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Category:GENERAL EXTERNAL TECHNICAL REPORTS
MONTHYEARML20217A9931999-09-30030 September 1999
NRC Regulatory Assessment & Oversight Pilot Program, Performance Indicator Data
ML20211A9981999-07-12012 July 1999
Draft,Probabilistic Safety Assessment, Risk Info Matrix, Risk Ranking of Systems by Importance Measure
ML20196H8621999-06-30030 June 1999
NRC Regulatory Assessment & Oversight Pilot Program, Performance Indicator Data, June 1999 Rept
ML20155D9961998-10-31031 October 1998
Rev 0 to GE-NE-B13-01980-24, Fracture Mechanics Evaluation on Observed Indication at N3A Steam Outlet Nozzle to Shell Weld at Cooper Nuclear Station
ML20151Q1211998-08-14014 August 1998
Rev 0 to Control of Hazard Barriers
ML20236P2971998-07-0707 July 1998
Rev 2 to NPPD CNS Strategy for Achieving Engineering Excellence
ML20238E9201997-03-31031 March 1997
Geris 2000 Invessel Sys Alternate Method for Compliance to Reg Guide 1.150
ML20133F4561996-10-31031 October 1996
Engineering Self Assessment Follow-Up, for NPPD Cooper Nuclear Station
ML20113B2831996-05-31031 May 1996
USI A-46 Seismic Evaluation Rept Vol I/V
ML20113B2891996-05-0707 May 1996
Rev 1 to USNRC USI A-46 Resolution Ssel & Relay Evaluation Rept, Vol I of Viii
ML20101K9321996-02-29029 February 1996
Determination of Loc for Cooper Feedwater Nozzle Fracture Mechanics Evaluation, for Feb 1996
ML20117N5601996-02-23023 February 1996
Engineering Self Assessment 960205- 23
ML20095G2001995-12-31031 December 1995
Fracture Mechanics Evaluation of UT Indications Found During 1995 Reexam of FW Nozzle to Shell Welds at Cns
ML20095G0961995-12-18018 December 1995
Stresses from Applied Loadings for Level A,B,C & D Conditions Considered in Core Spray Line Fracture Mechanics Evaluation
ML20094P2731995-11-30030 November 1995
Internal Core Spray Line Flaw Evaluation at Cns
ML20078J4181994-11-0808 November 1994
Rev 0 to, Cooper Nuclear Station Restart Readiness Program
ML20072U7391994-09-0101 September 1994
CNS Diagnostic Self Assessment Jul-Aug 1994
ML20113C1921994-07-31031 July 1994
Generation of Conservative Design & Median-Centered In-Structure Response Spectra for Cooper Nuclear Plant Control & Reactor Bldgs
ML17352A8691993-05-31031 May 1993
Technical Rept, Assessment of Aging Degradation of Civil/ Structural Features at Selected Operating Nuclear Power Plants.
