03 dry cask simulator experiments for cfd validation durbin sand2017 4330 c
- 1. Sandia National Laboratories is a multi-program laboratory managed and operated by Sandia Corporation, a wholly owned subsidiary of Lockheed Martin Corporation, for the U.S. Department of Energy’s National Nuclear Security Administration under contract DE-AC04-94AL85000. Dry Cask Simulator Experiments for CFD Validation Sam Durbin, Eric Lindgren, Abdelghani Zigh*, and Jorge Solis* * Nuclear Regulatory Commission SAND2017-4330 C
- 2. Overview Purpose: Validate assumptions in CFD calculations for spent fuel cask thermal design analyses Used to determine steady-state cladding temperatures in dry casks Needed to evaluate cladding integrity throughout storage cycle Measure temperature profiles for a wide range of decay power and helium cask pressures Mimic conditions for above and belowground configurations of vertical, dry cask systems with canisters Simplified geometry with well-controlled boundary conditions Provide measure of mass flow rates and convection heat transfer coefficients Use existing prototypic BWR Incoloy-clad test assembly 2 Underground Storage Source: ww.holtecinternational.com/productsandservices/ wasteandfuelmanagement/hi-storm/ Aboveground Storage Source: www.nrc.gov/reading-rm/doc- collections/fact-sheets/storage-spent-fuel-fs.html (m) (m) Temp. (K)
- 3. Project Structure Boiling Water Reactor Dry Cask Simulator (DCS) Partnership between USNRC and DOE Equal cost sharing NRC staff leads technical review Mutual benefits Thermal-hydraulic data for validation exercises Complimentary data for High-Burnup Cask Demonstration Project Includes thermal lance comparisons to peak cladding temperature (PCT) 3
- 4. Past Validation Efforts Full Scale Full scale, unconsolidated Castor-V/21 cast iron/graphite with polyethylene rod shielding 1986: EPRI NP-4887, PNL-5917 21 PWRs 95 Thermocouples (TC’s) total Unventilated Sub-atmospheric (air and He) and vacuum REA 2023 prototype steel-lead-steel cask with glycol water shield 1986: PNL-5777 Vol. 1 52 BWRs 70 TC’s total Unventilated Sub-atmospheric (air & He) and vacuum Full scale, consolidated VSC-17 ventilated concrete cask 1992: EPRI TR-100305, PNL-7839 17 consolidated PWRs 98 Thermocouples (TC’s) total Ventilated Sub-atmospheric (air and He) and vacuum 4
- 5. Past Validation Efforts (cont.) Unconsolidated Fuel 5 Small scale, single assembly FTT (irradiated, vertical) and SAHTT (electric, vertical & horizontal) 1986 PNL-5571 Single 15x15 PWR Thermocouples (TC’s) – FTT: 187 TC’s total – SAHTT: 98 TC’s total BC: Controlled cask outer wall temperature Atmospheric (air & He) and vacuum Mitsubishi test assembly (electric, vertical & horizontal) 1986 IAEA-SM-286/139P Single 15x15 PWR 92 TC’s total, all distributed over 4 levels inside tube bundle BC: Controlled outer wall temperature of fuel tube Atmospheric (air & He) and vacuum Not appropriate for elevated helium pressures or belowground configurations
- 6. Current Approach Focus on pressurized canister systems DCS capable of 24 bar internal pressure @ 400 ◦C Current commercial designs up to ~8 bar Ventilated designs Aboveground configuration (This presentation) Belowground configuration With crosswind conditions Thermocouple (TC) attachment allows better peak cladding temperature measurement 0.030” diameter sheath Tip in direct contact with cladding Provide validation quality data for CFD Complimentary to High-Burnup Cask Demo. Project 6
- 7. DCS Pressure Vessel Hardware Scaled components with instrumentation well Coated with ultra high temperature paint 7
- 8. Prototypic Assembly Hardware Most common 99 BWR in US Prototypic 99 BWR hardware Full length, prototypic 99 BWR components Electric heater rods with Incoloy cladding 74 fuel rods 8 of these are partial length Partial length rods 2/3 the length of assembly 2 water rods 7 spacers 8 Nose piece and debris catcher BWR channel, water tubes and spacers Upper tie plate
- 9. Thermocouple Layout 97 total TC’s internal to assembly 10 TC’s mounted to channel box 7 External wall 24 in. spacing starting at 24 in. level 3 Internal wall 96, 119, and 144 in. levels 9 Radial Array 24” spacing 11 TC’s each level 66 TC’s total (details below) Axial array A1 6” spacing 20 TCs Axial array A2 12” spacing – 7 TC’s Water rods inlet and exit – 4 TC’s Total of 97 TCs 24” 48” 72” 96” 119” 144” Internal Thermocouples a b c d e f g h i Q R S T U V X Y Z 24” & 96” levels 48” & 119” levels 72” & 144” levels a b c d e f g h i Q R S T U V X Y Z a b c d e f g h i Q R S T U V X Y Z
- 10. CYBL Test Facility Large stainless steel containment Repurposed from earlier CYLINDRICAL BOILING Testing sponsored by DOE Excellent general-use engineered barrier for isolation of high-energy tests 3/8 in. stainless steel 17 ft diam. by 28 ft cylindrical workspace Part of the Nuclear Energy Work Complex (NEWC) 10
