Modeling noise experiments performed at AKR-2 and CROCUS zero-power reactors

Research output: Contribution to journalResearch articleContributedpeer-review

Contributors

  • M. Hursin - , Swiss Federal Institute of Technology Lausanne (EPFL), Paul Scherrer Institute (Author)
  • A. Zoia - , Université Paris-Saclay (Author)
  • A. Rouchon - , Université Paris-Saclay (Author)
  • A. Brighenti - , Université Paris-Saclay (Author)
  • I. Zmijarevic - , Université Paris-Saclay (Author)
  • S. Santandrea - , Université Paris-Saclay (Author)
  • P. Vinai - , Chalmers University of Technology (Author)
  • A. Mylonakis - , Chalmers University of Technology (Author)
  • H. Yi - , Chalmers University of Technology (Author)
  • C. Demazière - , Chalmers University of Technology (Author)
  • V. Lamirand - , Swiss Federal Institute of Technology Lausanne (EPFL), Paul Scherrer Institute (Author)
  • K. Ambrozic - , Swiss Federal Institute of Technology Lausanne (EPFL) (Author)
  • T. Yamamoto - , Kyoto University (Author)
  • S. Hübner - , Chair of Hydrogen and Nuclear Energy (Author)
  • A. Knospe - , Chair of Hydrogen and Nuclear Energy (Author)
  • C. Lange - , Chair of Hydrogen and Nuclear Energy (Author)
  • S. Yum - , Technical University of Munich (Author)
  • R. Macian - , Technical University of Munich (Author)
  • A. Vidal - , Polytechnic University of Valencia (Author)
  • D. Ginestar - , Polytechnic University of Valencia (Author)
  • G. Verdú - , Polytechnic University of Valencia (Author)

Abstract

CORTEX is a EU H2020 project (2017-2021) devoted to the analysis of ’reactor neutron noise’ in nuclear reactors, i.e. the small fluctuations occurring around the stationary state due to external or internal disturbances in the core. One important aspect of CORTEX is the development of neutron noise simulation codes capable of modeling the spatial variations of the noise distribution in a reactor. In this paper we illustrate the validation activities concerning the comparison of the simulation results obtained by several noise simulation codes with respect to experimental data produced at the zero-power reactors AKR-2 (operated at TUD, Germany) and CROCUS (operated at EPFL, Switzerland). Both research reactors are modeled in the time and frequency domains, using transport or diffusion theory. Overall, the noise simulators managed to capture the main features of the neutron noise behavior observed in the experimental campaigns carried out in CROCUS and AKR-2, even though computational biases exist close to the region where the noise-inducing mechanical vibration was located (the so-called ”noise source”). In some of the experiments, it was possible to observe the spatial variation of the relative neutron noise, even relatively far from the noise source. This was achieved through reduced uncertainties using long measurements, the installation of numerous, robust and efficient detectors at a variety of positions in the near vicinity or inside the core, as well as new post-processing methods. For the numerical simulation tools, modeling the spatial variations of the neutron noise behavior in zero-power research reactors is an extremely challenging problem, because of the small magnitude of the noise field; and because deviations from a point-kinetics behavior are most visible in portions of the core that are especially difficult to be precisely represented by simulation codes, such as experimental channels. Nonetheless the limitations of the simulation tools reported in the paper were not an issue for the CORTEX project, as most of the computational biases are found close to the noise source.

Details

Original languageEnglish
Article number110066
Number of pages16
JournalAnnals of nuclear energy
Volume194
Publication statusPublished - 15 Dec 2023
Peer-reviewedYes

Keywords

ASJC Scopus subject areas

Keywords

  • CORTEX, Experimental data, Noise simulators, Validation