1 / 10

Assembly Discontinuity Factor calculation for use in the Nodal Expansion Method

G. Scholtz, V. Naicker, K. Ivanov. Assembly Discontinuity Factor calculation for use in the Nodal Expansion Method. School of Mechanical and Nuclear Engineering North-West University. Energy Postgraduate Conference 2013. Outline. 1. Introduction Research aims and objectives

jasonrivera
Download Presentation

Assembly Discontinuity Factor calculation for use in the Nodal Expansion Method

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. G. Scholtz, V. Naicker, K. Ivanov Assembly Discontinuity Factor calculation for use in the Nodal Expansion Method School of Mechanical and Nuclear Engineering North-West University Energy Postgraduate Conference 2013

  2. Outline 1. Introduction • Research aims and objectives • Neutron flux calculation 2. Homogenization • Generalized Equivalence Theory (GET) • Assembly Discontinuity Factors (ADF’s) 3. Core layout and MCNP model 4. Results and Discussion • ADF • MCNP • Nodal Expansion Method (NEM) 5. Conclusion and further work

  3. Introduction – Research aims & objectives • Benchmark studies for major reactor types. • Stand-alone neutronics and T- H simulations, coupled afterwards. • Develop input model for SAFARI-1 using NEM. • Calculate Assembly Discontinuity Factors using MCNP. • Perform steady state analysis to calculate flux, power, etc.

  4. Neutron flux calculation • Knowledge of flux distribution required for power, criticality and fast fluence. • NEM is a deterministic, nodal diffusion neutronics code. • Nodal methods - Reduced computational times. - Large nodes compared to finite difference methods. - Space averaged (homogenized) parameters. - Modern, established method for full core calculations. • Deterministic methods - Based on the solution of neutron transport equation. - Discrete ordinates, integral transport, diffusion theory. • Stochastic methods (MCNP) - Simulates particle behaviour by random sampling. - Highly accurate but computationally expensive.

  5. Homogenization • Generalized equivalence theory - Methods employed to replace heterogeneous lattice of materials with an equivalent homogeneous mixture. - Aim is to preserve reaction rates and multiplication factor. - Generalized Equivalence Theory matches the heterogeneous and homogeneous solutions by allowing for discontinuities. - Accomplished through suitable multiplier on each side of node boundary. • Assembly Discontinuity Factors - Reduces homogenization error. - ADF is ratio of the surface averaged heterogeneous flux to the volume averaged homogeneous flux.

  6. Core layout & MCNP model MCNP (3 x 3 x 3) SAFARI-1 core

  7. Results - ADF

  8. Results - MCNP • Fuel filled core

  9. Results - NEM • 15 x14x12 Nodes • Homogenized cross sections (NECSA)

  10. Conclusions and further work Conclusions • MCNP can be used for ADF calculation. • Consistent values for ADF. • Current NEM results are sufficient for ADF implementation. • MCNP calculation provides second set of results to compare to NEM. Further work • Complete heterogeneous model of SAFARI-1 reactor. • Determine multi-group surface and volume fluxes for ADF calculation. • Implement ADF into NEM input model. This work is based upon research supported by the South African Research Chairs Initiative of the Department of Science and Technology and National Research Foundation.

More Related