered.  
Required Action G.1 shall be completed if this Condition is entered. --------------------------------
--------------------------------
Required Action C.3 or C.4, or E.2 and associated Completion Time not met. REQUIRED ACTION CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls COMPLETION TIME F.1 ----------------NOTE------------------
Required Action C.3 or C.4, or E.2 and associated Completion Time not met. REQUIRED ACTION CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls COMPLETION TIME F.1 ----------------NOTE------------------
Pump curves for instrument 3.a, or known valve positions for instrument 3.b, may be used to estimate flow. --------------------------------------------
Pump curves for instrument 3.a, or known valve positions for instrument 3.b, may be used to estimate flow. --------------------------------------------
Estimate the flow rate for the Once per 4 hours release in progress via the affected pathway.
Estimate the flow rate for the Once per 4 hours release in progress via the affected pathway. F.2 With remote position indication Prior to each release. for OWL005 (BDFCV) not available, verify valve position locally. G.1 Explain why the inoperability In accordance with was not corrected in a timely Technical manner in the next Radioactive Specification  
F.2 With remote position indication Prior to each release. for OWL005 (BDFCV) not available, verify valve position locally.
 
G.1 Explain why the inoperability In accordance with was not corrected in a timely Technical manner in the next Radioactive Specification 5.6.3. Effluent Release Report. Page 1-12.2.1-3 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls SURVEILLANCE REQUIREMENTS SURVEILLANCE FREQUENCY RSR 12.2.1.1 Perform SOURCE CHECK. Prior to each release RSR 12.2.1.2 Perform CHANNEL FUNCTIONAL TEST. Prior to each Release RSR 12.2.1.3 Perform CHANNEL CHECK. 24 hours RSR 12.2.1.4 Perform SOURCE CHECK. 31 days RSR 12.2.1.5 Perform CHANNEL FUNCTIONAL TEST. Except for 92 days Instrument 3.b, the test shall also demonstrate that the instrument indicates measured levels above the alarm/trip setpoint and that the control room alarm annunciates and the affected pathway automatically  
====5.6.3. Effluent====
: isolates, as applicable, under the following conditions:  
Release Report. Page 1-12.2.1-3 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls SURVEILLANCE REQUIREMENTS SURVEILLANCE FREQUENCY RSR 12.2.1.1 Perform SOURCE CHECK. Prior to each release RSR 12.2.1.2 Perform CHANNEL FUNCTIONAL TEST. Prior to each Release RSR 12.2.1.3 Perform CHANNEL CHECK. 24 hours RSR 12.2.1.4 Perform SOURCE CHECK. 31 days RSR 12.2.1.5 Perform CHANNEL FUNCTIONAL TEST. Except for 92 days Instrument 3.b, the test shall also demonstrate that the instrument indicates measured levels above the alarm/trip setpoint and that the control room alarm annunciates and the affected pathway automatically isolates, as applicable, under the following conditions:  
: a. Loss of power, b Downscale  
: a. Loss of power, b Downscale failure, or c. Controls not set in Operate or High Voltage mode. RSR 12.2.1.6 Perform CHANNEL CALIBRATION.
: failure, or c. Controls not set in Operate or High Voltage mode. RSR 12.2.1.6 Perform CHANNEL CALIBRATION.
N/A (No longer applicable per E.C. #360580) RSR 12.2.1.7 Perform CHANNEL CALIBRATION 24 months RSR 12.2.1.8 12 months Perform POSITION INDICATION VERIFICATION Page 1-12.2.1-4 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls Table R12.2.1-1(page1of2)
N/A (No longer applicable per E.C. #360580)
RSR 12.2.1.7 Perform CHANNEL CALIBRATION 24 months RSR 12.2.1.8 12 months Perform POSITION INDICATION VERIFICATION Page 1-12.2.1-4 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls Table R12.2.1-1(page1of2)
Radioactive Liquid Effluent Monitoring Instrumentation INSTRUMENT  
Radioactive Liquid Effluent Monitoring Instrumentation INSTRUMENT  
: 1. Gamma Scintillation Monitor providing Alarm and Automatic Termination of Release a. Liquid Radwaste Effluents Line 2. Gamma Scintillation Monitors providing Alarm but not providing Automatic Termination of Release a. Service Water Effluent Line (Unit 1) b. Service Water Effluent Line (Unit 2) c. RHR Service Water (Line A) Effluent Line (Unit 1) d. RHR Service Water (Line B) Effluent Line (Unit 1) e. RHR Service Water (Line A) Effluent Line (Unit 2) f. RHR Service Water (Line B) Effluent Line (Unit 2) REQUIRED CHANNELS PER !INSTRUMENT 1 1 1 CONDITION REFERENCED FROM REQUIRED ACTION A.2 AND B.1 c E E E E E E SURVEILLANCE REQUIREMENTS RSR 12.2.1.1 RSR 12.2.1.3 RSR 12.2.1.5 RSR 12.2.1. 7<al RSR 12.2.1.4 RSR 12.2.1.3 RSR 12.2.1.5 RSR 12.2.1.7(a) RSR 12.2.1.4 RSR 12.2.1.3 RSR 12.2.1.5 RSR 12.2.1.ia)
: 1. Gamma Scintillation Monitor providing Alarm and Automatic Termination of Release a. Liquid Radwaste Effluents Line 2. Gamma Scintillation Monitors providing Alarm but not providing Automatic Termination of Release a. Service Water Effluent Line (Unit 1) b. Service Water Effluent Line (Unit 2) c. RHR Service Water (Line A) Effluent Line (Unit 1) d. RHR Service Water (Line B) Effluent Line (Unit 1) e. RHR Service Water (Line A) Effluent Line (Unit 2) f. RHR Service Water (Line B) Effluent Line (Unit 2) REQUIRED CHANNELS PER !INSTRUMENT 1 1 1 CONDITION REFERENCED FROM REQUIRED ACTION A.2 AND B.1 c E E E E E E SURVEILLANCE REQUIREMENTS RSR 12.2.1.1 RSR 12.2.1.3 RSR 12.2.1.5 RSR 12.2.1. 7<al RSR 12.2.1.4 RSR 12.2.1.3 RSR 12.2.1.5 RSR 12.2.1.7(a) RSR 12.2.1.4 RSR 12.2.1.3 RSR 12.2.1.5 RSR 12.2.1.ia)
RSR 12.2.1.4 RSR 12.2.1.3 RSR 12.2.1.5 RSR 12.2.1.7(a)
RSR 12.2.1.4 RSR 12.2.1.3 RSR 12.2.1.5 RSR 12.2.1.7(a) RSR 12.2.1.4 RSR 12.2.1.3 RSR 12.2.1.5 RSR 12.2.1. 7(e) RSR 12.2.1.4 RSR 12.2.1.3 RSR 12.2.1.5 RSR 12.2.1. ia) RSR 12.2.1.4 RSR 12.2.1.3 RSR 12.2.1.5 RSR 12.2.1.ia) (continued)  
RSR 12.2.1.4 RSR 12.2.1.3 RSR 12.2.1.5 RSR 12.2.1. 7(e) RSR 12.2.1.4 RSR 12.2.1.3 RSR 12.2.1.5 RSR 12.2.1. ia) RSR 12.2.1.4 RSR 12.2.1.3 RSR 12.2.1.5 RSR 12.2.1.ia)  
(continued)  
<al The initial CHANNEL CALIBRATION shall be performed using one or more of the reference radioactive standards certified by the National Institute of Standards and Technology (NIST) or using standards that have been obtained from suppliers that participate in measurement assurance activities with NIST. These standards shall permit calibrating the system over its intended range of energy and measurement range. For subsequent CHANNEL CALIBRATION, the initial reference radioactive standards or radioactive sources that have been related to the initial calibration shall be used, in order to demonstrate linearity of the original calibration.
<al The initial CHANNEL CALIBRATION shall be performed using one or more of the reference radioactive standards certified by the National Institute of Standards and Technology (NIST) or using standards that have been obtained from suppliers that participate in measurement assurance activities with NIST. These standards shall permit calibrating the system over its intended range of energy and measurement range. For subsequent CHANNEL CALIBRATION, the initial reference radioactive standards or radioactive sources that have been related to the initial calibration shall be used, in order to demonstrate linearity of the original calibration.
This transfer calibration, combined with signal inputs, satisfies channel calibration and functional test requirements as implemented by station procedures.
This transfer calibration, combined with signal inputs, satisfies channel calibration and functional test requirements as implemented by station procedures.
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: 3. Flow Rate Measurement Devices a. Liquid Radwaste Effluent Line b. OWL005 BDFCV Position Indication REQUIRED CHANNELS PER !INSTRUMENT Page 1-12.2.1-6 CONDITION REFERENCED FROM REQUIRED ACTION A.2 AND B.1 F F SURVEILLANCE REQUIREMENTS RSR 12.2.1.2 RSR 12.2.1.3 RSR 12.2.1.7 RSR 12.2.1.8 12.2 INSTRUMENTATION 12.2.2 Radioactive Gaseous Effluent Monitoring Instrumentation CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls REC 12.2.2 The Radioactive Gaseous Effluent Instrumentation channels in Table R12.2.2-1 shall be OPERABLE with their alarm/trip setpoints set to ensure that the limits of REC 12.4.1 are not exceeded.
: 3. Flow Rate Measurement Devices a. Liquid Radwaste Effluent Line b. OWL005 BDFCV Position Indication REQUIRED CHANNELS PER !INSTRUMENT Page 1-12.2.1-6 CONDITION REFERENCED FROM REQUIRED ACTION A.2 AND B.1 F F SURVEILLANCE REQUIREMENTS RSR 12.2.1.2 RSR 12.2.1.3 RSR 12.2.1.7 RSR 12.2.1.8 12.2 INSTRUMENTATION 12.2.2 Radioactive Gaseous Effluent Monitoring Instrumentation CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls REC 12.2.2 The Radioactive Gaseous Effluent Instrumentation channels in Table R12.2.2-1 shall be OPERABLE with their alarm/trip setpoints set to ensure that the limits of REC 12.4.1 are not exceeded.
APPLICABILITY:
APPLICABILITY:
According to Table R12.2.2-1 ACTIONS Separate condition entry is allowed for each instrument channel.
According to Table R12.2.2-1 ACTIONS Separate condition entry is allowed for each instrument channel. CONDITION REQUIRED ACTION COMPLETION TIME A. One or more required A.1 Suspend the release of Immediately instrument channels radioactive gaseous inoperable due to its effluents monitored by alarm/trip setpoint less the instrument channel. conservative than required.
CONDITION REQUIRED ACTION COMPLETION TIME A. One or more required A.1 Suspend the release of Immediately instrument channels radioactive gaseous inoperable due to its effluents monitored by alarm/trip setpoint less the instrument channel.
OR A.2 Enter the Condition Immediately referenced in Table R12.2.2-1 for the instrument channel. B. One or more required B.1 Enter the Condition Immediately instrument channels referenced in Table R12.2.2-1 inoperable for reasons for the instrument channel. other than Condition A. (continued)
conservative than required.
OR A.2 Enter the Condition Immediately referenced in Table R12.2.2-1 for the instrument channel.
B. One or more required B.1 Enter the Condition Immediately instrument channels referenced in Table R12.2.2-1 inoperable for reasons for the instrument channel.
other than Condition A. (continued)
Page 1-12.2.2-1 ACTIONS CONDITION C. As required by Required C.1 Action A.2 or B.1 and referenced in Table R12.2.2-1.
Page 1-12.2.2-1 ACTIONS CONDITION C. As required by Required C.1 Action A.2 or B.1 and referenced in Table R12.2.2-1.
D. As required by Required D.1 Action A.2 or B.1 and referenced in Table R12.2.2-1.
D. As required by Required D.1 Action A.2 or B.1 and referenced in Table R12.2.2-1.
AND D.2 AND D.3 E. As required by Required E.1 Action A.2 or B.1 and referenced in Table AND R12.2.2-1.
AND D.2 AND D.3 E. As required by Required E.1 Action A.2 or B.1 and referenced in Table AND R12.2.2-1.
E.2 AND E.3 F. As required by Required F.1 Action A.2 or B.1 and referenced in Table R12.2.2-1.
E.2 AND E.3 F. As required by Required F.1 Action A.2 or B.1 and referenced in Table R12.2.2-1.
AND F.2 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls REQUIRED ACTION COMPLETION TIME Place instrument channel in 1 hour trip. Obtain grab samples.
AND F.2 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls REQUIRED ACTION COMPLETION TIME Place instrument channel in 1 hour trip. Obtain grab samples. Once per 8 hours Analyze grab samples for Within 24 hours noble gas emitters.
Once per 8 hours Analyze grab samples for Within 24 hours noble gas emitters.
following each grab sample Restore instrument channel to OPERABLE status. 30 days Obtain grab samples. Once per 8 hours Analyze grab samples for Within 24 hours noble gas emitters at an LLD following each grab as specified in Table sample R12.4.1-1.
following each grab sample Restore instrument channel to OPERABLE status. 30 days Obtain grab samples.
Once per 8 hours Analyze grab samples for Within 24 hours noble gas emitters at an LLD following each grab as specified in Table sample R12.4.1-1.
Restore instrument channel 30 days to OPERABLE status. Establish CONTINUOUS 4 hours SAMPLING with auxiliary sampling equipment as required in Table R12.4.1-1. Restore instrument channel 30 days to OPERABLE status. (continued)
Restore instrument channel 30 days to OPERABLE status. Establish CONTINUOUS 4 hours SAMPLING with auxiliary sampling equipment as required in Table R12.4.1-1. Restore instrument channel 30 days to OPERABLE status. (continued)
Page 1-12.2.2-2 ACTIONS CONDITION G. As required by Required Action A.2 or B.1 and referenced in Table R12.2.2-1.
Page 1-12.2.2-2 ACTIONS CONDITION G. As required by Required Action A.2 or B.1 and referenced in Table R12.2.2-1.
H. As required by Required Action A.2 or B.1 and referenced in Table R12.2.2-1.
H. As required by Required Action A.2 or B.1 and referenced in Table R12.2.2-1.
I.
I.
Required Action 1.1 shall be completed if this Condition is entered.  
Required Action 1.1 shall be completed if this Condition is entered. --------------------------------
--------------------------------
Required Action and associated Completion Time of Required Action D.3, E.3, F.2, or G.2 or H.4 not met. G.1 AND G.2 H.1 AND REQUIRED ACTION Estimate flow rate. CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls COMPLETION TIME Once per 4 hours Restore instrument channel 30 days to OPERABLE status. Verify offgas treatment Immediately system not bypassed.
Required Action and associated Completion Time of Required Action D.3, E.3, F.2, or G.2 or H.4 not met. G.1 AND G.2 H.1 AND REQUIRED ACTION Estimate flow rate. CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls COMPLETION TIME Once per 4 hours Restore instrument channel 30 days to OPERABLE status. Verify offgas treatment Immediately system not bypassed.
H.2.1 Verify at least one Immediately Instrument 1.a channel OPERABLE.
H.2.1 Verify at least one Immediately Instrument 1.a channel OPERABLE.
OR H.2.2 Verify Required Actions for Immediately Condition D are met. AND H.3 Obtain and analyze grab Once per 24 hours. samples.
OR H.2.2 Verify Required Actions for Immediately Condition D are met. AND H.3 Obtain and analyze grab Once per 24 hours. samples. AND H.4 Restore instrument channel 30 days to OPERABLE status. 1.1 Explain in the next In accordance with Radioactive Effluent Release Technical Report why the inoperability Specification 5.6.3. was not corrected within the time specified.
AND H.4 Restore instrument channel 30 days to OPERABLE status. 1.1 Explain in the next In accordance with Radioactive Effluent Release Technical Report why the inoperability Specification 5.6.3. was not corrected within the time specified.
Page 1-12.2.2-3 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls SURVEILLANCE REQUIREMENTS SURVEILLANCE RSR 12.2.2.1 Perform CHANNEL CHECK. RSR 12.2.2.2 Perform SOURCE CHECK. RS R 12. 2. 2. 3 -------------------------------NO TE-----------------------------------
Page 1-12.2.2-3 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls SURVEILLANCE REQUIREMENTS SURVEILLANCE RSR 12.2.2.1 Perform CHANNEL CHECK. RSR 12.2.2.2 Perform SOURCE CHECK. RS R 12. 2. 2. 3 -------------------------------NO TE-----------------------------------
F or Instruments 4.b and 4.c, not required to be performed until 7 days after Standby Gas Treatment is placed in operation.
F or Instruments 4.b and 4.c, not required to be performed until 7 days after Standby Gas Treatment is placed in operation.
Perform CHANNEL CHECK. FREQUENCY 24 hours 24 hours 7 days RSR 12.2.2.4 Perform SOURCE CHECK. 31 days RSR 12.2.2.5 Perform CHANNEL FUNCTIONAL TEST. For 92 days Instruments 3.a (log monitor only) and 1.a, the test shall also demonstrate that the control room alarm annunciates and the automatic isolation capability of the affected  
Perform CHANNEL CHECK. FREQUENCY 24 hours 24 hours 7 days RSR 12.2.2.4 Perform SOURCE CHECK. 31 days RSR 12.2.2.5 Perform CHANNEL FUNCTIONAL TEST. For 92 days Instruments 3.a (log monitor only) and 1.a, the test shall also demonstrate that the control room alarm annunciates and the automatic isolation capability of the affected pathway, as applicable, under the following conditions:  
: pathway, as applicable, under the following conditions:  
: a. Upscale, b. Inoperative, or c. Downscale RSR 12.2.2.6 Perform CHANNEL FUNCTIONAL TEST. The test shall 92 days also demonstrate that the instrument indicates measured levels above the alarm setpoint and that the control room alarm annunciates on a Loss of Counts condition.
: a. Upscale,  
: b. Inoperative, or c. Downscale RSR 12.2.2.6 Perform CHANNEL FUNCTIONAL TEST. The test shall 92 days also demonstrate that the instrument indicates measured levels above the alarm setpoint and that the control room alarm annunciates on a Loss of Counts condition.
RSR 12.2.2.7 Perform CHANNEL CALIBRATION 24 months Page 1-12.2.2-4   
RSR 12.2.2.7 Perform CHANNEL CALIBRATION 24 months Page 1-12.2.2-4   
: 1. a. Table R12.2.2-1 (page 1 of 2) CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls Radioactive Gaseous Effluent Monitoring Instrumentation APPLICABLE MODES OR REQUIRED CONDITION OTHER CHANNELS REFERENCED SPECIFIED PER FROM REQUIRED SURVEILLANCE INSTRUMEN&deg;Pa)
: 1. a. Table R12.2.2-1 (page 1 of 2) CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls Radioactive Gaseous Effluent Monitoring Instrumentation APPLICABLE MODES OR REQUIRED CONDITION OTHER CHANNELS REFERENCED SPECIFIED PER FROM REQUIRED SURVEILLANCE INSTRUMEN&deg;Pa)
CONDITIONS INSTRUMENT ACTION A.2 AND B.1 REQUIREMENTS Main Condenser Offgas Treatment System Effluent Monitoring System Noble Gas Activity Monitor -(b) 2 C, if only one required RSR 12.2.2.1 Providing Alarm and Automatic channel inoperable RSR 12.2.2.2 Termination of Release RSR 12.2.2.5 (Post-Treat)
CONDITIONS INSTRUMENT ACTION A.2 AND B.1 REQUIREMENTS Main Condenser Offgas Treatment System Effluent Monitoring System Noble Gas Activity Monitor -(b) 2 C, if only one required RSR 12.2.2.1 Providing Alarm and Automatic channel inoperable RSR 12.2.2.2 Termination of Release RSR 12.2.2.5 (Post-Treat)
D, if both required RSR 12.2.2.7(e) channels inoperable  
D, if both required RSR 12.2.2.7(e) channels inoperable  
: 2. Main Stack Monitoring System a. Noble Gas Activity Monitor (Low or Mid Range WRGM) b. Iodine Sampler (Grab Sampler)  
: 2. Main Stack Monitoring System a. Noble Gas Activity Monitor (Low or Mid Range WRGM) b. Iodine Sampler (Grab Sampler) c. Particulate Sampler (Grab Sampler) d. Effluent System Flow Rate Monitor e. Sampler Flow Rate Monitor (Low/Mid/Hi) (c) (c) (c) (c) (c) 1 1 (a) Equipment Part Numbers (EPN) are provided in Table R12.2.2-2. (b) During effluent releases via this pathway. (c) At all times. E F F G G RSR 12.2.2.1 RSR 12.2.2.4 RSR 12.2.2.6 RSR 12.2.2.7(d)
: c. Particulate Sampler (Grab Sampler)  
RSR 12.2.2.3 RSR 12.2.2.3 RSR 12.2.2.1 RSR 12.2.2.5 RSR 12.2.2.7 RSR 12.2.2.1 RSR 12.2.2.5 RSR 12.2.2.7 (Continued) (d) The initial CHANNEL CALIBRATION shall be performed using one or more of the referenced radioactive standards certified by the National Institute of Standards and Technology (NIST) or using standards that have been obtained from suppliers that participate in measurement assurance activities with NIST. These standards shall permit calibrating the system over its intended range of energy and measurement range. For subsequent CHANNEL CALIBRATIONS , the initial reference radioactive standards or radioactive sources that have been related to the initial calibration shall be used. (e) The initial CHANNEL CALIBRATION shall be performed using one or more of the reference radioactive standards cert i fied by the National Institute of Standards and Technology (NIST) or using standards that have been obtained from suppliers that participate in measurement assurance activities with NIST. These standards shall permit calibrating the system over its intended range of energy and measurement range. For subsequent CHANNEL CALIBRATION, the initial calibration shall be used, in order to demonstrate linearity of the original calibration. This transfer calibration, combined with signal inputs, satisfies channel calibration and functional test requirements as implemented by station procedures.
: d. Effluent System Flow Rate Monitor e. Sampler Flow Rate Monitor (Low/Mid/Hi)  
(c) (c) (c) (c) (c) 1 1 (a) Equipment Part Numbers (EPN) are provided in Table R12.2.2-2
. (b) During effluent releases via this pathway.  
(c) At all times. E F F G G RSR 12.2.2.1 RSR 12.2.2.4 RSR 12.2.2.6 RSR 12.2.2.7(d)
RSR 12.2.2.3 RSR 12.2.2.3 RSR 12.2.2.1 RSR 12.2.2.5 RSR 12.2.2.7 RSR 12.2.2.1 RSR 12.2.2.5 RSR 12.2.2.7 (Continued)  
(d) The initial CHANNEL CALIBRATION shall be performed using one or more of the referenced radioactive standards certified by the National Institute of Standards and Technology (NIST) or using standards that have been obtained from suppliers that participate in measurement assurance activities with NIST. These standards shall permit calibrating the system over its intended range of energy and measurement range. For subsequent CHANNEL CALIBRATIONS
, the initial reference radioactive standards or radioactive sources that have been related to the initial calibration shall be used. (e) The initial CHANNEL CALIBRATION shall be performed using one or more of the reference radioactive standards certified by the National Institute of Standards and Technology (NIST) or using standards that have been obtained from suppliers that participate in measurement assurance activities with NIST. These standards shall permit calibrating the system over its intended range of energy and measurement range. For subsequent CHANNEL CALIBRATION, the initial calibration shall be used, in order to demonstrate linearity of the original calibration
. This transfer calibration, combined with signal inputs, satisfies channel calibration and functional test requirements as implemented by station procedures.
Page 1-12.2.2-5   
Page 1-12.2.2-5   
: 3. 4. CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls Table R12.2.2-1 (page 2 of 2) Radioactive Gaseous Effluent Monitoring Instrumentation APPLICABLE MODES OR REQUIRED CONDITION OTHER CHANNELS REFERENCED SPECIFIED PER FROM REQUIRED SURVEILLANCE INSTRUMENTal CONDITIONS INSTRUMENT ACTION A.2 AND B.1 REQUIREMENTS Condenser Air Ejector Radioactivity Monitor (Prior to Input to Holdup System) a. Noble Gas Activity Monitor (f) H RSR 12.2.2.1 RSR 12.2.2.4 RSR 12.2.2.5 RSR 12.2.2.7(dl Standby Gas Treatment (SGT) Monitoring System a. Noble Gas Activity Monitor (Low (g) E RSR 12.2.2.1 or Mid Range WRGM) RSR 12.2.2.4 RSR 12.2.2.6 RSR 12.2.2.7(dl  
: 3. 4. CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls Table R12.2.2-1 (page 2 of 2) Radioactive Gaseous Effluent Monitoring Instrumentation APPLICABLE MODES OR REQUIRED CONDITION OTHER CHANNELS REFERENCED SPECIFIED PER FROM REQUIRED SURVEILLANCE INSTRUMENTal CONDITIONS INSTRUMENT ACTION A.2 AND B.1 REQUIREMENTS Condenser Air Ejector Radioactivity Monitor (Prior to Input to Holdup System) a. Noble Gas Activity Monitor (f) H RSR 12.2.2.1 RSR 12.2.2.4 RSR 12.2.2.5 RSR 12.2.2.7(dl Standby Gas Treatment (SGT) Monitoring System a. Noble Gas Activity Monitor (Low (g) E RSR 12.2.2.1 or Mid Range WRGM) RSR 12.2.2.4 RSR 12.2.2.6 RSR 12.2.2.7(dl  
: b. Iodine Sampler (Grab Sampler)  
: b. Iodine Sampler (Grab Sampler) (g) F RSR 12.2.2.3 c. Particulate Sampler (Grab (g) F RSR 12.2.2.3 Sampler) d. Effluent System Flow Rate (g) G RSR 12.2.2.1 Monitor RSR 12.2.2.5 RSR 12.2.2. 7 e. Sampler Flow Rate Monitor (g) 1 G RSR 12.2.2.1 (Low/Mid/Hi)
(g) F RSR 12.2.2.3  
RSR 12.2.2.5 RSR 12.2.2. 7 (a) Equipment Part Numbers (EPN) are provided in Table R12.2.2-2. (d) The initial CHANNEL CALIBRATION shall be performed using one or more of the referenced radioactive standards certified by the National Institute of Standards and Technology (NIST) or using standards that have been obtained from suppliers that participate in measurement assurance activities with NIST. These standards shall permit calibrating the system over its intended range of energy and measurement range. For subsequent CHANNEL CALIBRATIONS, the initial reference radioactive standards or radioactive sources that have been related to the initial calibration shall be used. (f) During operation of the main condenser air ejector. (g) During operation of SGT. Page 1-12.2.2-6 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls Table R 12.2.2-2 (page 1 of 2) Radioactive Gaseous Effluent Monitoring Instrumentation Applicability INSTRUMENT A. Unit 1 Applicable Instruments  
: c. Particulate Sampler (Grab (g) F RSR 12.2.2.3 Sampler)  
: 1. Main Condenser Offgas Treatment System Effluent Monitoring System a. Noble Gas Activity Monitor -Providing Alarm and Automatic Termination of Release 2. Main Stack Monitoring System a. Noble Gas Activity Monitor (Low or Mid Range WRGM) b. Iodine Sampler (Grab Sampler) c. Particulate Sampler (Grab Sampler) d. Effluent System Flow Rate Monitor e. Sampler Flow Rate Monitor (Low/Mid/Hi)  
: d. Effluent System Flow Rate (g) G RSR 12.2.2.1 Monitor RSR 12.2.2.5 RSR 12.2.2. 7 e. Sampler Flow Rate Monitor (g) 1 G RSR 12.2.2.1 (Low/Mid/Hi)
: 3. Condenser Air Ejector Radioactivity Monitor (Prior to Input to Holdup System) a. Noble Gas Activity Monitor 4. Standby Gas Treatment (SGT) Monitoring System a. Noble Gas Activity Monitor (Low/Mid Range WRGM) b. Iodine Sampler (Grab Sampler) c. Particulate Sampler (Grab Sampler) d. Effluent System Flow Rate Monitor e. Sampler Flow Rate Monitor (Low/Mid/Hi)
RSR 12.2.2.5 RSR 12.2.2. 7 (a) Equipment Part Numbers (EPN) are provided in Table R12.2.2-2.  
(d) The initial CHANNEL CALIBRATION shall be performed using one or more of the referenced radioactive standards certified by the National Institute of Standards and Technology (NIST) or using standards that have been obtained from suppliers that participate in measurement assurance activities with NIST. These standards shall permit calibrating the system over its intended range of energy and measurement range. For subsequent CHANNEL CALIBRATIONS, the initial reference radioactive standards or radioactive sources that have been related to the initial calibration shall be used. (f) During operation of the main condenser air ejector.  
(g) During operation of SGT. Page 1-12.2.2-6 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls Table R 12.2.2-2 (page 1 of 2) Radioactive Gaseous Effluent Monitoring Instrumentation Applicability INSTRUMENT A. Unit 1 Applicable Instruments  
: 1. Main Condenser Offgas Treatment System Effluent Monitoring System a. Noble Gas Activity Monitor -Providing Alarm and Automatic Termination of Release 2. Main Stack Monitoring System a. Noble Gas Activity Monitor (Low or Mid Range WRGM) b. Iodine Sampler (Grab Sampler)  
: c. Particulate Sampler (Grab Sampler)  
: d. Effluent System Flow Rate Monitor e. Sampler Flow Rate Monitor (Low/Mid/Hi)  
: 3. Condenser Air Ejector Radioactivity Monitor (Prior to Input to Holdup System) a. Noble Gas Activity Monitor 4. Standby Gas Treatment (SGT) Monitoring System a. Noble Gas Activity Monitor (Low/Mid Range WRGM) b. Iodine Sampler (Grab Sampler)  
: c. Particulate Sampler (Grab Sampler)  
: d. Effluent System Flow Rate Monitor e. Sampler Flow Rate Monitor (Low/Mid/Hi)
EPNS OF APPLICABLE EQUIPMENT 1D18-N903A, K901A, K601A, R601 1D18-N903B, K901B, K601B,R601 OD18-N514, R517, R518 Low Range OD18-N515, R517, R518 Mid Range OFT-VR019, OFY-VR019 AND 019A, OFR-VR019, OD18-K510, OD18-R518 OD18-N527, OD18-N528, OD18-R518 Low OD18-N530, OD18-N531, OB18-R518 Mid/Hi 1D18-N002, K613, R604, or 1D18-N012, K600, R605 OD18-N511, R515, R516 Low Range OD18-N512, R515, R516 Mid Range 1 FT-VG009, 1 FY-VG009, 1 FR-VG-009 OD18-N521, OD18-N522, OD18-R516 Low OD18-N524, OD18-N525, OB18-R516 Mid/Hi (Continued)
EPNS OF APPLICABLE EQUIPMENT 1D18-N903A, K901A, K601A, R601 1D18-N903B, K901B, K601B,R601 OD18-N514, R517, R518 Low Range OD18-N515, R517, R518 Mid Range OFT-VR019, OFY-VR019 AND 019A, OFR-VR019, OD18-K510, OD18-R518 OD18-N527, OD18-N528, OD18-R518 Low OD18-N530, OD18-N531, OB18-R518 Mid/Hi 1D18-N002, K613, R604, or 1D18-N012, K600, R605 OD18-N511, R515, R516 Low Range OD18-N512, R515, R516 Mid Range 1 FT-VG009, 1 FY-VG009, 1 FR-VG-009 OD18-N521, OD18-N522, OD18-R516 Low OD18-N524, OD18-N525, OB18-R516 Mid/Hi (Continued)
Page 1-12.2.2-7 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls Table R12.2.2-2 (page 2 of 2) Radioactive Gaseous Effluent Monitoring Instrumentation Applicability INSTRUMENT B. Unit 2 Applicable Instruments  
Page 1-12.2.2-7 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls Table R12.2.2-2 (page 2 of 2) Radioactive Gaseous Effluent Monitoring Instrumentation Applicability INSTRUMENT B. Unit 2 Applicable Instruments  
: 1. Main Condenser Offgas Treatment System Effluent Monitoring System a. Noble Gas Activity Monitor -Providing Alarm and Automatic Termination of Release 2. Main Stack Monitoring System a. Noble Gas Activity Monitor (Low or Mid Range WRGM) b. Iodine Sampler (Grab Sampler)  
: 1. Main Condenser Offgas Treatment System Effluent Monitoring System a. Noble Gas Activity Monitor -Providing Alarm and Automatic Termination of Release 2. Main Stack Monitoring System a. Noble Gas Activity Monitor (Low or Mid Range WRGM) b. Iodine Sampler (Grab Sampler) c. Particulate Sampler (Grab Sampler) d. Effluent System Flow Rate Monitor e. Sampler Flow Rate Monitor (Low/Mid/Hi)  
: c. Particulate Sampler (Grab Sampler)  
: 3. Condenser Air Ejector Radioactivity Monitor (Prior to Input to Holdup System) a. Noble Gas Activity Monitor 4. Standby Gas Treatment (SGT) Monitoring System a. Noble Gas Activity Monitor (Low/Mid Range WRGM) b. Iodine Sampler (Grab Sampler) c. Particulate Sampler (Grab Sampler) d. Effluent System Flow Rate Monitor e. Sampler Flow Rate Monitor (Low/Mid/Hi)
: d. Effluent System Flow Rate Monitor e. Sampler Flow Rate Monitor (Low/Mid/Hi)  
: 3. Condenser Air Ejector Radioactivity Monitor (Prior to Input to Holdup System) a. Noble Gas Activity Monitor 4. Standby Gas Treatment (SGT) Monitoring System a. Noble Gas Activity Monitor (Low/Mid Range WRGM) b. Iodine Sampler (Grab Sampler)  
: c. Particulate Sampler (Grab Sampler)  
: d. Effluent System Flow Rate Monitor e. Sampler Flow Rate Monitor (Low/Mid/Hi)
EPNS OF APPLICABLE EQUIPMENT 2D18-N903A, K901A, K601A, R601 2D18-N9038, K9018, K6018,R601 OD18-N514, R517, R518 Low Range OD18-N515, R517, R518 Mid Range OFT-VR019, OFY-VR019 AND 019A, OFR-VR019, OD18-K510, OD18-R518 OD18-N527, OD18-N528, OD18-R518 Low OD18-N530, OD18-N531, OB18-R518 Mid/Hi 2D18-N002, K613, R604, or 2D18-N012, K600, R605 OD18-N511, R515, R516 Low Range OD18-N512, R515, R516 Mid Range 2FT-VG009, 2FY-VG009, 2FR-VG-009 OD18-N521, OD18-N522, OD18-R516 Low OD18-N524, OD18-N525, OB18-R516 Mid/Hi Page 1-12.2.2-8 12.3 LIQUID EFFLUENTS 12.3.1 Liquid Effluent Concentration CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls REC 12.3.1 The concentration of radioactive material released from the site to areas at or beyond the SITE BOUNDARY shall be limited to: a. 10 times the concentration specified in 10 CFR 20.1001-20.2402 Appendix B, Table 2, Column 2 for radionuclides other than dissolved or entrained noble gases; and b. the values listed in Table R12.3.1-1 for total activity concentration for all dissolved or entrained noble gases. APPLICABILITY:
EPNS OF APPLICABLE EQUIPMENT 2D18-N903A, K901A, K601A, R601 2D18-N9038, K9018, K6018,R601 OD18-N514, R517, R518 Low Range OD18-N515, R517, R518 Mid Range OFT-VR019, OFY-VR019 AND 019A, OFR-VR019, OD18-K510, OD18-R518 OD18-N527, OD18-N528, OD18-R518 Low OD18-N530, OD18-N531, OB18-R518 Mid/Hi 2D18-N002, K613, R604, or 2D18-N012, K600, R605 OD18-N511, R515, R516 Low Range OD18-N512, R515, R516 Mid Range 2FT-VG009, 2FY-VG009, 2FR-VG-009 OD18-N521, OD18-N522, OD18-R516 Low OD18-N524, OD18-N525, OB18-R516 Mid/Hi Page 1-12.2.2-8 12.3 LIQUID EFFLUENTS 12.3.1 Liquid Effluent Concentration CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls REC 12.3.1 The concentration of radioactive material released from the site to areas at or beyond the SITE BOUNDARY shall be limited to: a. 10 times the concentration specified in 10 CFR 20.1001-20.2402 Appendix B, Table 2, Column 2 for radionuclides other than dissolved or entrained noble gases; and b. the values listed in Table R12.3.1-1 for total activity concentration for all dissolved or entrained noble gases. APPLICABILITY:
At all times. ACTIONS CONDITION REQUIRED ACTION COMPLETION TIME A. Concentration of radioactive A.1 Initiate action to restore the Immediately material released to areas at concentration to within or beyond the SITE limits. BOUNDARY not within limits. B. Requirements of RSR B.1 Enter Condition A of Immediately 12.3.1.4 not met. Technical Requirements Manual Section 3.7.d. SURVEILLANCE REQUIREMENTS SURVEILLANCE RSR 12.3.1.1 Determine radioactivity content of each radioactive liquid waste batch by sampling and analysis in accordance with Table R12.3.1-2.
At all times. ACTIONS CONDITION REQUIRED ACTION COMPLETION TIME A. Concentration of radioactive A.1 Initiate action to restore the Immediately material released to areas at concentration to within or beyond the SITE limits. BOUNDARY not within limits. B. Requirements of RSR B.1 Enter Condition A of Immediately 12.3.1.4 not met. Technical Requirements Manual Section 3.7.d. SURVEILLANCE REQUIREMENTS SURVEILLANCE RSR 12.3.1.1 Determine radioactivity content of each radioactive liquid waste batch by sampling and analysis in accordance with Table R12.3.1-2.
RSR 12.3.1.2 Perform post-release analysis of samples composited from batch releases in accordance with Table R12.3.1-2.
RSR 12.3.1.2 Perform post-release analysis of samples composited from batch releases in accordance with Table R12.3.1-2.
RSR 12.3.1.3 Determine radioactivity concentration of liquids discharged from continuous release points by sampling and analysis in accordance with Table R12.3.1-2.
RSR 12.3.1.3 Determine radioactivity concentration of liquids discharged from continuous release points by sampling and analysis in accordance with Table R12.3.1-2.
Page 1-12.3.1-1 FREQUENCY In accordance with the Radioactive Liquid Waste Sampling and Analysis Program.
Page 1-12.3.1-1 FREQUENCY In accordance with the Radioactive Liquid Waste Sampling and Analysis Program. In accordance with the Radioactive Liquid Waste Sampling and Analysis Program. In accordance with the Radioactive Liquid Waste Sampling and Analysis Program. (Continued)
In accordance with the Radioactive Liquid Waste Sampling and Analysis Program.
In accordance with the Radioactive Liquid Waste Sampling and Analysis Program.  
(Continued)
SURVEILLANCE REQUIREMENTS RS R 12. ;3. 1 .4 ------------------------N 0
SURVEILLANCE REQUIREMENTS RS R 12. ;3. 1 .4 ------------------------N 0
N ot required to be performed until 7 days after the start of addition if tank(s) is empty at the beginning of the addition.
