Evaluation of critical experiments in the university of Wisconsin nuclear reactor (UWNR) with uncertainty quantification

Young Hui Park; Ye Cheng; Rabab Elzohery; Paul P.H. Wilson; Jeremy A. Roberts; Mark D. DeHart

doi:10.1051/epjconf/202124710032

Evaluation of critical experiments in the university of Wisconsin nuclear reactor (UWNR) with uncertainty quantification

Young Hui Park, Ye Cheng, Rabab Elzohery, Paul P.H. Wilson, Jeremy A. Roberts, Mark D. DeHart

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

An improved computational model of the University of Wisconsin Nuclear Reactor (UWNR) was developed to support the benchmark evaluation of recent data acquired during an experimental campaign conducted at UWNR. Previous efforts led to a scripted UWNR model for automated generation of MCNP6 and Serpent inputs. This capability was extended to SCALE/KENO. All three tools were used to evaluate a variety of zero-power, fresh-critical configurations, and the results agreed well. The MCNP6 model was extended to support shuffling the core configuration, which allows the modeling of burnup for evaluation of depleted critical configurations. The MCNP6 model successfully predicts core reactivity over time, after accounting for the initial reactivity bias. The inclusion of SCALE/KENO input generation enables sensitivity and uncertainty analyses using the TSUNAMI and Sampler modules of SCALE. A preliminary uncertainty analysis was performed with TSUNAMI for nuclear data uncertainties while direct perturbation calculations were performed using MCNP6 for geometry and material uncertainties, which helped to identify model parameters with the largest effect on the eigenvalue. A transient UWNR transport Model in Mammoth/Rattlesnake is under development to simulate the transient experiments. The existing MCNP6 and Serpent models are used to provide the CAD file for meshing and homogenized cross-sections. In conclusion, the evaluation of UWNR benchmark data provides increased confidence in various states of the UWNR computational model and will provide a unique model for use by other analysts.

Original language	English
Title of host publication	International Conference on Physics of Reactors
Subtitle of host publication	Transition to a Scalable Nuclear Future, PHYSOR 2020
Editors	Marat Margulis, Partrick Blaise
Publisher	EDP Sciences - Web of Conferences
Pages	2214-2223
Number of pages	10
ISBN (Electronic)	9781713827245
DOIs	https://doi.org/10.1051/epjconf/202124710032
State	Published - 2020
Externally published	Yes
Event	2020 International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020 - Cambridge, United Kingdom Duration: Mar 28 2020 → Apr 2 2020

Publication series

Name	International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020
Volume	2020-March

Conference

Conference	2020 International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020
Country/Territory	United Kingdom
City	Cambridge
Period	03/28/20 → 04/2/20

Funding

This material is based upon work supported by the DOE Office of Nuclear Energy's Nuclear Energy University Program under Award Numbers DE-NE0008408 and DE-NE0008750. This research was performed using the compute resources and assistance of the UW-Madison Center For High Throughput Computing (CHTC) in the Department of Computer Sciences. The CHTC is supported by UW-Madison, the Advanced Computing Initiative, the Wisconsin Alumni Research Foundation, the Wisconsin Institutes for Discovery, and the National Science Foundation, and is an active member of the Open Science Grid, which is supported by the National Science Foundation and the U.S. Department of Energy's Office of Science. In addition, some of the computing for this project was performed on the Beocat Research Cluster at K-State, which is funded in part by NSF grants CNS-1006860, EPS-1006860, EPS-0919443, ACI-1440548, CHE-1726332, and NIH P20GM113109. This material is based upon work supported by the DOE Office of Nuclear Energy’s Nuclear Energy University Program under Award Numbers DE-NE0008408 and DE-NE0008750. This research was performed using the compute resources and assistance of the UW-Madison Center For High Throughput Computing (CHTC) in the Department of Computer Sciences. The CHTC is supported by UW-Madison, the Advanced Computing Initiative, the Wisconsin Alumni Research Foundation, the Wisconsin Institutes for Discovery, and the National Science Foundation, and is an active member of the Open Science Grid, which is supported by the National Science Foundation and the U.S. Department of Energy’s Office of Science. In addition, some of the computing for this project was performed on the Beocat Research Cluster at K-State, which is funded in part by NSF grants CNS-1006860, EPS-1006860, EPS-0919443, ACI-1440548, CHE-1726332, and NIH P20GM113109.