ML20044G1701993-05-0404 May 1993
Seismic Occurrence of 930330, Engineering Evaluation
ML20086S8811991-12-13013 December 1991
Fracture Mechanics Evaluation of UT Indications Found in Cooper Feedwater-Nozzle-to Shell Weld
ML20086Q1961991-11-0101 November 1991
Emergency Preparedness Assessment Rept
ML20065L6761990-11-30030 November 1990
Initial Simulator Certification Submittal
ML20246C6101989-08-31031 August 1989
Dcrdr Suppl III to Summary Rept
ML20151F9501988-06-27027 June 1988
Change 1,Rev 1 to SAIC-86/1797, Summary of Human Factors Activities Related to Cooper Nuclear Station Plant Mgt Info Sys & Spds
ML20235U4311987-09-23023 September 1987
Turbine Bypass Valve Out-of-Svc Evaluation Summary. Related Info Encl
ML20235U3931987-09-21021 September 1987
Turbine Bypass Valve Out-of-Svc Assessment. W/Records of 870921 Telcons
ML20235H2741987-05-31031 May 1987
Mechanical Level Instrument Availability Analysis
ML20209G8701987-01-31031 January 1987
Dcrdr Suppl II to Summary Rept
ML20199C8431986-06-12012 June 1986
Rev C to Failure Mode & Effects Analyses
ML20198H0201986-05-15015 May 1986
Nebraska Public Power District Response to Initial Requirements of IE Bulletin 85-003
ML20154N4741986-03-31031 March 1986
Safety Evaluation of Main Steam Line High Flow Setpoint for Cooper Nuclear Station
ML20154L3281986-02-27027 February 1986
Dcrdr Suppl to Summary Rept
ML20107D5231985-02-0404 February 1985
Detailed Control Room Design Review Summary Rept
ML20099D4841985-02-0101 February 1985
Rev 2 to Detailed Descriptions of Displays for Cooper Nuclear Station Spds
ML20087A9491984-03-0101 March 1984
Safety Parameter Display Sys Safety Analysis
ML20083C6191983-11-23023 November 1983
Containment Purge & Vent Valve Operability Rept
ML20073R2061983-04-30030 April 1983
Wetwell-Drywell Vacuum Breaker Valves:Long-Term Program Structural Evaluation
ML20076E8611983-04-30030 April 1983
Nuclear Mgt Appraisal Rept for Nebraska Public Power District
ML20064C0131982-12-31031 December 1982
10CFR50,App R Supplementary Info Rept to Vols I & II Submitted to NRC 820628
ML20084Q5361982-07-31031 July 1982
BWR Owners Group Position on NRC Reg Guide 1.97,Rev 2
ML20052C0741982-04-30030 April 1982
Plant Unique Analysis Rept:Mark I Containment Program.
ML20052J0011982-02-12012 February 1982
to IF-300 Redundant Yoke,NUREG-0612 Evaluation.
ML20038B7251981-10-31031 October 1981
Evaluation Rept,Oct,1981.
ML20009A5351981-01-26026 January 1981
Meteorological Monitoring Sys Development Plan for Emergency Preparedness for Ne Public Power District,Cooper Nuclear Station & Brownsville,Ne, Preliminary Rept
ML19295D8031980-10-31031 October 1980
Master List of Class IE Equipment.
ML19262C3801980-01-21021 January 1980
Proposed Process Control Program
ML20125B9931979-10-31031 October 1979
Voltage Drop Analysis Computations, Revision 1
ML19270G3301979-06-0606 June 1979
Offsite Dose Assessment Manual.
ML19270G3331979-06-0606 June 1979
Radiological Environ Monitoring Manual.
1999-09-30
[Table view]
Category:TEXT-SAFETY REPORT
MONTHYEARML20212K9781999-09-30030 September 1999
Safety Evaluation Accepting USI A-46 Implementation Program
ML20217A9931999-09-30030 September 1999
NRC Regulatory Assessment & Oversight Pilot Program, Performance Indicator Data
ML20217G7461999-09-30030 September 1999
Monthly Operating Rept for Sept 1999 for Cooper Nuclear Station
ML20217A1691999-09-22022 September 1999
Part 21 Rept Re Engine Sys,Inc Controllers,Manufactured Between Dec 1997 & May 1999,that May Have Questionable Soldering Workmanship.Caused by Inadequate Personnel Training.Sent Rept to All Nuclear Customers
ML20212C5001999-08-31031 August 1999
Monthly Operating Rept for Aug 1999 for Cooper Nuclear Station