N ot required to be performed until 7 days after the start of addition if tank(s) is empty at the beginning of the addition.
Verify the quantity of radioactive material of each outside temporary tank is low enough to ensure that in the event of an uncontrolled release of the tanks contents, the resulting concentration would be less than the REC limits. Page 1-12.3.1-2 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 7 days when radioactive material is being added to the tank(s).
Verify the quantity of radioactive material of each outside temporary tank is low enough to ensure that in the event of an uncontrolled release of the tanks contents, the resulting concentration would be less than the REC limits. Page 1-12.3.1-2 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 7 days when radioactive material is being added to the tank(s). Once within 7 days after each completion of addition of radioactive material to the tank(s).   
Once within 7 days after each completion of addition of radioactive material to the tank(s).   
.. NUCLIDE Kr-85m Kr-85 Kr-87 Kr-88 Ar-41 Xe-131m Xe-133m Xe-133 Xe-135m Xe-135 Table R12.3.1-1 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls ALLOWABLE CONCENTRATION (AC) OF DISSOLVED OR ENTRAINED NOBLE GASES RELEASED FROM THE SITE TO UNRESTRICTED AREAS IN LIQUID WASTE ALLOWABLE CONCENTRATION  
.. NUCLIDE Kr-85m Kr-85 Kr-87 Kr-88 Ar-41 Xe-131m Xe-133m Xe-133 Xe-135m Xe-135 Table R12.3.1-1 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls ALLOWABLE CONCENTRATION (AC) OF DISSOLVED OR ENTRAINED NOBLE GASES RELEASED FROM THE SITE TO UNRESTRICTED AREAS IN LIQUID WASTE ALLOWABLE CONCENTRATION  
(&#xb5;Ci/ml)* 2 x 10-4 5 x 10-4 4 x 10-5 9 x 10-5 7 x 10-5 7 x 10-4 5 x 10-4 6 x 10-4 2 x 10-4 2 x 10-4 Computed from Equation 20 of ICRP Publication 2 (1959), adjusted for infinite cloud submersion in water, and R = 0.01 rem/week, density=
(&#xb5;Ci/ml)* 2 x 10-4 5 x 10-4 4 x 10-5 9 x 10-5 7 x 10-5 7 x 10-4 5 x 10-4 6 x 10-4 2 x 10-4 2 x 10-4 Computed from Equation 20 of ICRP Publication 2 (1959), adjusted for infinite cloud submersion in water, and R = 0.01 rem/week, density= 1.0 glee and Pw/Pt = 1.0. Page 1-12.3.1-3 Table R12.3.1-2 (Page 1of4) CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls RADIOACTIVE LIQUID WASTE SAMPLING AND ANALYSIS PROGRAM LOWER LIMIT LIQUID RELEASE SAMPLING MINIMUM ANALYSIS TYPE OF ACTIVITY OF DETECTION TYPE FREQUENCY(gl FREQUENCY(gl ANALYSIS (LLD)(al (&#xb5;Ci/ml) A Batch Waste Prior to each Prior to each release, Principal Gamma 5x10-7 Release Tanks<dl release, Each Each Batch Emitters(fl Batch 1-131 1 x1 o-s Prior to each 31 days H-3 1x10-5 release, Each Composite (bl Batch Gross Alpha 1x10-7 Prior to each 92 days Sr-89, Sr-90 5x1 o-s release, Each Composite  
1.0 glee and Pw/Pt = 1.0. Page 1-12.3.1-3 Table R12.3.1-2 (Page 1of4) CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls RADIOACTIVE LIQUID WASTE SAMPLING AND ANALYSIS PROGRAM LOWER LIMIT LIQUID RELEASE SAMPLING MINIMUM ANALYSIS TYPE OF ACTIVITY OF DETECTION TYPE FREQUENCY(gl FREQUENCY(gl ANALYSIS (LLD)(al  
(&#xb5;Ci/ml)
A Batch Waste Prior to each Prior to each release, Principal Gamma 5x10-7 Release Tanks<dl  
: release, Each Each Batch Emitters(fl Batch 1-131 1 x1 o-s Prior to each 31 days H-3 1x10-5 release, Each Composite (bl Batch Gross Alpha 1x10-7 Prior to each 92 days Sr-89, Sr-90 5x1 o-s release, Each Composite  
<bl Batch Fe-55 1x10*5 Prior to each release, One 31 days Dissolved  
<bl Batch Fe-55 1x10*5 Prior to each release, One 31 days Dissolved  
& Batch per 31 Entrained Gases 1 x10*5 days (Gamma Emitters)
& Batch per 31 Entrained Gases 1 x10*5 days (Gamma Emitters)
Line 150: Line 101:
Gross Alpha 1x10*7 CONTINUOUS(c>
Gross Alpha 1x10*7 CONTINUOUS(c>
92 days Sr-89, Sr-90 5x10-s Composite(c>
92 days Sr-89, Sr-90 5x10-s Composite(c>
Fe-55 1x10"6 Page 1-12.3.1-4 Table R12.3.1-2 (Page 2of4) CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls RADIOACTIVE LIQUID WASTE SAMPLING AND ANALYSIS PROGRAM TABLE NOTATION  
Fe-55 1x10" 6 Page 1-12.3.1-4 Table R12.3.1-2 (Page 2of4) CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls RADIOACTIVE LIQUID WASTE SAMPLING AND ANALYSIS PROGRAM TABLE NOTATION a. The LLD is the smallest concentration of radioactive material in a sample that will be detected with 95% probability with only 5% probability of falsely concluding that a blank observation represents a "real" signal. For a particular measurement system, which may include radiochemical separation:
: a. The LLD is the smallest concentration of radioactive material in a sample that will be detected with 95% probability with only 5% probability of falsely concluding that a blank observation represents a "real" signal. For a particular measurement system, which may include radiochemical separation:
Where: LLD= 4.668 6 E
Where: LLD= 4.6686 E
* V
* V
* 2.22xl06
* 2.22xl0 6
* Y
* Y
* e<-Mi> LLD = the a priori lower limit of detection (microcurie per unit mass or volume),
* e<-Mi> LLD = the a priori lower limit of detection (microcurie per unit mass or volume), sb = the standard deviation of the background counting rate or of the counting rate of a blank sample as appropriate (counts per minute), JS B = background sum (counts) t = count time (minutes)
sb = the standard deviation of the background counting rate or of the counting rate of a blank sample as appropriate (counts per minute),
E =the counting efficiency (counts per transformation), V = the sample size (units of mass or volume), 2.22 x 10 6 = the number of transformations per minute per microcurie, Y = the fractional radiochemical yield, when applicable, A.= the radioactive decay constant for the particular radionuclide and for composite samples, and tit = the elapsed time between the midpoint of sample collection and the time of counting (for plant effluents, not environmental samples).
JS B = background sum (counts) t = count time (minutes)
E =the counting efficiency (counts per transformation), V = the sample size (units of mass or volume),
2.22 x 106 = the number of transformations per minute per microcurie, Y = the fractional radiochemical yield, when applicable, A.= the radioactive decay constant for the particular radionuclide and for composite  
: samples, and tit = the elapsed time between the midpoint of sample collection and the time of counting (for plant effluents, not environmental samples).
For batch samples taken and analyzed prior to release, tit is taken to be zero. The value of sb used in the calculation of the LLD for a detection system shall be based on the actual observed variance of the background counting rate or of the counting rate of the blank samples (as appropriate) rather than on an unverified theoretically predicted variance.
For batch samples taken and analyzed prior to release, tit is taken to be zero. The value of sb used in the calculation of the LLD for a detection system shall be based on the actual observed variance of the background counting rate or of the counting rate of the blank samples (as appropriate) rather than on an unverified theoretically predicted variance.
Typical values of E, V, Y, and tit shall be used in the calculation.
Typical values of E, V, Y, and tit shall be used in the calculation.
Alternate LLD Methodology An alternate methodology for LLD determination follows and is similar to the above LLD equation:
Alternate LLD Methodology An alternate methodology for LLD determination follows and is similar to the above LLD equation:
LLD= (2.71+4.65.JB)*Decay E *q *b
LLD= (2.71+4.65.JB)*Decay E *q *b
* Y *t *(2.22xl0
* Y *t *(2.22xl0 6) Page 1-12.3.1-5 Table R12.3.1-2 (Page 3 of 4) CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls RADIOACTIVE LIQUID WASTE SAMPLING AND ANALYSIS PROGRAM TABLE NOTATION Where: 8 = background sum (counts) E = counting efficiency q =sample quantity (mass or volume) b = abundance (if applicable)
: 6) Page 1-12.3.1-5 Table R12.3.1-2 (Page 3 of 4) CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls RADIOACTIVE LIQUID WASTE SAMPLING AND ANALYSIS PROGRAM TABLE NOTATION Where: 8 = background sum (counts) E = counting efficiency q =sample quantity (mass or volume) b = abundance (if applicable)
Y= fractional radiochemical yield or collection efficiency  
Y= fractional radiochemical yield or collection efficiency  
{if applicable) t= count time (minutes) 2.22 x 106 = number of disintegrations per minute per microcurie  
{if applicable) t= count time (minutes) 2.22 x 10 6 = number of disintegrations per minute per microcurie  
: 2. 71 + 4.65&deg;'18 = k2 + (2k '12 &deg;'18), and k = 1.645 (k=value of the t statistic from the single-tailed t distribution at a significance level of 0.95 and infinite degrees of freedom.
: 2. 71 + 4.65&deg;'18 = k 2 + (2k '12 &deg;'18), and k = 1.645 (k=value of the t statistic from the single-tailed t distribution at a significance level of 0.95 and infinite degrees of freedom. This means that the LLD result represents a 95% detection probability with a 5% probability of falsely concluding that the nuclide is present when it is not or that the nuclide is not present when it is.) Decay = eu.1 [/* .. RT/(1-e*ART)][A.
This means that the LLD result represents a 95% detection probability with a 5% probability of falsely concluding that the nuclide is present when it is not or that the nuclide is not present when it is.) Decay = eu.1 [/* .. RT/(1-e*ART)][A.
Td /(1-e*Hd)]
Td /(1-e*Hd)]
if applicable A.= radioactive decay constant (units consistent with RT and Td) = "delta t'', or the elapsed time between sample collection or the midpoint of sample collection and the time the count is started, depending on the type of sample (units consistent with A.) RT= elapsed real time, or the duration of the sample count {units consistent with A.) Td =sample deposition time, or the duration of analyte collection onto the sample media (units consistent with A.) The LLD may alternately be determined using installed radioanalytical software, if available
if applicable A.= radioactive decay constant (units consistent with RT and Td) = "delta t'', or the elapsed time between sample collection or the midpoint of sample collection and the time the count is started, depending on the type of sample (units consistent with A.) RT= elapsed real time , or the duration of the sample count {units consistent with A.) Td =sample deposition time, or the duration of analyte collection onto the sample media (units consistent with A.) The LLD may alternately be determined using installed radioanalytical software , if available. In addition to determining the correct number of channels over which to total the background sum, utilizing the software's ability to perform decay corrections (i.e. during sample collection, from sample collection to start of analysis, and during counting), this alternate method will result in a more accurate determination of the LLD. It should be recognized that the LLD is defined as a before the fact limit representing the capability of a measurement system and not as an after the fact limit for a particular measurement.
. In addition to determining the correct number of channels over which to total the background sum, utilizing the software's ability to perform decay corrections (i.e. during sample collection, from sample collection to start of analysis, and during counting),
Page 1-12.3.1-6 Table R12.3.1-2 (Page4 of4) CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls RADIOACTIVE LIQUID WASTE SAMPLING AND ANALYSIS PROGRAM TABLE NOTATION b. A composite sample is one in which the quantity of liquid sampled is proportional to the quantity of liquid waste discharged and in which the method of sample employed results in a specimen which is representative of the liquids released.  
this alternate method will result in a more accurate determination of the LLD. It should be recognized that the LLD is defined as a before the fact limit representing the capability of a measurement system and not as an after the fact limit for a particular measurement.
: c. To be representative of the quantities and concentrations of radioactive materials in liquid effluents, samples shall be collected in proportion to the rate of flow of the effluent stream. Prior to analyses, all samples taken for the composite shall be thoroughly mixed in order for the composite sample to be representative of the effluent release. d. A batch release is the discharge of liquid waste of a discrete volume. Prior to sampling for analyses , each batch shall be isolated, and then thoroughly mixed to assure representative sampling.  
Page 1-12.3.1-6 Table R12.3.1-2 (Page4 of4) CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls RADIOACTIVE LIQUID WASTE SAMPLING AND ANALYSIS PROGRAM TABLE NOTATION  
: e. A continuous release is the discharge of liquid wastes of a non-discrete volume; e.g., from a volume of system that has an input flow during the continuous release. f. The principal gamma emitters for which the LLD specification applies exclusively are the following radionuclides
: b. A composite sample is one in which the quantity of liquid sampled is proportional to the quantity of liquid waste discharged and in which the method of sample employed results in a specimen which is representative of the liquids released.  
: c. To be representative of the quantities and concentrations of radioactive materials in liquid effluents, samples shall be collected in proportion to the rate of flow of the effluent stream. Prior to analyses, all samples taken for the composite shall be thoroughly mixed in order for the composite sample to be representative of the effluent release.  
: d. A batch release is the discharge of liquid waste of a discrete volume. Prior to sampling for analyses, each batch shall be isolated, and then thoroughly mixed to assure representative sampling.  
: e. A continuous release is the discharge of liquid wastes of a non-discrete volume; e.g., from a volume of system that has an input flow during the continuous release.  
: f. The principal gamma emitters for which the LLD specification applies exclusively are the following radionuclides
: Mn-54, Fe-59, Co-58, Co-60, Zn-65, Mo-99, Cs-134, Cs-137, Ce-141, and Ce-144. This list does not mean that only these nuclides are to be detected and reported.
: Mn-54, Fe-59, Co-58, Co-60, Zn-65, Mo-99, Cs-134, Cs-137, Ce-141, and Ce-144. This list does not mean that only these nuclides are to be detected and reported.
Other peaks that are measurable and identifiable, at the 95% confidence level, together with the above nuclides, shall also be identified and reported.  
Other peaks that are measurable and identifiable, at the 95% confidence level, together with the above nuclides, shall also be identified and reported.  
: g. The provisions of RSR 12.0.2 and RSR 12.0.3 are applicable to the Radioactive Liquid Waste Sampling and Analysis Program.
: g. The provisions of RSR 12.0.2 and RSR 12.0.3 are applicable to the Radioactive Liquid Waste Sampling and Analysis Program. Page 1-12.3.1-7 12.3 LIQUID EFFLUENTS 12.3.2 Dose from Liquid Effluents CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls REC 12.3.2 The dose or dose commitment to a MEMBER OF THE PUBLIC from radioactive materials in liquid effluents released, from each reactor unit, from the site shall be limited to: a. 1.5 mrem to the total body and 5.0 mrem to any organ during any calendar quarter; and b. 3.0 mrem to the total body and 10.0 mrem to any organ during any calendar year. APPLICABILITY:
Page 1-12.3.1-7 12.3 LIQUID EFFLUENTS 12.3.2 Dose from Liquid Effluents CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls REC 12.3.2 The dose or dose commitment to a MEMBER OF THE PUBLIC from radioactive materials in liquid effluents  
: released, from each reactor unit, from the site shall be limited to: a. 1.5 mrem to the total body and 5.0 mrem to any organ during any calendar quarter; and b. 3.0 mrem to the total body and 10.0 mrem to any organ during any calendar year. APPLICABILITY:
At all times. Page 1-12.3.2-1 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls ACTIONS CONDITION REQUIRED ACTION COMPLETION TIME A. ------------NOTE------------
At all times. Page 1-12.3.2-1 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls ACTIONS CONDITION REQUIRED ACTION COMPLETION TIME A. ------------NOTE------------
A.1 Submit a Report, pursuant to 30 days following the Required Action A.1 shall 1 OCFR50, Appendix I, Section end of the quarter in be completed if this IV.A, to the NRC that identifies which the release Condition is entered.
A.1 Submit a Report, pursuant to 30 days following the Required Action A.1 shall 1 OCFR50, Appendix I, Section end of the quarter in be completed if this IV.A, to the NRC that identifies which the release Condition is entered. causes for exceeding limits, occurred radiological impact on finished ---------------------------------
causes for exceeding limits, occurred radiological impact on finished  
---------------------------------
drinking water supplies at the Calculated dose not nearest downstream drinking within limits. water source and defines actions to be taken to reduce releases of radioactive materials in liquid effluents during the remainder of the current calendar quarter and during the subsequent three calendar quarters so that the cumulative dose or dose commitment is within the limits of REC 12.3.2.b.
drinking water supplies at the Calculated dose not nearest downstream drinking within limits. water source and defines actions to be taken to reduce releases of radioactive materials in liquid effluents during the remainder of the current calendar quarter and during the subsequent three calendar quarters so that the cumulative dose or dose commitment is within the limits of REC 12.3.2.b.
B. Calculated dose B.1 Enter Condition A of REC 12.4.7. Immediately exceeds two times (2x) the limits. SURVEILLANCE REQUIREMENTS SURVEILLANCE FREQUENCY RS R 12. 3. 2. 1 ----------------------------------N 0 TE--------------------------------
B. Calculated dose B.1 Enter Condition A of REC 12.4.7. Immediately exceeds two times (2x) the limits. SURVEILLANCE REQUIREMENTS SURVEILLANCE FREQUENCY RS R 12. 3. 2. 1 ----------------------------------N 0 TE--------------------------------
Line 196: Line 131:
At all times. ACTIONS CONDITION REQUIRED ACTION COMPLETION TIME A. Liquid Radwaste A.1 Restore Liquid Radwaste 31 days Treatment System Treatment System to inoperable.
At all times. ACTIONS CONDITION REQUIRED ACTION COMPLETION TIME A. Liquid Radwaste A.1 Restore Liquid Radwaste 31 days Treatment System Treatment System to inoperable.
OPERABLE status. B.
OPERABLE status. B.
B.1 Submit a report to the NRC 30 days Required Action B.1 that includes inoperable shall be completed if this equipment or subsystem Condition is entered.
B.1 Submit a report to the NRC 30 days Required Action B.1 that includes inoperable shall be completed if this equipment or subsystem Condition is entered. identification and reason, --------------------------------
identification and reason, --------------------------------
action taken to restore the Untreated liquid waste inoperable equipment to release in progress.
action taken to restore the Untreated liquid waste inoperable equipment to release in progress.
OPERABLE status, and a summary description of the action(s) taken to prevent AND recurrence.
OPERABLE status, and a summary description of the action(s) taken to prevent AND recurrence.
Projected dose not within limits. C.
Projected dose not within limits. C.
C.1 Submit a report to the NRC 30 days Required Action C.1 that includes inoperable shall be completed if this equipment or subsystem Condition is entered.
C.1 Submit a report to the NRC 30 days Required Action C.1 that includes inoperable shall be completed if this equipment or subsystem Condition is entered. identification and reason , --------------------------------
identification and reason, --------------------------------
action taken to restore the Required Action and inoperable equipment to Associated Completion OPERABLE status, and a time of Condition A not summary description of the met. action(s) taken to prevent recurrence.
action taken to restore the Required Action and inoperable equipment to Associated Completion OPERABLE status, and a time of Condition A not summary description of the met. action(s) taken to prevent recurrence.
Page 1-12.3.3-1 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls SURVEILLANCE REQUIREMENTS SURVEILLANCE RS R 12. 3. 3. 1 -------------------------------N 0 TE-------------------------------
Page 1-12.3.3-1 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls SURVEILLANCE REQUIREMENTS SURVEILLANCE RS R 12. 3. 3. 1 -------------------------------N 0 TE-------------------------------
On ly required to be performed if liquid releases are planned and RSR has not been performed in the last 38 days 18 hours. FREQUENCY Determine projected doses due to liquid releases in 31 days accordance with the ODCM methods.
On ly required to be performed if liquid releases are planned and RSR has not been performed in the last 38 days 18 hours. FREQUENCY Determine projected doses due to liquid releases in 31 days accordance with the ODCM methods. RS R 12. 3. 3. 2 -------------------------------N 0 TE------------------------------
RS R 12. 3. 3. 2 -------------------------------N 0 TE------------------------------
N ot required to be performed if Liquid Radwaste Treatment System has been used to process radioactive liquid effluents in the last 115 days. Operate the Liquid Radwaste Treatment System equipment for at least 30 minutes. Page 1-12.3.3-2 92 days if a portable (vendor supplied) waste treatment system is being used. 180 days if a portable supplied) waste treatment system is not being used.
N ot required to be performed if Liquid Radwaste Treatment System has been used to process radioactive liquid effluents in the last 115 days. Operate the Liquid Radwaste Treatment System equipment for at least 30 minutes.
Page 1-12.3.3-2 92 days if a portable (vendor supplied) waste treatment system is being used. 180 days if a portable supplied) waste treatment system is not being used.
CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 12.4 GASEOUS EFFLUENTS AND TOTAL DOSE 12.4.1 Gaseous Effluent Dose Rates REC 12.4.1 The dose rate at or beyond the SITE BOUNDARY due to radioactive materials in gaseous effluents released from the site shall be limited to the following:  
CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 12.4 GASEOUS EFFLUENTS AND TOTAL DOSE 12.4.1 Gaseous Effluent Dose Rates REC 12.4.1 The dose rate at or beyond the SITE BOUNDARY due to radioactive materials in gaseous effluents released from the site shall be limited to the following:  
: a. For noble gases, 500 mrem/year to the total body and 3000 mrem/year to the skin; and b. For iodine-131, iodine-133,  
: a. For noble gases, 500 mrem/year to the total body and 3000 mrem/year to the skin; and b. For iodine-131, iodine-133, tritium, and all radionuclides in particulate form with half-lives  
: tritium, and all radionuclides in particulate form with half-lives  
> 8 days, 1500 mrem/year to any organ via the inhalation pathway. APPLICABILITY:
> 8 days, 1500 mrem/year to any organ via the inhalation pathway.
At all times. ACTIONS CONDITION REQUIRED ACTION COMPLETION TIME A. Dose rate not within limits. A.1 Initiate action to Immediately decrease release rates to maintain dose rates within limits. SURVEILLANCE REQUIREMENTS RSR 12.4.1.1 SURVEILLANCE Verify the dose rates due to noble gases, iodine-131, iodine-133, tritium, and all radionuclides in particulate form with half lives > 8 days in gaseous effluents is within limits utilizing the methodology and parameters of the ODCM limits by obtaining and analyzing representative samples in accordance with Table R12.4.1-1.
APPLICABILITY:
Page 1-12.4.1-1 FREQUENCY In accordance with the Radioactive Gaseous Waste Sampling and Analysis Program GASEOUS RELEASE TYPE A Containment Vent and Purge System" B. Main Vent Stack c. Standby Gas Treatment System D. Main Vent Stack And Standby Gas Treatment Systemc CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls Table R12.4.1-1 (Page 1 of 5) RADIOACTIVE GASEOUS WASTE SAMPLING AND ANALYSIS PROGRAM MINIMUM TYPE OF LOWER LIMIT OF SAMPLING ANALYSIS ACTIVITY DETECTION (LLD) FREQUENCY(il FREQUENCY(il ANALYSIS (&#xb5;Ci/ml)8 Prior to each Prior to each Principal Gamma release release Emitters 9 1x10-4 Each Purgeb, k Each Purgeb Grab Sample 31 daysb, k H-3 1x10*5 31 daysb 31 daysb Principal Gamma 1x10-4 Grab Sample Emitters 9 7 daysb,e 7 daysb.e H-3 1x10-6 Grab Sample 24 hoursc 24 hoursc Principal Gamma 1x10-4 Grab Sample Emitters 9 7 daysd 1-131 1x10*12 CONTINUOUS, Charcoal 1x10*10 Sample 1-133 CONTINUOUS, 7 daysd Principal Gamma 1x10*11 Particulate Emitters 9 (1-131, Sample Others) 31 days CONTINUOUS, Composite Gross Alpha 1x10*11 Particulate Sample 92 days CONTINUOUS, Composite Sr-89,Sr-90 1x10*11 Particulate Sample Noble Gas Noble Gases, CONTINUOUS' Gross Beta or 1x10*5 Monitor Gamma Page 1-12.4.1-2 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls Table R12.4.1-1(Page2 of 5) RADIOACTIVE GASEOUS WASTE SAMPLING AND ANALYSIS PROGRAM TABLE NOTATION a. The LLD is the smallest concentration of radioactive material in a sample that will be detected with 95% probability with 5% probability of falsely concluding that a blank observation represents a "real" signal. For a particular measurement system (which may include radiochemical separation):
At all times. ACTIONS CONDITION REQUIRED ACTION COMPLETION TIME A. Dose rate not within limits. A.1 Initiate action to Immediately decrease release rates to maintain dose rates within limits. SURVEILLANCE REQUIREMENTS RSR 12.4.1.1 SURVEILLANCE Verify the dose rates due to noble gases, iodine-131, iodine-133,  
: tritium, and all radionuclides in particulate form with half lives > 8 days in gaseous effluents is within limits utilizing the methodology and parameters of the ODCM limits by obtaining and analyzing representative samples in accordance with Table R12.4.1-1.
Page 1-12.4.1-1 FREQUENCY In accordance with the Radioactive Gaseous Waste Sampling and Analysis Program GASEOUS RELEASE TYPE A Containment Vent and Purge System" B. Main Vent Stack c. Standby Gas Treatment System D. Main Vent Stack And Standby Gas Treatment Systemc CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls Table R12.4.1-1 (Page 1 of 5) RADIOACTIVE GASEOUS WASTE SAMPLING AND ANALYSIS PROGRAM MINIMUM TYPE OF LOWER LIMIT OF SAMPLING ANALYSIS ACTIVITY DETECTION (LLD) FREQUENCY(il FREQUENCY(il ANALYSIS  
(&#xb5;Ci/ml)8 Prior to each Prior to each Principal Gamma release release Emitters9 1x10-4 Each Purgeb, k Each Purgeb Grab Sample 31 daysb, k H-3 1x10*5 31 daysb 31 daysb Principal Gamma 1x10-4 Grab Sample Emitters9 7 daysb,e 7 daysb.e H-3 1x10-6 Grab Sample 24 hoursc 24 hoursc Principal Gamma 1x10-4 Grab Sample Emitters9 7 daysd 1-131 1x10*12 CONTINUOUS, Charcoal 1x10*10 Sample 1-133 CONTINUOUS, 7 daysd Principal Gamma 1x10*11 Particulate Emitters9 (1-131, Sample Others) 31 days CONTINUOUS, Composite Gross Alpha 1x10*11 Particulate Sample 92 days CONTINUOUS, Composite Sr-89,Sr-90 1x10*11 Particulate Sample Noble Gas Noble Gases, CONTINUOUS' Gross Beta or 1x10*5 Monitor Gamma Page 1-12.4.1-2 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls Table R12.4.1-1(Page2 of 5) RADIOACTIVE GASEOUS WASTE SAMPLING AND ANALYSIS PROGRAM TABLE NOTATION  
: a. The LLD is the smallest concentration of radioactive material in a sample that will be detected with 95% probability with 5% probability of falsely concluding that a blank observation represents a "real" signal. For a particular measurement system (which may include radiochemical separation):
LLD= 4.66Sb E
LLD= 4.66Sb E
* V
* V
* 2.22xl 06
* 2.22xl 0 6
* Y
* Y
* e<-Mil Where: LLD is the "a priori" lower limit of detection as defined above (as microcurie per unit mass or volume),
* e<-Mil Where: LLD is the "a priori" lower limit of detection as defined above (as microcurie per unit mass or volume), sb is the standard deviation of the background counting rate or of the counting rate of a blank sample as appropriate (as counts per minute), B = background sum (counts) t = count time (minutes)
sb is the standard deviation of the background counting rate or of the counting rate of a blank sample as appropriate (as counts per minute),
E is the counting efficiency (as counts per transformation), V is the sample size (in units of mass or volume), 2.22x10 6 is the number of transformations per minute per microcurie, Y is the fractional radiochemical yield (when applicable), /... is the radioactive decay constant for the particular radionuclide, and is the elapsed time between midpoint of sample collection and time of counting (for plant effluents, not environmental samples).
B = background sum (counts) t = count time (minutes)
E is the counting efficiency (as counts per transformation),
V is the sample size (in units of mass or volume),
2.22x106 is the number of transformations per minute per microcurie, Y is the fractional radiochemical yield (when applicable),  
/... is the radioactive decay constant for the particular radionuclide, and is the elapsed time between midpoint of sample collection and time of counting (for plant effluents, not environmental samples).
The value of sb used in the calculation of the LLD for a detection system shall be based on the actual observed variance of the background counting rate or of the counting rate of the blank samples (as appropriate) rather than on an unverified theoretically predicted variance.
The value of sb used in the calculation of the LLD for a detection system shall be based on the actual observed variance of the background counting rate or of the counting rate of the blank samples (as appropriate) rather than on an unverified theoretically predicted variance.
Typical values of E, V, Y, and shall be used in the calculation.
Typical values of E, V, Y, and shall be used in the calculation.
Line 235: Line 156:
LLD= (2.71+4.65.fB)*Decay E
LLD= (2.71+4.65.fB)*Decay E
* q *b
* q *b
* Y *t *(2.22xl0
* Y *t *(2.22xl0 6) Page 1-12.4.1-3 Where: CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls Table R12.4.1-1 (Page 3 of 5) RADIOACTIVE GASEOUS WASTE SAMPLING AND ANALYSIS PROGRAM TABLE NOTATION 8 =background sum (counts) E = counting efficiency q = sample quantity (mass or volume) b = abundance (if applicable)
: 6) Page 1-12.4.1-3 Where: CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls Table R12.4.1-1 (Page 3 of 5) RADIOACTIVE GASEOUS WASTE SAMPLING AND ANALYSIS PROGRAM TABLE NOTATION 8 =background sum (counts) E = counting efficiency q = sample quantity (mass or volume) b = abundance (if applicable)
Y =fractional radiochemical yield or collection efficiency (if applicable)  
Y =fractional radiochemical yield or collection efficiency (if applicable)  
= count time (minutes) 2.22 x 106 = number of disintegrations per minute per microcurie  
= count time (minutes) 2.22 x 10 6 = number of disintegrations per minute per microcurie  
: 2. 71 + 4.65--/8 = k2 + (2k --/2 --/8), and k = 1.645 Decay RT (k=value of the t statistic from the single-tailed t distribution at a significance level of 0.95 and infinite degrees of freedom. This means that the LLD result represents a 95% detection probability with a 5% probability of falsely concluding that the nuclide is present when it is not or that the nuclide is not present when it is.) = e'-61 [A.RT/(1-e--.RT)][A.
: 2. 71 + 4.65--/8 = k 2 + (2k --/2 --/8), and k = 1.645 Decay RT (k=value of the t statistic from the single-tailed t distribution at a significance level of 0.95 and infinite degrees of freedom. This means that the LLD result represents a 95% detection probability with a 5% probability of falsely concluding that the nuclide is present when it is not or that the nuclide is not present when it is.) = e'-6 1 [A.RT/(1-e--.RT)][A.
Td /(1-e-Hd)]
Td /(1-e-Hd)]
if applicable  
if applicable  
=radioactive decay constant (units consistent with RT and Td) = "delta t", or the elapsed time between sample collection or the midpoint of sample collection and the time the count is started, depending on the type of sample (units consistent with A.) = elapsed real time, or the duration of the sample count (units consistent with A.) = sample deposition time, or the duration of analyte collection onto the sample media (units consistent with A.) The LLD may alternately be determined using installed radioanalytical  
=radioactive decay constant (units consistent with RT and Td) = "delta t", or the elapsed time between sample collection or the midpoint of sample collection and the time the count is started, depending on the type of sample (units consistent with A.) = elapsed real time, or the duration of the sample count (units consistent with A.) = sample deposition time, or the duration of analyte collection onto the sample media (units consistent with A.) The LLD may alternately be determined using installed radioanalytical software, if available.
: software, if available.
In addition to determining the correct number of channels over which to total the background sum , utilizing the software's ability to perform decay corrections (i.e. during sample collection, from sample collection to start of analysis, and during counting), this alternate method will result in a more accurate determination of the LLD. It should be recognized that the LLD is defined as a before the fact limit representing the capability of a measurement system and not as an after the fact limit for a particular measurement.  
In addition to determining the correct number of channels over which to total the background sum, utilizing the software's ability to perform decay corrections (i.e. during sample collection, from sample collection to start of analysis, and during counting),
: b. Sampling and analyses shall also be performed following shutdown, startup, or a thermal power change exceeding 20 percent of RATED THERMAL POWER in 1 hour unless (1) analysis shows that the dose equivalent 1-131 concentration in the primary coolant has not increased more than a factor of 5, and (2) the noble gas activity monitor shows that effluent activity has not increased by more than a factor of 3. Page 1-12.4.1-4 Table R12.4.1-1(Page4 of 5) CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls RADIOACTIVE GASEOUS WASTE SAMPLING AND ANALYSIS PROGRAM TABLE NOTATION c. Whenever there is flow through the SGT. If SGT is run more than 2 hrs in a 24-hour period, ensure a noble gas sample is obtained prior to securing SGT and particulate and iodine samples are taken within 24 hrs after securing SGT. A 2-hour run ensures required sample lower limits of detection are met for particulates and iodine. A SGT run of less than 2 hrs is not a significant contribution to offsite dose and requires no sampling.  
