ML14142A323

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May 21, 2014 Public Meeting Presentation
ML14142A323
Person / Time
Site: Calvert Cliffs  Constellation icon.png
Issue date: 05/22/2014
From: Nadiyah Morgan
Division of Operating Reactor Licensing
To:
Office of Nuclear Reactor Regulation
References
Download: ML14142A323 (39)


Text

1 NRR-PMDAPEm Resource From: Morgan, Nadiyah Sent: Thursday, May 22, 2014 11:45 AM To: NRR-PMDA-ECapture Resource

Subject:

Calvert Cliffs May 21, 2014 P ublic Meeting Presentation Attachments:

RI GSI-191 May, 2014 Meeting with NRC Rev. 4.pdfHi Leslie, Would you please add the attached document to ADAMS?

Docket Nos.: 05000317 and 05000318 Thanks, Dee

Nadiyah S. Morgan Calvert Cliffs and Pilgrim Project Manager, NRR US Nuclear Regulatory Commission O-8F4 (301) 415-1016 Nadiyah.Morgan@NRC.GOV

Hearing Identifier: NRR_PMDA Email Number: 1305 Mail Envelope Properties (9C2386A0C0BC584684916F7A0482B6CAFCB2EA1FB9)

Subject:

Calvert Cliffs May 21, 2014 Public Meeting Presentation Sent Date: 5/22/2014 11:45:28 AM Received Date: 5/22/2014 11:45:29 AM From: Morgan, Nadiyah Created By: Nadiyah.Morgan@nrc.gov Recipients: "NRR-PMDA-ECapture Resource" <NRR-PMDA-ECapture.Resource@nrc.gov> Tracking Status: None

Post Office: HQCLSTR02.nrc.gov Files Size Date & Time MESSAGE 311 5/22/2014 11:45:29 AM RI GSI-191 May, 2014 Meeting with NRC Rev. 4.pdf 1293700 Options Priority: Standard Return Notification: No Reply Requested: No Sensitivity: Normal Expiration Date: Recipients Received:

Calvert Cliffs GSI-191 Program Plans for Chemical Effects Testing Plans for Penetration/Bypass Testing Eighth Discussion With NRC Staff May 21, 2014 Agenda *Introductions

  • Objectives for Meeting
  • Introduction to CCNPP Program for Vic Cusumano
  • Discussion of Autoclave Chemical Effects Test Results
  • Discussion of Integrated Chemical Effects Testing Plans
  • Discussion of Small-Scale Debris Penetration Testing Plans
  • Schedule for Future Periodic Meetings Calvert Cliffs Chemical Effects

- Plans for Integrated Testing 1

CCNPP Attendees

  • Tom Konerth

- Supervisor Mechanical & Civil Design

  • Anne Lederer

- Mechanical Design Engineer

  • Ken Greene

- Licensing Engineer

  • Jim Landale

- PRA Lead RI GSI-191

  • John Swailes

- Project Manager GSI-191

  • Craig Sellers

- Project Manager RI GSI-191

  • Andy Henni

- Lead Design Engineer RI GSI-191

  • Steve Kinsey

- Chemical Effects Testing

  • Eric Federline

- Project Support & Testing Calvert Cliffs Chemical Effects

- Plans for Integrated Testing 2

Objectives of this Meeting

  • Introduce CCNPP Risk Informed GSI-191 Resolution Project
  • Discuss Autoclave Test Results

-CCNPP-CHLE-005 High Temperature Tests

-CCNPP-CHLE-006 Metals Tests

-CCNPP-CHLE-010 Concrete & Insulation Tests

-CCNPP-CHLE-011 Long Term Integrated Simulation Tests

  • Discuss Integrated Chemical-Effects Head Loss Experiment (CHLE) Test Plans
  • Establish Schedule for Future Meetings
  • Capture Staff Issues and Concerns Calvert Cliffs Chemical Effects

