Browse > Article
http://dx.doi.org/10.1016/j.net.2020.02.020

Large eddy simulation on the turbulent mixing phenomena in 3×3 bare tight lattice rod bundle using spectral element method  

Ju, Haoran (State Key Laboratory of Multiphase Flow in Power Engineering, School of Nuclear Science and Technology, Xi'an Jiaotong University)
Wang, Mingjun (State Key Laboratory of Multiphase Flow in Power Engineering, School of Nuclear Science and Technology, Xi'an Jiaotong University)
Wang, Yingjie (State Key Laboratory of Multiphase Flow in Power Engineering, School of Nuclear Science and Technology, Xi'an Jiaotong University)
Zhao, Minfu (China Institute of Atomic Energy)
Tian, Wenxi (State Key Laboratory of Multiphase Flow in Power Engineering, School of Nuclear Science and Technology, Xi'an Jiaotong University)
Liu, Tiancai (China Institute of Atomic Energy)
Su, G.H. (State Key Laboratory of Multiphase Flow in Power Engineering, School of Nuclear Science and Technology, Xi'an Jiaotong University)
Qiu, Suizheng (State Key Laboratory of Multiphase Flow in Power Engineering, School of Nuclear Science and Technology, Xi'an Jiaotong University)
Publication Information
Nuclear Engineering and Technology / v.52, no.9, 2020 , pp. 1945-1954 More about this Journal
Abstract
Subchannel code is one of the effective simulation tools for thermal-hydraulic analysis in nuclear reactor core. In order to reduce the computational cost and improve the calculation efficiency, empirical correlation of turbulent mixing coefficient is employed to calculate the lateral mixing velocity between adjacent subchannels. However, correlations utilized currently are often fitted from data achieved in central channel of fuel assembly, which would simply neglect the wall effects. In this paper, the CFD approach based on spectral element method is employed to predict turbulent mixing phenomena through gaps in 3 × 3 bare tight lattice rod bundle and investigate the flow pulsation through gaps in different positions. Re = 5000,10000,20500 and P/D = 1.03 and 1.06 have been covered in the simulation cases. With a well verified mesh, lateral velocities at gap center between corner channel and wall channel (W-Co), wall channel and wall channel (W-W), wall channel and center channel (W-C) as well as center channel and center channel (C-C) are collected and compared with each other. The obvious turbulent mixing distributions are presented in the different channels of rod bundle. The peak frequency values at W-Co channel could have about 40%-50% reduction comparing with the C-C channel value and the turbulent mixing coefficient β could decrease around 25%. corrections for β should be performed in subchannel code at wall channel and corner channel for a reasonable prediction result. A preliminary analysis on fluctuation at channel gap has also performed. Eddy cascade should be considered carefully in detailed analysis for fluctuating in rod bundle.
Keywords
Turbulent mixing; Rod bundle; CFD; Spectral element method;
Citations & Related Records
연도 인용수 순위
  • Reference
1 H. Choi, P. Moin, Grid-point requirements for large eddy simulation: chapman's estimates revisited, Phys. Fluids 24 (1) (2012) 11702.   DOI
2 M. Wang, Q. Zuo, H. Yu, W. Tian, G.H. Su, S. Qiu, Multiscale thermal hydraulic study under the inadvertent safety injection system operation scenario of typical pressurized water reactor, Sci. Technol. Nucl. Ins. (2017) 1-15, 2017.
3 B. Koncar, S. Kosmrlj, Simulation of turbulent flow in MATIS-H rod bundle with split-type mixing vanes, Nucl. Eng. Des. 327 (2018) 112-126.   DOI
4 J. Xiong, R. Cheng, C. Lu, X. Chai, X. Liu, X. Cheng, CFD simulation of swirling flow induced by twist vanes in a rod bundle, Nucl. Eng. Des. 338 (2018) 52-62.   DOI
5 M. Wang, D. Fang, Y. Xiang, Y. Fei, Y. Wang, W. Ren, W. Tian, G.H. Su, S. Qiu, Study on the coolant mixing phenomenon in a $45^{\circ}$ T junction based on the thermal-mechanical coupling method, Appl. Therm. Eng. 144 (2018) 600-613.   DOI
6 T. Feng, M. Wang, P. Song, L. Liu, W. Tian, G.H. Su, S. Qiu, Numerical research on thermal mixing characteristics in a 45-degree T-junction for two-phase stratified flow during the emergency core cooling safety injection, Prog. Nucl. Energy 114 (2019) 91-104.   DOI
7 J. Chen, D. Zhang, P. Song, X. Wang, S. Wang, Y. Liang, S. Qiu, Y. Zhang, M. Wang, G.H. Su, CFD investigation on thermal-hydraulic behaviors of a wirewrapped fuel subassembly for sodium-cooled fast reactor, Ann. Nucl. Energy 113 (2018) 256-269.   DOI