this alternate method will result in a more accurate determination of the LLD. It should be recognized that the LLD is defined as a before the fact limit representing the capability of a measurement system and not as an after the fact limit for a particular measurement.  
: d. Samples shall be changed at least once per 7 days and the analyses completed within 48 hours after removal from the sampler. Sampling shall also be performed within 24 hours following each shutdown, startup, or thermal power level change exceeding 20% of RATED THERMAL POWER in one hour. This requirement does not apply if 1) analysis shows that the dose equivalent 1-131 concentration in the primary coolant has not increased by more than a factor of 5, and 2) the noble gas activity monitor shows that effluent activity has not increased by more than a factor of 3. When samples collected for 24 hours are analyzed, the corresponding LLDs may be increased by a factor of 10. e. Tritium grab samples shall be taken at least once per 7 days from the plant vent to determine tritium releases in the ventilation exhaust from the spent fuel pool area whenever spent fuel is in the spent fuel pool. If there is no spent fuel in the fuel pool, sampling and analysis of tritium grab samples shall be performed at least once per 31 days. f. The ratio of the sample flow rate to the sampled stream flow rate shall be known for the time period covered by each dose or dose rate calculation made in accordance with RECs 12.4.1, 12.4.2 and 12.4.3. g. The principal gamma emitters for which the LLD specification applies include the following radionuclides:
: b. Sampling and analyses shall also be performed following  
Kr-87, Kr-88, Xe-133, Xe-133m, Xe-135, and Xe-138 for gaseous emissions and Mn-54, Fe-59, Co-58, Co-60, Zn-65, Mo-99, Cs-134, Cs-137, Ce-141 and Ce-144 for particulate emissions. This list does not mean that only these nuclides are to be detected and reported.
: shutdown, startup, or a thermal power change exceeding 20 percent of RATED THERMAL POWER in 1 hour unless (1) analysis shows that the dose equivalent 1-131 concentration in the primary coolant has not increased more than a factor of 5, and (2) the noble gas activity monitor shows that effluent activity has not increased by more than a factor of 3. Page 1-12.4.1-4 Table R12.4.1-1(Page4 of 5) CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls RADIOACTIVE GASEOUS WASTE SAMPLING AND ANALYSIS PROGRAM TABLE NOTATION  
: c. Whenever there is flow through the SGT. If SGT is run more than 2 hrs in a 24-hour period, ensure a noble gas sample is obtained prior to securing SGT and particulate and iodine samples are taken within 24 hrs after securing SGT. A 2-hour run ensures required sample lower limits of detection are met for particulates and iodine. A SGT run of less than 2 hrs is not a significant contribution to offsite dose and requires no sampling.  
: d. Samples shall be changed at least once per 7 days and the analyses completed within 48 hours after removal from the sampler.
Sampling shall also be performed within 24 hours following each shutdown,  
: startup, or thermal power level change exceeding 20% of RATED THERMAL POWER in one hour. This requirement does not apply if 1) analysis shows that the dose equivalent 1-131 concentration in the primary coolant has not increased by more than a factor of 5, and 2) the noble gas activity monitor shows that effluent activity has not increased by more than a factor of 3. When samples collected for 24 hours are analyzed, the corresponding LLDs may be increased by a factor of 10. e. Tritium grab samples shall be taken at least once per 7 days from the plant vent to determine tritium releases in the ventilation exhaust from the spent fuel pool area whenever spent fuel is in the spent fuel pool. If there is no spent fuel in the fuel pool, sampling and analysis of tritium grab samples shall be performed at least once per 31 days. f. The ratio of the sample flow rate to the sampled stream flow rate shall be known for the time period covered by each dose or dose rate calculation made in accordance with RECs 12.4.1, 12.4.2 and 12.4.3. g. The principal gamma emitters for which the LLD specification applies include the following radionuclides:
Kr-87, Kr-88, Xe-133, Xe-133m, Xe-135, and Xe-138 for gaseous emissions and Mn-54, Fe-59, Co-58, Co-60, Zn-65, Mo-99, Cs-134, Cs-137, Ce-141 and Ce-144 for particulate emissions
. This list does not mean that only these nuclides are to be detected and reported.
Other peaks that are measurable and identifiable, at the 95% confidence level, together with the above nuclides, shall also be identified and reported.  
Other peaks that are measurable and identifiable, at the 95% confidence level, together with the above nuclides, shall also be identified and reported.  
: h. The drywell tritium and noble gas samples and associated purge calculations are required when the Unit is at power (i.e. critical) and for the first 24 hours of purging activities following shutdown. The drywell tritium and noble gas sample results are valid for 30 hours from sample time if 1) the drywell radioactivity monitors have not indicated an increase in airborne or gaseous radioactivity, and 2) the drywell equipment and floor drain sump pumps run times have not indicated an increase in leakage in the drywell since the sample was taken, and 3) conditions are such that activity can be calculated for the radionuclide concentration at the time of the release.
: h. The drywell tritium and noble gas samples and associated purge calculations are required when the Unit is at power (i.e. critical) and for the first 24 hours of purging activities following shutdown. The drywell tritium and noble gas sample results are valid for 30 hours from sample time if 1) the drywell radioactivity monitors have not indicated an increase in airborne or gaseous radioactivity, and 2) the drywell equipment and floor drain sump pumps run times have not indicated an increase in leakage in the drywell since the sample was taken, and 3) conditions are such that activity can be calculated for the radionuclide concentration at the time of the release. If there is any reason to suspect that gaseous radioactivity levels have changed in the drywell that would compromise the calculated, or estimated, radionuclide concentrations at the time of the release, since the last sample (30 hours), a new sample and analyses should be requested prior to starting a drywell purge to meet the intent of providing current analyses to reflect actual activity released to the environment.
If there is any reason to suspect that gaseous radioactivity levels have changed in the drywell that would compromise the calculated, or estimated, radionuclide concentrations at the time of the release, since the last sample (30 hours), a new sample and analyses should be requested prior to starting a drywell purge to meet the intent of providing current analyses to reflect actual activity released to the environment.
If a known steady state leakage condition exists in the drywell it is possible to calculate a safe and accurate release package. Final release quantification will be based on calculated radionuclide concentrations at the time of the actual release. Page 1-12.4.1-5 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls Table R12.4.1-1 (Page 5 of 5) RADIOACTIVE GASEOUS WASTE SAMPLING AND ANALYSIS PROGRAM TABLE NOTATION If the drywell is PURGED in accordance with the ODCM definition, both noble gas and tritium sampling along with the appropriate purge calculations must be completed before the purge begins. If the drywell is simply VENTING in accordance with the ODCM definition, no sample is required before venting. i. The provisions of RSR 12.0.2 and RSR 12.0.3 are applicable to the Radioactive Gaseous Waste Sampling and Analysis Program. j. Not used. k. Drywell tritium results obtained during the previous 31 days may be used in the purge calculations, in lieu of actual results (from most recent purge sample), to allow completion of the purge calculations in an expeditious manner permitting a timely drywell entry, if necessary.
If a known steady state leakage condition exists in the drywell it is possible to calculate a safe and accurate release package.
However, the substitute tritium results are valid for use only if the three (3) conditions set forth in Note "h" surrounding sample validity are met. In addition, the substitute results do not change the requirements for tritium sampling frequency (Prior to each release Each Purge) per Table R12.4.1-1.
Final release quantification will be based on calculated radionuclide concentrations at the time of the actual release. Page 1-12.4.1-5 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls Table R12.4.1-1 (Page 5 of 5) RADIOACTIVE GASEOUS WASTE SAMPLING AND ANALYSIS PROGRAM TABLE NOTATION If the drywell is PURGED in accordance with the ODCM definition, both noble gas and tritium sampling along with the appropriate purge calculations must be completed before the purge begins. If the drywell is simply VENTING in accordance with the ODCM definition, no sample is required before venting. i. The provisions of RSR 12.0.2 and RSR 12.0.3 are applicable to the Radioactive Gaseous Waste Sampling and Analysis Program.  
: j. Not used. k. Drywell tritium results obtained during the previous 31 days may be used in the purge calculations, in lieu of actual results (from most recent purge sample),
to allow completion of the purge calculations in an expeditious manner permitting a timely drywell entry, if necessary.  
: However, the substitute tritium results are valid for use only if the three (3) conditions set forth in Note "h" surrounding sample validity are met. In addition, the substitute results do not change the requirements for tritium sampling frequency (Prior to each release Each Purge) per Table R12.4.1-1.
The most recent purge sample tritium analyses should be completed, and the associated purge calculations should be updated as soon as possible following sampling.
The most recent purge sample tritium analyses should be completed, and the associated purge calculations should be updated as soon as possible following sampling.
For reporting purposes (i.e. annual reports, etc.), actual results are used, when possible. Page 1-12.4.1-6 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 12.4 GASEOUS EFFLUENTS AND TOTAL DOSE 12.4.2 Dose from Noble Gases REC 12.4.2 The air dose due to noble gases in gaseous effluents released from each reactor unit from the site shall be limited to the following:  
For reporting purposes (i.e. annual reports, etc.), actual results are used, when possible. Page 1-12.4.1-6 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 12.4 GASEOUS EFFLUENTS AND TOTAL DOSE 12.4.2 Dose from Noble Gases REC 12.4.2 The air dose due to noble gases in gaseous effluents released from each reactor unit from the site shall be limited to the following:  
: a. For gamma radiation, 5 mrad during any calendar quarter and 10 mrad during any calendar year; and b. For beta radiation, 10 mrad during any calendar quarter and 20 mrad during any calendar year. APPLICABILITY:
: a. For gamma radiation, 5 mrad during any calendar quarter and 10 mrad during any calendar year; and b. For beta radiation, 10 mrad during any calendar quarter and 20 mrad during any calendar year. APPLICABILITY:
At all times. ACTIONS CONDITION REQUIRED ACTION A.
At all times. ACTIONS CONDITION REQUIRED ACTION A.
A.1 Submit a report to the NRC, Required Action A.1 shall pursuant to 1 OCFR50 be completed if this Appendix I Section IV.A, that Condition is entered.
A.1 Submit a report to the NRC, Required Action A.1 shall pursuant to 1 OCFR50 be completed if this Appendix I Section IV.A, that Condition is entered. identifies causes for exceeding limits, defines ------------------------------------
identifies causes for exceeding limits, defines ------------------------------------
corrective actions to be Calculated air dose not taken to reduce the releases, within limits. and proposed corrective actions to assure that subsequent releases are within limits. B. Calculated air dose B.1 Enter Condition A of REC exceeds two times (2x) the 12.4.7. limits. SURVEILLANCE REQUIREMENTS SURVEILLANCE RSR 12.4.2.1 Determine cumulative dose contributions for the current calendar quarter and current calendar year in accordance with the ODCM. Page 1-12.4.2-1 COMPLETION TIME 30 days following the end of the quarter in which the release occurred Immediately FREQUENCY 31 days CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 12.4 GASEOUS EFFLUENTS AND TOTAL DOSE 12.4.3 Dose From Iodine -131, Iodine -133, Tritium, and Radioactive Materials in Particulate Form REC 12.4.3 The dose to a MEMBER OF THE PUBLIC from iodine-131, iodine-133, tritium and all radionuclides in particulate form, with half-lives  
corrective actions to be Calculated air dose not taken to reduce the releases, within limits. and proposed corrective actions to assure that subsequent releases are within limits. B. Calculated air dose B.1 Enter Condition A of REC exceeds two times (2x) the 12.4.7. limits. SURVEILLANCE REQUIREMENTS SURVEILLANCE RSR 12.4.2.1 Determine cumulative dose contributions for the current calendar quarter and current calendar year in accordance with the ODCM. Page 1-12.4.2-1 COMPLETION TIME 30 days following the end of the quarter in which the release occurred Immediately FREQUENCY 31 days CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 12.4 GASEOUS EFFLUENTS AND TOTAL DOSE 12.4.3 Dose From Iodine -131, Iodine -133, Tritium, and Radioactive Materials in Particulate Form REC 12.4.3 The dose to a MEMBER OF THE PUBLIC from iodine-131, iodine-133, tritium and all radionuclides in particulate form, with half-lives  
> 8 days, in gaseous effluents released from each reactor unit, to areas at and beyond the SITE BOUNDARY shall be limited to: a. 5 7.5 mrem to any organ during any calendar quarter; and b. 5 15 mrem to any organ during any calendar year. APPLICABILITY
> 8 days, in gaseous effluents released from each reactor unit, to areas at and beyond the SITE BOUNDARY shall be limited to: a. 5 7.5 mrem to any organ during any calendar quarter; and b. 5 15 mrem to any organ during any calendar year. APPLICABILITY
: At all times. ACTIONS CONDITION REQUIRED ACTION COMPLETION TIME A. --------------NOTE---------------
: At all times. ACTIONS CONDITION REQUIRED ACTION COMPLETION TIME A. --------------NOTE---------------
A.1 Submit a report to the NRC, 30 days following the Required Action A.1 shall be pursuant to 10CFR50 end of the quarter in completed if this Condition is Appendix I Section IV.A, which the release entered.
A.1 Submit a report to the NRC, 30 days following the Required Action A.1 shall be pursuant to 10CFR50 end of the quarter in completed if this Condition is Appendix I Section IV.A, which the release entered. that identifies causes for occurred exceeding limits, defines --------------------------------------
that identifies causes for occurred exceeding limits, defines --------------------------------------
corrective actions to be Calculated dose not within taken to reduce the limits. releases, and proposed corrective actions to assure that subsequent releases are within limits. B. Calculated dose exceeds B.1 Enter Condition A of Immediately two times (2x) the limits. REC 12.4.7. SURVEILLANCE REQUIREMENTS SURVEILLANCE FREQUENCY RSR 12.4.3.1 Determine cumulative dose contributions for the current 31 days calendar quarter and calendar year for iodine-131, iodine-133, tritium, and radionuclides in particulate form with half-lives greater than 8 days in accordance with the methodology and parameters in the ODCM. Page 1-12.4.3-1 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 12.4 GASEOUS EFFLUENTS AND TOTAL DOSE 12.4.4 GASEOUS RADWASTE TREATMENT SYSTEM REC 12.4.4 The GASEOUS RADWASTE (OFF-GAS)
corrective actions to be Calculated dose not within taken to reduce the limits. releases, and proposed corrective actions to assure that subsequent releases are within limits. B. Calculated dose exceeds B.1 Enter Condition A of Immediately two times (2x) the limits. REC 12.4.7. SURVEILLANCE REQUIREMENTS SURVEILLANCE FREQUENCY RSR 12.4.3.1 Determine cumulative dose contributions for the current 31 days calendar quarter and calendar year for iodine-131, iodine-133,  
: tritium, and radionuclides in particulate form with half-lives greater than 8 days in accordance with the methodology and parameters in the ODCM. Page 1-12.4.3-1 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 12.4 GASEOUS EFFLUENTS AND TOTAL DOSE 12.4.4 GASEOUS RADWASTE TREATMENT SYSTEM REC 12.4.4 The GASEOUS RADWASTE (OFF-GAS)
TREATMENT SYSTEM shall be OPERABLE and in operation.
TREATMENT SYSTEM shall be OPERABLE and in operation.
APPLICABILITY:
APPLICABILITY:
During Main Condenser Air Ejector system operation.
During Main Condenser Air Ejector system operation.
ACTIONS CONDITION REQUIRED ACTION A. GASEOUS RADWASTE A.1 Restore system to TREATMENT SYSTEM OPERABLE status. inoperable.
ACTIONS CONDITION REQUIRED ACTION A. GASEOUS RADWASTE A.1 Restore system to TREATMENT SYSTEM OPERABLE status. inoperable.
AND OR A.2 Place system in operation
AND OR A.2 Place system in operation. GASEOUS RADWASTE TREATMENT SYSTEM not in operation.
. GASEOUS RADWASTE TREATMENT SYSTEM not in operation.
B. --------------NOTE--------------
B. --------------NOTE--------------
B.1 Submit a report to the NRC Required Action B.1 shall that includes defective be completed if this equipment or subsystem Condition is entered.
B.1 Submit a report to the NRC Required Action B.1 shall that includes defective be completed if this equipment or subsystem Condition is entered. identification and inoperability cause, actions ------------------------------------
identification and inoperability cause, actions ------------------------------------
taken to restore the Required action and inoperable equipment to Associated Completion OPERABLE status, and Time not met. summary description of actions taken to prevent a recurrence.
taken to restore the Required action and inoperable equipment to Associated Completion OPERABLE status, and Time not met. summary description of actions taken to prevent a recurrence.
SURVEILLANCE REQUIREMENTS SURVEILLANCE RSR 12.4.4.1 Verify the GASEOUS RADWASTE TREATMENT SYSTEM is in operation.
SURVEILLANCE REQUIREMENTS SURVEILLANCE RSR 12.4.4.1 Verify the GASEOUS RADWASTE TREATMENT SYSTEM is in operation.
Page 1-12.4.4-1 COMPLETION TIME 7 days 30 days FREQUENCY 7 days CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 12.4 GASEOUS EFFLUENTS AND TOTAL DOSE 12.4.5 VENTILATION EXHAUST TREATMENT SYSTEM REC 12.4.5 The appropriate portions of the VENTILATION EXHAUST TREATMENT SYSTEM shall; a. BE OPERABLE; and b. be used to reduce radioactive materials in gaseous waste prior to their discharge when the projected doses from each reactor unit from the site would exceed 0.3 mrem to any organ, when average over 31 days. APPLICABILITY:
Page 1-12.4.4-1 COMPLETION TIME 7 days 30 days FREQUENCY 7 days CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 12.4 GASEOUS EFFLUENTS AND TOTAL DOSE 12.4.5 VENTILATION EXHAUST TREATMENT SYSTEM REC 12.4.5 The appropriate portions of the VENTILATION EXHAUST TREATMENT SYSTEM shall; a. BE OPERABLE; and b. be used to reduce radioactive materials in gaseous waste prior to their discharge when the projected doses from each reactor unit from the site would exceed 0.3 mrem to any organ, when average over 31 days. APPLICABILITY:
At all times.
At all times.
Separate Condition entry is allowed for each VENTILATION EXHAUST TREATMENT system pathway.
Separate Condition entry is allowed for each VENTILATION EXHAUST TREATMENT system pathway. ACTIONS CONDITION REQUIRED ACTION COMPLETION TIME A. One or more required A.1 Restore system to 31 days VENTILATION EXHAUST OPERABLE status. TREATMENT SYSTEMS inoperable.
ACTIONS CONDITION REQUIRED ACTION COMPLETION TIME A. One or more required A.1 Restore system to 31 days VENTILATION EXHAUST OPERABLE status. TREATMENT SYSTEMS inoperable.
B.
B.
B.1 Submit a report to the NRC 30 days Required Action 8.1 shall that includes inoperable be completed if this equipment or subsystem condition is entered.
B.1 Submit a report to the NRC 30 days Required Action 8.1 shall that includes inoperable be completed if this equipment or subsystem condition is entered. identification and reason for inoperability, actions ------------------------------------
identification and reason for inoperability, actions ------------------------------------
taken to restore the Untreated gaseous waste inoperable equipment to release in progress. OPERABLE status, and summary description of AND actions taken to prevent a recurrence.
taken to restore the Untreated gaseous waste inoperable equipment to release in progress. OPERABLE status, and summary description of AND actions taken to prevent a recurrence.
Projected dose not within limits. (continued)
Projected dose not within limits. (continued)
Page 1-12.4.5-1 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls ACTIONS CONDITION REQUIRED ACTION COMPLETION TIME C. -------------NOTE---------------
Page 1-12.4.5-1 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls ACTIONS CONDITION REQUIRED ACTION COMPLETION TIME C. -------------NOTE---------------
C.1 Required Action C.1 shall Submit a report to the NRC 30 days that includes inoperable be completed if this Condition is entered.
C.1 Required Action C.1 shall Submit a report to the NRC 30 days that includes inoperable be completed if this Condition is entered. Required Action and associated Completion Time of Condition A not met. SURVEILLANCE REQUIREMENTS equipment or subsystem identification and reason for inoperability, actions taken to restore the inoperable equipment to OPERABLE status, and summary description of actions taken to prevent a recurrence.
Required Action and associated Completion Time of Condition A not met. SURVEILLANCE REQUIREMENTS equipment or subsystem identification and reason for inoperability, actions taken to restore the inoperable equipment to OPERABLE status, and summary description of actions taken to prevent a recurrence.
SURVEILLANCE RSR 12.4.5.1 Project doses due to gaseous releases from the site in accordance with the ODCM. RS R 12 .4 .5 .2 -------------------------NOTE---------------------------
SURVEILLANCE RSR 12.4.5.1 Project doses due to gaseous releases from the site in accordance with the ODCM. RS R 12 .4 .5 .2 -------------------------NOTE---------------------------
Not required to be performed if the VENTILATION EXHAUST TREATMENT SYSTEM has been used to process gaseous effluents in the last 115 days. OPERATE each required VENTILATION EXHAUST TREATMENT SYSTEM equipment for at least 30 minutes.
Not required to be performed if the VENTILATION EXHAUST TREATMENT SYSTEM has been used to process gaseous effluents in the last 115 days. OPERATE each required VENTILATION EXHAUST TREATMENT SYSTEM equipment for at least 30 minutes. Page 1-12.4.5-2 FREQUENCY 31 days 92 days CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 12.4 GASEOUS EFFLUENTS AND TOTAL DOSE 12.4.6 MARK II Containment REC 12.4.6 VENTING or PURGING of the containment drywell shall be: a. through the Primary Containment Vent and Purge System, or b. through the Standby Gas Treatment (SGT) System. APPLICABILITY:
Page 1-12.4.5-2 FREQUENCY 31 days 92 days CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 12.4 GASEOUS EFFLUENTS AND TOTAL DOSE 12.4.6 MARK II Containment REC 12.4.6 VENTING or PURGING of the containment drywell shall be: a. through the Primary Containment Vent and Purge System, or b. through the Standby Gas Treatment (SGT) System. APPLICABILITY:
During drywell VENTING or PURGING. ACTIONS CONDITION REQUIRED ACTION COMPLETION TIME A. Above requirements not met. A.1 Suspend all drywell Immediately VENTING and PURGING. SURVEILLANCE REQUIREMENTS SURVEILLANCE FREQUENCY RSR 12.4.6.1 Verify containment drywell is aligned for VENTING or 12 hours PURGING through the Primary Containment Vent and Purge System or the SGT System. RS R 12. 4. 6. 2 ---------------------------------N 0 TE-----------------------------
During drywell VENTING or PURGING.
On ly required to be met when in MODES 1, 2, or 3. Verify: a. Both SGT trains are OPERABLE, and b. Only one of the SGT System trains to be used for PURGING. Page 1-12.4.6-1 Prior to PURGING through the SGT System.
ACTIONS CONDITION REQUIRED ACTION COMPLETION TIME A. Above requirements not met. A.1 Suspend all drywell Immediately VENTING and PURGING.
SURVEILLANCE REQUIREMENTS SURVEILLANCE FREQUENCY RSR 12.4.6.1 Verify containment drywell is aligned for VENTING or 12 hours PURGING through the Primary Containment Vent and Purge System or the SGT System. RS R 12. 4. 6. 2 ---------------------------------N 0 TE-----------------------------
On ly required to be met when in MODES 1, 2, or 3. Verify: a. Both SGT trains are OPERABLE, and b. Only one of the SGT System trains to be used for PURGING.
Page 1-12.4.6-1 Prior to PURGING through the SGT System.
CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 12.4 GASEOUS EFFLUENTS AND TOTAL DOSE 12.4.7 Total Dose REC 12.4.7 The dose or dose commitment to any MEMBER OF THE PUBLIC due to releases of radioactivity and radiation from all uranium fuel cycle sources over 12 consecutive months shall be limited to: 25 mrem to the total body; and b. 75 mrem to the thyroid; and c. 25 mrem to any other organ. APPLICABILITY:
CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 12.4 GASEOUS EFFLUENTS AND TOTAL DOSE 12.4.7 Total Dose REC 12.4.7 The dose or dose commitment to any MEMBER OF THE PUBLIC due to releases of radioactivity and radiation from all uranium fuel cycle sources over 12 consecutive months shall be limited to: 25 mrem to the total body; and b. 75 mrem to the thyroid; and c. 25 mrem to any other organ. APPLICABILITY:
At all times. ACTIONS CONDITION A. -------------N 0 TE---------------
At all times. ACTIONS CONDITION A. -------------N 0 TE---------------
Req u ired Action A.1 and A.2 shall be completed if this Condition is entered.
Req u ired Action A.1 and A.2 shall be completed if this Condition is entered. As required by Required Action B.1 of REC 12.3.2, 12.4.2, or 12.4.3. Calculated Total Dose not within limits. REQUIRED ACTION A.1 Submit a report to the NRC (Director, Nuclear Reactor Regulation) that defines the corrective action to be taken to reduce subsequent releases to prevent recurrence of exceeding the limits to include estimates of radiation exposure to a MEMBER OF THE PUBLIC from uranium fuel cycle sources, including all effluent pathways and direct radiation, for a 12 consecutive month period that includes the release(s) covered by this report. Page 1-12.4.7-1 COMPLETION TIME 30 days (continued)
As required by Required Action B.1 of REC 12.3.2, 12.4.2, or 12.4.3. Calculated Total Dose not within limits. REQUIRED ACTION A.1 Submit a report to the NRC (Director, Nuclear Reactor Regulation) that defines the corrective action to be taken to reduce subsequent releases to prevent recurrence of exceeding the limits to include estimates of radiation exposure to a MEMBER OF THE PUBLIC from uranium fuel cycle sources, including all effluent pathways and direct radiation, for a 12 consecutive month period that includes the release(s) covered by this report. Page 1-12.4.7-1 COMPLETION TIME 30 days (continued)
ACTIONS CONDITION A. (continued)
ACTIONS CONDITION A. (continued)
SURVEILLANCE REQUIREMENTS CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls REQUIRED ACTION A. 2 --------------N 0
SURVEILLANCE REQUIREMENTS CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls REQUIRED ACTION A. 2 --------------N 0
On ly applicable if the release condition resulting in violation of 40 CFR 190 has not been corrected.
On ly applicable if the release condition resulting in violation of 40 CFR 190 has not been corrected.
COMPLETION TIME Submit a request for a 30 days variance in accordance with 40 CFR 190, including the specified information of 40 CFR 190.11. SURVEILLANCE FREQUENCY RSR 12.4.7.1 Determine cumulative dose contributions from direct radiation and liquid and gaseous effluents in accordance with the ODCM. Page 1-12.4.7-2 31 days CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 12.4 GASEOUS EFFLUENTS AND TOTAL DOSE 12.4.8 Main Condenser REC 12.4.8 The release rate of the sum of the activities from the noble gases measured prior to the holdup line shall be limited to .::. 3.4 x 105 &#xb5;Ci/sec after 30 minutes decay. APPLICABILITY:
COMPLETION TIME Submit a request for a 30 days variance in accordance with 40 CFR 190, including the specified information of 40 CFR 190.11. SURVEILLANCE FREQUENCY RSR 12.4.7.1 Determine cumulative dose contributions from direct radiation and liquid and gaseous effluents in accordance with the ODCM. Page 1-12.4.7-2 31 days CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 12.4 GASEOUS EFFLUENTS AND TOTAL DOSE 12.4.8 Main Condenser REC 12.4.8 The release rate of the sum of the activities from the noble gases measured prior to the holdup line shall be limited to .::. 3.4 x 10 5 &#xb5;Ci/sec after 30 minutes decay. APPLICABILITY:
MODE 1, MODES 2 and 3 with any steam line not isolated and steam jet air ejectors (SJAE) in operation.
MODE 1, MODES 2 and 3 with any steam line not isolated and steam jet air ejectors (SJAE) in operation.
ACTIONS CONDITION REQUIRED ACTION COMPLETION TIME A. Release rate of the sum of A.1 Restore the release rate to 72 hours the activities from noble within limit. gases prior to the holdup line not within the limits. B. Required Action and B.1 Isolate all main steam 12 hours associated Completion lines. Time not met. OR B.2 Isolate the SJAE. 12 hours OR B.3.1 MODE3 12 hours AND B.3.2 MODE 4 36 hours Page 1-12.4.8-1 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls SURVEILLANCE REQUIREMENTS SURVEILLANCE RSR 12.4.8.1 Monitor the noble gas radioactivity rate prior to the holdup line in accordance with the ODCM and Table R12.2.2-1 RS R 12. 4. 8. 2 -----------------------------N 0 TE------------------------------------
ACTIONS CONDITION REQUIRED ACTION COMPLETION TIME A. Release rate of the sum of A.1 Restore the release rate to 72 hours the activities from noble within limit. gases prior to the holdup line not within the limits. B. Required Action and B.1 Isolate all main steam 12 hours associated Completion lines. Time not met. OR B.2 Isolate the SJAE. 12 hours OR B.3.1 MODE3 12 hours AND B.3.2 MODE 4 36 hours Page 1-12.4.8-1 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls SURVEILLANCE REQUIREMENTS SURVEILLANCE RSR 12.4.8.1 Monitor the noble gas radioactivity rate prior to the holdup line in accordance with the ODCM and Table R12.2.2-1 RS R 12. 4. 8. 2 -----------------------------N 0 TE------------------------------------
N ot required to be performed until 31 days after any Main Steam line not isolated and SJAE in operation.
N ot required to be performed until 31 days after any Main Steam line not isolated and SJAE in operation.
Verify the release rate of the sum of the activities from noble gases prior to the holdup line is within limits by performing an isotopic analysis of a representative sample of gases taken prior to the holdup line. Page 1-12.4.8-2 FREQUENCY CONTINUOUSLY Once within 4 hours after a increase in the nominal steady state fission gas release from the primary coolant, as indicated by the off gas treatment Noble Gas Activity  
Verify the release rate of the sum of the activities from noble gases prior to the holdup line is within limits by performing an isotopic analysis of a representative sample of gases taken prior to the holdup line. Page 1-12.4.8-2 FREQUENCY CONTINUOUSLY Once within 4 hours after a increase in the nominal steady state fission gas release from the primary coolant, as indicated by the off gas treatment Noble Gas Activity Monitor, after factoring out increases due to changes in THERMAL POWER level 31 days CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 12.4 GASEOUS EFFLUENTS AND TOTAL DOSE 12.4.9 Dose Limits for MEMBERS OF THE PUBLIC REC 12.4.9 Operations shall be conducted such that: a. Total Effective Dose Equivalent (TEDE) to individual MEMBERS OF THE PUBLIC does not exceed 100 mrem/year; and b. The dose in any unrestricted area from external sources does not exceed 2 mrem in any one hour. APPLICABILITY:
: Monitor, after factoring out increases due to changes in THERMAL POWER level 31 days CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 12.4 GASEOUS EFFLUENTS AND TOTAL DOSE 12.4.9 Dose Limits for MEMBERS OF THE PUBLIC REC 12.4.9 Operations shall be conducted such that: a. Total Effective Dose Equivalent (TEDE) to individual MEMBERS OF THE PUBLIC does not exceed 100 mrem/year; and b. The dose in any unrestricted area from external sources does not exceed 2 mrem in any one hour. APPLICABILITY:
At all times. ACTIONS CONDITION REQUIRED ACTION COMPLETION TIME A.
At all times. ACTIONS CONDITION REQUIRED ACTION COMPLETION TIME A.
A.1 Submit a report to the NRC 30 days Required Action A.1 shall be in accordance with completed if this Condition is 10 CFR 20.2203.
A.1 Submit a report to the NRC 30 days Required Action A.1 shall be in accordance with completed if this Condition is 10 CFR 20.2203. entered. -------------------------------------
entered.  
-------------------------------------
Dose limit of REC Item a. exceeded.
Dose limit of REC Item a. exceeded.
B.
B.
B.1 Submit a report to the NRC 30 days Required Action B.1 shall be in accordance with completed if this Condition is 10 CFR 20.2203.
B.1 Submit a report to the NRC 30 days Required Action B.1 shall be in accordance with completed if this Condition is 10 CFR 20.2203. entered. -------------------------------------
entered.  
-------------------------------------
Dose limit of REC Item b. exceeded.
Dose limit of REC Item b. exceeded.
Page 1-12.4.9-1 SURVEILLANCE REQUIREMENTS SURVEILLANCE CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls FREQUENCY RSR 12.4.9.1 Calculate the TEDE to individual MEMBERS OF THE PUBLIC in accordance with the ODCM. 12 months RSR 12.4.9.2 Determine and/or evaluate direct radiation exposures in unrestricted areas. Page 1-12.4.9-2 12 months CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 12.5 RADIOLOGICAL ENVIRONMENTAL MONITORING PROGRAM 12.5.1 Radiological Environmental Monitoring Program (REMP) REC 12.5.1 The REMP shall be conducted as specified in Table R12.5.1-1.
Page 1-12.4.9-1 SURVEILLANCE REQUIREMENTS SURVEILLANCE CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls FREQUENCY RSR 12.4.9.1 Calculate the TEDE to individual MEMBERS OF THE PUBLIC in accordance with the ODCM. 12 months RSR 12.4.9.2 Determine and/or evaluate direct radiation exposures in unrestricted areas. Page 1-12.4.9-2 12 months CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 12.5 RADIOLOGICAL ENVIRONMENTAL MONITORING PROGRAM 12.5.1 Radiological Environmental Monitoring Program (REMP) REC 12.5.1 The REMP shall be conducted as specified in Table R12.5.1-1.