- Plans for Integrated Testing 3

Introduction to CCNPP RI GSI-191 Project SECY-12-0093 Option 2

  • Parallel Deterministic and Risk-Informed Resolution

-Refined Testing and Analysis to Support Deterministic Resolution

-Replacing Fibrous Insulation as Needed to Support Deterministic Closure

  • Select Insulation Already Identified and Replaced
  • Additional Replacement Possible Based on Deterministic Testing

-Risk-Informed Testing and Analysis Partnered with STP

-Close by 12/2019 Calvert Cliffs Chemical Effects

- Plans for Integrated Testing 4

Introduction to CCNPP RI GSI-191 Project (Continued)

  • Plant Modifications Completed to Date

-Aluminum Minimization

  • Partial Insulation Replacement with SS RMI
  • Scissor Lift Removal
  • Scaffolding Materiel Removal

-NPSH Assurance

  • New Large 6,000 sq. ft. CCI Pocket Strainer with Structural Reinforcement -Multiple Large-Scale Strainer Head Loss Tests -2009 Chemical Effects Testing Suggesting Minimal Chemical Effects Head Loss -Extensive 2013/2014 Autoclave Testing Yielding No Detectible Precipitates
  • Refueling Cavity Drain Enlargement
  • Recirculation Suction Header Temperature Instrumentation

-Debris and Chemical Effects Reduction

  • Removal of Specific Mineral Wool in ZOI
  • Removal of Specific Generic Fiberglass in ZOI
  • Removal of Some Calcium Silicate and Double-Banding of that Remaining in ZOI
  • Replaced TSP Buffer with NaTB
  • Containment Aluminum Minimization Calvert Cliffs Chemical Effects

- Plans for Integrated Testing 5

Introduction to CCNPP RI GSI-191 Project (Continued)

  • Downstream Effects

-Ex-Vessel

  • Replaced HPSI Pump Cyclone Separators

-In-Vessel

  • 2007 Strainer Bypass Testing
  • Current Activities

-Testing *Integrated Chemical Effects Testing -Extensive Interaction with NRC Staff -Establish Agreement on Methods/Protocols and Acceptance of Results

  • Strainer Penetration (Bypass) Testing -Small-Scale Sensitivity Testing

-Large-Scale Penetration Quantification Testing

  • Strainer Head Loss Testing, as Required

-Re-Evaluation of Downstream Effects

  • As Needed by Updated Penetration Test Results Calvert Cliffs Chemical Effects

- Plans for Integrated Testing 6

Introduction to CCNPP RI GSI-191 Project (Continued)

-Industry Activities

  • Partner in STP RI GSI-191 Resolution Project -Best-Estimate Calculations
  • Containment Water Mass
  • Pool Temperature Profiles for VS, S, M, L, and VL LOCAs
  • Debris Generation, including CRUD Debris
  • Debris Transport
  • Pool Strong Acid Production
  • Pool pH *Copper and Galvanized Steel Surface Areas
  • Submerged Concrete Surface Area
  • Calculations Support Deterministic and Risk-Informed Resolution Approaches -Risk-Informed Analyses
  • Hybrid LOCA Frequency
  • Initial Risk-Assessment Quantification
  • Participant in PWROG Comprehensive Analysis and Test Program -Member of PWROG GSI-191 Challenge Board -Participating with PWROG GSI-191 TIGER Team Calvert Cliffs Chemical Effects

- Plans for Integrated Testing 7

Introduction to CCNPP RI GSI-191 Project (Continued) Overview of On-Going Chemical Effects Test Program