Keywords

Benchmark
Critical configuration
Reaction rate measurement
Transient experiment
Uncertainty quantification

Access to Document

10.1051/epjconf/202124710032

Cite this

Park, Y. H., Cheng, Y., Elzohery, R., Wilson, P. P. H., Roberts, J. A., & DeHart, M. D. (2020). Evaluation of critical experiments in the university of Wisconsin nuclear reactor (UWNR) with uncertainty quantification. In M. Margulis, & P. Blaise (Eds.), International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020 (pp. 2214-2223). (International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020; Vol. 2020-March). EDP Sciences - Web of Conferences. https://doi.org/10.1051/epjconf/202124710032

Park, Young Hui ; Cheng, Ye ; Elzohery, Rabab et al. / Evaluation of critical experiments in the university of Wisconsin nuclear reactor (UWNR) with uncertainty quantification. International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020. editor / Marat Margulis ; Partrick Blaise. EDP Sciences - Web of Conferences, 2020. pp. 2214-2223 (International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020).

@inproceedings{cbc911eefd6748bbb66df605ef77d117,

title = "Evaluation of critical experiments in the university of Wisconsin nuclear reactor (UWNR) with uncertainty quantification",

abstract = "An improved computational model of the University of Wisconsin Nuclear Reactor (UWNR) was developed to support the benchmark evaluation of recent data acquired during an experimental campaign conducted at UWNR. Previous efforts led to a scripted UWNR model for automated generation of MCNP6 and Serpent inputs. This capability was extended to SCALE/KENO. All three tools were used to evaluate a variety of zero-power, fresh-critical configurations, and the results agreed well. The MCNP6 model was extended to support shuffling the core configuration, which allows the modeling of burnup for evaluation of depleted critical configurations. The MCNP6 model successfully predicts core reactivity over time, after accounting for the initial reactivity bias. The inclusion of SCALE/KENO input generation enables sensitivity and uncertainty analyses using the TSUNAMI and Sampler modules of SCALE. A preliminary uncertainty analysis was performed with TSUNAMI for nuclear data uncertainties while direct perturbation calculations were performed using MCNP6 for geometry and material uncertainties, which helped to identify model parameters with the largest effect on the eigenvalue. A transient UWNR transport Model in Mammoth/Rattlesnake is under development to simulate the transient experiments. The existing MCNP6 and Serpent models are used to provide the CAD file for meshing and homogenized cross-sections. In conclusion, the evaluation of UWNR benchmark data provides increased confidence in various states of the UWNR computational model and will provide a unique model for use by other analysts.",

keywords = "Benchmark, Critical configuration, Reaction rate measurement, Transient experiment, Uncertainty quantification",

author = "Park, \{Young Hui\} and Ye Cheng and Rabab Elzohery and Wilson, \{Paul P.H.\} and Roberts, \{Jeremy A.\} and DeHart, \{Mark D.\}",

note = "Publisher Copyright: {\textcopyright} The Authors, published by EDP Sciences. This is an open access article distributed under the terms of the Creative Commons Attribution License 4.0 (http://creativecommons.org/licenses/by/4.0/).; 2020 International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020 ; Conference date: 28-03-2020 Through 02-04-2020",

year = "2020",

doi = "10.1051/epjconf/202124710032",

language = "English",

series = "International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020",

publisher = "EDP Sciences - Web of Conferences",

pages = "2214--2223",

editor = "Marat Margulis and Partrick Blaise",

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}

Park, YH, Cheng, Y, Elzohery, R, Wilson, PPH, Roberts, JA & DeHart, MD 2020, Evaluation of critical experiments in the university of Wisconsin nuclear reactor (UWNR) with uncertainty quantification. in M Margulis & P Blaise (eds), International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020. International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020, vol. 2020-March, EDP Sciences - Web of Conferences, pp. 2214-2223, 2020 International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020, Cambridge, United Kingdom, 03/28/20. https://doi.org/10.1051/epjconf/202124710032

Evaluation of critical experiments in the university of Wisconsin nuclear reactor (UWNR) with uncertainty quantification. / Park, Young Hui; Cheng, Ye; Elzohery, Rabab et al.
International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020. ed. / Marat Margulis; Partrick Blaise. EDP Sciences - Web of Conferences, 2020. p. 2214-2223 (International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020; Vol. 2020-March).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

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AU - Wilson, Paul P.H.