APPLICABILITY:
APPLICABILITY:
At all times. ACTIONS CONDITION REQUIRED ACTION COMPLETION TIME A. --------------NOTE--------------
At all times. ACTIONS CONDITION REQUIRED ACTION COMPLETION TIME A. --------------NOTE--------------
A. 1 Initiate action to identify Jmmediately Required Action A.2 shall be completed if this Condition is entered.
A. 1 Initiate action to identify Jmmediately Required Action A.2 shall be completed if this Condition is entered. Sample type or location(s) required by Table R12.5.1-1 permanently unavailable.
Sample type or location(s) required by Table R12.5.1-1 permanently unavailable.  
suitable, alternative sampling media and/or specific locations for obtaining replacement samples for the pathway of interest and add them to the REMP. Delete locations from which samples are unavailable.
: suitable, alternative sampling media and/or specific locations for obtaining replacement samples for the pathway of interest and add them to the REMP. Delete locations from which samples are unavailable.
A.2 Prepare and submit a controlled version of the ODCM, in the next Annual Radiological Environmental Operating Report (REOR) including revised figures and tables reflecting the new location(s) with supporting information identifying the sample unavailability cause and justification of the new sampling location(s).
A.2 Prepare and submit a controlled version of the ODCM, in the next Annual Radiological Environmental Operating Report (REOR) including revised figures and tables reflecting the new location(s) with supporting information identifying the sample unavailability cause and justification of the new sampling location(s).
Page 1-12.5.1-1 In accordance with Technical Specification 5.6.2 (continued)
Page 1-12.5.1-1 In accordance with Technical Specification 5.6.2 (continued)
ACTIONS CONDITION B.
ACTIONS CONDITION B.
Required Action B.1 shall be completed if this Condition is entered.  
Required Action B.1 shall be completed if this Condition is entered. ------------------------------------
------------------------------------
Level of radioactivity as the result of plant effluents in an environmental sampling medium at a specified location exceeds the reporting levels of Table R 12.5.1-2 when averaged over any calendar quarter. C. -------------NOTE--------------
Level of radioactivity as the result of plant effluents in an environmental sampling medium at a specified location exceeds the reporting levels of Table R 12.5.1-2 when averaged over any calendar quarter.
Required Action C.1 shall be completed if this Condition is entered. ------------------------------------
C. -------------NOTE--------------
Required Action C.1 shall be completed if this Condition is entered.  
------------------------------------
More than one radionuclide in Table R12.5.1-2 detected in the sampling medium. AND C1 C2 --+--+ ...
More than one radionuclide in Table R12.5.1-2 detected in the sampling medium. AND C1 C2 --+--+ ...
RL1 RL2 where; C = concentration RL = reporting level. B.1 C.1 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls REQUIRED ACTION COMPLETION TIME Submit a report to the NRC 30 days that identifies the cause(s) for exceeding the limits and defines the corrective actions to be taken to reduce radioactive effluents so that the potential annual dose to a MEMBER OF THE PUBLIC is less than the calendar year reporting level of REC 12.3.2, 12.4.2 or 12.4.3. The methodology and parameters used to estimate the potential annual dose to a MEMBER OF THE PUBLIC shall be indicated in this report. Submit a report to the NRC 30 days that identifies the cause(s) for exceeding the limits and defines the corrective actions to be taken to reduce radioactive effluents so that the potential annual dose to a MEMBER OF THE PUBLIC is less than the calendar year reporting level of REC 12.3.2, 12.4.2 or 12.4.3. The methodology and parameters used to estimate the potential annual dose to a MEMBER OF THE PUBLIC shall be indicated in this report. (continued)
RL1 RL2 where; C = concentration RL = reporting level. B.1 C.1 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls REQUIRED ACTION COMPLETION TIME Submit a report to the NRC 30 days that identifies the cause(s) for exceeding the limits and defines the corrective actions to be taken to reduce radioactive effluents so that the potential annual dose to a MEMBER OF THE PUBLIC is less than the calendar year reporting level of REC 12.3.2, 12.4.2 or 12.4.3. The methodology and parameters used to estimate the potential annual dose to a MEMBER OF THE PUBLIC shall be indicated in this report. Submit a report to the NRC 30 days that identifies the cause(s) for exceeding the limits and defines the corrective actions to be taken to reduce radioactive effluents so that the potential annual dose to a MEMBER OF THE PUBLIC is less than the calendar year reporting level of REC 12.3.2, 12.4.2 or 12.4.3. The methodology and parameters used to estimate the potential annual dose to a MEMBER OF THE PUBLIC shall be indicated in this report. (continued)
Page 1-12.5.1-2 ACTIONS CONDITION D. -------------N 0 TE--------------
Page 1-12.5.1-2 ACTIONS CONDITION D. -------------N 0 TE--------------
Req u ired Action D.1 and D.2 shall be completed if this Condition is entered.
Req u ired Action D.1 and D.2 shall be completed if this Condition is entered. Radionuclides other than those in Table R12.5.1-2 are detected.
Radionuclides other than those in Table R12.5.1-2 are detected.
AND The potential annual dose to a MEMBER OF THE PUBLIC from all radionuclides is greater than or equal to the calendar year limits of REC 12.3.2, 12.4.2, or 12.4.3. CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls REQUIRED ACTION D.1 Only required when the measured levels of radioactivity are the result of plant effluents.
AND The potential annual dose to a MEMBER OF THE PUBLIC from all radionuclides is greater than or equal to the calendar year limits of REC 12.3.2, 12.4.2, or 12.4.3. CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls REQUIRED ACTION D.1 Only required when the measured levels of radioactivity are the result of plant effluents.
COMPLETION TIME Submit a report to the NRC 30 days that identifies the cause(s) for exceeding the limits and defines the corrective actions to be taken to reduce radioactive effluents so that the potential annual dose to a MEMBER OF THE PUBLIC is less than the calendar year reporting level. The methodology and parameters used to estimate the potential annual dose to a MEMBER OF THE PUBLIC shall be indicated in this report. D. 2 -----------------N 0 TE---------------
COMPLETION TIME Submit a report to the NRC 30 days that identifies the cause(s) for exceeding the limits and defines the corrective actions to be taken to reduce radioactive effluents so that the potential annual dose to a MEMBER OF THE PUBLIC is less than the calendar year reporting level. The methodology and parameters used to estimate the potential annual dose to a MEMBER OF THE PUBLIC shall be indicated in this report. D. 2 -----------------N 0 TE---------------
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Describe the condition in the next Annual REOR. Page 1-12.5.1-3 In accordance with Technical Specification 5.6.2. (continued)
Describe the condition in the next Annual REOR. Page 1-12.5.1-3 In accordance with Technical Specification 5.6.2. (continued)
ACTIONS CONDITION E. -----------NOTE----------
ACTIONS CONDITION E. -----------NOTE----------
E.1 Required Action E.1 shall be completed if this Condition is entered.
E.1 Required Action E.1 shall be completed if this Condition is entered. RSR 12.5.1.1 not met. CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls REQUIRED COMPENSATORY MEASURE Prepare and submit to the NRC, in the next Annual REOR, a description of the reasons for not conducting the program as required and the plans for preventing a recurrence.
RSR 12.5.1.1 not met. CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls REQUIRED COMPENSATORY MEASURE Prepare and submit to the NRC, in the next Annual REOR, a description of the reasons for not conducting the program as required and the plans for preventing a recurrence.
Page 1-12.5.1-4 COMPLETION TIME In accordance with Technical Specification 5.6.2.
Page 1-12.5.1-4 COMPLETION TIME In accordance with Technical Specification 5.6.2.
CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls SURVEILLANCE REQUIREMENTS SURVEILLANCE RSR 12.5.1.1  
CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls SURVEILLANCE REQUIREMENTS SURVEILLANCE RSR 12.5.1.1 -------------------------------NOTES------------------------------
-------------------------------NOTES------------------------------
: 1. Deviations to the sampling schedule for the following reasons may occur and the RSR still be considered met provided the deviations are described in the next Annual REOR: a. specimens are unobtainable due to hazardous conditions, seasonal unavailability, or malfunction of sampling equipment, or b. a person or business who participates in the program goes out of business or can no longer provide samples, or c. a contractor omission which is corrected as soon as discovered.  
: 1. Deviations to the sampling schedule for the following reasons may occur and the RSR still be considered met provided the deviations are described in the next Annual REOR: a. specimens are unobtainable due to hazardous conditions, seasonal unavailability, or malfunction of sampling equipment, or b. a person or business who participates in the program goes out of business or can no longer provide samples, or c. a contractor omission which is corrected as soon as discovered.  
: 2. Malfunctioning equipment shall be corrected/replaced and replacement suppliers shall be found, as applicable, as soon as practicable.
: 2. Malfunctioning equipment shall be corrected/replaced and replacement suppliers shall be found, as applicable, as soon as practicable.
Collect and analyze samples in accordance with Table R12.5.1-1 and the ODCM to the detection capabilities required by Table R12.5.1-3.
Collect and analyze samples in accordance with Table R12.5.1-1 and the ODCM to the detection capabilities required by Table R12.5.1-3.
Page 1-12.5.1-5 FREQUENCY In accordance with the Radiological Environmental Monitoring Program EXPOSURE PATHWAY AND/ OR SAMPLE 1. Airborne Radioiodine and Particulates Table R12.5.1-1 (Page 1 of 6) RADIOLOGICAL ENVIRONMENTAL MONITORING PROGRAM NUMBER OF REPRESENTATIVE SAMPLES AND SAMPLING AND COLLECTION SAMPLE LOCATIONS 111 FREQUENCY 1111 Samples from a total of eight locations:
Page 1-12.5.1-5 FREQUENCY In accordance with the Radiological Environmental Monitoring Program EXPOSURE PATHWAY AND/ OR SAMPLE 1. Airborne Radioiodine and Particulates Table R12.5.1-1 (Page 1 of 6) RADIOLOGICAL ENVIRONMENTAL MONITORING PROGRAM NUMBER OF REPRESENTATIVE SAMPLES AND SAMPLING AND COLLECTION SAMPLE LOCATIONS 111 FREQUENCY 1111 Samples from a total of eight locations:
CONTINUOUS sampler operation with particulate sample a. Indicator-Near Field collection weekly, or more frequently if required due to dust Four samples from locations within 4.0 km (2.5 mi) in loading, and radioiodine canister different sectors.
CONTINUOUS sampler operation with particulate sample a. Indicator-Near Field collection weekly, or more frequently if required due to dust Four samples from locations within 4.0 km (2.5 mi) in loading , and radioiodine canister different sectors. collection weekly. b. Indicator-Far Field Four additional locations within 4.0 to 10 km (2.5 to 6.2 mi) in different sectors. c. Control One sample from a control location within 10 to 30 km (6.2 to 18.6 mi). Page 1-12.5.1-6 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls TYPE AND FREQUENCY OF ANAL YSIS 1111 Radioiodine Canister: 1-131 analysis weekly on near field samples and control(2 l samples. Particulate Samgler: Gross beta analysis weekly filter change l and gamma isotopic analysis(4 l quarterly on composite filters by location on near field and contro1<2> samples. (continued)
collection weekly. b. Indicator-Far Field Four additional locations within 4.0 to 10 km (2.5 to 6.2 mi) in different sectors.  
EXPOSURE PATHWAY AND/ OR SAMPLE 2. Direct Radiation 1" 1 Table R12.5.1-1 (Page 2 of 6) RADIOLOGICAL ENVIRONMENTAL MONITORING PROGRAM NUMBER OF REPRESENTATIVE SAMPLES AND SAMPLING AND COLLECTION SAMPLE LOCATIONS 111 FREQUENCY 1111 Forty routine monitoring stations, either with a Field Quarterly Dosimeter or with one instrument for measuring dose rate continuously, placed as follows: a. Indicator-Inner Ring (100 Series) One in each meteorological sector, in the general area of the SITE BOUNDARY (within 0.1 to 2.0 miles; 0.2 to 3.2 km); b. Indicator-Outer Ring (200 Series) One in each meteorological sector, within 4.8 to 10 km (3 to 6.2 mi); c. Other One at each Airborne location given in part 1.a. and 1.b. The balance of the Field Dosimeters to be placed at special interest locations beyond the Restricted Area where either a MEMBER OF THE PUBLIC or Exelon Nuclear employees have routine access. d. Control One at each airborne control location given in part 1.c. Page 1-12.5.1-7 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls TYPE AND FREQUENCY OF ANAL vs1s 1111 Gamma dose on each Field Dosimeter quarterly. (continued)
: c. Control One sample from a control location within 10 to 30 km (6.2 to 18.6 mi). Page 1-12.5.1-6 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls TYPE AND FREQUENCY OF ANAL YSIS1111 Radioiodine Canister: 1-131 analysis weekly on near field samples and control(2l samples.
Particulate Samgler:
Gross beta analysis weekly filter change l and gamma isotopic analysis(
4l quarterly on composite filters by location on near field and contro1<2> samples. (continued)
EXPOSURE PATHWAY AND/ OR SAMPLE 2. Direct Radiation 1"1 Table R12.5.1-1 (Page 2 of 6) RADIOLOGICAL ENVIRONMENTAL MONITORING PROGRAM NUMBER OF REPRESENTATIVE SAMPLES AND SAMPLING AND COLLECTION SAMPLE LOCATIONS 111 FREQUENCY 1111 Forty routine monitoring  
: stations, either with a Field Quarterly Dosimeter or with one instrument for measuring dose rate continuously, placed as follows:
: a. Indicator-Inner Ring (100 Series) One in each meteorological sector, in the general area of the SITE BOUNDARY (within 0.1 to 2.0 miles; 0.2 to 3.2 km); b. Indicator-Outer Ring (200 Series) One in each meteorological sector, within 4.8 to 10 km (3 to 6.2 mi); c. Other One at each Airborne location given in part 1.a. and 1.b. The balance of the Field Dosimeters to be placed at special interest locations beyond the Restricted Area where either a MEMBER OF THE PUBLIC or Exelon Nuclear employees have routine access. d. Control One at each airborne control location given in part 1.c. Page 1-12.5.1-7 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls TYPE AND FREQUENCY OF ANAL vs1s1111 Gamma dose on each Field Dosimeter quarterly
. (continued)
EXPOSURE PATHWAY AND/ OR SAMPLE 3. Waterborne  
EXPOSURE PATHWAY AND/ OR SAMPLE 3. Waterborne  
: a. a. Ground/Well  
: a. a. Ground/Well  
: a. b. Drinking<
: a. b. Drinking<7> c. Surface Water<1> a. b. d. Sediment a. CY-LA-170-301 Revision 8 June 2016 Part I, Radio l ogical Effluent Controls Table R12.5.1-1 (Page 3 of 6) RADIOLOGICAL ENVIRONMENTAL MONITORING PROGRAM NUMBER OF REPRESENTATIVE SAMPLES AND SAMPLING AND COLLECTION TYPE AND FREQUENCY SAMPLE LOCATIONS 111 FREQUENCY 1111 OF ANAL YSIS 1111 Indicator Quarterly Gamma isotopic!"'
7> c. Surface Water<1> a. b. d. Sediment  
: a. CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls Table R12.5.1-1 (Page 3 of 6) RADIOLOGICAL ENVIRONMENTAL MONITORING PROGRAM NUMBER OF REPRESENTATIVE SAMPLES AND SAMPLING AND COLLECTION TYPE AND FREQUENCY SAMPLE LOCATIONS 111 FREQUENCY 1111 OF ANAL YSIS1111 Indicator Quarterly Gamma isotopic!"'
and tritium analysis quarterly.
and tritium analysis quarterly.
Samples from two sources only if likely to be affected.  
Samples from two sources only if likely to be affected.  
<5> Indicator Grab samples weekly. Gross beta and gamma isotopic analyses<
<5> Indicator Grab samples weekly. Gross beta and gamma isotopic analyses<4> on One Sample from each community drinking water monthly composite; trit i um supply that could be affected by the station discharge analysis on quaterly within 10 km (6.2 mi) downstream of discharge.
4> on One Sample from each community drinking water monthly composite; tritium supply that could be affected by the station discharge analysis on quaterly within 10 km (6.2 mi) downstream of discharge.
composite. 1-131 on each composite when calculated dose for water consumption>
composite
1 mrem/vear. If no community water supply (Drinking Water) exists Grab samples weekly. Gross beta and gamma within 10 km downstream of discharge then surface isotopic analyses 14> on water sampling shall be performed. monthly composite; tritium lndicator<
. 1-131 on each composite when calculated dose for water consumption>
1 mrem/vear
. If no community water supply (Drinking Water) exists Grab samples weekly. Gross beta and gamma within 10 km downstream of discharge then surface isotopic analyses14> on water sampling shall be performed
. monthly composite
; tritium lndicator<
1> analysis on quarterly composite.
1> analysis on quarterly composite.
One surface sample downstream of discharge.
One surface sample downstream of discharge.
Contro1<7> One surface sample upstream of discharqe
Contro1<7> One surface sample upstream of discharqe. Indicator Semiannually Gamma isotopic At least one sample from downstream<
. Indicator Semiannually Gamma isotopic At least one sample from downstream<
1> area within 1 O analysis<4> semiannually. km (6.2 mi) of discharQe. (continued)
1> area within 1 O analysis<
4> semiannually
. km (6.2 mi) of discharQe.  
(continued)
Page 1-12.5.1-8 EXPOSURE PATHWAY AND/ OR SAMPLE 4. Ingestion  
Page 1-12.5.1-8 EXPOSURE PATHWAY AND/ OR SAMPLE 4. Ingestion  
: a. Milk(B) b. Fish c. Food Products CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls Table R12.5.1-1 (Page 4 of 6) RADIOLOGICAL ENVIRONMENTAL MONITORING PROGRAM NUMBER OF REPRESENTATIVE SAMPLES AND SAMPLING AND COLLECTION TYPE AND FREQUENCY SAMPLE LOCATIONS 111 FREQUENCY 1111 OF ANAL YSIS1111 a. Indicator Biweekly when animals are on Gamma isotopicl 41 and Samples from milking animals from a maximum pasture (May through October),
: a. Milk(B) b. Fish c. Food Products CY-LA-170-301 Revision 8 June 2016 Part I , Radiological Effluent Controls Table R12.5.1-1 (Page 4 of 6) RADIOLOGICAL ENVIRONMENTAL MONITORING PROGRAM NUMBER OF REPRESENTATIVE SAMPLES AND SAMPLING AND COLLECTION TYPE AND FREQUENCY SAMPLE LOCATIONS 111 FREQUENCY 1111 OF ANAL YSIS 1111 a. Indicator Biweekly when animals are on Gamma isotopicl 41 and Samples from milking animals from a maximum pasture (May through October), 1-131 <9> analysis on each monthly at other times sample. of three locations within 10 km (6.2 mi) distance. (November through April). b. Control One sample from milking animals at a control location within 10 to 30 km (6.2 to 18.6 mi). a. Indicator Two times annually.
1-131 <9> analysis on each monthly at other times sample. of three locations within 10 km (6.2 mi) distance. (November through April). b. Control One sample from milking animals at a control location within 10 to 30 km (6.2 to 18.6 mi). a. Indicator Two times annually.
Gamma isotopic Representative samples of commercially and analysis 14> on edible portions recreationally important species in discharge area, and representative samples from the LaSalle Lake. b. Control Representative samples of commercially and recreationally important species in control locations upstream of discharge.  
Gamma isotopic Representative samples of commercially and analysis14> on edible portions recreationally important species in discharge area, and representative samples from the LaSalle Lake. b. Control Representative samples of commercially and recreationally important species in control locations upstream of discharge.  
: a. Indicator Annually Gamma isotopid" 1 and Two representative samples from the principal 1-131 analysis on each sample. food pathways grown in each of four major quadrants within 10 km (6.2 mi), if available: At least one root vegetable sample(10> At least one broad leaf vegetable (or vegetation)(10> b. Control Two representative samples similar to indicator samples grown within 15 to 30 km (9.3 to 18.6 mi). (continued)
: a. Indicator Annually Gamma isotopid" 1 and Two representative samples from the principal 1-131 analysis on each sample. food pathways grown in each of four major quadrants within 10 km (6.2 mi), if available
: At least one root vegetable sample(10> At least one broad leaf vegetable (or vegetation)(
10> b. Control Two representative samples similar to indicator samples grown within 15 to 30 km (9.3 to 18.6 mi). (continued)
Page 1-12.5.1-9 EXPOSURE PATHWAY AND/ OR SAMPLE 4. Ingestion  
Page 1-12.5.1-9 EXPOSURE PATHWAY AND/ OR SAMPLE 4. Ingestion  
: d. Vegetation CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls Table R12.5.1-1 (Page 5 of 6) RADIOLOGICAL ENVIRONMENTAL MONITORING PROGRAM NUMBER OF REPRESENTATIVE SAMPLES AND SAMPLING AND COLLECTION TYPE AND FREQUENCY SAMPLE LOCATIONSl 1l FREQUENCY 1111 OF ANAL YSIS1111 -------------------NOTE--------------
: d. Vegetation CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls Table R12.5.1-1 (Page 5 of 6) RADIOLOGICAL ENVIRONMENTAL MONITORING PROGRAM NUMBER OF REPRESENTATIVE SAMPLES AND SAMPLING AND COLLECTION TYPE AND FREQUENCY SAMPLE LOCATIONSl 1 l FREQUENCY 1111 OF ANAL YSIS 1111 -------------------NOTE--------------
Monthly during the growing Gamma isotopic  
Monthly during the growing Gamma isotopic <4> These vegetation samples are only required if milk season (May through October). analysis and 1-131 sampling is not performed.
<4> These vegetation samples are only required if milk season (May through October). analysis and 1-131 sampling is not performed.
analysis on each sample. --a. Indicator Samples of 3 different types of broadleaf vegetation within 10 km (6.2 miles) at 2 different offsite locations in the highest D/Q sector of the station, if available.  
analysis on each sample. --a. Indicator Samples of 3 different types of broadleaf vegetation within 10 km (6.2 miles) at 2 different offsite locations in the highest D/Q sector of the station, if available.  
: b. Control Samples of 3 different types of broadleaf vegetation within 15 to 30 km (9.3 to 18.6 miles) in the lowest D/Q sector of station, if available.
: b. Control Samples of 3 different types of broadleaf vegetation within 15 to 30 km (9.3 to 18.6 miles) in the lowest D/Q sector of station, if available.
Page 1-12.5.1-10 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls Table R12.5.1-1(Page6of6)
Page 1-12.5.1-10 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls Table R12.5.1-1(Page6of6)
RADIOLOGICAL ENVIRONMENTAL MONITORING PROGRAM TABLE NOTATIONS (1) Specific parameters of distance and direction from the centerline of the midpoint of the two units and additional description where pertinent, shall be provided for each and every sample location in Table R12.5.1-1, except for vegetation.
RADIOLOGICAL ENVIRONMENTAL MONITORING PROGRAM TABLE NOTATIONS (1) Specific parameters of distance and direction from the centerline of the midpoint of the two units and additional description where pertinent, shall be provided for each and every sample location in Table R12.5.1-1, except for vegetation.
For vegetation (both food product and vegetation exposure pathways),
For vegetation (both food product and vegetation exposure pathways), due to location variability year to year, the parameters of distance and direction shall be provided in the Annual Environmental Operating Report. (2) Far field samples are analyzed when the respective near field sample results are inconsistent with previous measurements and radioactivity is confirmed as having its origin in airborne effluents from the station, or at the discretion of the ODCM Specialist.  
due to location variability year to year, the parameters of distance and direction shall be provided in the Annual Environmental Operating Report. (2) Far field samples are analyzed when the respective near field sample results are inconsistent with previous measurements and radioactivity is confirmed as having its origin in airborne effluents from the station, or at the discretion of the ODCM Specialist.  
(3) Airborne particulate sample filters shall be analyzed for gross beta radioactivity 24 hours or more after sampling to allow for radon and thoron daughter decay. If gross beta activity in air particulate samples is greater than 10 times the yearly mean of control samples, gamma isotopic analysis shall be performed on the individual samples. (4) Gamma isotopic analysis means the identification and quantification of gamma emitting radionuclides that may be attributable to the effluents from the station. (5) One or more instruments, such as a pressurized ion chamber, for measuring and recording dose rate continuously may be used in place of, or in addition to, integrating dosimeters.
(3) Airborne particulate sample filters shall be analyzed for gross beta radioactivity 24 hours or more after sampling to allow for radon and thoron daughter decay. If gross beta activity in air particulate samples is greater than 10 times the yearly mean of control samples, gamma isotopic analysis shall be performed on the individual samples.  
(4) Gamma isotopic analysis means the identification and quantification of gamma emitting radionuclides that may be attributable to the effluents from the station.  
(5) One or more instruments, such as a pressurized ion chamber, for measuring and recording dose rate continuously may be used in place of, or in addition to, integrating dosimeters.
Film badges shall not be used as dosimeters for measuring direct radiation.
Film badges shall not be used as dosimeters for measuring direct radiation.
The 40 locations is not an absolute number. The number of direct radiation monitoring stations may be reduced according to geographical limitations; e.g., if a station is adjacent to a lake, some sectors may be over water thereby reducing the number of dosimeters that could be placed at the indicated distances.
The 40 locations is not an absolute number. The number of direct radiation monitoring stations may be reduced according to geographical limitations; e.g., if a station is adjacent to a lake, some sectors may be over water thereby reducing the number of dosimeters that could be placed at the indicated distances.
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(9) 1-131 analysis means the analytical separation and counting procedure are specific for this radionuclide.  
(9) 1-131 analysis means the analytical separation and counting procedure are specific for this radionuclide.  
(10) One sample shall consist of a volume/weight of sample large enough to fill contractor specified container.  
(10) One sample shall consist of a volume/weight of sample large enough to fill contractor specified container.  
(11) The provisions of RSR 12.0.2 and RSR 12.0.3 are not applicable to the REMP. Page 1-12.5.1-11 Table R12.5.1-2 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls REPORTING LEVELS FOR RADIOACTIVITY CONCENTRATIONS IN ENVIRONMENTAL SAMPLES REPORTING LEVELS AIRBORNE PARTICULATE FOOD PRODUCTS ANALYSIS WATER (pCill) OR GASES (pCi/m3} FISH (pCi/kg, wet} MILK (pCi/I} (pCi/kc:i, wet) H-3 Mn-54 Fe-59 Co-58 Co-60 Zn-65 Zr-Nb-95 1-131 Cs-134 Cs-137 Ba-La-140 (1) (2) 20,000<1> 1,000 30,000 400 10,000 1,000 30,000 300 10,000 300 20,000 400 2(2) 0.9 3 100 30 10 1,000 60 1,000 50 20 2,000 70 2,000 200 300 For drinking water samples.
(11) The provisions of RSR 12.0.2 and RSR 12.0.3 are not applicable to the REMP. Page 1-12.5.1-11 Table R12.5.1-2 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls REPORTING LEVELS FOR RADIOACTIVITY CONCENTRATIONS IN ENVIRONMENTAL SAMPLES REPORTING LEVELS AIRBORNE PARTICULATE FOOD PRODUCTS ANALYSIS WATER (pCill) OR GASES (pCi/m 3} FISH (pCi/kg, wet} MILK (pCi/I} (pCi/kc:i, wet) H-3 Mn-54 Fe-59 Co-58 Co-60 Zn-65 Zr-Nb-95 1-131 Cs-134 Cs-137 Ba-La-140 (1) (2) 20,000<1> 1,000 30,000 400 10,000 1,000 30,000 300 10,000 300 20,000 400 2(2) 0.9 3 100 30 10 1,000 60 1,000 50 20 2,000 70 2,000 200 300 For drinking water samples. This is 40 CFR Part 141 value. If no drinking water pathway exists, a value of 30,000 pCi/I may be used. If no drinking water pathway exists, a value of 20 pCi/I may be used. Page 1-12.5.1-12 Table R12.5.1-3 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls DETECTION CAPABILITIES FOR ENVIRONMENTAL SAMPLE ANAL vs1s<a) LOWER LIMIT OF DETECTION (LLD)(bl AIRBORNE PARTICULATE FISH FOOD PRODUCTS SEDIMENT/SOIL ANALYSIS WATER (pCill) OR GASES CoCi/m 3) CoCi/ka, wet) MILK CoCill) (pCi/kg, wet) CoCi/ka, drv) Gross Beta 4 0.01 H-3 2,000 Mn-54 15 130 Fe-59 30 260 Co-58,60 15 130 Zn-65 30 260 Zr-95 30 Nb-95 15 1-131 1<c) 0.07 1 60 Cs-134 15 0.05 130 15 60 150 Cs-137 18 0.06 150 18 80 180 Ba-140 60 60 La-140 15 15 (a) All peaks identified at the 95% confidence level, shall also be analyzed and reported. (b) Most restrictive ODCM LLD requirement or technical requirement.
This is 40 CFR Part 141 value. If no drinking water pathway exists, a value of 30,000 pCi/I may be used. If no drinking water pathway exists, a value of 20 pCi/I may be used. Page 1-12.5.1-12 Table R12.5.1-3 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls DETECTION CAPABILITIES FOR ENVIRONMENTAL SAMPLE ANAL vs1s<a) LOWER LIMIT OF DETECTION (LLD)(bl AIRBORNE PARTICULATE FISH FOOD PRODUCTS SEDIMENT/SOIL ANALYSIS WATER (pCill) OR GASES CoCi/m3) CoCi/ka, wet) MILK CoCill) (pCi/kg, wet) CoCi/ka, drv) Gross Beta 4 0.01 H-3 2,000 Mn-54 15 130 Fe-59 30 260 Co-58,60 15 130 Zn-65 30 260 Zr-95 30 Nb-95 15 1-131 1<c) 0.07 1 60 Cs-134 15 0.05 130 15 60 150 Cs-137 18 0.06 150 18 80 180 Ba-140 60 60 La-140 15 15 (a) All peaks identified at the 95% confidence level, shall also be analyzed and reported.  
(b) Most restrictive ODCM LLD requirement or technical requirement.
The reported minimum detectable concentration (MDC) shall these values. (c) If no drinking water pathway exists, a value of 15 pCi/I may be used (NUREG 1301/1302)
The reported minimum detectable concentration (MDC) shall these values. (c) If no drinking water pathway exists, a value of 15 pCi/I may be used (NUREG 1301/1302)
Page 1-12.5.1-13 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 12.5 RADIOLOGICAL ENVIRONMENTAL MONITORING PROGRAM 12.5.2 Land Use Census REC 12.5.2 A Land Use Census shall be conducted and shall identify within a distance of 10 km (6.2 miles) the location in each of the 16 meteorological sectors of the nearest milk animal, the nearest residence, and an enumeration of livestock.
Page 1-12.5.1-13 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 12.5 RADIOLOGICAL ENVIRONMENTAL MONITORING PROGRAM 12.5.2 Land Use Census REC 12.5.2 A Land Use Census shall be conducted and shall identify within a distance of 10 km (6.2 miles) the location in each of the 16 meteorological sectors of the nearest milk animal, the nearest residence, and an enumeration of livestock.
Line 435: Line 291:
APPLICABILITY:
APPLICABILITY:
At all times. ACTIOl\IS CONDITIOl\I A. ------------1\!0TE--------------
At all times. ACTIOl\IS CONDITIOl\I A. ------------1\!0TE--------------
A.1 Required Action A.1 and A.2 shall be completed if this Condition is entered. Land use census identifies Al\ID a location which yields a calculated dose or dose commitment, via the same exposure  
A.1 Required Action A.1 and A.2 shall be completed if this Condition is entered. Land use census identifies Al\ID a location which yields a calculated dose or dose commitment, via the same exposure pathway, that is at least 20% greater than at a location from which samples are currently being obtained in accordance with REC 12.5.1. REQUIRED ACTIOl\I Add the new location to the Radiological Environmental Monitoring Program (REMP). Page 1-12.5.2-1 COMPLETIOl\I TIME 30 days (continued)
: pathway, that is at least 20% greater than at a location from which samples are currently being obtained in accordance with REC 12.5.1. REQUIRED ACTIOl\I Add the new location to the Radiological Environmental Monitoring Program (REMP). Page 1-12.5.2-1 COMPLETIOl\I TIME 30 days (continued)
ACTIONS CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls CONDITION REQUIRED ACTION COMPLETION TIME A. (continued)
ACTIONS CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls CONDITION REQUIRED ACTION COMPLETION TIME A. (continued)
A. 2 ---------------N 0 TE--------------
A. 2 ---------------N 0 TE--------------
----The sampling location(s),
----The sampling location(s), excluding the control location, having the lowest calculated dose or dose commitment(s), via the same exposure pathway, may be deleted from the REMP after October 31 of the year in which Land Use Census was conducted.
excluding the control location, having the lowest calculated dose or dose commitment(s),
via the same exposure  
: pathway, may be deleted from the REMP after October 31 of the year in which Land Use Census was conducted.
Submit the documentation for a change in the ODCM in the next Annual Radiological Environmental Operating Report and include the revised figures and tables for the ODCM reflecting the new location(s) with information supporting the change in sampling locations.
Submit the documentation for a change in the ODCM in the next Annual Radiological Environmental Operating Report and include the revised figures and tables for the ODCM reflecting the new location(s) with information supporting the change in sampling locations.
SURVEILLANCE REQUIREMENTS RSR 12.5.2.1 SURVEILLANCE Conduct a land use census during the growing season, between June 1 and October 1, using information that will provide the best results, such as by a door-to-door survey, aerial survey, or by consulting local agriculture authorities.
SURVEILLANCE REQUIREMENTS RSR 12.5.2.1 SURVEILLANCE Conduct a land use census during the growing season, between June 1 and October 1, using information that will provide the best results, such as by a door-to-door survey, aerial survey, or by consulting local agriculture authorities.
The results of the census shall be included in the Annual Radiological Environmental Operating Report. Page 1-12.5.2-2 In accordance with Technical Specification 5.6.2. FREQUENCY RSR 12.0.2 and 12.0.3 are not applicable.
The results of the census shall be included in the Annual Radiological Environmental Operating Report. Page 1-12.5.2-2 In accordance with Technical Specification  
 