  • Objective

-Demonstrate Minimal Chemical Effects

-Identify Chemical Effects P on Detector Debris Bed

-Determine Time and/or Temperature at Which Chemical Effects Are Detected or Not

-Used as Basis for Deterministic and Risk-Informed Resolution of GSI-191

  • Approach -Long-Term Integrated Chemical Effects Tests

-Circulate Flow Through Repeatable and Sensitive Detector Debris Bed

-Extensive Autoclave Testing to Refine Design of Experimental Protocols

  • Begin with Design Basis Chemical Effects Tests

-DEGB LBLOCA Conditions w/Post 2014 RFO Insulation Configuration

-Post 2018 RFO Insulation Configuration, as required

  • Potential Negligible Chemical Effects Outcome

-Permits Deterministic Resolution of GSI-191

  • Risk-Informed Testing, As Necessary

-Medium & Small Break Chemical Effects Testing, as Necessary

-Appropriate with STP RI Approach Calvert Cliffs Chemical Effects

- Plans for Integrated Testing 8

Introduction to CCNPP RI GSI-191 Project (Continued) Autoclave Test Program

- More Than 50 Autoclave Tests

  • CCNPP-CHLE-005 High Temperature Experiment [Complete, Results Herein]

-Address Initial High Temperature (>195°F) Portion of LOCA (<10 hours)

  • CCNPP-CHLE-006 Metals Experiments [Complete, Results Herein]

-Single and Synergistic Corrosion Effects of Differing Metal Combinations

-Determine Most Appropriate Metals for Integrated Tests

  • CCNPP-CHLE-007 Alkyds Coating Experiments

[In-Progress]

-Investigate Chemical Effects Impact of Alkyd Coatings

  • CCNPP-CHLE-010 Concrete Experiments [Complete, Results Herein]

-Single and Synergistic Corrosion Effects of Concrete and Insulation

  • CCNPP-CHLE-011 Long-Term Integrated Simulation Autoclave Experiments [In-Progress, Early Results Herein]

-Determination of Duration for Long-Term Integrated Experiments Day Autoclave Simulation of Full Integrated Test

-Tests Completed

  • No Increased Filtration Times Observed
  • Chemistry Analysis Pending Calvert Cliffs Chemical Effects

- Plans for Integrated Testing 9

Introduction to CCNPP RI GSI-191 Project (Continued)

  • Integrated Chemical Effects Head Loss Experiment (CHLE)

-Reviewed Conceptual Design with NRC Staff

-Facility Designed & Constructed

-Shakedown Testing in Process Calvert Cliffs Chemical Effects

- Plans for Integrated Testing 10 Autoclave Testing Preliminary Results

  • CCNPP-CHLE-005 High-Temperature Test Results
  • CCNPP-CHLE-006 Metals Test Results Synergistic Interactions Filtration Results
  • CCNPP-CHLE-010 Concrete & Insulation Test Results
  • CCNPP-CHLE-011 Long-Term Integrated Test Simulation Calvert Cliffs Chemical Effects

- Plans for Integrated Testing 11 High Temperature Portion of LOCA

- CCNPP-CHLE-005

  • Initial 10 Hour Portion of DBA LOCA Temperature Profile in Sump > 195°F
  • Autoclave Testing Compared Initial DBA LOCA Profile to 24 Hours at Sustained 195°F
  • Testing with a Maximum Temperature of 195°F was given a 14 Hour Head Start start on the LOCA to Allow Extra Dissolution/Corrosion Such That the Constant 195°F Test Reaches LOCA Conditions at 10 hours1.157407e-4 days <br />0.00278 hours <br />1.653439e-5 weeks <br />3.805e-6 months <br />
  • Chart Nomenclature

-Red Line, Round Mark: Concentration at Time for Temperature Profile > 195°F

-Black Line, Square Mark: Concentration at Time for Temperature Maintained at 195°F

-Time = 0: Beginning of 24 Hour Constant 195°F

  • 14 Hour Advanced Start on High Temperature Profile

-Final Concentration of Red Line is at 195°F Calvert Cliffs Chemical Effects

- Plans for Integrated Testing 12 High Temperature Portion of LOCA (Continued) Ca, Zn, and Cu Releases Comparable at 195°F WCAP-16530-NP-A Predicts >40,000 ppb Ca Calvert Cliffs Chemical Effects

