Numerical and experimental investigation of the water flow through PWR spacer grids

Authors

  • Higor Fabiano Pereira de Castro Universidade Federal de Minas Gerais https://orcid.org/0000-0003-3822-0546
  • Guilherme Augusto Moura Vidal Nuclear Technology Development Center - CDTN
  • Tiago Augusto Santiago Vieira Nuclear Technology Development Center - CDTN
  • Vitor Vasconcelos Araújo Silva Nuclear Technology Development Center - CDTN
  • Daniel de Almeida Magalhães Campolina Nuclear Technology Development Center - CDTN
  • Graiciany de Paula Barros Nuclear Technology Development Center - CDTN
  • Rebeca Cabral Gonçalves Nuclear Technology Development Center - CDTN
  • Andre Augusto Campagnole dos Santos Nuclear Technology Development Center - CDTN
  • Maria Auxiliadora Fortini Veloso Universidade Federal de Minas Gerais

DOI:

https://doi.org/10.15392/bjrs.v8i3A.1294

Keywords:

Spacer grids, LDV, CFD, Thermo-hydraulic, PWR

Abstract

Spacer grids are one of main components of a Pressurized Water Reactor (PWR) fuel assembly. They are able to improve heat transfer from rod bundles to the water flow by increasing turbulence and mixture of this flow. On the other hand the pressure drop increases because spacer grids. Experimental and Computational Fluid Dynamics (CFD) analysis have been used to understand how spacer grids affect the water flow. This analysis is important to improve spacer grids thermal-hydraulic performance. This paper aims to investigate numerically and experimentally the water flow through PWR spacer grids. The numerical and experimental procedures have been developed for a 5x5 rod bundle with spacer grids at the Nuclear Technology Development Center (CDTN) in Belo Horizonte, Brazil. At CDTN, measurements of the velocity components are acquired with a 2D LDV (Laser Doppler Velocimetry) system and the numerical results are obtained using ANSYS CFX code. The measurements are obtained at one height downstream from a spacer grid and compared to CFD simulations for a flow rate at Reynolds number of 5.4x104 . Results show good agreement between both methodologies. The great repeatability and low experimental uncertainty evaluated (< 1.24%) in this work can be used to validate other CFD codes.

Downloads

Download data is not yet available.

Author Biographies

  • Higor Fabiano Pereira de Castro, Universidade Federal de Minas Gerais
    Department of Nuclear Engineering
  • Guilherme Augusto Moura Vidal, Nuclear Technology Development Center - CDTN
    Thermal-Hydraulic and Neutronics Laboratory - LTHN
  • Tiago Augusto Santiago Vieira, Nuclear Technology Development Center - CDTN
    Thermal-Hydraulic and Neutronics Laboratory - LTHN
  • Vitor Vasconcelos Araújo Silva, Nuclear Technology Development Center - CDTN
    Thermal-Hydraulic and Neutronics Laboratory - LTHN
  • Daniel de Almeida Magalhães Campolina, Nuclear Technology Development Center - CDTN
    Thermal-Hydraulic and Neutronics Laboratory - LTHN
  • Graiciany de Paula Barros, Nuclear Technology Development Center - CDTN
    Thermal-Hydraulic and Neutronics Laboratory - LTHN
  • Rebeca Cabral Gonçalves, Nuclear Technology Development Center - CDTN
    Thermal-Hydraulic and Neutronics Laboratory - LTHN
  • Andre Augusto Campagnole dos Santos, Nuclear Technology Development Center - CDTN
    Thermal-Hydraulic and Neutronics Laboratory - LTHN
  • Maria Auxiliadora Fortini Veloso, Universidade Federal de Minas Gerais
    Department of Nuclear Engineering

References

TODREAS, N. E., and KAZIMI, M.S. Nuclear Systems Vol 1: Thermal Hydraulic. Fun- damentals, Ed.CRC Press, New York & United States of America (2012).

CONNER, M. E., “Hydraulic Benchmark Data for PWR Mixing Vane Grid”, Conference Proceedings of the NURETH-14, Toronto, September, Vol. 337, pp. 25–30, (2011).

IN, W. K., et. al., “Experimental Observation and CFD Prediction of Flow Mixing in a Rod Bundle with Mixing-vane Spacer Grid”, 10th Pacific Symposium on Flow Visualization and Image Processing, Naples, June, Vol. 337, pp. 15–18, (2015).

KANG, S. K., and HASSAN, Y. A., “Computational fluid dynamics (CFD) round robin benchmark for a pressurized water reactor (PWR) rod bundle”, Nuclear Engineering and Design, 304, pp. 204–231, (2016).

CHANG, S. K., et. al., “Turbulent mixing in a rod bundle with vaned spacer grids”, Nuclear Engineering and Design, 279, pp. 19–36, (2014).

SANTOS, A. A. C. S., et. al., “Convergence study and uncertainty quantification of average and statistical PIV measurements in a matched refractive index 5x5 rod bundle with mixing vane spacer grid”, Experimental Thermal and Fluid Science, 102, pp. 215–231, (2019).

ANSYS, IC, “CFX-13 Pre Users Guide, Release 13.0”, Canonsburg. ANSYS, 344p. (2012).

ISO 5167-1, “Measurement of fluid flow by means of pressure differential devices”, ISO, Geneva, Switzerland (1991).

NAVARRO, M.A., “Procedimento para calibração dos transmissores de pressão do circuito água-ar (CAA)”, Nota interna CNEN/CDTN (2011).

NAVARRO, M.A., “Procedimento para calibração das linhas de medição de temperatura do circuito água-ar (CAA)”, Nota interna CNEN/CDTN (2012).

BSA Flow Software, “BSA Flow Software Version 4.10 Instalation & Users Guide”, Dantec Dynamics A/S, Denmark (2006).

CASTRO, H. F. P., Investigação Experimental do Escoamento de Água Após Grade Espaçadora de Elemento Combustível Para Reatores Nucleares do Tipo PWR, Dissertação, Programa de Pós Graduação do Centro de Desenvolvimento da Tecnologia Nuclear, Belo Horizonte, Brazil (2016).

ISO GUM, JCGM, “Evaluation of measurement data Guide to the expression of uncer-tainty in measurement”, (2008).

WAGNER.W., et. al., “IAPWS Industrial Formulation 1997 for the Thermodynamic Proper-ties of Water and Steam”, Journal of Engineering for Gas Turbines and Power - ASME, 122, pp. 150–182, (2000).

SANTOS, A. A. C., et. al., “Verification and validation of a PWR rod bundle seg- ment CFD simulation”, The 15th International Topical Meeting on Nuclear Reactor Thermal-hydraulics - NURETH-15, Pisa, May 12-15, (2013).

Downloads

Published

2021-02-09

Issue

Section

XXI Meeting on Nuclear Reactor Physics and Thermal Hydraulics (XXI ENFIR) and VI ENIN

How to Cite

Numerical and experimental investigation of the water flow through PWR spacer grids. Brazilian Journal of Radiation Sciences, Rio de Janeiro, Brazil, v. 8, n. 3A (Suppl.), 2021. DOI: 10.15392/bjrs.v8i3A.1294. Disponível em: https://bjrs.org.br/revista/index.php/REVISTA/article/view/1294.. Acesso em: 24 nov. 2024.

Similar Articles

21-30 of 97

You may also start an advanced similarity search for this article.

Most read articles by the same author(s)