====5.6.2. FREQUENCY====
 
RSR 12.0.2 and 12.0.3 are not applicable.
12 months CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 12.5 RADIOLOGICAL ENVIRONMENTAL MONITORING PROGRAM 12.5.3 lnterlaboratory Comparison Program REC 12.5.3 Analyses shall be performed on radioactive materials supplied as part of an lnterlaboratory Comparison Program that is traceable to NIST. APPLICABILITY:
12 months CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 12.5 RADIOLOGICAL ENVIRONMENTAL MONITORING PROGRAM 12.5.3 lnterlaboratory Comparison Program REC 12.5.3 Analyses shall be performed on radioactive materials supplied as part of an lnterlaboratory Comparison Program that is traceable to NIST. APPLICABILITY:
At all times. ACTIONS CONDITION A ------------NOTE------------
At all times. ACTIONS CONDITION A ------------NOTE------------
A.1 Required Action A.1 shall be completed if this Condition is entered.
A.1 Required Action A.1 shall be completed if this Condition is entered. Requirements of the REC not met. SURVEILLANCE REQUIREMENTS REQUIRED ACTION Report corrective actions to prevent recurrence to the NRC in the next Annual Radiological Environmental Operating Report. SURVEILLANCE RSR 12.5.3 Include a summary of the results of the lnterlaboratory Comparison Program in the Annual Radiological Environmental Operating Report. Page 1-12.5.3-1 COMPLETION TIME In accordance with Technical Specification  
Requirements of the REC not met. SURVEILLANCE REQUIREMENTS REQUIRED ACTION Report corrective actions to prevent recurrence to the NRC in the next Annual Radiological Environmental Operating Report. SURVEILLANCE RSR 12.5.3 Include a summary of the results of the lnterlaboratory Comparison Program in the Annual Radiological Environmental Operating Report. Page 1-12.5.3-1 COMPLETION TIME In accordance with Technical Specification 5.6.2 FREQUENCY In accordance with Technical Specification 5.6.2 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 12.5 RADIOLOGICAL ENVIRONMENTAL MONITORING PROGRAM 12.5.4 Meteorological Monitoring Program (NOT APPLICABLE)
 