- Plans for Integrated Testing 13 0 500 1000 1500 2000 2500 3000 3500 4000 4500 0.0 5.0 10.0 15.0 20.0 25.0 30.0 Concentration (ppb) Time (hr)

Calcium Profile 195-Ave 0 2000 4000 6000 8000 0 5 10 15 20 25 30 Concentration (ppb) Time (hr) Zinc Profile195-Ave 0 200 400 600 0 5 10 15 20 25 30 Concentration (ppb) Time (hr)

Copper Profile 195-Ave High Temperature Portion of LOCA (Continued)

  • Al, Si, Mg, & Pb Concentrations Lower at Constant 195°F
  • Al, Mg, and Pb Concentrations are all Low (<1.5 ppm) in Either Temperature Profile
  • WCAP-16530-NP-APredicts >65,000 ppb Al and >170,000 ppb Si, Silent on Mg and Pb Calvert Cliffs Chemical Effects

- Plans for Integrated Testing 14 0 400 800 1200 1600 0 5 10 15 20 25 30 Concentration (ppb) Time (hr) Aluminum Profile 195-Ave 0 5000 10000 15000 20000 25000 0 5 10 15 20 25 30 Concentration (ppb) Time (hr)

Silicon Profile 195-Ave 0 200 400 600 800 0 5 10 15 20 25 30 Concentration (ppb) Time (hr Magnesium Profile 195-Ave 0 400 800 1200 1600 0 5 10 15 20 25 30 Concentration (ppb) Time (hr)

Lead Profile 195-Ave High Temperature Portion of LOCA (Continued) CCNPP Proposes to Add Metal Salts to Solution to Account for Increased Release at High Temp *Candidate Salts:

-Sodium Metasilicate

-Aluminum Nitrate Nonahydrate

-Magnesium Nitrate Hexahydrate

-Lead Nitrate

-Each has High Solubility in Water

-Avoids New Chemistry

  • Nitrates Consistent with Nitric Acid Addition
  • Silicate (from Sodium Metasilicate) Consistent with High Na Concentration (from NaTB)
  • Required Quantities Added to 750 Gallon Fluid Volume (192,000 Tablespoons)

-Aluminum *Required Boost = 0.92 ppm grams Aluminum Nitrate (<1.5 Tablespoons)

-Silicon *Required Boost = 6.11 75.5 grams Sodium Metasilicate (~2.2 Tablespoons)

-Magnesium

  • Required Boost = 0.39 11.7 grams Magnesium Nitrate (~1.2 Teaspoons)

-Lead *Required Boost = 0.83 3.8 grams Lead Nitrate (<0.25 Teaspoon)

Calvert Cliffs Chemical Effects

- Plans for Integrated Testing 15 Autoclave Testing of Metals

- CCNPP-CHLE-006

  • CCNPP Performed >25 Autoclave Tests of Metals
  • Various Combinations
  • Objectives were:

-Investigate Single and Synergistic Corrosion Effects of Differing Metal Combinations

-Determine Which Metals are Appropriate for Integrated CHLE Tests

  • 48 Hour Tests with Insulation & Containment Debris Materials
  • CHLE-006 Tests Used More Severe Temperature Profile than CHLE-005 Tests Which Unexpectedly Resulted in Higher Dissolved Concentrations of Metals
  • Filtration Results Show No Indication of Precipitates Adversely Impacting Filtration Times and Therefore not Affecting Head Loss Calvert Cliffs Chemical Effects

- Plans for Integrated Testing 16 190 210 230 250 270 290 -80 120 320 520 720 Temp (F) Time (min) CHLE-005 CHLE-006 Autoclave Testing of Metals (Continued)

  • Results -The Following Metals Used in Containment Will Be Included in Integrated Tests