8 B.H. Yan, The thermal hydraulic phenomenon in tight lattice bundles: a review, Ann. Nucl. Energy 126 (2019) 330-349.   DOI
9 S. Tavoularis, Rod bundle vortex networks, gap vortex streets, and gap instability: a nomenclature and some comments on available methodologies, Nucl. Eng. Des. 241 (7) (2011) 2624-2626.   DOI
10 S.V. Moller, On phenomena of turbulent flow through rod bundles, Exp. Therm. Fluid Sci. 4 (1) (1991) 25-35.   DOI
11 M.S. Guellouz, S. Tavoularis, The structure of turbulent flow in a rectangular channel containing a cylindrical rod - Part 2: phase-averaged measurements, Exp. Therm. Fluid Sci. 23 (1) (2000b) 75-91.   DOI
12 E. Merzari, A. Obabko, P. Fischer, N. Halford, J. Walker, A. Siegel, Y. Yu, Largescale large eddy simulation of nuclear reactor flows: issues and perspectives, Nucl. Eng. Des. 312 (2017a) 86-98.   DOI
13 J.D. Hooper, K. Rehme, Large-scale structural effects in developed turbulent flow through closely-spaced rod arrays, J. Fluid Mech. 145 (1) (1984) 305-337.   DOI
14 T. Krauss, L. Meyer, Characteristics of turbulent velocity and temperature in a wall channel of a heated rod bundle, Exp. Therm. Fluid Sci. 12 (1) (1996) 75-86.   DOI
15 T. Krauss, L. Meyer, Experimental investigation of turbulent transport of momentum and energy in a heated rod bundle, Nucl. Eng. Des. 180 (3) (1998) 185-206.   DOI
16 M.S. Guellouz, S. Tavoularis, The structure of turbulent flow in a rectangular channel containing a cylindrical rod - Part 1: Reynolds-averaged measurements, Exp. Therm. Fluid Sci. 23 (1) (2000a) 59-73.   DOI
17 Y.Q. Yu, B.H. Yan, X. Cheng, H.Y. Gu, Simulation of turbulent flow inside different subchannels in tight lattice bundle, Ann. Nucl. Energy 38 (11) (2011) 2363-2373.   DOI
18 F. Baratto, S.C.C. Bailey, S. Tavoularis, Measurements of frequencies and spatial correlations of coherent structures in rod bundle flows, Nucl. Eng. Des. 236 (17) (2006) 1830-1837.   DOI
19 E. Merzari, H. Ninokata, E. Baglietto, Numerical simulation of flows in tightlattice fuel bundles, Nucl. Eng. Des. 238 (7) (2008) 1703-1719.   DOI
20 B.H. Yan, L. Yu, URANS simulation of the turbulent flow in a tight lattice: effect of the pitch to diameter ratio, Prog. Nucl. Energy 53 (4) (2011) 428-437.   DOI
21 J. Wang, W.X. Tian, Y.H. Tian, G.H. Su, S.Z. Qiu, A sub-channel analysis code for advanced lead bismuth fast reactor, Prog. Nucl. Energy 63 (2013) 34-48.   DOI
22 M.O. Deville, P.F. Fischer, E.H. Mund, High Order Methods for Incompressible Fluid Flow, Cambridge University Press, 2002.
23 D.S. Rowe, C.W. Angle, Crossflow mixing between parallel flow channels during boiling, in: Part Ii. Measurement of Flow and Enthalpy in Two Parallel Channels, Pacific Northwest Lab, Richland, Wash, 1967. Battelle-Northwest.
24 N. Silin, L. Juanico, Experimental study on the Reynolds number dependence of turbulent mixing in a rod bundle, Nucl. Eng. Des. 236 (18) (2006) 1860-1866.   DOI
25 P. Fischer, J. Lottes, K. S. https://nek5000.mcs.anl.gov/title, 2019.
26 Y. Maday, A.T. Patera, E.M. R Nquist, An Operator-integration-factor splitting method for time-dependent problems: application to incompressible fluid flow, J. Sci. Comput. 5 (4) (1990) 263-292.   DOI
27 G. Busco, E. Merzari, Y.A. Hassan, Invariant analysis of the Reynolds stress tensor for a nuclear fuel assembly with spacer grid and split type vanes, Int. J. Heat Fluid Flow 77 (2019) 144-156.   DOI
28 N. Goth, P. Jones, D.T. Nguyen, R. Vaghetto, Y.A. Hassan, A. Obabko, E. Merzari, P.F. Fischer, Comparison of experimental and simulation results on interior subchannels of a 61-pin wire-wrapped hexagonal fuel bundle, Nucl. Eng. Des. 338 (2018) 130-136.   DOI
29 J. Martinez, Y. Lan, E. Merzari, M. Min, On the use of LES-based turbulent thermal-stress models for rod bundle simulations, Int. J. Heat Mass Tran. 142 (2019), 118399.   DOI
30 S. Stolz, P. Schlatter, L. Kleiser, High-pass filtered eddy-viscosity models for large-eddy simulations of transitional and turbulent flow, Phys. Fluids 17 (6) (2005) 65103.   DOI
31 H. Jeong, K. Ha, Y. Kwon, Y. Lee, D. Hahn, A dominant geometrical parameter affecting the turbulent mixing rate in rod bundles, Int. J. Heat Mass Tran. 50 (5-6) (2007) 908-918.   DOI
32 H. Ju, M. Wang, C. Chen, X. Zhao, M. Zhao, W. Tian, G.H. Su, S. Qiu, Numerical study on the turbulent mixing in channel with Large Eddy Simulation (LES) using spectral element method, Nucl. Eng. Des. 348 (2019) 169-176.   DOI
33 C.Y. Lee, C.H. Shin, W.K. In, Effect of gap width on turbulent mixing of parallel flow in a square channel with a cylindrical rod, Exp. Therm. Fluid Sci. 47 (2013) 98-107.   DOI