====5.6.2 FREQUENCY====
 
In accordance with Technical Specification 5.6.2 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 12.5 RADIOLOGICAL ENVIRONMENTAL MONITORING PROGRAM 12.5.4 Meteorological Monitoring Program (NOT APPLICABLE)
Page 1-12.5.4-1}}
Page 1-12.5.4-1}}

Latest revision as of 03:22, 9 October 2018

LaSalle County, Units 1 and 2 - 2016 Annual Radioactive Effluent Release Report, Part 10
ML17117A588
Person / Time
Site: LaSalle  Constellation icon.png
Issue date: 04/27/2017
From:
Exelon Generation Co
To:
Office of Nuclear Reactor Regulation
Shared Package
ML17117A559 List:
References
RA17-040
Download: ML17117A588 (62)


Text

NRC RA17-040 2016 Annual Radioactive Effluent Release Report Part 10 12.1 NOT USED CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls INTENTIONALLY BLANK Page 1-12.1-1 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 12.2 INSTRUMENTATION 12.2.1 Radioactive Liquid Effluent Monitoring Instrumentation.

REC 12.2.1 The Radioactive Liquid Effluent Instrumentation channels in Table R12.2.1-1 shall be OPERABLE with their alarm/trip setpoints to ensure that the limits of REC 12.3.1 are not exceeded.

APPLICABILITY:

When pump flow is present in the system. For Slowdown, when the Slowdown Flow Control Valve is >0% open and the Slowdown line is not otherwise isolated.

ACTIONS

1. Separate Condition entry is allowed for each instrument channel. CONDITION REQUIRED ACTION COMPLETION TIME A. One or more required A.1 Suspend the release of Immediately instrument channels radioactive liquid effluents inoperable due to its monitored by the alarm/trip setpoint less instrument channel. conservative than required.

OR A.2 Enter the Condition referenced Immediately in Table R12.2.1-1 forthe instrument channel. 8. One or more required 8.1 Enter the Condition referenced Immediately instrument channels In Table R12.2.1-1 forthe inoperable for reasons instrument channel. other than Condition A. (continued)

Page 1-12.2.1-1 ACTIONS CONDITION C. As required by Required C.1 Action A.2 or B.1 and referenced in Table R12.2.1-1.

AND C.2 AND C.3 C.4 D. Required Action and D.1 associated Completion Time of Condition C not met. E. As required by Required E.1 Action A.2 or B.1 and referenced in Table R12.2.1-1.

AND E.2 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls REQUIRED ACTION COMPLETION TIME Perform RSR 12.3.1.1 on at Prior to each release least two independent samples of the tanks contents.

Verify the release rate Prior to each release calculations and discharge valve line-up independently with at least two qualified members of the technical staff. Return instrument channel to 30 days OPERABLE status. OR Place Administrative Control 30 days Clearance order to Lock-Closed OWF201, RW DSCH Tank River DSCH Valve, to remove the ability to conduct a Liquid Radwaste Discharge.

Suspend release of radioactive Immediately effluents via this pathway. Analyze affected effluent grab Once per 8 hours9.259259e-5 days <br />0.00222 hours <br />1.322751e-5 weeks <br />3.044e-6 months <br /> samples for principal gamma emitters and 1-131 at an LLD as specified in Table R12.3.1-2. Restore the instrument channel 30 days to OPERABLE status. Page 1-12.2.1-2 ACTIONS CONDITION F. As required by Required Action A.2 or 8.1 and referenced in Table R12.2.1-1.

G. -----------NOTE-------------

Required Action G.1 shall be completed if this Condition is entered. --------------------------------

Required Action C.3 or C.4, or E.2 and associated Completion Time not met. REQUIRED ACTION CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls COMPLETION TIME F.1 ----------------NOTE------------------

Pump curves for instrument 3.a, or known valve positions for instrument 3.b, may be used to estimate flow. --------------------------------------------

Estimate the flow rate for the Once per 4 hours4.62963e-5 days <br />0.00111 hours <br />6.613757e-6 weeks <br />1.522e-6 months <br /> release in progress via the affected pathway. F.2 With remote position indication Prior to each release. for OWL005 (BDFCV) not available, verify valve position locally. G.1 Explain why the inoperability In accordance with was not corrected in a timely Technical manner in the next Radioactive Specification

5.6.3. Effluent

Release Report. Page 1-12.2.1-3 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls SURVEILLANCE REQUIREMENTS SURVEILLANCE FREQUENCY RSR 12.2.1.1 Perform SOURCE CHECK. Prior to each release RSR 12.2.1.2 Perform CHANNEL FUNCTIONAL TEST. Prior to each Release RSR 12.2.1.3 Perform CHANNEL CHECK. 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> RSR 12.2.1.4 Perform SOURCE CHECK. 31 days RSR 12.2.1.5 Perform CHANNEL FUNCTIONAL TEST. Except for 92 days Instrument 3.b, the test shall also demonstrate that the instrument indicates measured levels above the alarm/trip setpoint and that the control room alarm annunciates and the affected pathway automatically isolates, as applicable, under the following conditions:

a. Loss of power, b Downscale failure, or c. Controls not set in Operate or High Voltage mode. RSR 12.2.1.6 Perform CHANNEL CALIBRATION.

N/A (No longer applicable per E.C. #360580) RSR 12.2.1.7 Perform CHANNEL CALIBRATION 24 months RSR 12.2.1.8 12 months Perform POSITION INDICATION VERIFICATION Page 1-12.2.1-4 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls Table R12.2.1-1(page1of2)

Radioactive Liquid Effluent Monitoring Instrumentation INSTRUMENT

1. Gamma Scintillation Monitor providing Alarm and Automatic Termination of Release a. Liquid Radwaste Effluents Line 2. Gamma Scintillation Monitors providing Alarm but not providing Automatic Termination of Release a. Service Water Effluent Line (Unit 1) b. Service Water Effluent Line (Unit 2) c. RHR Service Water (Line A) Effluent Line (Unit 1) d. RHR Service Water (Line B) Effluent Line (Unit 1) e. RHR Service Water (Line A) Effluent Line (Unit 2) f. RHR Service Water (Line B) Effluent Line (Unit 2) REQUIRED CHANNELS PER !INSTRUMENT 1 1 1 CONDITION REFERENCED FROM REQUIRED ACTION A.2 AND B.1 c E E E E E E SURVEILLANCE REQUIREMENTS RSR 12.2.1.1 RSR 12.2.1.3 RSR 12.2.1.5 RSR 12.2.1. 7<al RSR 12.2.1.4 RSR 12.2.1.3 RSR 12.2.1.5 RSR 12.2.1.7(a) RSR 12.2.1.4 RSR 12.2.1.3 RSR 12.2.1.5 RSR 12.2.1.ia)

RSR 12.2.1.4 RSR 12.2.1.3 RSR 12.2.1.5 RSR 12.2.1.7(a) RSR 12.2.1.4 RSR 12.2.1.3 RSR 12.2.1.5 RSR 12.2.1. 7(e) RSR 12.2.1.4 RSR 12.2.1.3 RSR 12.2.1.5 RSR 12.2.1. ia) RSR 12.2.1.4 RSR 12.2.1.3 RSR 12.2.1.5 RSR 12.2.1.ia) (continued)

<al The initial CHANNEL CALIBRATION shall be performed using one or more of the reference radioactive standards certified by the National Institute of Standards and Technology (NIST) or using standards that have been obtained from suppliers that participate in measurement assurance activities with NIST. These standards shall permit calibrating the system over its intended range of energy and measurement range. For subsequent CHANNEL CALIBRATION, the initial reference radioactive standards or radioactive sources that have been related to the initial calibration shall be used, in order to demonstrate linearity of the original calibration.

This transfer calibration, combined with signal inputs, satisfies channel calibration and functional test requirements as implemented by station procedures.

Page 1-12.2.1-5 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls Table R12.2.1-1 (page 2 of 2) Radioactive Liquid Effluent Monitoring Instrumentation INSTRUMENT

3. Flow Rate Measurement Devices a. Liquid Radwaste Effluent Line b. OWL005 BDFCV Position Indication REQUIRED CHANNELS PER !INSTRUMENT Page 1-12.2.1-6 CONDITION REFERENCED FROM REQUIRED ACTION A.2 AND B.1 F F SURVEILLANCE REQUIREMENTS RSR 12.2.1.2 RSR 12.2.1.3 RSR 12.2.1.7 RSR 12.2.1.8 12.2 INSTRUMENTATION 12.2.2 Radioactive Gaseous Effluent Monitoring Instrumentation CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls REC 12.2.2 The Radioactive Gaseous Effluent Instrumentation channels in Table R12.2.2-1 shall be OPERABLE with their alarm/trip setpoints set to ensure that the limits of REC 12.4.1 are not exceeded.

APPLICABILITY:

According to Table R12.2.2-1 ACTIONS Separate condition entry is allowed for each instrument channel. CONDITION REQUIRED ACTION COMPLETION TIME A. One or more required A.1 Suspend the release of Immediately instrument channels radioactive gaseous inoperable due to its effluents monitored by alarm/trip setpoint less the instrument channel. conservative than required.

OR A.2 Enter the Condition Immediately referenced in Table R12.2.2-1 for the instrument channel. B. One or more required B.1 Enter the Condition Immediately instrument channels referenced in Table R12.2.2-1 inoperable for reasons for the instrument channel. other than Condition A. (continued)

Page 1-12.2.2-1 ACTIONS CONDITION C. As required by Required C.1 Action A.2 or B.1 and referenced in Table R12.2.2-1.

D. As required by Required D.1 Action A.2 or B.1 and referenced in Table R12.2.2-1.

AND D.2 AND D.3 E. As required by Required E.1 Action A.2 or B.1 and referenced in Table AND R12.2.2-1.

E.2 AND E.3 F. As required by Required F.1 Action A.2 or B.1 and referenced in Table R12.2.2-1.

AND F.2 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls REQUIRED ACTION COMPLETION TIME Place instrument channel in 1 hour1.157407e-5 days <br />2.777778e-4 hours <br />1.653439e-6 weeks <br />3.805e-7 months <br /> trip. Obtain grab samples. Once per 8 hours9.259259e-5 days <br />0.00222 hours <br />1.322751e-5 weeks <br />3.044e-6 months <br /> Analyze grab samples for Within 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> noble gas emitters.

following each grab sample Restore instrument channel to OPERABLE status. 30 days Obtain grab samples. Once per 8 hours9.259259e-5 days <br />0.00222 hours <br />1.322751e-5 weeks <br />3.044e-6 months <br /> Analyze grab samples for Within 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> noble gas emitters at an LLD following each grab as specified in Table sample R12.4.1-1.

Restore instrument channel 30 days to OPERABLE status. Establish CONTINUOUS 4 hours4.62963e-5 days <br />0.00111 hours <br />6.613757e-6 weeks <br />1.522e-6 months <br /> SAMPLING with auxiliary sampling equipment as required in Table R12.4.1-1. Restore instrument channel 30 days to OPERABLE status. (continued)

Page 1-12.2.2-2 ACTIONS CONDITION G. As required by Required Action A.2 or B.1 and referenced in Table R12.2.2-1.

H. As required by Required Action A.2 or B.1 and referenced in Table R12.2.2-1.

I.

Required Action 1.1 shall be completed if this Condition is entered. --------------------------------

Required Action and associated Completion Time of Required Action D.3, E.3, F.2, or G.2 or H.4 not met. G.1 AND G.2 H.1 AND REQUIRED ACTION Estimate flow rate. CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls COMPLETION TIME Once per 4 hours4.62963e-5 days <br />0.00111 hours <br />6.613757e-6 weeks <br />1.522e-6 months <br /> Restore instrument channel 30 days to OPERABLE status. Verify offgas treatment Immediately system not bypassed.

H.2.1 Verify at least one Immediately Instrument 1.a channel OPERABLE.

OR H.2.2 Verify Required Actions for Immediately Condition D are met. AND H.3 Obtain and analyze grab Once per 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br />. samples. AND H.4 Restore instrument channel 30 days to OPERABLE status. 1.1 Explain in the next In accordance with Radioactive Effluent Release Technical Report why the inoperability Specification 5.6.3. was not corrected within the time specified.

Page 1-12.2.2-3 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls SURVEILLANCE REQUIREMENTS SURVEILLANCE RSR 12.2.2.1 Perform CHANNEL CHECK. RSR 12.2.2.2 Perform SOURCE CHECK. RS R 12. 2. 2. 3 -------------------------------NO TE-----------------------------------

F or Instruments 4.b and 4.c, not required to be performed until 7 days after Standby Gas Treatment is placed in operation.

Perform CHANNEL CHECK. FREQUENCY 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> 24 hours 7 days RSR 12.2.2.4 Perform SOURCE CHECK. 31 days RSR 12.2.2.5 Perform CHANNEL FUNCTIONAL TEST. For 92 days Instruments 3.a (log monitor only) and 1.a, the test shall also demonstrate that the control room alarm annunciates and the automatic isolation capability of the affected pathway, as applicable, under the following conditions:

a. Upscale, b. Inoperative, or c. Downscale RSR 12.2.2.6 Perform CHANNEL FUNCTIONAL TEST. The test shall 92 days also demonstrate that the instrument indicates measured levels above the alarm setpoint and that the control room alarm annunciates on a Loss of Counts condition.

RSR 12.2.2.7 Perform CHANNEL CALIBRATION 24 months Page 1-12.2.2-4

1. a. Table R12.2.2-1 (page 1 of 2) CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls Radioactive Gaseous Effluent Monitoring Instrumentation APPLICABLE MODES OR REQUIRED CONDITION OTHER CHANNELS REFERENCED SPECIFIED PER FROM REQUIRED SURVEILLANCE INSTRUMEN°Pa)

CONDITIONS INSTRUMENT ACTION A.2 AND B.1 REQUIREMENTS Main Condenser Offgas Treatment System Effluent Monitoring System Noble Gas Activity Monitor -(b) 2 C, if only one required RSR 12.2.2.1 Providing Alarm and Automatic channel inoperable RSR 12.2.2.2 Termination of Release RSR 12.2.2.5 (Post-Treat)

D, if both required RSR 12.2.2.7(e) channels inoperable

2. Main Stack Monitoring System a. Noble Gas Activity Monitor (Low or Mid Range WRGM) b. Iodine Sampler (Grab Sampler) c. Particulate Sampler (Grab Sampler) d. Effluent System Flow Rate Monitor e. Sampler Flow Rate Monitor (Low/Mid/Hi) (c) (c) (c) (c) (c) 1 1 (a) Equipment Part Numbers (EPN) are provided in Table R12.2.2-2. (b) During effluent releases via this pathway. (c) At all times. E F F G G RSR 12.2.2.1 RSR 12.2.2.4 RSR 12.2.2.6 RSR 12.2.2.7(d)

RSR 12.2.2.3 RSR 12.2.2.3 RSR 12.2.2.1 RSR 12.2.2.5 RSR 12.2.2.7 RSR 12.2.2.1 RSR 12.2.2.5 RSR 12.2.2.7 (Continued) (d) The initial CHANNEL CALIBRATION shall be performed using one or more of the referenced radioactive standards certified by the National Institute of Standards and Technology (NIST) or using standards that have been obtained from suppliers that participate in measurement assurance activities with NIST. These standards shall permit calibrating the system over its intended range of energy and measurement range. For subsequent CHANNEL CALIBRATIONS , the initial reference radioactive standards or radioactive sources that have been related to the initial calibration shall be used. (e) The initial CHANNEL CALIBRATION shall be performed using one or more of the reference radioactive standards cert i fied by the National Institute of Standards and Technology (NIST) or using standards that have been obtained from suppliers that participate in measurement assurance activities with NIST. These standards shall permit calibrating the system over its intended range of energy and measurement range. For subsequent CHANNEL CALIBRATION, the initial calibration shall be used, in order to demonstrate linearity of the original calibration. This transfer calibration, combined with signal inputs, satisfies channel calibration and functional test requirements as implemented by station procedures.

Page 1-12.2.2-5

3. 4. CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls Table R12.2.2-1 (page 2 of 2) Radioactive Gaseous Effluent Monitoring Instrumentation APPLICABLE MODES OR REQUIRED CONDITION OTHER CHANNELS REFERENCED SPECIFIED PER FROM REQUIRED SURVEILLANCE INSTRUMENTal CONDITIONS INSTRUMENT ACTION A.2 AND B.1 REQUIREMENTS Condenser Air Ejector Radioactivity Monitor (Prior to Input to Holdup System) a. Noble Gas Activity Monitor (f) H RSR 12.2.2.1 RSR 12.2.2.4 RSR 12.2.2.5 RSR 12.2.2.7(dl Standby Gas Treatment (SGT) Monitoring System a. Noble Gas Activity Monitor (Low (g) E RSR 12.2.2.1 or Mid Range WRGM) RSR 12.2.2.4 RSR 12.2.2.6 RSR 12.2.2.7(dl
b. Iodine Sampler (Grab Sampler) (g) F RSR 12.2.2.3 c. Particulate Sampler (Grab (g) F RSR 12.2.2.3 Sampler) d. Effluent System Flow Rate (g) G RSR 12.2.2.1 Monitor RSR 12.2.2.5 RSR 12.2.2. 7 e. Sampler Flow Rate Monitor (g) 1 G RSR 12.2.2.1 (Low/Mid/Hi)

RSR 12.2.2.5 RSR 12.2.2. 7 (a) Equipment Part Numbers (EPN) are provided in Table R12.2.2-2. (d) The initial CHANNEL CALIBRATION shall be performed using one or more of the referenced radioactive standards certified by the National Institute of Standards and Technology (NIST) or using standards that have been obtained from suppliers that participate in measurement assurance activities with NIST. These standards shall permit calibrating the system over its intended range of energy and measurement range. For subsequent CHANNEL CALIBRATIONS, the initial reference radioactive standards or radioactive sources that have been related to the initial calibration shall be used. (f) During operation of the main condenser air ejector. (g) During operation of SGT. Page 1-12.2.2-6 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls Table R 12.2.2-2 (page 1 of 2) Radioactive Gaseous Effluent Monitoring Instrumentation Applicability INSTRUMENT A. Unit 1 Applicable Instruments

1. Main Condenser Offgas Treatment System Effluent Monitoring System a. Noble Gas Activity Monitor -Providing Alarm and Automatic Termination of Release 2. Main Stack Monitoring System a. Noble Gas Activity Monitor (Low or Mid Range WRGM) b. Iodine Sampler (Grab Sampler) c. Particulate Sampler (Grab Sampler) d. Effluent System Flow Rate Monitor e. Sampler Flow Rate Monitor (Low/Mid/Hi)
3. Condenser Air Ejector Radioactivity Monitor (Prior to Input to Holdup System) a. Noble Gas Activity Monitor 4. Standby Gas Treatment (SGT) Monitoring System a. Noble Gas Activity Monitor (Low/Mid Range WRGM) b. Iodine Sampler (Grab Sampler) c. Particulate Sampler (Grab Sampler) d. Effluent System Flow Rate Monitor e. Sampler Flow Rate Monitor (Low/Mid/Hi)

EPNS OF APPLICABLE EQUIPMENT 1D18-N903A, K901A, K601A, R601 1D18-N903B, K901B, K601B,R601 OD18-N514, R517, R518 Low Range OD18-N515, R517, R518 Mid Range OFT-VR019, OFY-VR019 AND 019A, OFR-VR019, OD18-K510, OD18-R518 OD18-N527, OD18-N528, OD18-R518 Low OD18-N530, OD18-N531, OB18-R518 Mid/Hi 1D18-N002, K613, R604, or 1D18-N012, K600, R605 OD18-N511, R515, R516 Low Range OD18-N512, R515, R516 Mid Range 1 FT-VG009, 1 FY-VG009, 1 FR-VG-009 OD18-N521, OD18-N522, OD18-R516 Low OD18-N524, OD18-N525, OB18-R516 Mid/Hi (Continued)

Page 1-12.2.2-7 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls Table R12.2.2-2 (page 2 of 2) Radioactive Gaseous Effluent Monitoring Instrumentation Applicability INSTRUMENT B. Unit 2 Applicable Instruments

1. Main Condenser Offgas Treatment System Effluent Monitoring System a. Noble Gas Activity Monitor -Providing Alarm and Automatic Termination of Release 2. Main Stack Monitoring System a. Noble Gas Activity Monitor (Low or Mid Range WRGM) b. Iodine Sampler (Grab Sampler) c. Particulate Sampler (Grab Sampler) d. Effluent System Flow Rate Monitor e. Sampler Flow Rate Monitor (Low/Mid/Hi)
3. Condenser Air Ejector Radioactivity Monitor (Prior to Input to Holdup System) a. Noble Gas Activity Monitor 4. Standby Gas Treatment (SGT) Monitoring System a. Noble Gas Activity Monitor (Low/Mid Range WRGM) b. Iodine Sampler (Grab Sampler) c. Particulate Sampler (Grab Sampler) d. Effluent System Flow Rate Monitor e. Sampler Flow Rate Monitor (Low/Mid/Hi)

EPNS OF APPLICABLE EQUIPMENT 2D18-N903A, K901A, K601A, R601 2D18-N9038, K9018, K6018,R601 OD18-N514, R517, R518 Low Range OD18-N515, R517, R518 Mid Range OFT-VR019, OFY-VR019 AND 019A, OFR-VR019, OD18-K510, OD18-R518 OD18-N527, OD18-N528, OD18-R518 Low OD18-N530, OD18-N531, OB18-R518 Mid/Hi 2D18-N002, K613, R604, or 2D18-N012, K600, R605 OD18-N511, R515, R516 Low Range OD18-N512, R515, R516 Mid Range 2FT-VG009, 2FY-VG009, 2FR-VG-009 OD18-N521, OD18-N522, OD18-R516 Low OD18-N524, OD18-N525, OB18-R516 Mid/Hi Page 1-12.2.2-8 12.3 LIQUID EFFLUENTS 12.3.1 Liquid Effluent Concentration CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls REC 12.3.1 The concentration of radioactive material released from the site to areas at or beyond the SITE BOUNDARY shall be limited to: a. 10 times the concentration specified in 10 CFR 20.1001-20.2402 Appendix B, Table 2, Column 2 for radionuclides other than dissolved or entrained noble gases; and b. the values listed in Table R12.3.1-1 for total activity concentration for all dissolved or entrained noble gases. APPLICABILITY:

At all times. ACTIONS CONDITION REQUIRED ACTION COMPLETION TIME A. Concentration of radioactive A.1 Initiate action to restore the Immediately material released to areas at concentration to within or beyond the SITE limits. BOUNDARY not within limits. B. Requirements of RSR B.1 Enter Condition A of Immediately 12.3.1.4 not met. Technical Requirements Manual Section 3.7.d. SURVEILLANCE REQUIREMENTS SURVEILLANCE RSR 12.3.1.1 Determine radioactivity content of each radioactive liquid waste batch by sampling and analysis in accordance with Table R12.3.1-2.

RSR 12.3.1.2 Perform post-release analysis of samples composited from batch releases in accordance with Table R12.3.1-2.

RSR 12.3.1.3 Determine radioactivity concentration of liquids discharged from continuous release points by sampling and analysis in accordance with Table R12.3.1-2.

Page 1-12.3.1-1 FREQUENCY In accordance with the Radioactive Liquid Waste Sampling and Analysis Program. In accordance with the Radioactive Liquid Waste Sampling and Analysis Program. In accordance with the Radioactive Liquid Waste Sampling and Analysis Program. (Continued)

SURVEILLANCE REQUIREMENTS RS R 12. ;3. 1 .4 ------------------------N 0

N ot required to be performed until 7 days after the start of addition if tank(s) is empty at the beginning of the addition.

