TY - CONF
T1 - Validation of NEK5000 for 37- And 61-pin wire-wrap geometries with conjugate heat transfer
AU - Obabko, Aleksandr
AU - Merzari, Elia
AU - Brockmeyer, Landon
AU - Fischer, Paul
AU - Sofu, Tanju
AU - Jackson, Brian
AU - Steer, Michael
AU - Vaghetto, Rodolfo
AU - Hassan, Yassin A.
N1 - Funding Information:
Originally funded by NIC∗ Cost-Share Award, this project was a joint venture with AREVA, TerraPower, and TAMU that was aimed at design and completion of well-defined first-of-a-kind validation campaign for the TH CFD modeling of hexagonal packed fuel assemblies with helically wire-wrapped pin geometries typical of SFRs. The FOA benchmark of 61-pin wire-wrap cases specified by TerraPower aimed at addressing the recent renewal of interest of several private companies with a particular focus on longer-life cores. The prediction of thermal performance in fuel assemblies is vital for evaluating overall reactor performance and safety, and it is particularly important as the assembly ages. In fact, the effect of pin and duct deformation driven by thermal expansion and radiation damage is increasingly important as reactor designs look to longer assembly lifetimes. The results of isothermal and conjugate heat transfer cases presented here is the first step toward this goal. Also some of the isothermal results were shared with our Euratom colleagues in European Horizon 2020’s SESAME INERI collaborators from NRG, SCK-CEN, UGent, and ENEA.
Funding Information:
This research used resources of the Argonne Leadership Computing Facility (ALCF), which is a DOE Office of Science User Facility supported under Contract DE-AC02-06CH11357, under mostly Argonne Leadership Computation Challenge (ALCC) allocations.
Funding Information:
Argonne National Laboratory’s work was mostly supported by the U. S. Department of Energy, Office of Nuclear Energy under contract No. DE-AC02-06CH11357.
Funding Information:
This research used resources of the Argonne Leadership Computing Facility (ALCF), which is a DOE Office of Science User Facility supported under Contract DE-AC02-06CH11357, under mostly Argonne Leadership Computation Challenge (ALCC) allocations. Argonne National Laboratory?s work was mostly supported by the U. S. Department of Energy, Office of Nuclear Energy under contract No. DE-AC02-06CH11357.
Funding Information:
Here we report Nek5000 LES validation simulations for 37-pin and 61-pin wire-wrap conjugate heat transfer geometries. As a part NEAMS TH component of the SHARP multi-physics toolkit V&V-driven development, we have conducted a series of isothermal single wire-wrap pitch and multi pitch conjugate heat transfer calculations scaled up to 1 million MPI ranks with Reynolds number up to 120,000. The 37-pin 4-wire-wrap PLANDTL sodium experiment LES campaign was conducted as a part of the advanced M&S activity of CNWG under the U.S.-Japan Bilateral Commission Civil Nuclear Cooperation on advanced reactor R&D between DOE and JAEA. Originally funded by Nuclear Infrastructure Council (NIC) Cost-Share Award, the 61-pin FOA project was a joint venture with TerraPower, Texas A&M University, AREVA, and Argonne National Laboratory, a well-defined first-of-a-kind validation campaign for the CFD TH modeling of hexagonal packed fuel assemblies with helically wire-wrapped pin SFR geometries for both conjugate heat transfer and high-resolution isothermal validation.
Publisher Copyright:
© 2019 American Nuclear Society. All rights reserved.
PY - 2019
Y1 - 2019
N2 - The turbulent mixing modeling for unsteady heat transfer problems in thermal-hydraulics has long been a focus in nuclear engineering community. One of the promising approaches that takes a full advantage of recent advances in HPC is the use of hierarchy of fidelity simulations that are cross-verified and validated in the regimes of interest. In particular, it is beneficial to have a higher fidelity reference simulation that could be used for benchmarking of the faster-turn-around lower-fidelity tools. Another good use of (validated) high-fidelity models that are less dependent on parameter and geometry perturbations than their lower-fidelity counterparts is to provide closure relations for reduced-order and -fidelity approaches where experiment data is either incomplete or not yet available. Here we report Nek5000 LES validation simulations for 37-pin and 61-pin wire-wrap conjugate heat transfer geometries. As a part NEAMS TH component of the SHARP multi-physics toolkit V&V-driven development, we have conducted a series of isothermal single wire-wrap pitch and multi pitch conjugate heat transfer calculations scaled up to 1 million MPI ranks with Reynolds number up to 120,000. The 37-pin 4-wire-wrap PLANDTL sodium experiment LES campaign was conducted as a part of the advanced M&S activity of CNWG under the U.S.-Japan Bilateral Commission Civil Nuclear Cooperation on advanced reactor R&D between DOE and JAEA. Originally funded by Nuclear Infrastructure Council (NIC) Cost-Share Award, the 61-pin FOA project was a joint venture with TerraPower, Texas A&M University, AREVA, and Argonne National Laboratory, a well-defined first-of-a-kind validation campaign for the CFD TH modeling of hexagonal packed fuel assemblies with helically wire-wrapped pin SFR geometries for both conjugate heat transfer and high-resolution isothermal validation.
AB - The turbulent mixing modeling for unsteady heat transfer problems in thermal-hydraulics has long been a focus in nuclear engineering community. One of the promising approaches that takes a full advantage of recent advances in HPC is the use of hierarchy of fidelity simulations that are cross-verified and validated in the regimes of interest. In particular, it is beneficial to have a higher fidelity reference simulation that could be used for benchmarking of the faster-turn-around lower-fidelity tools. Another good use of (validated) high-fidelity models that are less dependent on parameter and geometry perturbations than their lower-fidelity counterparts is to provide closure relations for reduced-order and -fidelity approaches where experiment data is either incomplete or not yet available. Here we report Nek5000 LES validation simulations for 37-pin and 61-pin wire-wrap conjugate heat transfer geometries. As a part NEAMS TH component of the SHARP multi-physics toolkit V&V-driven development, we have conducted a series of isothermal single wire-wrap pitch and multi pitch conjugate heat transfer calculations scaled up to 1 million MPI ranks with Reynolds number up to 120,000. The 37-pin 4-wire-wrap PLANDTL sodium experiment LES campaign was conducted as a part of the advanced M&S activity of CNWG under the U.S.-Japan Bilateral Commission Civil Nuclear Cooperation on advanced reactor R&D between DOE and JAEA. Originally funded by Nuclear Infrastructure Council (NIC) Cost-Share Award, the 61-pin FOA project was a joint venture with TerraPower, Texas A&M University, AREVA, and Argonne National Laboratory, a well-defined first-of-a-kind validation campaign for the CFD TH modeling of hexagonal packed fuel assemblies with helically wire-wrapped pin SFR geometries for both conjugate heat transfer and high-resolution isothermal validation.
KW - 61 pin
KW - Conjugate heat transfer 37 pin
KW - Large-eddy simulation
KW - V&V
KW - Wire-wrap
UR - http://www.scopus.com/inward/record.url?scp=85073721250&partnerID=8YFLogxK
UR - http://www.scopus.com/inward/citedby.url?scp=85073721250&partnerID=8YFLogxK
M3 - Paper
AN - SCOPUS:85073721250
SP - 2036
EP - 2049
T2 - 18th International Topical Meeting on Nuclear Reactor Thermal Hydraulics, NURETH 2019
Y2 - 18 August 2019 through 23 August 2019
ER -