- 11. Aboveground Configuration 11 Pressure Boundary BWR Dry Cask Simulator (DCS) system capabilities Power: 0.1 – 15 kW Pressure vessel: 3E-3 – 24 bar Vessel temperatures up to 400 C ~200 thermocouples throughout system Test conditions presented here Power: 0.5 – 5 kW Pressure: 3E-3 – 8 bar Air velocity measurements at inlets Calculate external mass flow rate
- 12. Internal Dimensional Analyses Internal flow and convection near prototypic Prototypic geometry for fuel and basket Downcomer scaling insensitive to wide range of decay heats External cooling flows matched using elevated decay heat Downcomer dimensionless groups 12 Parameter Aboveground DCS Low Power DCS High Power Cask Power (kW) 0.5 5.0 36.9 ReDown 170 190 250 RaH * 3.1E+11 5.9E+11 4.6E+11 NuH 200 230 200 Downcomer “Canister”Channel Box “Basket”
- 13. External Dimensional Analyses 13 External cooling flow path Parameter Aboveground DCS Low Power DCS High Power Cask Power (kW) 0.5 5.0 36.9 ReEx 3,700 7,100 5,700 RaDH * 2.7E+08 2.7E+09 2.3E+08 (DH, Cooling / HPV) × RaDH * 1.1E+07 1.1E+08 4.8E+06 NuDH 16 26 14 External cooling flows evaluated against prototypic External dimensionless groups 1 in.1 cm
- 14. Steady State Values vs. Decay Heat 14 PCT and air flow as simulated decay heat Significant increase in PCT for P = 3E-3 bar Due to air in “canister” instead of helium
- 15. Transient Data 15 Power = 2.5 kW Internal pressure = 1.0 bar Steady state values PCT = 570 K Q = 673 slpm
- 16. CFD Modeling 16 Computational fluid dynamics modeling ANSYS Fluent 16.1 Discrete Ordinates (DO) for radiation heat transfer Semi-Implicit Method for Pressure-Linked Equations (SIMPLE) Link for momentum and continuity equations 3-D mesh with symmetric mid-plane Fuel represented as porous media Internal laminar flow External Low-Re k-ε Modeling performed consistent with best practices and best available data representing fuel properties NUREG-2152, “CFD Best Practice Guidelines for Dry Cask Applications” NUREG-2208, “Validation of CFD Methods Using Prototypic Light Water Reactor Spent Fuel Assembly Thermal-Hydraulic Data”
- 17. Steady State Comparisons 17 Press. (bar) Quantity Power (kW) 0.5 1 2.5 5 Test CFD Diff. Error (%) Test CFD Diff. Error (%) Test CFD Diff. Error (%) Test CFD Diff. Error (%) 1.0 PCT (K) 376 378 2 0.5 434 438 4 0.9 570 569 -1 -0.2 715 717 2 0.3 Q (slpm) 335 326 -9 -2.7 448 449 1 0.2 673 669 -4 -0.6 874 877 3 0.3 4.5 PCT (K) 367 368 1 0.3 426 423 -3 -0.7 545 549 4 0.7 689 698 9 1.3 Q (slpm) 306 293 -13 -4.2 415 396 -19 -4.6 603 601 -2 -0.3 830 826 -4 -0.5 8.0 PCT (K) 359 362 3 0.8 410 408 -2 -0.5 521 523 2 0.4 659 663 4 0.6 Q (slpm) 280 277 -3 -1.1 392 387 -5 -1.3 593 579 -14 -2.4 793 773 -20 -2.5 Agreement within experimental uncertainty for majority of results Only one instance of difference beyond estimated uncertainty Further analysis shown next
- 18. Graphical Steady State Comparisons 18 PCT average difference of 2 K across all conditions 95% exp. uncertainty +/- 1% reading in Kelvin (UPCT, max = 7 K) Max. observed difference = 9 K (5 kW and 4.5 bar) Air flow rate average difference of -8 slpm for all conditions 95% exp. uncertainty of UQ = 35 slpm Max. observed difference = -20 slpm (5 kW and 8.0 bar)
- 19. Summary 19 Dry cask simulator (DCS) testing complete for aboveground configuration 12 data sets available for pressurized canister conditions 3 data sets available for sub-atmospheric Comparisons with CFD simulations show favorable agreement Within experimental uncertainty for nearly all cases Additional steady state comparisons for basket, “canister”, and “overpack” also show good agreement
- 20. EXTRA SLIDES 20
- 21. Custom TC Lance 21 Compliments the TC lance in the Cask Demo Project Same fabricator (AREVA) “Same” materials and fabrication process – Closure method for SNL TC lance significantly different – Sealed using brazing method with water-based flux TC elevations match BWR assembly TCs Provides direct comparison between lance TCs and clad TCs TC Lance
- 22. Thermocouple (TC) Lance Anomalies “Glitches” observed in SNL TC lance Sharp changes in dT/dt Coincidentally occurring near ~100 oC? Generally recovered by end of Steady State Discussions with vendor revealed unique closure for SNL TC lance Hypothesis developed that TC chamber contaminated with water Closure formed by brazing with water-based flux 22
- 23. Proposed Solution: Vent TC Lance 23 Pierce lance collar below brazed seal Introduce vent path for any trapped water Breach created using rotary tool with grinding wheel Performed May 2nd, 2017
- 24. Well? Test conditions repeated for 2500 W, 1 bar He Significant difference in response Success? Supports water contamination hypothesis Good news for Cask Demo 24
- 25. Belowground Configuration Modification to aboveground ventilation configuration Additional annular flow path Currently testing Inlet and outlet based on prototypic configuration Scaling analysis completed Favorable comparisons Modified, channel Rayleigh number (Ra*) Reynolds (Re) number 25
- 29. Effect of Wind Speed on External Air Flow 29