ML20211D6491999-08-25025 August 1999
Part 21 Rept Re Nonconformance within LCR-25 safety-related Lead Acid Battery Cells Manufactured by C&D.Analysis of Cells Completed.Analysis of Positive Grid Matl Shows Nonconforming Levels of Calcium within Positive Grid Alloy
ML20210R0381999-07-31031 July 1999
Monthly Operating Rept for July 1999 for Cooper Nuclear Station
ML20210J2921999-07-29029 July 1999
Special Rept:On 990406,OG TS & Associated Charcoal Absorbers Were Removed from Svc.Caused by Scheduled Maint on Hpci. Evaluation of Offsite Effluent Release Dose Effects Was Performed to Ensure Plant Remained in Compliance
ML20209H8281999-07-15015 July 1999
Safety Evaluation Accepting GL 95-07, Pressure Locking & Thermal Binding of Safety-Related Power-Operated Gate Valves, for Cooper Nuclear Station
ML20211A9981999-07-12012 July 1999
Draft,Probabilistic Safety Assessment, Risk Info Matrix, Risk Ranking of Systems by Importance Measure
ML20196H8621999-06-30030 June 1999
NRC Regulatory Assessment & Oversight Pilot Program, Performance Indicator Data, June 1999 Rept
ML20209E1061999-06-30030 June 1999
Monthly Operating Rept for June 1999 for Cns.With
ML20196B3851999-06-17017 June 1999
Summary Rept of Facility Changes,Test & Experiments,Per 10CFR50.59 for Period 970901-990331.Summary of Commitment Changes Made During Same Time Period Also Encl
ML20195K2851999-05-31031 May 1999
Monthly Operating Rept for May 1999 for Cooper Nuclear Station.With
ML20206P0481999-05-12012 May 1999
Safety Evaluation Concluding That NPP Established Acceptable Program to Verify Periodically design-basis Capability of safety-related MOVs at CNS & Adequately Addressed Actions Requested in GL 96-05
ML20206J0811999-05-0404 May 1999
Rev 14 to CNS QA Program for Operation
ML20206P9751999-04-30030 April 1999
Monthly Operating Rept for Apr 1999 for Cooper Nuclear Station
ML20205Q0891999-03-31031 March 1999
Monthly Operating Rept for Mar 1999 for Cooper Nuclear Station.With
ML20204G8951999-03-15015 March 1999
CNS Inservice Insp Summary Rept Fall 1998 Refueling Outage (RFO-18)
ML20207M9231999-03-12012 March 1999
Amended Part 21 Rept Re Cooper-Bessemer Ksv EDG Power Piston Failure.Total of 198 or More Pistons Have Been Measured at Seven Different Sites.All Potentially Defective Pistons Have Been Removed from Svc Based on Encl Results
ML20204B3701999-03-11011 March 1999
SER Accepting Third 10-year Interval Inservice Insp Plan Requests for Relief for RI-17,Rev 1 and RI-25,Rev 0.Request for Relief RI-13,Rev 2 Involving Snubber Testing & Is Being Evaluated in Separate Report
ML20204C9751999-02-28028 February 1999
Monthly Operating Rept for Feb 1999 for Cooper Nuclear Station
ML20199E6751999-01-14014 January 1999
Monthly Operating Rept for Dec 1998 for Cooper Nuclear Station
ML20195B9191998-12-31031 December 1998
1998 NPPD Annual Rept. with
ML20196J9641998-12-0707 December 1998
Safety Evaluation Accepting Licensee Third 10-yr Interval Inservice Insp Plan Request for Relief RI-27,rev 1
ML20198D2471998-11-30030 November 1998
Monthly Operating Rept for Nov 1998 for Cooper Nuclear Station.With
ML20196A2861998-11-23023 November 1998
SER Re Core Spray Piping Weld for Cooper Nuclear Station. Staff Concluded That Operation During Cycle 19 Acceptable with Indication re-examined During RFO 18
ML20196A5241998-11-23023 November 1998
Safety Evaluation Accepting Proposed Alternative to Use UT Techniques Qualified to Objectives of App Viil as Implemented by PDI Program in Performing RPV Shell Weld & Shell to Flange Weld Examinations
ML20196A5061998-11-23023 November 1998
Safety Evaluation Re Flaw Indication Found in Main Steam Nozzle to Shell Weld NVE-BD-N3A at Cns.Plant Can Be Safely Operated for at Least One Fuel Cycle with Indication in as-is Condition