-Interactions Observed

-Presence of Zn in Solution With Insulation, Concrete, and Marini te Reduces Release of Al, Mg, and Si

  • High Zn Concentration from Metallic Zn Coupons Used as Surrogate for Inorganic Zinc-Rich Coatings (IOZ )
  • Propose to use IOZ Coated Coupons instead of Metallic Zinc Calvert Cliffs Chemical Effects

- Plans for Integrated Testing 17 Autoclave Testing of Metals (Continued) Presence of Zn in Solution Reduces Release of Al, Mg, & Si Calvert Cliffs Chemical Effects

- Plans for Integrated Testing 18 140 160 180 200 220 240 260 280 0 2000 4000 6000 8000 -100 400 900 1400 1900 2400 2900 Temp (F) Al Concentration (ppb) Time (min) Aluminum With Zn No Zn Temp 140 160 180 200 220 240 260 280 0 10000 20000 30000 40000 50000 60000 -100 400 900 1400 1900 2400 2900 Temp (F) Si Concentration (ppb) Time (min) Silicon With Zn No Zn Temp 140 160 180 200 220 240 260 280 0 1000 2000 3000 4000 5000 -100 400 900 1400 1900 2400 2900 Temp (F) Mg Concentration (ppb) Time (min)

Magnesium With Zn No Zn Temp 351 in 2 Metallic Zn ~33% of 10µm Sphere Surface Area Autoclave Testing of Metals (Continued) Filtration Results

  • 116 Filtration Sample Times
  • Average Filtration Time <20 Seconds
  • <100 Second Filtration Times

-No Indication of Difficult to Filter Precipitates

-Consistent with PWROG Criterion

  • PWROG Filtration Time for NaTB Buffered Borated Water Ranged Between ~10 to ~20 Seconds Calvert Cliffs Chemical Effects

- Plans for Integrated Testing 19 ation Time f o r N a TB B u ffered Borated Water Ran ged Between

~0 20 40 60 80 100 Filtration Time (s) Test Number - Description 8 hr 24 hr 32 hr 48 hr Autoclave Tests of Concrete and Insulation - CCNPP-CHLE-010

  • The Following Autoclave Tests Were Run
  • Insulation and Concrete
  • Insulation Only
  • Concrete Only
  • Results *Al, Ca, Mg, and Si Released from Both
  • Tests Very Repeatable
  • No Synergies Observed
  • Plant-Specific Concrete to be Used in Integrated Tests Calvert Cliffs Chemical Effects

- Plans for Integrated Testing 20 CCNPP-CHLE-011 Long-Term Integrated Simulation

  • Four Autoclave Tests

-Simulated Integrated Tests

-All Materials Included

  • Insulation, Metals, Concrete, etc. *Filtration Times

-No Indication of Difficult to Filter Precipitates

-PWROG Filtration Time for NaTB Buffered Borated Water Ranged Between ~10 to ~20 Seconds Calvert Cliffs Chemical Effects

- Plans for Integrated Testing 21 0 10 20 30 40 50 60 Filtration Time (s) Sample Description Sample Filtration Times from 10-Day Integrated Test Simulations 501 502 503 504 PWROG Filtration Data

- 24 Hour Autoclave Tests

  • Same Data Provided to NRC by PWROG on April 16, 2014 *Slide 15 Of The Chemical Effects Autoclave Testing Presentation
  • The Difference Is That The Plot Has Filtration Time Plotted On A Log Scale
  • Calvert Cliffs is Test Number 03-01 Calvert Cliffs Chemical Effects

- Plans for Integrated Testing 22 Autoclave Test Filtration Times CCNPP Filtration Times from 6 Integrated Simulations

  • PWROG Filtration Criteria

->100 Second

- Indication of Potential for Some Chemical Effects

-Filtration Testing of Borated Demineralized Water Buffered with NaTB

  • Low Filtration Time = 8.4 Seconds
  • High Filtration Time = 17.3 Seconds Calvert Cliffs Chemical Effects

