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Yuhang Fang, J. Niu, S. Deng (2018)
Numerical analysis for maximizing effective energy storage capacity of thermal energy storage systems by enhancing heat transfer in PCMEnergy and Buildings, 160
(2012)
The first Russian production of diatomite fillers will be launched
Yu-Jen Chiu, Wei‐Mon Yan, H. Chiu, Jer‐Huan Jang, Guang-Ya Ling (2018)
Investigation on the thermophysical properties and transient heat transfer characteristics of composite phase change materialsInternational Communications in Heat and Mass Transfer
J. Jaguemont, N. Omar, P. Bossche, J. Mierlo (2018)
Phase-change materials (PCM) for automotive applications: A reviewApplied Thermal Engineering, 132
A. Tokuç, Tahsin Başaran, S. Yesügey (2015)
An experimental and numerical investigation on the use of phase change materials in building elements: The case of a flat roof in IstanbulEnergy and Buildings, 102
T. Dolley (2021)
DiatomiteEncyclopedic Dictionary of Archaeology
No. RU Patent RF (2006)
Patent RF, No. RU 2276178 C1, 2006, A.A. Emelyanov, V.A. Poluboyarov, V.P. Prokhorov, Z.A. Korotaeva, M.G. Makarenko, N.Z. Lyakhov, Heat storage material and solar energy converter based on it.
L. Royon, L. Karim, A. Bontemps (2014)
Optimization of PCM embedded in a floor panel developed for thermal management of the lightweight envelope of buildingsEnergy and Buildings, 82
O. Castro-Orgaz, W. Hager (2019)
and sShallow Water Hydraulics
E. Vasil’ev, V. Derevyanko (2018)
The dynamics of phase changes in a heat storage of thermal control system for onboard radio-electronic equipmentThermophysics and Aeromechanics, 25
The first Russian production of diatomite fillers will be launched in V.A. Melnichenko (2012)
Chemical J
S. Patankar (2018)
Numerical Heat Transfer and Fluid FlowLecture Notes in Mechanical Engineering
citation_title=Geological Encyclopedia, citation_publication_date= (2010)
Geological Encyclopedia
Peifeng Huang, A. Verma, D. Robles, Qingsong Wang, P. Mukherjee, Jinhua Sun (2018)
Probing the cooling effectiveness of phase change materials on lithium-ion battery thermal response under overcharge conditionApplied Thermal Engineering, 132
Wei Li, Z. Qu, Yanan He, Y. Tao (2014)
Experimental study of a passive thermal management system for high-powered lithium ion batteries using porous metal foam saturated with phase change materialsJournal of Power Sources, 255
Alexander Rovira, Nicolas Müller, Weiwen Deng, Chudi Ndubaku, Richmond Sarpong (2019)
Bio-inspired synthesis of xishacorenes A, B, and C, and a new congener from fuscol† †Electronic supplementary information (ESI) available. See DOI: 10.1039/c9sc02572cChemical Science, 10
(2018)
den Bossche, and J
Li Zhu, Yang Yang, Sarula Chen, Yong Sun (2018)
Numerical study on the thermal performance of lightweight temporary building integrated with phase change materialsApplied Thermal Engineering
Farah Souayfane, F. Fardoun, P. Biwole (2016)
Phase change materials (PCM) for cooling applications in buildings: A reviewEnergy and Buildings, 129
D. Lafri, D. Semmar, A. Hamid, M. Ouzzane (2019)
Experimental investigation on combined sensible and latent heat storage in two different configurations of tank filled with PCMApplied Thermal Engineering
Farah Souayfane, P. Biwole, F. Fardoun (2018)
Melting of a phase change material in presence of natural convection and radiation: A simplified ModelApplied Thermal Engineering, 130
M. Kenisarin, K. Mahkamov (2016)
Passive thermal control in residential buildings using phase change materialsRenewable & Sustainable Energy Reviews, 55
Rami Zeinelabdein, S. Omer, G. Gan (2018)
Critical review of latent heat storage systems for free cooling in buildingsRenewable & Sustainable Energy Reviews, 82
Abstract A new composite phase change material based on porous diatomite, saturated with paraffin by immersion method, has been developed. The results of the study of heat propagation in this material heated from one side with a constant power source are presented. On the basis of the enthalpy model, numerical computations were carried out, a comparison with the experimental results was made, and the influence of the properties of the composite material on the thermal processes in it was analyzed. In the computations, the heat flux power, the phase transition temperature range, and the characteristics of the phase change material were varied. The analysis of the computation results has shown that the use of the phase change material allows not only increasing the heat-storage capacity of the composite material, but also controlling the heat fluxes. As a result, it becomes possible to reduce the peak values of the heat flux passing through the material and to limit the material temperature range during heating for a long time.
Thermophysics and Aeromechanics – Springer Journals
Published: May 1, 2019
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