Verify the quantity of radioactive material of each outside temporary tank is low enough to ensure that in the event of an uncontrolled release of the tanks contents, the resulting concentration would be less than the REC limits. Page 1-12.3.1-2 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 7 days when radioactive material is being added to the tank(s). Once within 7 days after each completion of addition of radioactive material to the tank(s).

.. NUCLIDE Kr-85m Kr-85 Kr-87 Kr-88 Ar-41 Xe-131m Xe-133m Xe-133 Xe-135m Xe-135 Table R12.3.1-1 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls ALLOWABLE CONCENTRATION (AC) OF DISSOLVED OR ENTRAINED NOBLE GASES RELEASED FROM THE SITE TO UNRESTRICTED AREAS IN LIQUID WASTE ALLOWABLE CONCENTRATION

(µCi/ml)* 2 x 10-4 5 x 10-4 4 x 10-5 9 x 10-5 7 x 10-5 7 x 10-4 5 x 10-4 6 x 10-4 2 x 10-4 2 x 10-4 Computed from Equation 20 of ICRP Publication 2 (1959), adjusted for infinite cloud submersion in water, and R = 0.01 rem/week, density= 1.0 glee and Pw/Pt = 1.0. Page 1-12.3.1-3 Table R12.3.1-2 (Page 1of4) CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls RADIOACTIVE LIQUID WASTE SAMPLING AND ANALYSIS PROGRAM LOWER LIMIT LIQUID RELEASE SAMPLING MINIMUM ANALYSIS TYPE OF ACTIVITY OF DETECTION TYPE FREQUENCY(gl FREQUENCY(gl ANALYSIS (LLD)(al (µCi/ml) A Batch Waste Prior to each Prior to each release, Principal Gamma 5x10-7 Release Tanks<dl release, Each Each Batch Emitters(fl Batch 1-131 1 x1 o-s Prior to each 31 days H-3 1x10-5 release, Each Composite (bl Batch Gross Alpha 1x10-7 Prior to each 92 days Sr-89, Sr-90 5x1 o-s release, Each Composite

<bl Batch Fe-55 1x10*5 Prior to each release, One 31 days Dissolved

& Batch per 31 Entrained Gases 1 x10*5 days (Gamma Emitters)

B. Plant Continuous 7 days 1-131 1x10*5 Releases(eJ CONTINUOus<c>

Cooling Pond Composite (cJ Principal Gamma 5x10*1 Slowdown Emitters<fl 31 days 31 days Dissolved

& 1 x10*5 Entrained Gases Grab Sample (Gamma Emitters)

CONTINUOus<c) 31 days H-3 1x10-5 Composite<c>

Gross Alpha 1x10*7 CONTINUOUS(c>

92 days Sr-89, Sr-90 5x10-s Composite(c>

Fe-55 1x10" 6 Page 1-12.3.1-4 Table R12.3.1-2 (Page 2of4) CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls RADIOACTIVE LIQUID WASTE SAMPLING AND ANALYSIS PROGRAM TABLE NOTATION a. The LLD is the smallest concentration of radioactive material in a sample that will be detected with 95% probability with only 5% probability of falsely concluding that a blank observation represents a "real" signal. For a particular measurement system, which may include radiochemical separation:

Where: LLD= 4.668 6 E

  • V
  • 2.22xl0 6
  • Y
  • e<-Mi> LLD = the a priori lower limit of detection (microcurie per unit mass or volume), sb = the standard deviation of the background counting rate or of the counting rate of a blank sample as appropriate (counts per minute), JS B = background sum (counts) t = count time (minutes)

E =the counting efficiency (counts per transformation), V = the sample size (units of mass or volume), 2.22 x 10 6 = the number of transformations per minute per microcurie, Y = the fractional radiochemical yield, when applicable, A.= the radioactive decay constant for the particular radionuclide and for composite samples, and tit = the elapsed time between the midpoint of sample collection and the time of counting (for plant effluents, not environmental samples).

For batch samples taken and analyzed prior to release, tit is taken to be zero. The value of sb used in the calculation of the LLD for a detection system shall be based on the actual observed variance of the background counting rate or of the counting rate of the blank samples (as appropriate) rather than on an unverified theoretically predicted variance.

Typical values of E, V, Y, and tit shall be used in the calculation.

Alternate LLD Methodology An alternate methodology for LLD determination follows and is similar to the above LLD equation:

LLD= (2.71+4.65.JB)*Decay E *q *b

  • Y *t *(2.22xl0 6) Page 1-12.3.1-5 Table R12.3.1-2 (Page 3 of 4) CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls RADIOACTIVE LIQUID WASTE SAMPLING AND ANALYSIS PROGRAM TABLE NOTATION Where: 8 = background sum (counts) E = counting efficiency q =sample quantity (mass or volume) b = abundance (if applicable)

Y= fractional radiochemical yield or collection efficiency

{if applicable) t= count time (minutes) 2.22 x 10 6 = number of disintegrations per minute per microcurie

2. 71 + 4.65°'18 = k 2 + (2k '12 °'18), and k = 1.645 (k=value of the t statistic from the single-tailed t distribution at a significance level of 0.95 and infinite degrees of freedom. This means that the LLD result represents a 95% detection probability with a 5% probability of falsely concluding that the nuclide is present when it is not or that the nuclide is not present when it is.) Decay = eu.1 [/* .. RT/(1-e*ART)][A.

Td /(1-e*Hd)]

if applicable A.= radioactive decay constant (units consistent with RT and Td) = "delta t, or the elapsed time between sample collection or the midpoint of sample collection and the time the count is started, depending on the type of sample (units consistent with A.) RT= elapsed real time , or the duration of the sample count {units consistent with A.) Td =sample deposition time, or the duration of analyte collection onto the sample media (units consistent with A.) The LLD may alternately be determined using installed radioanalytical software , if available. In addition to determining the correct number of channels over which to total the background sum, utilizing the software's ability to perform decay corrections (i.e. during sample collection, from sample collection to start of analysis, and during counting), this alternate method will result in a more accurate determination of the LLD. It should be recognized that the LLD is defined as a before the fact limit representing the capability of a measurement system and not as an after the fact limit for a particular measurement.

Page 1-12.3.1-6 Table R12.3.1-2 (Page4 of4) CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls RADIOACTIVE LIQUID WASTE SAMPLING AND ANALYSIS PROGRAM TABLE NOTATION b. A composite sample is one in which the quantity of liquid sampled is proportional to the quantity of liquid waste discharged and in which the method of sample employed results in a specimen which is representative of the liquids released.

c. To be representative of the quantities and concentrations of radioactive materials in liquid effluents, samples shall be collected in proportion to the rate of flow of the effluent stream. Prior to analyses, all samples taken for the composite shall be thoroughly mixed in order for the composite sample to be representative of the effluent release. d. A batch release is the discharge of liquid waste of a discrete volume. Prior to sampling for analyses , each batch shall be isolated, and then thoroughly mixed to assure representative sampling.
e. A continuous release is the discharge of liquid wastes of a non-discrete volume; e.g., from a volume of system that has an input flow during the continuous release. f. The principal gamma emitters for which the LLD specification applies exclusively are the following radionuclides
Mn-54, Fe-59, Co-58, Co-60, Zn-65, Mo-99, Cs-134, Cs-137, Ce-141, and Ce-144. This list does not mean that only these nuclides are to be detected and reported.

Other peaks that are measurable and identifiable, at the 95% confidence level, together with the above nuclides, shall also be identified and reported.

g. The provisions of RSR 12.0.2 and RSR 12.0.3 are applicable to the Radioactive Liquid Waste Sampling and Analysis Program. Page 1-12.3.1-7 12.3 LIQUID EFFLUENTS 12.3.2 Dose from Liquid Effluents CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls REC 12.3.2 The dose or dose commitment to a MEMBER OF THE PUBLIC from radioactive materials in liquid effluents released, from each reactor unit, from the site shall be limited to: a. 1.5 mrem to the total body and 5.0 mrem to any organ during any calendar quarter; and b. 3.0 mrem to the total body and 10.0 mrem to any organ during any calendar year. APPLICABILITY:

At all times. Page 1-12.3.2-1 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls ACTIONS CONDITION REQUIRED ACTION COMPLETION TIME A. ------------NOTE------------

A.1 Submit a Report, pursuant to 30 days following the Required Action A.1 shall 1 OCFR50, Appendix I, Section end of the quarter in be completed if this IV.A, to the NRC that identifies which the release Condition is entered. causes for exceeding limits, occurred radiological impact on finished ---------------------------------

drinking water supplies at the Calculated dose not nearest downstream drinking within limits. water source and defines actions to be taken to reduce releases of radioactive materials in liquid effluents during the remainder of the current calendar quarter and during the subsequent three calendar quarters so that the cumulative dose or dose commitment is within the limits of REC 12.3.2.b.

B. Calculated dose B.1 Enter Condition A of REC 12.4.7. Immediately exceeds two times (2x) the limits. SURVEILLANCE REQUIREMENTS SURVEILLANCE FREQUENCY RS R 12. 3. 2. 1 ----------------------------------N 0 TE--------------------------------

0 n ly required to be performed if liquid releases have occurred since the last performance of this RSR. Calculate cumulative dose contributions from liquid effluents 31 days in accordance with the ODCM. Page 1-12.3.2-2 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 12.3 LIQUID EFFLUENTS 12.3.3 Liquid Radwaste Treatment Systems REC 12.3.3. The Liquid Radwaste Treatment System shall: a. Be OPERABLE; and b. Be used to reduce the radioactive materials in liquid wastes prior to their discharge when the projected doses due to the liquid effluent, from each reactor unit, from the site would exceed 0.06 mrem to the total body or 0.2 mrem to any organ when averaged over 31 days. APPLICABILITY:

At all times. ACTIONS CONDITION REQUIRED ACTION COMPLETION TIME A. Liquid Radwaste A.1 Restore Liquid Radwaste 31 days Treatment System Treatment System to inoperable.

OPERABLE status. B.

B.1 Submit a report to the NRC 30 days Required Action B.1 that includes inoperable shall be completed if this equipment or subsystem Condition is entered. identification and reason, --------------------------------

action taken to restore the Untreated liquid waste inoperable equipment to release in progress.

OPERABLE status, and a summary description of the action(s) taken to prevent AND recurrence.

Projected dose not within limits. C.

C.1 Submit a report to the NRC 30 days Required Action C.1 that includes inoperable shall be completed if this equipment or subsystem Condition is entered. identification and reason , --------------------------------

action taken to restore the Required Action and inoperable equipment to Associated Completion OPERABLE status, and a time of Condition A not summary description of the met. action(s) taken to prevent recurrence.

Page 1-12.3.3-1 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls SURVEILLANCE REQUIREMENTS SURVEILLANCE RS R 12. 3. 3. 1 -------------------------------N 0 TE-------------------------------

On ly required to be performed if liquid releases are planned and RSR has not been performed in the last 38 days 18 hours2.083333e-4 days <br />0.005 hours <br />2.97619e-5 weeks <br />6.849e-6 months <br />. FREQUENCY Determine projected doses due to liquid releases in 31 days accordance with the ODCM methods. RS R 12. 3. 3. 2 -------------------------------N 0 TE------------------------------

N ot required to be performed if Liquid Radwaste Treatment System has been used to process radioactive liquid effluents in the last 115 days. Operate the Liquid Radwaste Treatment System equipment for at least 30 minutes. Page 1-12.3.3-2 92 days if a portable (vendor supplied) waste treatment system is being used. 180 days if a portable supplied) waste treatment system is not being used.

CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 12.4 GASEOUS EFFLUENTS AND TOTAL DOSE 12.4.1 Gaseous Effluent Dose Rates REC 12.4.1 The dose rate at or beyond the SITE BOUNDARY due to radioactive materials in gaseous effluents released from the site shall be limited to the following:

a. For noble gases, 500 mrem/year to the total body and 3000 mrem/year to the skin; and b. For iodine-131, iodine-133, tritium, and all radionuclides in particulate form with half-lives

> 8 days, 1500 mrem/year to any organ via the inhalation pathway. APPLICABILITY:

At all times. ACTIONS CONDITION REQUIRED ACTION COMPLETION TIME A. Dose rate not within limits. A.1 Initiate action to Immediately decrease release rates to maintain dose rates within limits. SURVEILLANCE REQUIREMENTS RSR 12.4.1.1 SURVEILLANCE Verify the dose rates due to noble gases, iodine-131, iodine-133, tritium, and all radionuclides in particulate form with half lives > 8 days in gaseous effluents is within limits utilizing the methodology and parameters of the ODCM limits by obtaining and analyzing representative samples in accordance with Table R12.4.1-1.

Page 1-12.4.1-1 FREQUENCY In accordance with the Radioactive Gaseous Waste Sampling and Analysis Program GASEOUS RELEASE TYPE A Containment Vent and Purge System" B. Main Vent Stack c. Standby Gas Treatment System D. Main Vent Stack And Standby Gas Treatment Systemc CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls Table R12.4.1-1 (Page 1 of 5) RADIOACTIVE GASEOUS WASTE SAMPLING AND ANALYSIS PROGRAM MINIMUM TYPE OF LOWER LIMIT OF SAMPLING ANALYSIS ACTIVITY DETECTION (LLD) FREQUENCY(il FREQUENCY(il ANALYSIS (µCi/ml)8 Prior to each Prior to each Principal Gamma release release Emitters 9 1x10-4 Each Purgeb, k Each Purgeb Grab Sample 31 daysb, k H-3 1x10*5 31 daysb 31 daysb Principal Gamma 1x10-4 Grab Sample Emitters 9 7 daysb,e 7 daysb.e H-3 1x10-6 Grab Sample 24 hour2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br />sc 24 hour2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br />sc Principal Gamma 1x10-4 Grab Sample Emitters 9 7 daysd 1-131 1x10*12 CONTINUOUS, Charcoal 1x10*10 Sample 1-133 CONTINUOUS, 7 daysd Principal Gamma 1x10*11 Particulate Emitters 9 (1-131, Sample Others) 31 days CONTINUOUS, Composite Gross Alpha 1x10*11 Particulate Sample 92 days CONTINUOUS, Composite Sr-89,Sr-90 1x10*11 Particulate Sample Noble Gas Noble Gases, CONTINUOUS' Gross Beta or 1x10*5 Monitor Gamma Page 1-12.4.1-2 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls Table R12.4.1-1(Page2 of 5) RADIOACTIVE GASEOUS WASTE SAMPLING AND ANALYSIS PROGRAM TABLE NOTATION a. The LLD is the smallest concentration of radioactive material in a sample that will be detected with 95% probability with 5% probability of falsely concluding that a blank observation represents a "real" signal. For a particular measurement system (which may include radiochemical separation):

LLD= 4.66Sb E

  • V
  • 2.22xl 0 6
  • Y
  • e<-Mil Where: LLD is the "a priori" lower limit of detection as defined above (as microcurie per unit mass or volume), sb is the standard deviation of the background counting rate or of the counting rate of a blank sample as appropriate (as counts per minute), B = background sum (counts) t = count time (minutes)

E is the counting efficiency (as counts per transformation), V is the sample size (in units of mass or volume), 2.22x10 6 is the number of transformations per minute per microcurie, Y is the fractional radiochemical yield (when applicable), /... is the radioactive decay constant for the particular radionuclide, and is the elapsed time between midpoint of sample collection and time of counting (for plant effluents, not environmental samples).

The value of sb used in the calculation of the LLD for a detection system shall be based on the actual observed variance of the background counting rate or of the counting rate of the blank samples (as appropriate) rather than on an unverified theoretically predicted variance.

Typical values of E, V, Y, and shall be used in the calculation.

Alternate LLD Methodology An alternate methodology for LLD determination follows and is similar to the above LLD equation:

LLD= (2.71+4.65.fB)*Decay E

  • q *b
  • Y *t *(2.22xl0 6) Page 1-12.4.1-3 Where: CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls Table R12.4.1-1 (Page 3 of 5) RADIOACTIVE GASEOUS WASTE SAMPLING AND ANALYSIS PROGRAM TABLE NOTATION 8 =background sum (counts) E = counting efficiency q = sample quantity (mass or volume) b = abundance (if applicable)

Y =fractional radiochemical yield or collection efficiency (if applicable)

= count time (minutes) 2.22 x 10 6 = number of disintegrations per minute per microcurie

2. 71 + 4.65--/8 = k 2 + (2k --/2 --/8), and k = 1.645 Decay RT (k=value of the t statistic from the single-tailed t distribution at a significance level of 0.95 and infinite degrees of freedom. This means that the LLD result represents a 95% detection probability with a 5% probability of falsely concluding that the nuclide is present when it is not or that the nuclide is not present when it is.) = e'-6 1 [A.RT/(1-e--.RT)][A.

Td /(1-e-Hd)]

if applicable

=radioactive decay constant (units consistent with RT and Td) = "delta t", or the elapsed time between sample collection or the midpoint of sample collection and the time the count is started, depending on the type of sample (units consistent with A.) = elapsed real time, or the duration of the sample count (units consistent with A.) = sample deposition time, or the duration of analyte collection onto the sample media (units consistent with A.) The LLD may alternately be determined using installed radioanalytical software, if available.

In addition to determining the correct number of channels over which to total the background sum , utilizing the software's ability to perform decay corrections (i.e. during sample collection, from sample collection to start of analysis, and during counting), this alternate method will result in a more accurate determination of the LLD. It should be recognized that the LLD is defined as a before the fact limit representing the capability of a measurement system and not as an after the fact limit for a particular measurement.

b. Sampling and analyses shall also be performed following shutdown, startup, or a thermal power change exceeding 20 percent of RATED THERMAL POWER in 1 hour1.157407e-5 days <br />2.777778e-4 hours <br />1.653439e-6 weeks <br />3.805e-7 months <br /> unless (1) analysis shows that the dose equivalent 1-131 concentration in the primary coolant has not increased more than a factor of 5, and (2) the noble gas activity monitor shows that effluent activity has not increased by more than a factor of 3. Page 1-12.4.1-4 Table R12.4.1-1(Page4 of 5) CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls RADIOACTIVE GASEOUS WASTE SAMPLING AND ANALYSIS PROGRAM TABLE NOTATION c. Whenever there is flow through the SGT. If SGT is run more than 2 hrs in a 24-hour period, ensure a noble gas sample is obtained prior to securing SGT and particulate and iodine samples are taken within 24 hrs after securing SGT. A 2-hour run ensures required sample lower limits of detection are met for particulates and iodine. A SGT run of less than 2 hrs is not a significant contribution to offsite dose and requires no sampling.
d. Samples shall be changed at least once per 7 days and the analyses completed within 48 hours5.555556e-4 days <br />0.0133 hours <br />7.936508e-5 weeks <br />1.8264e-5 months <br /> after removal from the sampler. Sampling shall also be performed within 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> following each shutdown, startup, or thermal power level change exceeding 20% of RATED THERMAL POWER in one hour. This requirement does not apply if 1) analysis shows that the dose equivalent 1-131 concentration in the primary coolant has not increased by more than a factor of 5, and 2) the noble gas activity monitor shows that effluent activity has not increased by more than a factor of 3. When samples collected for 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> are analyzed, the corresponding LLDs may be increased by a factor of 10. e. Tritium grab samples shall be taken at least once per 7 days from the plant vent to determine tritium releases in the ventilation exhaust from the spent fuel pool area whenever spent fuel is in the spent fuel pool. If there is no spent fuel in the fuel pool, sampling and analysis of tritium grab samples shall be performed at least once per 31 days. f. The ratio of the sample flow rate to the sampled stream flow rate shall be known for the time period covered by each dose or dose rate calculation made in accordance with RECs 12.4.1, 12.4.2 and 12.4.3. g. The principal gamma emitters for which the LLD specification applies include the following radionuclides:

Kr-87, Kr-88, Xe-133, Xe-133m, Xe-135, and Xe-138 for gaseous emissions and Mn-54, Fe-59, Co-58, Co-60, Zn-65, Mo-99, Cs-134, Cs-137, Ce-141 and Ce-144 for particulate emissions. This list does not mean that only these nuclides are to be detected and reported.

Other peaks that are measurable and identifiable, at the 95% confidence level, together with the above nuclides, shall also be identified and reported.

h. The drywell tritium and noble gas samples and associated purge calculations are required when the Unit is at power (i.e. critical) and for the first 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> of purging activities following shutdown. The drywell tritium and noble gas sample results are valid for 30 hours3.472222e-4 days <br />0.00833 hours <br />4.960317e-5 weeks <br />1.1415e-5 months <br /> from sample time if 1) the drywell radioactivity monitors have not indicated an increase in airborne or gaseous radioactivity, and 2) the drywell equipment and floor drain sump pumps run times have not indicated an increase in leakage in the drywell since the sample was taken, and 3) conditions are such that activity can be calculated for the radionuclide concentration at the time of the release. If there is any reason to suspect that gaseous radioactivity levels have changed in the drywell that would compromise the calculated, or estimated, radionuclide concentrations at the time of the release, since the last sample (30 hours3.472222e-4 days <br />0.00833 hours <br />4.960317e-5 weeks <br />1.1415e-5 months <br />), a new sample and analyses should be requested prior to starting a drywell purge to meet the intent of providing current analyses to reflect actual activity released to the environment.

If a known steady state leakage condition exists in the drywell it is possible to calculate a safe and accurate release package. Final release quantification will be based on calculated radionuclide concentrations at the time of the actual release. Page 1-12.4.1-5 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls Table R12.4.1-1 (Page 5 of 5) RADIOACTIVE GASEOUS WASTE SAMPLING AND ANALYSIS PROGRAM TABLE NOTATION If the drywell is PURGED in accordance with the ODCM definition, both noble gas and tritium sampling along with the appropriate purge calculations must be completed before the purge begins. If the drywell is simply VENTING in accordance with the ODCM definition, no sample is required before venting. i. The provisions of RSR 12.0.2 and RSR 12.0.3 are applicable to the Radioactive Gaseous Waste Sampling and Analysis Program. j. Not used. k. Drywell tritium results obtained during the previous 31 days may be used in the purge calculations, in lieu of actual results (from most recent purge sample), to allow completion of the purge calculations in an expeditious manner permitting a timely drywell entry, if necessary.

However, the substitute tritium results are valid for use only if the three (3) conditions set forth in Note "h" surrounding sample validity are met. In addition, the substitute results do not change the requirements for tritium sampling frequency (Prior to each release Each Purge) per Table R12.4.1-1.

The most recent purge sample tritium analyses should be completed, and the associated purge calculations should be updated as soon as possible following sampling.

For reporting purposes (i.e. annual reports, etc.), actual results are used, when possible. Page 1-12.4.1-6 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 12.4 GASEOUS EFFLUENTS AND TOTAL DOSE 12.4.2 Dose from Noble Gases REC 12.4.2 The air dose due to noble gases in gaseous effluents released from each reactor unit from the site shall be limited to the following:

a. For gamma radiation, 5 mrad during any calendar quarter and 10 mrad during any calendar year; and b. For beta radiation, 10 mrad during any calendar quarter and 20 mrad during any calendar year. APPLICABILITY:

At all times. ACTIONS CONDITION REQUIRED ACTION A.

A.1 Submit a report to the NRC, Required Action A.1 shall pursuant to 1 OCFR50 be completed if this Appendix I Section IV.A, that Condition is entered. identifies causes for exceeding limits, defines ------------------------------------

corrective actions to be Calculated air dose not taken to reduce the releases, within limits. and proposed corrective actions to assure that subsequent releases are within limits. B. Calculated air dose B.1 Enter Condition A of REC exceeds two times (2x) the 12.4.7. limits. SURVEILLANCE REQUIREMENTS SURVEILLANCE RSR 12.4.2.1 Determine cumulative dose contributions for the current calendar quarter and current calendar year in accordance with the ODCM. Page 1-12.4.2-1 COMPLETION TIME 30 days following the end of the quarter in which the release occurred Immediately FREQUENCY 31 days CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 12.4 GASEOUS EFFLUENTS AND TOTAL DOSE 12.4.3 Dose From Iodine -131, Iodine -133, Tritium, and Radioactive Materials in Particulate Form REC 12.4.3 The dose to a MEMBER OF THE PUBLIC from iodine-131, iodine-133, tritium and all radionuclides in particulate form, with half-lives

> 8 days, in gaseous effluents released from each reactor unit, to areas at and beyond the SITE BOUNDARY shall be limited to: a. 5 7.5 mrem to any organ during any calendar quarter; and b. 5 15 mrem to any organ during any calendar year. APPLICABILITY

At all times. ACTIONS CONDITION REQUIRED ACTION COMPLETION TIME A. --------------NOTE---------------

A.1 Submit a report to the NRC, 30 days following the Required Action A.1 shall be pursuant to 10CFR50 end of the quarter in completed if this Condition is Appendix I Section IV.A, which the release entered. that identifies causes for occurred exceeding limits, defines --------------------------------------

corrective actions to be Calculated dose not within taken to reduce the limits. releases, and proposed corrective actions to assure that subsequent releases are within limits. B. Calculated dose exceeds B.1 Enter Condition A of Immediately two times (2x) the limits. REC 12.4.7. SURVEILLANCE REQUIREMENTS SURVEILLANCE FREQUENCY RSR 12.4.3.1 Determine cumulative dose contributions for the current 31 days calendar quarter and calendar year for iodine-131, iodine-133, tritium, and radionuclides in particulate form with half-lives greater than 8 days in accordance with the methodology and parameters in the ODCM. Page 1-12.4.3-1 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 12.4 GASEOUS EFFLUENTS AND TOTAL DOSE 12.4.4 GASEOUS RADWASTE TREATMENT SYSTEM REC 12.4.4 The GASEOUS RADWASTE (OFF-GAS)

TREATMENT SYSTEM shall be OPERABLE and in operation.

APPLICABILITY:

During Main Condenser Air Ejector system operation.

ACTIONS CONDITION REQUIRED ACTION A. GASEOUS RADWASTE A.1 Restore system to TREATMENT SYSTEM OPERABLE status. inoperable.

AND OR A.2 Place system in operation. GASEOUS RADWASTE TREATMENT SYSTEM not in operation.

B. --------------NOTE--------------

B.1 Submit a report to the NRC Required Action B.1 shall that includes defective be completed if this equipment or subsystem Condition is entered. identification and inoperability cause, actions ------------------------------------

taken to restore the Required action and inoperable equipment to Associated Completion OPERABLE status, and Time not met. summary description of actions taken to prevent a recurrence.

SURVEILLANCE REQUIREMENTS SURVEILLANCE RSR 12.4.4.1 Verify the GASEOUS RADWASTE TREATMENT SYSTEM is in operation.

Page 1-12.4.4-1 COMPLETION TIME 7 days 30 days FREQUENCY 7 days CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 12.4 GASEOUS EFFLUENTS AND TOTAL DOSE 12.4.5 VENTILATION EXHAUST TREATMENT SYSTEM REC 12.4.5 The appropriate portions of the VENTILATION EXHAUST TREATMENT SYSTEM shall; a. BE OPERABLE; and b. be used to reduce radioactive materials in gaseous waste prior to their discharge when the projected doses from each reactor unit from the site would exceed 0.3 mrem to any organ, when average over 31 days. APPLICABILITY:

At all times.

Separate Condition entry is allowed for each VENTILATION EXHAUST TREATMENT system pathway. ACTIONS CONDITION REQUIRED ACTION COMPLETION TIME A. One or more required A.1 Restore system to 31 days VENTILATION EXHAUST OPERABLE status. TREATMENT SYSTEMS inoperable.