- Plans for Integrated Testing 23 0 10 20 30 40 50 60 70 80 90 100 8 32 56 80 104 128 152 176 200 224 Filtration Time (s) Sample Time (hr) Filtration Times PWROG Indication of Some Chemical Effects PWROG Borated/NaTB High Filtration Times CCNPP Average Time from 6 Integrated Simulations PWROG Borated/NaTB Low Filtration Times Integrated Chemical Effects Head Loss Experiment (CHLE)

  • Use CCNPP-Specific Chemistry Conditions
  • Use CCNPP-Specific Materials
  • Materials Scaled Appropriately by Volume or Surface Area
  • Autoclave Test Results Influenced Design of Experimental Protocols
  • Simulate Bounding Sump Temperature Profile
  • Circulate Solution Through Detector Debris Bed
  • Stepwise Temperature Reduction at End of Experiments Calvert Cliffs Chemical Effects

- Plans for Integrated Testing 24 Integrated CHLE Test Plans

- Test Facility Schematic Calvert Cliffs Chemical Effects

- Plans for Integrated Testing 25 Vertical Head Loss Column Loop Heating

& Cooling Heat Exchanger Loop Recirculatio n Loop Integrated CHLE Test Facility - Photos Calvert Cliffs Chemical Effects

- Plans for Integrated Testing 26 Initial Prep Tank Primary Reaction Chamber Vertical Head Loss Loop Heat Exchanger Loop Integrated CHLE Test Plans

- Reaction Chamber Layout Calvert Cliffs Chemical Effects

- Plans for Integrated Testing 27 Submerged Coupons in Center Below Recirculation System to Assure Flow Across Coupons and Tank Mixing Integrated CHLE Test Plans

- Reaction Chamber CFD

  • Pump Recirculation to Assure Flow Across Coupons and Tank Mixing Calvert Cliffs Chemical Effects

- Plans for Integrated Testing 28 *CFD Simulation Integrated CHLE Test Plans

- Reaction Chamber CFD CFD Shows Mixing and Dissolution of Buffer Calvert Cliffs Chemical Effects

- Plans for Integrated Testing 29 Buffer Basket Integrated CHLE Test Facility

- Long-Term Operation Calvert Cliffs Chemical Effects

- Plans for Integrated Testing 30 Integrated CHLE Test Plans

  • Plant-Specific Chemistry

-Use Best Estimate (BE) Concentrations

  • Sump Boron Concentration -Bounding Range: 2575

- 2897 ppm -Best Estimate (BE): 2740 ppm (PD)

  • Sump Lithium Concentration -Bounding Range: 0.036

-0.974 ppm -BE: 0.50 ppm (Average)

  • NaTB Buffer Concentration -16,500 lbm NaTB Installed -BE Water Mass for LBLOCA: 4,099,799 lbm -BE Water Volume @195°F: 509,998 gallons -Test Water Volume @195°F: 750 gallons -NaTB: 24.26 lbm
  • Strong Acids -HNO 3 & HCl Added at Rate Produced -30 Day Total Added Before Stepwise Cooldown -Assures Higher pH for Release and Lower pH for Potential Precipitation Calvert Cliffs Chemical Effects

- Plans for Integrated Testing 31 *Plant-Specific Materials -Mineral Wool Insulation

-Nukon *Equivalent for

  • Nukon *Thermal Wrap
  • Generic Fiberglass
  • Temp-Mat -Lead Shielding Blankets
  • Materials Provided by Lancs Industries -Marinite Board Fire Barrier
  • Materials from CCNPP Warehouse -Concrete
  • Materials from CCNPP Demolition -Galvanized Steel & Copper
  • Materials Conforming to Same ASTM Stds -Coatings*Inorganic Zinc Coated Coupons
  • Epoxy Coating Excluded

Integrated CHLE Test Plans (Continued)

