Pore-scale study on Rayleigh-Bénard convection formed in the melting process of metal foam composite phase change material
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[1] S. Ahmadi,et al. Increasing the electrical efficiency and thermal management of a photovoltaic module using expanded graphite (EG)/paraffin-beef tallow-coconut oil composite as phase change material , 2021 .
[2] Zhengguo Zhang,et al. Phase change material coat for battery thermal management with integrated rapid heating and cooling functions from −40 °C to 50 °C , 2021 .
[3] Pushpendra Kumar Singh Rathore,et al. Enhanced thermophysical properties of organic PCM through shape stabilization for thermal energy storage in buildings: A state of the art review , 2021 .
[4] Dawei Tang,et al. Influence of fin parameters on the melting behavior in a horizontal shell-and-tube latent heat storage unit with longitudinal fins , 2021 .
[5] Jiafei Zhao,et al. Simulation of forced convective heat transfer in Kelvin cells with optimized skeletons , 2021 .
[6] Jiafei Zhao,et al. Comparison of forced convective heat transfer between pillar and real foam structure under high Reynolds number , 2021 .
[7] Ya-Ling He,et al. Design of non-uniformly distributed annular fins for a shell-and-tube thermal energy storage unit , 2020 .
[8] Hongyi Gao,et al. Smart Utilization of Multifunctional Metal Oxides in Phase Change Materials , 2020, Matter.
[9] Dawei Tang,et al. Pore-scale investigation on the heat-storage characteristics of phase change material in graded copper foam , 2020 .
[10] X. Duan,et al. Effects of nanoparticles on phase change heat transfer rate in the presence of Rayleigh–Benard convection , 2020 .
[11] H. Ali,et al. Nanoparticles enhanced phase change materials (NePCMs)-A recent review , 2020 .
[12] H. Bahai,et al. Energy recovery from domestic radiators using a compact composite metal Foam/PCM latent heat storage , 2020, Journal of Cleaner Production.
[13] X. Duan,et al. Numerical and Experimental Investigation of Phase Change Heat Transfer in the Presence of Rayleigh–Benard Convection , 2020 .
[14] Jiafei Zhao,et al. Pore-scale simulation of forced convection heat transfer under turbulent conditions in open-cell metal foam , 2020, Chemical Engineering Journal.
[15] X. Sui,et al. Shape-stabilized hydrated salt/paraffin composite phase change materials for advanced thermal energy storage and management , 2020 .
[16] Chunwei Zhang,et al. Performance evaluation and analysis of a vertical heat pipe latent thermal energy storage system with fins-copper foam combination , 2020 .
[17] A. K. Pathak,et al. Thermal performance of phase change material integrated heat pipe evacuated tube solar collector system: An experimental assessment , 2020, Energy Conversion and Management.
[18] Ruzhu Wang,et al. High energy-density and power-density thermal storage prototype with hydrated salt for hot water and space heating , 2019, Applied Energy.
[19] Hao Peng,et al. Solidification performance of a latent heat storage unit with innovative longitudinal triangular fins , 2019, International Journal of Heat and Mass Transfer.
[20] Emmanuel C. Nsofor,et al. Hybrid heat transfer enhancement for latent-heat thermal energy storage systems: A review , 2019, International Journal of Heat and Mass Transfer.
[21] W. Yan,et al. A critical review on heat transfer augmentation of phase change materials embedded with porous materials/foams , 2019, International Journal of Heat and Mass Transfer.
[22] H. Bao,et al. Magnetically-accelerated large-capacity solar-thermal energy storage within high-temperature phase-change materials , 2019, Energy & Environmental Science.
[23] X. Gong,et al. Pore-scale numerical simulation of the thermal performance for phase change material embedded in metal foam with cubic periodic cell structure , 2019, Applied Thermal Engineering.
[24] Wei Yang,et al. High-performance composite phase change materials for energy conversion based on macroscopically three-dimensional structural materials , 2019, Materials Horizons.
[25] Hongyi Gao,et al. Shape-stabilized phase change materials based on porous supports for thermal energy storage applications , 2019, Chemical Engineering Journal.
[26] V. Jain,et al. Performance evaluation of nano-enhanced phase change materials during discharge stage in waste heat recovery , 2018, Renewable Energy.
[27] S. Madruga,et al. Dynamic of plumes and scaling during the melting of a Phase Change Material heated from below , 2017, International Journal of Heat and Mass Transfer.
[28] Romeu Vicente,et al. Phase change materials and carbon nanostructures for thermal energy storage: A literature review , 2017 .
[29] Liwu Fan,et al. A pore-scale visualized study of melting heat transfer of a paraffin wax saturated in a copper foam: Effects of the pore size , 2017 .
[30] Huiying Wu,et al. Pore scale investigation of heat conduction of high porosity open-cell metal foam/paraffin composite , 2017 .
[31] Wei Li,et al. The effect of pore size and porosity on thermal management performance of phase change material infiltrated microcellular metal foams , 2014 .
[32] R. Ruoff,et al. Enhanced thermal conductivity of phase change materials with ultrathin-graphite foams for thermal energy storage , 2014 .
[33] M. Rosen,et al. Analytical modeling of PCM solidification in a shell and tube finned thermal storage for air conditioning systems , 2012 .
[34] W. Tao,et al. Experimental and numerical studies on melting phase change heat transfer in open-cell metallic foams filled with paraffin , 2012 .
[35] T. L. Bergman,et al. Enhancement of latent heat energy storage using embedded heat pipes , 2011 .
[36] Francis Agyenim,et al. A review of materials, heat transfer and phase change problem formulation for latent heat thermal energy storage systems (LHTESS) , 2010 .
[37] J. Murthy,et al. Simulation of Thermal Transport in Open-Cell Metal Foams: Effect of Periodic Unit-Cell Structure , 2008 .
[38] C. Druma,et al. Analysis of thermal conduction in carbon foams , 2004 .
[39] Hasan Karabay,et al. Melting of nanoparticle-enhanced paraffin wax in a rectangular enclosure with partially active walls , 2017 .