B.

B.1 Submit a report to the NRC 30 days Required Action 8.1 shall that includes inoperable be completed if this equipment or subsystem condition is entered. identification and reason for inoperability, actions ------------------------------------

taken to restore the Untreated gaseous waste inoperable equipment to release in progress. OPERABLE status, and summary description of AND actions taken to prevent a recurrence.

Projected dose not within limits. (continued)

Page 1-12.4.5-1 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls ACTIONS CONDITION REQUIRED ACTION COMPLETION TIME C. -------------NOTE---------------

C.1 Required Action C.1 shall Submit a report to the NRC 30 days that includes inoperable be completed if this Condition is entered. Required Action and associated Completion Time of Condition A not met. SURVEILLANCE REQUIREMENTS equipment or subsystem identification and reason for inoperability, actions taken to restore the inoperable equipment to OPERABLE status, and summary description of actions taken to prevent a recurrence.

SURVEILLANCE RSR 12.4.5.1 Project doses due to gaseous releases from the site in accordance with the ODCM. RS R 12 .4 .5 .2 -------------------------NOTE---------------------------

Not required to be performed if the VENTILATION EXHAUST TREATMENT SYSTEM has been used to process gaseous effluents in the last 115 days. OPERATE each required VENTILATION EXHAUST TREATMENT SYSTEM equipment for at least 30 minutes. Page 1-12.4.5-2 FREQUENCY 31 days 92 days CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 12.4 GASEOUS EFFLUENTS AND TOTAL DOSE 12.4.6 MARK II Containment REC 12.4.6 VENTING or PURGING of the containment drywell shall be: a. through the Primary Containment Vent and Purge System, or b. through the Standby Gas Treatment (SGT) System. APPLICABILITY:

During drywell VENTING or PURGING. ACTIONS CONDITION REQUIRED ACTION COMPLETION TIME A. Above requirements not met. A.1 Suspend all drywell Immediately VENTING and PURGING. SURVEILLANCE REQUIREMENTS SURVEILLANCE FREQUENCY RSR 12.4.6.1 Verify containment drywell is aligned for VENTING or 12 hours1.388889e-4 days <br />0.00333 hours <br />1.984127e-5 weeks <br />4.566e-6 months <br /> PURGING through the Primary Containment Vent and Purge System or the SGT System. RS R 12. 4. 6. 2 ---------------------------------N 0 TE-----------------------------

On ly required to be met when in MODES 1, 2, or 3. Verify: a. Both SGT trains are OPERABLE, and b. Only one of the SGT System trains to be used for PURGING. Page 1-12.4.6-1 Prior to PURGING through the SGT System.

CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 12.4 GASEOUS EFFLUENTS AND TOTAL DOSE 12.4.7 Total Dose REC 12.4.7 The dose or dose commitment to any MEMBER OF THE PUBLIC due to releases of radioactivity and radiation from all uranium fuel cycle sources over 12 consecutive months shall be limited to: 25 mrem to the total body; and b. 75 mrem to the thyroid; and c. 25 mrem to any other organ. APPLICABILITY:

At all times. ACTIONS CONDITION A. -------------N 0 TE---------------

Req u ired Action A.1 and A.2 shall be completed if this Condition is entered. As required by Required Action B.1 of REC 12.3.2, 12.4.2, or 12.4.3. Calculated Total Dose not within limits. REQUIRED ACTION A.1 Submit a report to the NRC (Director, Nuclear Reactor Regulation) that defines the corrective action to be taken to reduce subsequent releases to prevent recurrence of exceeding the limits to include estimates of radiation exposure to a MEMBER OF THE PUBLIC from uranium fuel cycle sources, including all effluent pathways and direct radiation, for a 12 consecutive month period that includes the release(s) covered by this report. Page 1-12.4.7-1 COMPLETION TIME 30 days (continued)

ACTIONS CONDITION A. (continued)

SURVEILLANCE REQUIREMENTS CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls REQUIRED ACTION A. 2 --------------N 0

On ly applicable if the release condition resulting in violation of 40 CFR 190 has not been corrected.

COMPLETION TIME Submit a request for a 30 days variance in accordance with 40 CFR 190, including the specified information of 40 CFR 190.11. SURVEILLANCE FREQUENCY RSR 12.4.7.1 Determine cumulative dose contributions from direct radiation and liquid and gaseous effluents in accordance with the ODCM. Page 1-12.4.7-2 31 days CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 12.4 GASEOUS EFFLUENTS AND TOTAL DOSE 12.4.8 Main Condenser REC 12.4.8 The release rate of the sum of the activities from the noble gases measured prior to the holdup line shall be limited to .::. 3.4 x 10 5 µCi/sec after 30 minutes decay. APPLICABILITY:

MODE 1, MODES 2 and 3 with any steam line not isolated and steam jet air ejectors (SJAE) in operation.

ACTIONS CONDITION REQUIRED ACTION COMPLETION TIME A. Release rate of the sum of A.1 Restore the release rate to 72 hours8.333333e-4 days <br />0.02 hours <br />1.190476e-4 weeks <br />2.7396e-5 months <br /> the activities from noble within limit. gases prior to the holdup line not within the limits. B. Required Action and B.1 Isolate all main steam 12 hours1.388889e-4 days <br />0.00333 hours <br />1.984127e-5 weeks <br />4.566e-6 months <br /> associated Completion lines. Time not met. OR B.2 Isolate the SJAE. 12 hours1.388889e-4 days <br />0.00333 hours <br />1.984127e-5 weeks <br />4.566e-6 months <br /> OR B.3.1 MODE3 12 hours1.388889e-4 days <br />0.00333 hours <br />1.984127e-5 weeks <br />4.566e-6 months <br /> AND B.3.2 MODE 4 36 hours4.166667e-4 days <br />0.01 hours <br />5.952381e-5 weeks <br />1.3698e-5 months <br /> Page 1-12.4.8-1 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls SURVEILLANCE REQUIREMENTS SURVEILLANCE RSR 12.4.8.1 Monitor the noble gas radioactivity rate prior to the holdup line in accordance with the ODCM and Table R12.2.2-1 RS R 12. 4. 8. 2 -----------------------------N 0 TE------------------------------------

N ot required to be performed until 31 days after any Main Steam line not isolated and SJAE in operation.

Verify the release rate of the sum of the activities from noble gases prior to the holdup line is within limits by performing an isotopic analysis of a representative sample of gases taken prior to the holdup line. Page 1-12.4.8-2 FREQUENCY CONTINUOUSLY Once within 4 hours4.62963e-5 days <br />0.00111 hours <br />6.613757e-6 weeks <br />1.522e-6 months <br /> after a increase in the nominal steady state fission gas release from the primary coolant, as indicated by the off gas treatment Noble Gas Activity Monitor, after factoring out increases due to changes in THERMAL POWER level 31 days CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 12.4 GASEOUS EFFLUENTS AND TOTAL DOSE 12.4.9 Dose Limits for MEMBERS OF THE PUBLIC REC 12.4.9 Operations shall be conducted such that: a. Total Effective Dose Equivalent (TEDE) to individual MEMBERS OF THE PUBLIC does not exceed 100 mrem/year; and b. The dose in any unrestricted area from external sources does not exceed 2 mrem in any one hour. APPLICABILITY:

At all times. ACTIONS CONDITION REQUIRED ACTION COMPLETION TIME A.

A.1 Submit a report to the NRC 30 days Required Action A.1 shall be in accordance with completed if this Condition is 10 CFR 20.2203. entered. -------------------------------------

Dose limit of REC Item a. exceeded.

B.

B.1 Submit a report to the NRC 30 days Required Action B.1 shall be in accordance with completed if this Condition is 10 CFR 20.2203. entered. -------------------------------------

Dose limit of REC Item b. exceeded.

Page 1-12.4.9-1 SURVEILLANCE REQUIREMENTS SURVEILLANCE CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls FREQUENCY RSR 12.4.9.1 Calculate the TEDE to individual MEMBERS OF THE PUBLIC in accordance with the ODCM. 12 months RSR 12.4.9.2 Determine and/or evaluate direct radiation exposures in unrestricted areas. Page 1-12.4.9-2 12 months CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 12.5 RADIOLOGICAL ENVIRONMENTAL MONITORING PROGRAM 12.5.1 Radiological Environmental Monitoring Program (REMP) REC 12.5.1 The REMP shall be conducted as specified in Table R12.5.1-1.

APPLICABILITY:

At all times. ACTIONS CONDITION REQUIRED ACTION COMPLETION TIME A. --------------NOTE--------------

A. 1 Initiate action to identify Jmmediately Required Action A.2 shall be completed if this Condition is entered. Sample type or location(s) required by Table R12.5.1-1 permanently unavailable.

suitable, alternative sampling media and/or specific locations for obtaining replacement samples for the pathway of interest and add them to the REMP. Delete locations from which samples are unavailable.

A.2 Prepare and submit a controlled version of the ODCM, in the next Annual Radiological Environmental Operating Report (REOR) including revised figures and tables reflecting the new location(s) with supporting information identifying the sample unavailability cause and justification of the new sampling location(s).

Page 1-12.5.1-1 In accordance with Technical Specification 5.6.2 (continued)

ACTIONS CONDITION B.

Required Action B.1 shall be completed if this Condition is entered. ------------------------------------

Level of radioactivity as the result of plant effluents in an environmental sampling medium at a specified location exceeds the reporting levels of Table R 12.5.1-2 when averaged over any calendar quarter. C. -------------NOTE--------------

Required Action C.1 shall be completed if this Condition is entered. ------------------------------------

More than one radionuclide in Table R12.5.1-2 detected in the sampling medium. AND C1 C2 --+--+ ...

RL1 RL2 where; C = concentration RL = reporting level. B.1 C.1 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls REQUIRED ACTION COMPLETION TIME Submit a report to the NRC 30 days that identifies the cause(s) for exceeding the limits and defines the corrective actions to be taken to reduce radioactive effluents so that the potential annual dose to a MEMBER OF THE PUBLIC is less than the calendar year reporting level of REC 12.3.2, 12.4.2 or 12.4.3. The methodology and parameters used to estimate the potential annual dose to a MEMBER OF THE PUBLIC shall be indicated in this report. Submit a report to the NRC 30 days that identifies the cause(s) for exceeding the limits and defines the corrective actions to be taken to reduce radioactive effluents so that the potential annual dose to a MEMBER OF THE PUBLIC is less than the calendar year reporting level of REC 12.3.2, 12.4.2 or 12.4.3. The methodology and parameters used to estimate the potential annual dose to a MEMBER OF THE PUBLIC shall be indicated in this report. (continued)

Page 1-12.5.1-2 ACTIONS CONDITION D. -------------N 0 TE--------------

Req u ired Action D.1 and D.2 shall be completed if this Condition is entered. Radionuclides other than those in Table R12.5.1-2 are detected.

AND The potential annual dose to a MEMBER OF THE PUBLIC from all radionuclides is greater than or equal to the calendar year limits of REC 12.3.2, 12.4.2, or 12.4.3. CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls REQUIRED ACTION D.1 Only required when the measured levels of radioactivity are the result of plant effluents.

COMPLETION TIME Submit a report to the NRC 30 days that identifies the cause(s) for exceeding the limits and defines the corrective actions to be taken to reduce radioactive effluents so that the potential annual dose to a MEMBER OF THE PUBLIC is less than the calendar year reporting level. The methodology and parameters used to estimate the potential annual dose to a MEMBER OF THE PUBLIC shall be indicated in this report. D. 2 -----------------N 0 TE---------------

0 n ly required when the radionuclides detected are not the result of plant effluents.

Describe the condition in the next Annual REOR. Page 1-12.5.1-3 In accordance with Technical Specification 5.6.2. (continued)

ACTIONS CONDITION E. -----------NOTE----------

E.1 Required Action E.1 shall be completed if this Condition is entered. RSR 12.5.1.1 not met. CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls REQUIRED COMPENSATORY MEASURE Prepare and submit to the NRC, in the next Annual REOR, a description of the reasons for not conducting the program as required and the plans for preventing a recurrence.

Page 1-12.5.1-4 COMPLETION TIME In accordance with Technical Specification 5.6.2.

CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls SURVEILLANCE REQUIREMENTS SURVEILLANCE RSR 12.5.1.1 -------------------------------NOTES------------------------------

1. Deviations to the sampling schedule for the following reasons may occur and the RSR still be considered met provided the deviations are described in the next Annual REOR: a. specimens are unobtainable due to hazardous conditions, seasonal unavailability, or malfunction of sampling equipment, or b. a person or business who participates in the program goes out of business or can no longer provide samples, or c. a contractor omission which is corrected as soon as discovered.
2. Malfunctioning equipment shall be corrected/replaced and replacement suppliers shall be found, as applicable, as soon as practicable.

Collect and analyze samples in accordance with Table R12.5.1-1 and the ODCM to the detection capabilities required by Table R12.5.1-3.

Page 1-12.5.1-5 FREQUENCY In accordance with the Radiological Environmental Monitoring Program EXPOSURE PATHWAY AND/ OR SAMPLE 1. Airborne Radioiodine and Particulates Table R12.5.1-1 (Page 1 of 6) RADIOLOGICAL ENVIRONMENTAL MONITORING PROGRAM NUMBER OF REPRESENTATIVE SAMPLES AND SAMPLING AND COLLECTION SAMPLE LOCATIONS 111 FREQUENCY 1111 Samples from a total of eight locations:

CONTINUOUS sampler operation with particulate sample a. Indicator-Near Field collection weekly, or more frequently if required due to dust Four samples from locations within 4.0 km (2.5 mi) in loading , and radioiodine canister different sectors. collection weekly. b. Indicator-Far Field Four additional locations within 4.0 to 10 km (2.5 to 6.2 mi) in different sectors. c. Control One sample from a control location within 10 to 30 km (6.2 to 18.6 mi). Page 1-12.5.1-6 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls TYPE AND FREQUENCY OF ANAL YSIS 1111 Radioiodine Canister: 1-131 analysis weekly on near field samples and control(2 l samples. Particulate Samgler: Gross beta analysis weekly filter change l and gamma isotopic analysis(4 l quarterly on composite filters by location on near field and contro1<2> samples. (continued)

EXPOSURE PATHWAY AND/ OR SAMPLE 2. Direct Radiation 1" 1 Table R12.5.1-1 (Page 2 of 6) RADIOLOGICAL ENVIRONMENTAL MONITORING PROGRAM NUMBER OF REPRESENTATIVE SAMPLES AND SAMPLING AND COLLECTION SAMPLE LOCATIONS 111 FREQUENCY 1111 Forty routine monitoring stations, either with a Field Quarterly Dosimeter or with one instrument for measuring dose rate continuously, placed as follows: a. Indicator-Inner Ring (100 Series) One in each meteorological sector, in the general area of the SITE BOUNDARY (within 0.1 to 2.0 miles; 0.2 to 3.2 km); b. Indicator-Outer Ring (200 Series) One in each meteorological sector, within 4.8 to 10 km (3 to 6.2 mi); c. Other One at each Airborne location given in part 1.a. and 1.b. The balance of the Field Dosimeters to be placed at special interest locations beyond the Restricted Area where either a MEMBER OF THE PUBLIC or Exelon Nuclear employees have routine access. d. Control One at each airborne control location given in part 1.c. Page 1-12.5.1-7 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls TYPE AND FREQUENCY OF ANAL vs1s 1111 Gamma dose on each Field Dosimeter quarterly. (continued)

EXPOSURE PATHWAY AND/ OR SAMPLE 3. Waterborne

a. a. Ground/Well
a. b. Drinking<7> c. Surface Water<1> a. b. d. Sediment a. CY-LA-170-301 Revision 8 June 2016 Part I, Radio l ogical Effluent Controls Table R12.5.1-1 (Page 3 of 6) RADIOLOGICAL ENVIRONMENTAL MONITORING PROGRAM NUMBER OF REPRESENTATIVE SAMPLES AND SAMPLING AND COLLECTION TYPE AND FREQUENCY SAMPLE LOCATIONS 111 FREQUENCY 1111 OF ANAL YSIS 1111 Indicator Quarterly Gamma isotopic!"'

and tritium analysis quarterly.

Samples from two sources only if likely to be affected.

<5> Indicator Grab samples weekly. Gross beta and gamma isotopic analyses<4> on One Sample from each community drinking water monthly composite; trit i um supply that could be affected by the station discharge analysis on quaterly within 10 km (6.2 mi) downstream of discharge.

composite. 1-131 on each composite when calculated dose for water consumption>

1 mrem/vear. If no community water supply (Drinking Water) exists Grab samples weekly. Gross beta and gamma within 10 km downstream of discharge then surface isotopic analyses 14> on water sampling shall be performed. monthly composite; tritium lndicator<

1> analysis on quarterly composite.

One surface sample downstream of discharge.

Contro1<7> One surface sample upstream of discharqe. Indicator Semiannually Gamma isotopic At least one sample from downstream<

1> area within 1 O analysis<4> semiannually. km (6.2 mi) of discharQe. (continued)

Page 1-12.5.1-8 EXPOSURE PATHWAY AND/ OR SAMPLE 4. Ingestion

a. Milk(B) b. Fish c. Food Products CY-LA-170-301 Revision 8 June 2016 Part I , Radiological Effluent Controls Table R12.5.1-1 (Page 4 of 6) RADIOLOGICAL ENVIRONMENTAL MONITORING PROGRAM NUMBER OF REPRESENTATIVE SAMPLES AND SAMPLING AND COLLECTION TYPE AND FREQUENCY SAMPLE LOCATIONS 111 FREQUENCY 1111 OF ANAL YSIS 1111 a. Indicator Biweekly when animals are on Gamma isotopicl 41 and Samples from milking animals from a maximum pasture (May through October), 1-131 <9> analysis on each monthly at other times sample. of three locations within 10 km (6.2 mi) distance. (November through April). b. Control One sample from milking animals at a control location within 10 to 30 km (6.2 to 18.6 mi). a. Indicator Two times annually.

Gamma isotopic Representative samples of commercially and analysis 14> on edible portions recreationally important species in discharge area, and representative samples from the LaSalle Lake. b. Control Representative samples of commercially and recreationally important species in control locations upstream of discharge.

a. Indicator Annually Gamma isotopid" 1 and Two representative samples from the principal 1-131 analysis on each sample. food pathways grown in each of four major quadrants within 10 km (6.2 mi), if available: At least one root vegetable sample(10> At least one broad leaf vegetable (or vegetation)(10> b. Control Two representative samples similar to indicator samples grown within 15 to 30 km (9.3 to 18.6 mi). (continued)

Page 1-12.5.1-9 EXPOSURE PATHWAY AND/ OR SAMPLE 4. Ingestion

d. Vegetation CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls Table R12.5.1-1 (Page 5 of 6) RADIOLOGICAL ENVIRONMENTAL MONITORING PROGRAM NUMBER OF REPRESENTATIVE SAMPLES AND SAMPLING AND COLLECTION TYPE AND FREQUENCY SAMPLE LOCATIONSl 1 l FREQUENCY 1111 OF ANAL YSIS 1111 -------------------NOTE--------------

Monthly during the growing Gamma isotopic <4> These vegetation samples are only required if milk season (May through October). analysis and 1-131 sampling is not performed.

analysis on each sample. --a. Indicator Samples of 3 different types of broadleaf vegetation within 10 km (6.2 miles) at 2 different offsite locations in the highest D/Q sector of the station, if available.

b. Control Samples of 3 different types of broadleaf vegetation within 15 to 30 km (9.3 to 18.6 miles) in the lowest D/Q sector of station, if available.

Page 1-12.5.1-10 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls Table R12.5.1-1(Page6of6)

RADIOLOGICAL ENVIRONMENTAL MONITORING PROGRAM TABLE NOTATIONS (1) Specific parameters of distance and direction from the centerline of the midpoint of the two units and additional description where pertinent, shall be provided for each and every sample location in Table R12.5.1-1, except for vegetation.

For vegetation (both food product and vegetation exposure pathways), due to location variability year to year, the parameters of distance and direction shall be provided in the Annual Environmental Operating Report. (2) Far field samples are analyzed when the respective near field sample results are inconsistent with previous measurements and radioactivity is confirmed as having its origin in airborne effluents from the station, or at the discretion of the ODCM Specialist.

(3) Airborne particulate sample filters shall be analyzed for gross beta radioactivity 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> or more after sampling to allow for radon and thoron daughter decay. If gross beta activity in air particulate samples is greater than 10 times the yearly mean of control samples, gamma isotopic analysis shall be performed on the individual samples. (4) Gamma isotopic analysis means the identification and quantification of gamma emitting radionuclides that may be attributable to the effluents from the station. (5) One or more instruments, such as a pressurized ion chamber, for measuring and recording dose rate continuously may be used in place of, or in addition to, integrating dosimeters.

Film badges shall not be used as dosimeters for measuring direct radiation.

The 40 locations is not an absolute number. The number of direct radiation monitoring stations may be reduced according to geographical limitations; e.g., if a station is adjacent to a lake, some sectors may be over water thereby reducing the number of dosimeters that could be placed at the indicated distances.

The frequency of analysis or readout for Field Dosimeter systems will depend upon the of the specific system used and should be selected to obtain optimum dose information with minimal fading. (6) Groundwater samples shall be taken when this source is tapped for drinking or irrigation purposes in areas where the hydraulic gradient or recharge properties are suitable for contamination.

(7) The "downstream" sample shall be taken in an area beyond but near the mixing zone. The "upstream sample" shall be taken at a distance beyond significant influence of the discharge.

Upstream samples in an estuary must be taken far enough upstream to be beyond the station influence.

(8) If milking animals are not found in the designated indicator locations, or if the owners decline to participate in the REMP, all milk sampling may be discontinued.

See the vegetation exposure pathway for additional sampling requirements.

(9) 1-131 analysis means the analytical separation and counting procedure are specific for this radionuclide.

(10) One sample shall consist of a volume/weight of sample large enough to fill contractor specified container.

(11) The provisions of RSR 12.0.2 and RSR 12.0.3 are not applicable to the REMP. Page 1-12.5.1-11 Table R12.5.1-2 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls REPORTING LEVELS FOR RADIOACTIVITY CONCENTRATIONS IN ENVIRONMENTAL SAMPLES REPORTING LEVELS AIRBORNE PARTICULATE FOOD PRODUCTS ANALYSIS WATER (pCill) OR GASES (pCi/m 3} FISH (pCi/kg, wet} MILK (pCi/I} (pCi/kc:i, wet) H-3 Mn-54 Fe-59 Co-58 Co-60 Zn-65 Zr-Nb-95 1-131 Cs-134 Cs-137 Ba-La-140 (1) (2) 20,000<1> 1,000 30,000 400 10,000 1,000 30,000 300 10,000 300 20,000 400 2(2) 0.9 3 100 30 10 1,000 60 1,000 50 20 2,000 70 2,000 200 300 For drinking water samples. This is 40 CFR Part 141 value. If no drinking water pathway exists, a value of 30,000 pCi/I may be used. If no drinking water pathway exists, a value of 20 pCi/I may be used. Page 1-12.5.1-12 Table R12.5.1-3 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls DETECTION CAPABILITIES FOR ENVIRONMENTAL SAMPLE ANAL vs1s<a) LOWER LIMIT OF DETECTION (LLD)(bl AIRBORNE PARTICULATE FISH FOOD PRODUCTS SEDIMENT/SOIL ANALYSIS WATER (pCill) OR GASES CoCi/m 3) CoCi/ka, wet) MILK CoCill) (pCi/kg, wet) CoCi/ka, drv) Gross Beta 4 0.01 H-3 2,000 Mn-54 15 130 Fe-59 30 260 Co-58,60 15 130 Zn-65 30 260 Zr-95 30 Nb-95 15 1-131 1<c) 0.07 1 60 Cs-134 15 0.05 130 15 60 150 Cs-137 18 0.06 150 18 80 180 Ba-140 60 60 La-140 15 15 (a) All peaks identified at the 95% confidence level, shall also be analyzed and reported. (b) Most restrictive ODCM LLD requirement or technical requirement.

The reported minimum detectable concentration (MDC) shall these values. (c) If no drinking water pathway exists, a value of 15 pCi/I may be used (NUREG 1301/1302)

Page 1-12.5.1-13 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 12.5 RADIOLOGICAL ENVIRONMENTAL MONITORING PROGRAM 12.5.2 Land Use Census REC 12.5.2 A Land Use Census shall be conducted and shall identify within a distance of 10 km (6.2 miles) the location in each of the 16 meteorological sectors of the nearest milk animal, the nearest residence, and an enumeration of livestock.

For dose calculation, a garden will be assumed at the nearest residence.


l\IOTES-------------------------------------------------------

1. The 16 meteorological sectors requirement may be reduced according to geographical limitations; e.g. at a lake site where some sectors will be over water. 2. The nearest industrial facility shall also be documented if closer than the nearest residence.

APPLICABILITY:

At all times. ACTIOl\IS CONDITIOl\I A. ------------1\!0TE--------------

A.1 Required Action A.1 and A.2 shall be completed if this Condition is entered. Land use census identifies Al\ID a location which yields a calculated dose or dose commitment, via the same exposure pathway, that is at least 20% greater than at a location from which samples are currently being obtained in accordance with REC 12.5.1. REQUIRED ACTIOl\I Add the new location to the Radiological Environmental Monitoring Program (REMP). Page 1-12.5.2-1 COMPLETIOl\I TIME 30 days (continued)

ACTIONS CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls CONDITION REQUIRED ACTION COMPLETION TIME A. (continued)

A. 2 ---------------N 0 TE--------------


The sampling location(s), excluding the control location, having the lowest calculated dose or dose commitment(s), via the same exposure pathway, may be deleted from the REMP after October 31 of the year in which Land Use Census was conducted.

Submit the documentation for a change in the ODCM in the next Annual Radiological Environmental Operating Report and include the revised figures and tables for the ODCM reflecting the new location(s) with information supporting the change in sampling locations.

SURVEILLANCE REQUIREMENTS RSR 12.5.2.1 SURVEILLANCE Conduct a land use census during the growing season, between June 1 and October 1, using information that will provide the best results, such as by a door-to-door survey, aerial survey, or by consulting local agriculture authorities.

The results of the census shall be included in the Annual Radiological Environmental Operating Report. Page 1-12.5.2-2 In accordance with Technical Specification

5.6.2. FREQUENCY

RSR 12.0.2 and 12.0.3 are not applicable.

12 months CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 12.5 RADIOLOGICAL ENVIRONMENTAL MONITORING PROGRAM 12.5.3 lnterlaboratory Comparison Program REC 12.5.3 Analyses shall be performed on radioactive materials supplied as part of an lnterlaboratory Comparison Program that is traceable to NIST. APPLICABILITY:

At all times. ACTIONS CONDITION A ------------NOTE------------

A.1 Required Action A.1 shall be completed if this Condition is entered. Requirements of the REC not met. SURVEILLANCE REQUIREMENTS REQUIRED ACTION Report corrective actions to prevent recurrence to the NRC in the next Annual Radiological Environmental Operating Report. SURVEILLANCE RSR 12.5.3 Include a summary of the results of the lnterlaboratory Comparison Program in the Annual Radiological Environmental Operating Report. Page 1-12.5.3-1 COMPLETION TIME In accordance with Technical Specification

5.6.2 FREQUENCY

In accordance with Technical Specification 5.6.2 CY-LA-170-301 Revision 8 June 2016 Part I, Radiological Effluent Controls 12.5 RADIOLOGICAL ENVIRONMENTAL MONITORING PROGRAM 12.5.4 Meteorological Monitoring Program (NOT APPLICABLE)

Page 1-12.5.4-1