  • Temperature Conditions
  • Duration Determined Based on Results of CCNPP-CHLE-011 Autoclave Test Calvert Cliffs Chemical Effects

- Plans for Integrated Testing 32 *Final Step-Wise Temperature Reduction

  • Duration of Plateaus Based on Time for Detection in Debris Bed 50 60 70 80 90 100 110 120 130 140 150 240 245 250 255 260 265 270 Temperature (F) Time (Hr) Test Temperature 60 80 100 120 140 160 180 200 220 240 260 280 -14 34 82 130 178 226 Temperature (F) Time (hr) AOR Sump Temperature Test Temperature Integrated CHLE Test Status

- Detector Debris Bed Calvert Cliffs Chemical Effects

- Plans for Integrated Testing 33 *Building Bed at 6 gpm

  • Reduce Flow to 1 gpm for Testing

-CCNPP Prototypical Approach Velocity

  • Verify Sensitivity with WCAP-16530-NP-A Surrogate ReduceFlowAddBuffer Add 1 ppm Al as AlOOH 0 1 2 3 4 5 6 7 8 9 10 0 1 2 3 4 5 0 2 4 6 8 10 p [ft water]

Time after debris addition [h] Diff Press Notes Flow Integrated CHLE Test Plans (Continued) Modeling of Marinite

  • Marinite Fines Debris Historically Treated as 10 µm Spheres for Hydraulic Characteristics
  • Modeling as such in Chemical Effects Testing Results in Non-Prototypical Surface Area of Solid Marinite
  • Calvert Cliffs Proposed Approach -Marinite Fine Debris Tested using 1/2 Thick Marinite Board with 50% of the Surface Area as 44 µm Spheres Based on Surface Roughness

-Marinite non-Fines Tested using 1/2 Thick Marinite Board with Postulated Surface Area Submerged or Sprayed Calvert Cliffs Chemical Effects

- Plans for Integrated Testing 34 Modeling of Zinc-Rich Coatings

  • Failed Inorganic Zinc Coatings (IOZ) Historically Treated as 10 µm Spheres for Hydraulic Characteristics
  • Modeling as such in Chemical Effects Testing Results in Non-Prototypical Surface Area of Metallic Zinc
  • Calvert Cliffs Proposed Approach

-IOZ in Zone of Influence and Degraded Qualified IOZ Tested Using Cured/Aged IOZ Coated Coupons with 2x Surface Area of Destroyed or Degraded Coatings

-Organic Zinc-Rich Coatings Tested Using Cured Coupons Coated With Same Coating Small-Scale Penetration Test Plan

  • Sensitivity Tests

-Water Chemistry

  • Tap Water
  • Borated Buffered DI Water
  • Buffer Type
  • Boron Concentration
  • Buffer Concentration

-Water Temperature

  • Controlled Room Temp
  • Elevated (180°F)

-Fiber Mixture

  • Nukon *Nukon, Temp-Mat, Min Wool, Cocktail

-Approach Velocity

  • Prototypical Strainer

-Fabricated from Similar Perforated Plate

  • Continuous Filtration
  • Performing Jointly with Arkansas Nuclear One -3 Different Pocket Geometries
  • 400 mm Deep (ANO)
  • 200 mm Deep (ANO & CCNPP)
  • 100 mm Deep (ANO)

Calvert Cliffs Chemical Effects

- Plans for Integrated Testing 35 Future Meetings

  • June 2014

-Chemical Effects Autoclave Test Results

  • CCNPP-CHLE-007 Alkyds Test
  • CCNPP-CHLE-011 Long Term Test

-Final Chemical Effects Screening Test Protocol

  • Ready to Launch CCNPP-CHLE-002 Integrated CHLE Tests

-Small-Scale Penetration Test Results

  • Ready to Launch Large-Scale Penetration Tests Calvert Cliffs Chemical Effects

- Plans for Integrated Testing 36