Li Jun Wang
7 Papers
5 Citations
Li Jun Wang is an academic researcher. The author has contributed to research in topics: Heat transfer & Building envelope. The author has an hindex of 1, co-authored 6 publications.
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Papers
Effect of the Additive on Thermal Conductivity of the Phase Change Material
TL;DR: In this paper, the effect of expanded graphite on the thermal conductivity of phase change material was investigated and it was shown that expanded graphitic graphite which can be dispersed evenly in the composite phase change materials significantly improves the thermal stability.
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The Study of the Evaporative Condensation Heat Processing Schema Based on Utilization of the Exhaust Air
Rui Hai Wang,Li Jun Wang,Yu Wang,Wei Hua Li,Lu Yan Sui,Yong Li,Bo Wang,Feng Jiang,Xing Bin Xu +8 more
TL;DR: In this article, a new condensation heat processing schema was proposed, which is based on the theoretical analysis results that the condensation Heat should be transferred to the exotic environment, and the main idea of the proposal is utilizing exhaust air of the ventilation system and applying evaporative heat transferring mode.
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Effect of Latent Heat to Solidification Process of Phase Change Material
Jinfeng Mao,Wei Hua Li,Yong Li,Bo Wang,Dong Dong Lou,Dong Yi Zi,Guo Zheng Jiang,Li Jun Wang,Lu Yan Sui +8 more
TL;DR: In this paper, the phase change heat transfer process was analyzed both from theoretical and experimental, and the effect of initial temperature and the latent heat of the heat transfer material were both considered.
1
Simulation of Dynamic Heat Load for Underground Structure Envelope
TL;DR: In this article, the authors analyzed the mechanisms of dynamic heat transfer in the underground works envelope and the simplified calculation method for heat transfer with the cooperative function of MATLAB, Simulink and COMSOL.
1
2-D Numerical Analysis of Combined Heat and Mass Transfer in Straight Rectangular Fin with Natural Convection
Bo Wang,Jinfeng Mao,Li Jun Wang +2 more
TL;DR: In this article, the performance of straight rectangular fin with the psychometric correlations given by Hyland and Wexler when subjected to simultaneous heat and mass transfer was analyzed and numerical solutions were obtained for the fin efficiency and 2-D temperature distribution with SOR method when the fin surface is dry, fully wet and partially wet.
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