Abstract
The Simplified Spherical Harmonic (SPN) approximation was first introduced as a three-dimensional (3D) extension of the plane-geometry Spherical Harmonic (PN) equations. A third order SPN (SP3) solver, recently implemented in the Nodal Expansion Method (NEM), has shown promising performance in the reactor core neutronics simulations. This work is focused on the development and implementation of the transport-corrected interface and boundary conditions in an NEM SP3 solver, following recent published work on the rigorous SPN theory for piecewise homogeneous regions. A streamlined procedure has been developed to generate the flux zero and second order/moment discontinuity factors (DFs) of the generalized equivalence theory to minimize the error introduced by pin-wise homogenization. Moreover, several colorset models with varying sizes and configurations are later explored for their capability of generating DFs that can produce results equivalent to that using the whole-core homogenization model for more practical implementations. The new developments are tested and demonstrated on the C5G7 benchmark. The results show that the transport-corrected SP3 solver shows general improvements to power distribution prediction compared to the basic SP3 solver with no DFs or with only the zeroth moment DF. The complete equivalent calculations using the DFs can almost reproduce transport solutions with high accuracy. The use of equivalent parameters from larger size colorset models show a slightly reduced prediction error than that using smaller colorset models in the whole-core calculations.
Highlights
Accepted: 6 October 2021Obtaining solutions to the neutron transport equation with consistent angular discretization, such as discrete ordinates (SN ) or spherical harmonics (PN ), for the threedimensional (3D) transport problem can be challenging, even with the rapid increase in computing power
The method showed the potential to improve the accuracy of the pin power prediction; its application for practical core problems was limited because of the considerable amount of data required for whole core calculations
Further development and enhancement have since been conducted to improve its performance, such as incorporating the higher order scattering cross sections and discontinuity factors (DFs) [14,15]. This implementation adopted the ad hoc interface and boundary conditions based on the assumption of 1D behavior near a surface, which prevents the angular flux from being represented by the Simplified plane-geometry Spherical Harmonic (PN) (SPN) flux components
Summary
Obtaining solutions to the neutron transport equation with consistent angular discretization, such as discrete ordinates (SN ) or spherical harmonics (PN ), for the threedimensional (3D) transport problem can be challenging, even with the rapid increase in computing power. Since spatial homogenization is applied in pin homogenized fine-mesh calculations, a mitigation method is required to eliminate or reduce the homogenization error In this regard, discontinuity factors based on the generalized equivalence theory (GET) have been investigated, such as [8,9]. Further development and enhancement have since been conducted to improve its performance, such as incorporating the higher order scattering cross sections and discontinuity factors (DFs) [14,15] This implementation adopted the ad hoc interface and boundary conditions based on the assumption of 1D behavior near a surface, which prevents the angular flux from being represented by the SPN flux components.
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