Reduced basis approaches in time-dependent noncoercive settings for modelling the movement of nuclear reactor control rods
Loading...
Date
2015
Journal Title
Journal ISSN
Volume Title
Publisher
SISSA
Abstract
In this work, two approaches, based on the certified Reduced Basis method,
have been developed for simulating the movement of nuclear reactor control rods, in
time-dependent non-coercive settings featuring a 3D geometrical framework. In particular,
in a first approach, a piece-wise affine transformation based on subdomains
division has been implemented for modelling the movement of one control rod. In
the second approach, a “staircase” strategy has been adopted for simulating the movement of all the three rods featured by the nuclear reactor chosen as case study. The
neutron kinetics has been modelled according to the so-called multi-group neutron
diffusion, which, in the present case, is a set of ten coupled parametrized parabolic
equations (two energy groups for the neutron flux, and eight for the precursors). Both
the reduced order models, developed according to the two approaches, provided a
very good accuracy compared with high-fidelity results, assumed as “truth” solutions.
At the same time, the computational speed-up in the Online phase, with respect to the
fine “truth” finite element discretization, achievable by both the proposed approaches
is at least of three orders of magnitude, allowing a real-time simulation of the rod
movement and control.
Description
Keywords
reduced basis method, control rod movement, spatial kinetics, parametrized geometry, multi-group neutron diffusion, non-coercive operators