A finite element method for neutron noise analysis in hexagonal reactors
Paper in proceeding, 2020
geometries. The neutron noise is obtained by solving the frequency-domain two-group neutron diffusion equation in the first order approximation. In order to solve this partial differential equation a code based on a high order finite element method is developed. The novelty of this simulator resides on the possibility of dealing with rectangular meshes in any kind of geometry, thus allowing for complex domains and any location of the perturbation. The finite element method also permits automatic refinements in the cell size (h-adaptability) and in its polynomial degree (p-adaptability) that lead to a fast convergence. In order to show the possibilities of the neutron noise simulator developed a perturbation in a hexagonal two-dimensional reactor is investigated in this paper.
hexagonal geometry
finite element method
neutron noise
Author
Antoni Vidal-Ferràndiz
Universitat de Valencia
Damian Ginestar
Universitat de Valencia
Amanda Carreño
Universitat de Valencia
Gumersindo Verdú
Universitat de Valencia
Christophe Demaziere
Chalmers, Physics, Subatomic, High Energy and Plasma Physics
International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020
Vol. 2020-March 2939-2946
9781713827245 (ISBN)
Cambridge, United Kingdom,
Core monitoring techniques and experimental validation and demonstration (CORTEX)
European Commission (EC) (EC/H2020/754316), 2017-09-01 -- 2021-08-31.
Areas of Advance
Energy
Subject Categories
Other Physics Topics
DOI
10.1051/epjconf/202124721007