Simulation of Natural Convection in Square Porous Cavity Based on Chebyshev Spectral Method

doi:10.12068/j.issn.1005-3026.2017.04.014

Journal of Northeastern University Natural Science ›› 2017, Vol. 38 ›› Issue (4): 522-526.DOI: 10.12068/j.issn.1005-3026.2017.04.014

• Materials & Metallurgy • Previous Articles Next Articles

Simulation of Natural Convection in Square Porous Cavity Based on Chebyshev Spectral Method

CHEN Yuan-yuan^1,2， LI Ben-wen³， ZHANG Jing-kui²

1. Key Laboratory of Electromagnetic Processing of Materials， Ministry of Education， Northeastern University， Shenyang 110819， China; 2. The State Key Laboratory of Refractories and Metallurgy， Wuhan University of Science and Technology， Wuhan 430081， China; 3. School of Energy & Power Engineering， Dalian University of Technology， Dalian 116024， China.

Received:2015-11-16 Revised:2015-11-16 Online:2017-04-15 Published:2017-04-11
Contact: LI Ben-wen
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Abstract

Abstract: The Chebyshev spectral collocation method (CSCM) was used to simulate natural convection in the square porous cavity under a local thermal equilibrium condition. Using the Chebyshev-Gauss-Lobatto collocation points， the dimensionless govering equations can be spatially discredited. The matrix diagonalization method was used to solve these discredited equations. The simulation results were in well agreement with the existing data. Meanwhile， the exact solutions were further constructed to valid the method and the CSCM effectiveness was proved. Finally， the effects of Rayleigh number on the streamlines， the isotherms and the Nusselt number were studied based on the CSCM simulations.

Key words: Chebyshev spectral collocation method, porous media, natural convection, local thermal equilibrium, numerical simulation

CLC Number:

TB126

CHEN Yuan-yuan， LI Ben-wen， ZHANG Jing-kui. Simulation of Natural Convection in Square Porous Cavity Based on Chebyshev Spectral Method[J]. Journal of Northeastern University Natural Science, 2017, 38(4): 522-526.

References

[1]Baytas A C，Pop I.Free convection in oblique enclosures filled with a porous medium［J］.International Journal of Heat and Mass Transfer，1999，42(6):1047-1057.
[2]Baytas A C，Pop I.Natural convection in a trapezoidal enclosure filled with a porous medium［J］.International Journal of Engineering Science，2001，39(1):125-134.
[3]Baytas A C，Pop I.Free convection in a square porous cavity using a thermal nonequilibrium model［J］.International Journal of Thermal Sciences，2002，41(6):861-870.
[4]Misirlioglu A，Baytas A C，Pop I.Free convection in a wavy cavity filled with a porous medium［J］.International Journal of Heat and Mass Transfer，2005，48(9):1840-1850.
[5]Ma X，Zabaras N.A stabilized stochastic finite element second-order projection method for modeling natural convection in random porous media［J］.Journal of Computational Physics，2008，227(8):8448-8471.
[6]Gao D Y，Chen Z Q，Chen L H.A thermal lattice Boltzmann model for natural convection in porous media under local thermal non-equilibrium conditions［J］. International Journal of Heat and Mass Transfer，2014，70:979-989.
[7]Subich C J，Lamb K G，Stastna M.Simulation of the Naviere-Stokes equations in three dimensions with a spectral collocation method［J］.International Journal for Numerical Methods in Fluids，2013，73(1):103-129.
[8]Li B W，Sun Y S，Yu Y.Iterative and direct Chebyshev collocation spectral methods for one-dimensional radiative heat transfer［J］.International Journal of Heat and Mass Transfer，2008，51(5):5887-5894.
[9]Zhang J K，Li B W，Chen Y Y.Hall effects on natural convection of participating MHD with thermal radiation in a cavity［J］.International Journal of Heat and Mass Transfer，2013，66:838-843.
[10]Li Z C，Chen S Y，Chen C S，et al.A spectral collocation method for a rotating Bose-Einstein condensation in optical lattices［J］.Computer Physics Communications，2011，182(6):1215-1234.
[11]Khandelwal M K，Bera P，Chakrabarti A.Influence of periodicity of sinusoidal bottom boundary condition on natural convection in porous enclosure［J］.International Journal of Heat and Mass Transfer，2012，55(11):2889-2900.
[12]Canuto C，Hussaini M Y，Quarteroni A，et al.Spectral methods:fundamentals in single domains［M］.Berlin:Springer，2006.
[13]Peyret R.Spectral method for incompressible viscous flow［M］.New York:Springer，2002.
[14]Manole D M，Lage J L.Numerical benchmark results for natural convection in a porous medium cavity［J］.ASME Publications Heat Transfer Division，1993，216:55-55.
[15]Moya S L，Ramos E，Sen M.Numerical study of natural convection in a tilted rectangular porous material［J］.International Journal of Heat and Mass Transfer，1987，30(4):741-756.
[16]Chen Y Y，Li B W，Zhang J K.Spectral collocation method for natural convection in a square porous cavity with local thermal equilibrium and non-equilibrium models［J］.International Journal of Heat and Mass Transfer，2016，96:84-96.

Simulation of Natural Convection in Square Porous Cavity Based on Chebyshev Spectral Method

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