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Pore-scale investigation of gravity effects on phase change heat transfer characteristics using lattice Boltzmann method

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  • Li, Xinyi
  • Ma, Ting
  • Liu, Jun
  • Zhang, Hao
  • Wang, Qiuwang

Abstract

Latent heat thermal energy storage (LTES) has been recommended to complicated aerospace systems due to the excellent ability of storing thermal energy in recent years. Metal foam, as an effective additive to enhance the effective thermal conductive coefficient of phase change materials, has been wildly used in the LTES system. In support of the future space exploration, solid–liquid phase change within metal foam under different gravitational accelerations and corresponding heat transfer characteristics are investigated in this work to enhance understanding of heat transfer capability in reduced gravity conditions. A pore-scale lattice Boltzmann method with the double distribution functions is developed to study the solid–liquid phase change problems with the natural convection heat transfer in metal foam. Here, microstructure of metal foam is experimentally obtained by the use of X-ray computed tomography. Two numerical validation cases are performed, one for fluid–solid conjugate heat transfer problem, and the other for melting process in a square cavity without the porous media. The presented lattice Boltzmann results are in good agreement with previous analytical and numerical results. Based on the analysis of temperature and velocity fields during melting within metal foam, it is found that the clockwise circulation, caused by the temperature gradient, leads to the inhomogeneous distribution of liquid–solid interface along vertical direction. What’s more, gravity effects on the temperature and velocity fields together with the average Nusselt number and liquid fraction coefficient are investigated. Results show that with the decrease of gravitational accelerations from 1g to 0g, the maximum vertical velocity reduces and the thickness of velocity boundary layer thickens accordingly, and results in the pronounced reduction of average Nusselt number and melting rate. The natural convection appears to be even more tenuous as gravitational acceleration decreases, leading to the dominant heat transfer mechanism transited from convection to conduction, and finally alleviating the phase change process. The liquid fraction under 0g, 0.01g and 0.1g conditions are 54.6%, 58.9% and 67.9% respectively of that under 1g conditions at Fo = 0.06. In addition, porosity effects on phase change heat transfer characteristics are discussed by comparing the liquid fraction with porosity of 0.9, 0.94 and 1. It is found that metal foam with lower porosity shows higher effective thermal conductivity and outstanding heat transfer performance, while the restriction on natural convection should not be neglected, especially for melting region which is dominated by natural convection.

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  • Li, Xinyi & Ma, Ting & Liu, Jun & Zhang, Hao & Wang, Qiuwang, 2018. "Pore-scale investigation of gravity effects on phase change heat transfer characteristics using lattice Boltzmann method," Applied Energy, Elsevier, vol. 222(C), pages 92-103.
  • Handle: RePEc:eee:appene:v:222:y:2018:i:c:p:92-103
    DOI: 10.1016/j.apenergy.2018.03.184
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    1. Oró, E. & de Gracia, A. & Castell, A. & Farid, M.M. & Cabeza, L.F., 2012. "Review on phase change materials (PCMs) for cold thermal energy storage applications," Applied Energy, Elsevier, vol. 99(C), pages 513-533.
    2. Yang, Xiaohu & Lu, Zhao & Bai, Qingsong & Zhang, Qunli & Jin, Liwen & Yan, Jinyue, 2017. "Thermal performance of a shell-and-tube latent heat thermal energy storage unit: Role of annular fins," Applied Energy, Elsevier, vol. 202(C), pages 558-570.
    3. Liu, Zhenyu & Yao, Yuanpeng & Wu, Huiying, 2013. "Numerical modeling for solid–liquid phase change phenomena in porous media: Shell-and-tube type latent heat thermal energy storage," Applied Energy, Elsevier, vol. 112(C), pages 1222-1232.
    4. Fleming, Evan & Wen, Shaoyi & Shi, Li & da Silva, Alexandre K., 2013. "Thermodynamic model of a thermal storage air conditioning system with dynamic behavior," Applied Energy, Elsevier, vol. 112(C), pages 160-169.
    5. Warzoha, Ronald J. & Weigand, Rebecca M. & Fleischer, Amy S., 2015. "Temperature-dependent thermal properties of a paraffin phase change material embedded with herringbone style graphite nanofibers," Applied Energy, Elsevier, vol. 137(C), pages 716-725.
    6. Sharma, Susan Sunila, 2011. "Determinants of carbon dioxide emissions: Empirical evidence from 69 countries," Applied Energy, Elsevier, vol. 88(1), pages 376-382, January.
    7. Barzin, Reza & Chen, John J.J. & Young, Brent R. & Farid, Mohammed M., 2015. "Application of PCM underfloor heating in combination with PCM wallboards for space heating using price based control system," Applied Energy, Elsevier, vol. 148(C), pages 39-48.
    8. Rao, Zhonghao & Wang, Qingchao & Huang, Congliang, 2016. "Investigation of the thermal performance of phase change material/mini-channel coupled battery thermal management system," Applied Energy, Elsevier, vol. 164(C), pages 659-669.
    9. Wang, Weilong & Yang, Xiaoxi & Fang, Yutang & Ding, Jing & Yan, Jinyue, 2009. "Enhanced thermal conductivity and thermal performance of form-stable composite phase change materials by using [beta]-Aluminum nitride," Applied Energy, Elsevier, vol. 86(7-8), pages 1196-1200, July.
    10. Yang, Xiaohu & Feng, Shangsheng & Zhang, Qunli & Chai, Yue & Jin, Liwen & Lu, Tian Jian, 2017. "The role of porous metal foam on the unidirectional solidification of saturating fluid for cold storage," Applied Energy, Elsevier, vol. 194(C), pages 508-521.
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