ML20196C4241998-11-20020 November 1998
Rev 1 to Cooper Nuclear Station COLR Cycle 19
ML20195H1761998-11-17017 November 1998
SER Authorizing Proposed Alternative in Relief Requests RV-06,RV-07,RV-09,RV-11,RV-12 & RV-15 Pursuant to 10CFR50.55a(a)(3)(ii).RV-08 Granted Pursuant to 10CFR50.55a(f)(6)(i) & RV-13 Acceptable Under OM-10
ML20195F8601998-10-31031 October 1998
Monthly Operating Rept for Oct 1998 for Cooper Nuclear Station.With
ML20155D9961998-10-31031 October 1998
Rev 0 to GE-NE-B13-01980-24, Fracture Mechanics Evaluation on Observed Indication at N3A Steam Outlet Nozzle to Shell Weld at Cooper Nuclear Station
ML20154Q5661998-10-0505 October 1998
Rev 0 to CNS COLR Cycle 19
ML20154L5381998-09-30030 September 1998
Monthly Operating Rept for Sept 1998 for Cooper Nuclear Station.With
ML20151Z6141998-09-16016 September 1998
SER Accepting Util Responses to NRC Bulletin 95-002 for Cooper Nuclear Station
ML20154F7931998-08-31031 August 1998
Rev 0 to J11-03354-10, Supplemental Reload Licensing Rept for CNS Reload 18,Cycle 19
ML20153B1101998-08-31031 August 1998
Monthly Operating Rept for Aug 1998 for Cooper Nuclear Station
ML20237E7771998-08-20020 August 1998
Revised COLR Cycle 18 for Cooper Nuclear Station
ML20151Q1211998-08-14014 August 1998
Rev 0 to Control of Hazard Barriers
ML20237C0591998-07-31031 July 1998
Monthly Operating Rept for Jul 1998 for Cooper Nuclear Station
ML20236R9131998-07-20020 July 1998
SER Accepting Rev 13 to Quality Assurance Program for Operation Policy Document for Plant
ML20236P2971998-07-0707 July 1998
Rev 2 to NPPD CNS Strategy for Achieving Engineering Excellence
ML20236R0931998-06-30030 June 1998
Monthly Operating Rept for June 1998 for Cooper Nuclear Station
ML20249A7701998-05-31031 May 1998
Monthly Operating Rept for May 1998 for Cooper Nuclear Station
ML20247G6131998-05-13013 May 1998
Part 21 Rept Re Defect Contained in Automatic Switch Co, Solenoid Valves,Purchased Under Purchase Order (Po) 970161. Caused by Presence of Brass Strands.Replaced Defective Valves
ML20247G0951998-04-30030 April 1998
Monthly Operating Rept for Apr 1998 for Cooper Nuclear Station
ML20237B6861998-04-24024 April 1998
Vols I & II to CNS 1998 Biennial Emergency Exercise Scenario, Scheduled for 980609
ML20217A1531998-04-16016 April 1998
Closure to Interim Part 21 Rept Submitted to NRC on 970929. New Date Established for Completion of Level I & 2 Setpoint Project Committed to in .Final Approval of Setpoint Calculations Will Be Completed by 980531
ML20216G5331998-03-31031 March 1998
Monthly Operating Rept for Mar 1998 for Cooper Nuclear Station
1999-09-30
[Table view] |
Text
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ATTACHMENT III PROPOSED PROCESS CONTROL PROGRAM For Cooper Nuclear Station January 21, 1980 1948 098 80022Io , _yf p
PROCESS CONTROL PROGRAM INTRODUCTION This Process Control Program outlines the solidification of radioactive waste from liquid systems at Cooper Nuclear Station. It is not intended to be a substitute for station operating procedures, but to provide a general description of equipment, controls, and practices to be considered during waste solidification.
Station operating procedures will provide detailed instructions as to the actual operation during the solidification process.
CLASSIFICATION OF TERMS This Process Control Program Document describes the process used to solidify wet wastes. Wet wastes are those wastes produced from the liquid radwaste treatment system. These wastes may be typically described as spent resins (bead and powdex), filter material, waste sludges, and evaporator concentrates.
