Modelling of stationary fluctuations in nuclear reactor cores in the frequency domain
Paper in proceeding, 2015

This paper presents the development of a numerical tool to simulate the effect of stationary fluctuations in Light Water Reactor cores. The originating fluctuations are defined for the variables describing the boundary conditions of the system, i.e. inlet velocity, inlet enthalpy, and outlet pressure. The tool calculates the three-dimensional space-frequency distributions within the core of the corresponding fluctuations in neutron flux, coolant density, coolant velocity, coolant enthalpy, and fuel temperature. The tool is thus based on the simultaneous modelling of neutron transport, fluid dynamics, and heat transfer in a truly integrated and fully coupled manner. The modelling of neutron transport relies on the two-group diffusion approximation and a spatial discretization based on finite differences. The modelling of fluid dynamics is performed using the homogeneous equilibrium model complemented with pre-computed static slip ratio. Heat conduction in the fuel pins is also accounted for, and the heat transfer between the fuel pins and the coolant is modelled also using a pre-computed distribution of the heat transfer coefficient. The spatial discretization of the fluid dynamic and heat transfer problems is carried out using finite volumes. The tool is currently entirely Matlab based with input data provided by an external static core simulator. The paper also presents the results of dynamic simulations performed for a typical pressurized water reactor and for a typical boiling water reactor, as illustrations of the capabilities of the tool.

LWR multi-physics

heat transfer

neutron transport

noise analysis

fluid dynamics

Author

Christophe Demaziere

Chalmers, Applied Physics, Nuclear Engineering

Victor Dykin

Chalmers, Applied Physics, Nuclear Engineering

Augusto Hernandéz Solís

Royal Institute of Technology (KTH)

Chalmers, Applied Physics, Nuclear Engineering

Viktor Boman

Chalmers, Applied Physics, Nuclear Engineering

Mathematics and Computations, Supercomputing in Nuclear Applications and Monte Carlo International Conference, M and C+SNA+MC 2015, Nashville, United States, 19-23 April 2015

Vol. 3 2406-2419
978-151080804-1 (ISBN)

Subject Categories

Other Engineering and Technologies

Other Physics Topics

Areas of Advance

Energy

ISBN

978-151080804-1

More information

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7/12/2024