Physics and Safety Analysis for the Nist Research Reactor.

Cheng, L.; Diamond, D.J.; Xu, J.; Carew, J.; Rorer, D.

doi:10.2172/15007782

Cited by 11 publications

(14 citation statements)

References 2 publications

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“…MCNP has been previously used to design and analyze the new cold neutron source and to perform neutronics calculations needed for relicensing and safety analysis [7]. In performing the analyses of the changes to the 113 Cd distribution as a function of depletion [4,5], the MCNP model of the NBSR was modified by dividing each shim arm into 20 mesh cells, as shown in Figure 1.…”

Section: Methodsmentioning

confidence: 99%

Effect of Shim Arm Depletion in the NBSR

Hanson¹,

Brown²,

Diamond³

2013

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The cadmium shim arms in the NBSR undergo burnup during reactor operation and hence, require periodic replacement. Presently, the shim arms are replaced after every 25 cycles to guarantee they can maintain sufficient shutdown margin. Two prior reports document the expected change in the 113 Cd distribution because of the shim arm depletion. One set of calculations was for the present high-enriched uranium fuel and the other for the low-enriched uranium fuel when it was in the COMP7 configuration (7 inch fuel length vs. the present 11 inch length). The depleted 113 Cd distributions calculated for these cores were applied to the current design for an equilibrium lowenriched uranium core. This report details the predicted effects, if any, of shim arm depletion on the shim arm worth, the shutdown margin, power distributions, and kinetics parameters.

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Section: Methodsmentioning

confidence: 99%

Effect of Shim Arm Depletion in the NBSR

Hanson¹,

Brown²,

Diamond³

2013

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“…MCNP5 was used due to extensive benchmarking of all MCNP5-based models used in this study. The list of reactor models investigated for this study are: a typical Westinghouse pressurized water reactor (PWR) [41], the High Flux Isotope Reactor (HFIR) at Oak Ridge National Laboratory (ORNL) [42], and the National Bureau of Standards Reactor (NBSR) at the National Institute of Standards and Technology (NIST) [43]. The Westinghouse PWR operates with LEU fuel, while HFIR and NBSR operate with HEU fuel.…”

Section: Reactor Simulationsmentioning

confidence: 99%

Impact of fission neutron energies on reactor antineutrino spectra

et al. 2018

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Recent measurements of reactor-produced antineutrino fluxes and energy spectra are inconsistent with models based on measured thermal fission beta spectra. In this paper, we examine the dependence of antineutrino production on fission neutron energy. In particular, the variation of fission product yields with neutron energy has been considered as a possible source of the discrepancies between antineutrino observations and models. In simulations of low-enriched and highly-enriched reactor core designs, we find a substantial fraction of fissions (from 5% to more than 40%) are caused by non-thermal neutrons. Using tabulated evaluations of nuclear fission and decay, we estimate the variation in antineutrino emission by the prominent fission parents 235 U, 239 Pu, and 241 Pu versus neutron energy. The differences in fission neutron energy are found to produce less than 1% variation in detected antineutrino rate per fission of 235 U, 239 Pu, and 241 Pu. Corresponding variations in the antineutrino spectrum are found to be less than 10% below 7 MeV antineutrino energy, smaller than current model uncertainties. We conclude that insufficient modeling of fission neutron energy is unlikely to be the cause of the various reactor anomalies. Our results also suggest that comparisons of antineutrino measurements at low-enriched and highly-enriched reactors can safely neglect the differences in the distributions of their fission neutron energies.

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“…While thermal-hydraulic modeling plays a vital role in the design, operation, performance, and safety of a nuclear reactor, the present paper focuses particularly on the safety (or accident analysis) application. Examples of codes used for research reactor thermalhydraulic modeling are RELAP5 [21] for the NIST research reactor [22], the IPR-R1 TRIGA Brazilian reactor [23], and the High Flux reactor (HFR) in Netherlands [24]. The PARET code [25] has been used for the McMaster University research reactor [26], the University of Florida Training Reactor [27], and the NUR Algerian research reactor [28] among several others.…”

Section: Thermal-hydraulic Modelingmentioning

confidence: 99%

Methods and Models for the Coupled Neutronics and Thermal-Hydraulics Analysis of the CROCUS Reactor at EFPL

Rais

Siefman

Girardin

et al. 2015

Science and Technology of Nuclear Installations

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In order to analyze the steady state and transient behavior of the CROCUS reactor, several methods and models need to be developed in the areas of reactor physics, thermal-hydraulics, and multiphysics coupling. The long-term objectives of this project are to work towards the development of a modern method for the safety analysis of research reactors and to update the Final Safety Analysis Report of the CROCUS reactor. A first part of the paper deals with generation of a core simulator nuclear data library for the CROCUS reactor using the Serpent 2 Monte Carlo code and also with reactor core modeling using the PARCS code. PARCS eigenvalue, radial power distribution, and control rod reactivity worth results were benchmarked against Serpent 2 full-core model results. Using the Serpent 2 model as reference, PARCS eigenvalue predictions were within 240 pcm, radial power was within 3% in the central region of the core, and control rod reactivity worth was within 2%. A second part reviews the current methodology used for the safety analysis of the CROCUS reactor and presents the envisioned approach for the multiphysics modeling of the reactor.

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Physics and Safety Analysis for the Nist Research Reactor.

Cited by 11 publications

References 2 publications

Effect of Shim Arm Depletion in the NBSR

Effect of Shim Arm Depletion in the NBSR

Impact of fission neutron energies on reactor antineutrino spectra

Methods and Models for the Coupled Neutronics and Thermal-Hydraulics Analysis of the CROCUS Reactor at EFPL

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