The solidification of these wastes as defined is the conversion of radioactive wastes from liquid systems to a solid, which is as uninformly distributed as reasonably achievable, with definite volume and shape, bounded by a stable surface of distinct outline on all sides. The solidification of the wastes mentioned above is achieved with equipment installed at CNS and this equipment operated in accordance with CNS operating procedures. Those wastes which progress through the process system, fill, mix, and capping stations will normally meet the solidification criteria. Those wastes that deviate from the normal operation, needing special technique, such as hand mixing, material injection by manipulater or hand, etc. will be as uninformly distributed as reasonably achievable. Keeping exposures ALARA and physical makeup of the material to be solidified will be the governing considerations in determining what is reasonably achievable.
The radwaste solidification process will be operated on a batch basis. A batch will consist of all the resulting continuous drums processed from the contents of a single source. An example would be the sludge from a condensate phase separator solidified in a continuous drumming operation until the phase separator is empty or the batch is terminated.
Radioactive wastes from liquid systems processed on a batch basis for solidi-fication will normally be, but not limited to, the condensate phase separators, reactor water cleanup phase separators, waste sludge tank, spent resin tank, or concentrated waste tank.
OPERATION 1948 099 Wastes to be solidfied will normally be from the condensate or reactor water cleanup phase separators, waste sludge tank, or spent resin tank. These wastes are routed through the centrifuge units. After dewatering in the centrifuge, wastes then enter a storage hopper. Wastes at this step will vary from a fairly dry granular consistency to a wet putty like consistency depending upon the source material; filtered sludges, filter material, resins, etc.
Department of Transportation 17H specification 55 gallon drums containing cement are then transferred under the hopper and filled with wastes. The drum then progresses to the mixing station.
The in-drum mixer mixe.* the cement and waste materials. Water is then added to the mixture in quantities to ensure solidification. Because of the varying degree of wetness from one batch to the next, periodic visual inspection of the first few drums is necessary to determine the correct amount of water needed. After the amount of water to achieve solidification has been determined, it may be added automatically by the mixing program.
Af ter mixing has been achieved, radiation levels of each drum is taken. The drum is then transferred to the drum storage lines.
The drumming operation will be continuous, centrifuging, and drumming until the source, phase separators, or tanks are emptied or the batch terminated.
After at least 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> the drums are taken from the storage line to the capping station. Here the drum is visually inspected for free-standing water.
If the material is solid and no free-standing water is present, the drum is capped. If it is not solidif2ed or free-standing watar is present, cement may have to be added or the drum is put back on the stoce;e line to cure. After capping, the drum is washed to remove contamination. The capped drum is then taken to the storage line. Prior to shipment the ucums will be taken to the smear station and checked for contamination levels.
The third or fourth drum of each batch will be sampled prior to the mixing station. This sample is considered representative of that batch. The sample is taken to the Radiochemistry Laboratory for analysis.
PARAMETERS AND TESTING Two cubic feet of cement will be added to each 55 gallon 17H specification drum. It has been demonstrated that this volume of cement with the remaining drum "olume being powdex resins, powdex filter material, sludges, etc. and water .ill achieve solidification.
After the material to be solidified has been added to the drum, a sample of this material, considered to be representative of that batch, will be taken.
This sample will be analyzed for pH. It has been demonstrated that if the material to be solidified has a pH value within the range of 2 to 13, the solidification process will not be affected. This sample is also isotopically analyzed to determine isotope distribution. By comparing this isotopic distribution and radiation readings on each drum, the total concentration of the radionuclides present can be determined, also any carry-over from the previous batch or changes in the amount of solidified material may be taken into account.
Because of the variation in water content of the material after being centrifuged (dry to paste-like consistency), varying amounts of water will be added during the mixing stage. The first few drums will provide a basis for determining the correct amount of water to be added to each drum of the batch. This will be done visually and with mixer torque indications. Once the amount of water needed for solidification has been determined, this amount of water will be added to each drum by the automatic mixing sequence controls.
1948 100
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At least 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> after mixing and prior to capping each drum is visually inspected. This provides assurance that no free-standing water is present and that the radwaste material has been solidified.
REPORTS The volume and curie content of wet wastes solidified at Cooper Nuclear Station will be documented in the Station Semi-annual Reports. This information will be in the format outlinad in Regulatory Guide 1.21, Revision 1, Table 3.
1948 101