AU - Roberts, Jeremy A.

AU - DeHart, Mark D.

N1 - Publisher Copyright: © The Authors, published by EDP Sciences. This is an open access article distributed under the terms of the Creative Commons Attribution License 4.0 (http://creativecommons.org/licenses/by/4.0/).

PY - 2020

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N2 - An improved computational model of the University of Wisconsin Nuclear Reactor (UWNR) was developed to support the benchmark evaluation of recent data acquired during an experimental campaign conducted at UWNR. Previous efforts led to a scripted UWNR model for automated generation of MCNP6 and Serpent inputs. This capability was extended to SCALE/KENO. All three tools were used to evaluate a variety of zero-power, fresh-critical configurations, and the results agreed well. The MCNP6 model was extended to support shuffling the core configuration, which allows the modeling of burnup for evaluation of depleted critical configurations. The MCNP6 model successfully predicts core reactivity over time, after accounting for the initial reactivity bias. The inclusion of SCALE/KENO input generation enables sensitivity and uncertainty analyses using the TSUNAMI and Sampler modules of SCALE. A preliminary uncertainty analysis was performed with TSUNAMI for nuclear data uncertainties while direct perturbation calculations were performed using MCNP6 for geometry and material uncertainties, which helped to identify model parameters with the largest effect on the eigenvalue. A transient UWNR transport Model in Mammoth/Rattlesnake is under development to simulate the transient experiments. The existing MCNP6 and Serpent models are used to provide the CAD file for meshing and homogenized cross-sections. In conclusion, the evaluation of UWNR benchmark data provides increased confidence in various states of the UWNR computational model and will provide a unique model for use by other analysts.

AB - An improved computational model of the University of Wisconsin Nuclear Reactor (UWNR) was developed to support the benchmark evaluation of recent data acquired during an experimental campaign conducted at UWNR. Previous efforts led to a scripted UWNR model for automated generation of MCNP6 and Serpent inputs. This capability was extended to SCALE/KENO. All three tools were used to evaluate a variety of zero-power, fresh-critical configurations, and the results agreed well. The MCNP6 model was extended to support shuffling the core configuration, which allows the modeling of burnup for evaluation of depleted critical configurations. The MCNP6 model successfully predicts core reactivity over time, after accounting for the initial reactivity bias. The inclusion of SCALE/KENO input generation enables sensitivity and uncertainty analyses using the TSUNAMI and Sampler modules of SCALE. A preliminary uncertainty analysis was performed with TSUNAMI for nuclear data uncertainties while direct perturbation calculations were performed using MCNP6 for geometry and material uncertainties, which helped to identify model parameters with the largest effect on the eigenvalue. A transient UWNR transport Model in Mammoth/Rattlesnake is under development to simulate the transient experiments. The existing MCNP6 and Serpent models are used to provide the CAD file for meshing and homogenized cross-sections. In conclusion, the evaluation of UWNR benchmark data provides increased confidence in various states of the UWNR computational model and will provide a unique model for use by other analysts.

KW - Benchmark

KW - Critical configuration

KW - Reaction rate measurement

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Park YH, Cheng Y, Elzohery R, Wilson PPH, Roberts JA, DeHart MD. Evaluation of critical experiments in the university of Wisconsin nuclear reactor (UWNR) with uncertainty quantification. In Margulis M, Blaise P, editors, International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020. EDP Sciences - Web of Conferences. 2020. p. 2214-2223. (International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020). doi: 10.1051/epjconf/202124710032

Evaluation of critical experiments in the university of Wisconsin nuclear reactor (UWNR) with uncertainty quantification

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