Shift Verification and Validation

Tara M. Pandya; Thomas M. Evans; Gregory G Davidson; Seth R. Johnson; Andrew T. Godfrey

doi:10.2172/1329768

Shift Verification and Validation

Tara M. Pandya, Thomas M. Evans, Gregory G Davidson, Seth R. Johnson, Andrew T. Godfrey

Research output: Book/Report › Commissioned report

Abstract

This documentation outlines the verification and validation of Shift for the Consortium for Advanced Simulation of Light Water Reactors (CASL). Five main types of problems were used for validation: small criticality benchmark problems; full-core reactor benchmarks for light water reactors; fixed-source coupled neutron-photon dosimetry benchmarks; depletion/burnup benchmarks; and full-core reactor performance benchmarks. We compared Shift results to measured data and other simulated Monte Carlo radiation transport code results, and found very good agreement in a variety of comparison measures. These include prediction of critical eigenvalue, radial and axial pin power distributions, rod worth, leakage spectra, and nuclide inventories over a burn cycle. Based on this validation of Shift, we are confident in Shift to provide reference results for CASL benchmarking.

Original language	English
Place of Publication	United States
DOIs	https://doi.org/10.2172/1329768
State	Published - 2016

Keywords

21 SPECIFIC NUCLEAR REACTORS AND ASSOCIATED PLANTS
97 MATHEMATICS AND COMPUTING
VALIDATION
S CODES
BENCHMARKS
WATER MODERATED REACTORS
COMPARATIVE EVALUATIONS
NEUTRONS
REACTOR CORES
EIGENVALUES
MONTE CARLO METHOD
PHOTONS
COMPUTERIZED SIMULATION
VERIFICATION
WATER COOLED REACTORS
POWER DISTRIBUTION
RADIATION TRANSPORT
BURNUP
CRITICALITY
DOSIMETRY
FORECASTING
PERFORMANCE
CONTROL ROD WORTHS
FUEL PINS

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10.2172/1329768

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title = "Shift Verification and Validation",

abstract = "This documentation outlines the verification and validation of Shift for the Consortium for Advanced Simulation of Light Water Reactors (CASL). Five main types of problems were used for validation: small criticality benchmark problems; full-core reactor benchmarks for light water reactors; fixed-source coupled neutron-photon dosimetry benchmarks; depletion/burnup benchmarks; and full-core reactor performance benchmarks. We compared Shift results to measured data and other simulated Monte Carlo radiation transport code results, and found very good agreement in a variety of comparison measures. These include prediction of critical eigenvalue, radial and axial pin power distributions, rod worth, leakage spectra, and nuclide inventories over a burn cycle. Based on this validation of Shift, we are confident in Shift to provide reference results for CASL benchmarking.",

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author = "Pandya, {Tara M.} and Evans, {Thomas M.} and Davidson, {Gregory G} and Johnson, {Seth R.} and Godfrey, {Andrew T.}",

year = "2016",

doi = "10.2172/1329768",

language = "English",

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AU - Pandya, Tara M.

AU - Evans, Thomas M.

AU - Davidson, Gregory G

AU - Johnson, Seth R.

AU - Godfrey, Andrew T.

PY - 2016

Y1 - 2016

N2 - This documentation outlines the verification and validation of Shift for the Consortium for Advanced Simulation of Light Water Reactors (CASL). Five main types of problems were used for validation: small criticality benchmark problems; full-core reactor benchmarks for light water reactors; fixed-source coupled neutron-photon dosimetry benchmarks; depletion/burnup benchmarks; and full-core reactor performance benchmarks. We compared Shift results to measured data and other simulated Monte Carlo radiation transport code results, and found very good agreement in a variety of comparison measures. These include prediction of critical eigenvalue, radial and axial pin power distributions, rod worth, leakage spectra, and nuclide inventories over a burn cycle. Based on this validation of Shift, we are confident in Shift to provide reference results for CASL benchmarking.

AB - This documentation outlines the verification and validation of Shift for the Consortium for Advanced Simulation of Light Water Reactors (CASL). Five main types of problems were used for validation: small criticality benchmark problems; full-core reactor benchmarks for light water reactors; fixed-source coupled neutron-photon dosimetry benchmarks; depletion/burnup benchmarks; and full-core reactor performance benchmarks. We compared Shift results to measured data and other simulated Monte Carlo radiation transport code results, and found very good agreement in a variety of comparison measures. These include prediction of critical eigenvalue, radial and axial pin power distributions, rod worth, leakage spectra, and nuclide inventories over a burn cycle. Based on this validation of Shift, we are confident in Shift to provide reference results for CASL benchmarking.

KW - 21 SPECIFIC NUCLEAR REACTORS AND ASSOCIATED PLANTS

KW - 97 MATHEMATICS AND COMPUTING

KW - VALIDATION

KW - S CODES

KW - BENCHMARKS

KW - WATER MODERATED REACTORS

KW - COMPARATIVE EVALUATIONS

KW - NEUTRONS

KW - REACTOR CORES

KW - EIGENVALUES

KW - MONTE CARLO METHOD

KW - PHOTONS

KW - COMPUTERIZED SIMULATION

KW - VERIFICATION

KW - WATER COOLED REACTORS

KW - POWER DISTRIBUTION

KW - RADIATION TRANSPORT

KW - BURNUP

KW - CRITICALITY

KW - DOSIMETRY

KW - FORECASTING

KW - PERFORMANCE

KW - CONTROL ROD WORTHS

KW - FUEL PINS

U2 - 10.2172/1329768

DO - 10.2172/1329768

M3 - Commissioned report

BT - Shift Verification and Validation

CY - United States

ER -

Shift Verification and Validation

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Keywords

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