胡成志 - 大连理工大学 - 能源与动力学院

个人简介

教育经历 2010.9 -- 2016.10 大连理工大学工程热物理博士 2006.9 -- 2010.7 哈工大（威海）热能与动力工程学士工作经历 2017.5 -- 至今大连理工大学讲师

研究领域

新型高强度换热器件传热机理、器件开发及在电子散热方面的应用功能流体流动传热的多尺度耦合研究内燃机关键部件润滑摩擦传热耦合问题研究

近期论文

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Hu, C.; Pei, Z.; Shi, L.; Tang, D.; Bai, M., Phase transition properties of thin liquid films with various thickness on different wettability surfaces. International Communications in Heat and Mass Transfer 2022, 135, 106125. Hu, C.; Shi, L.; Yi, C.; Bai, M.; Li, Y.; Tang, D., Mechanism of enhanced phase-change process on structured surface: Evolution of solid-liquid-gas interface. International Journal of Heat and Mass Transfer 2023, 205, 123915. Hu, C.; Tang, D.; Lv, J.; Bai, M.; Zhang, X., Molecular dynamics simulation of frictional properties of Couette flow with striped superhydrophobic surfaces under different loads. Physical Chemistry Chemical Physics 2019, 21 (32), 17786-17791. Hu, C.; Li, H.; Tang, D.; Zhu, J.; Wang, K.; Hu, X.; Bai, M., Pore-scale investigation on the heat-storage characteristics of phase change material in graded copper foam. Applied Thermal Engineering 2020, 178, 115609. Hu, C.; Sun, M.; Xie, Z.; Yang, L.; Song, Y.; Tang, D.; Zhao, J., Numerical simulation on the forced convection heat transfer of porous medium for turbine engine heat exchanger applications. Applied Thermal Engineering 2020, 180, 115845. Hu, C.; Li, H.; Wang, Y.; Hu, X.; Tang, D., Experimental and numerical investigations of lithium-ion battery thermal management using flat heat pipe and phase change material. J. Energy Storage 2022, 55, 105743. Hu, C.; Lv, J.; Bai, M.; Zhang, X.; Tang, D., Molecular dynamics simulation of effects of nanoparticles on frictional heating and tribological properties at various temperatures. Friction 2020, 8 (3), 531-541. Wang, K.; Hu, C.; Cai, Y.; Li, Y.; Tang, D., Investigation of heat transfer and flow characteristics in two-phase loop thermosyphon by visualization experiments and CFD simulations. International Journal of Heat and Mass Transfer 2023, 203, 123812. Wang, K.; Hu, C.; Jiang, B.; Hu, X.; Tang, D., Numerical simulation on the heat transfer characteristics of two-phase loop thermosyphon with high filling ratios. International Journal of Heat and Mass Transfer 2022, 184, 122311. He, Y.; Hu, C.; Li, H.; Hu, X.; Tang, D., Experimental investigation on air-cooling type loop thermosyphon thermal characteristic with serpentine tube heat exchanger. International Journal of Refrigeration 2022, 138, 52-60. He, Y.; Hu, C.; Li, H.; Hu, X.; Tang, D., Visualized-experimental investigation on a mini-diameter loop thermosyphon with a wide range of filling ratios. International Communications in Heat and Mass Transfer 2022, 133, 105973. He, Y.; Hu, C.; Li, H.; Jiang, B.; Hu, X.; Wang, K.; Tang, D., A flexible image processing technique for measuring bubble parameters based on a neural network. Chemical Engineering Journal 2022, 429, 132138. He, Y.; Hu, C.; Li, H.; Hu, X.; Tang, D., Reliable predictions of bubble departure frequency in subcooled flow boiling: A machine learning-based approach. International Journal of Heat and Mass Transfer 2022, 195, 123217. He, Y.; Sun, Z.; Hu, C.; Wang, Z.; Li, H.; Yin, Z.; Tang, D., Data-driven engineering descriptor and refined scale relations for predicting bubble departure diameter. International Journal of Heat and Mass Transfer 2022, 195, 123078. He, Y.; Hu, C.; Hu, X.; Xu, H.; Tang, D., Assessment of the two-phase thermosyphon loop with high filling ratio under anti-gravity. International Journal of Heat and Mass Transfer 2023, 206, 123968. He, Y.; Hu, C.; Jiang, B.; Sun, Z.; Ma, J.; Li, H.; Tang, D., Data-driven approach to predict the flow boiling heat transfer coefficient of liquid hydrogen aviation fuel. Fuel 2022, 324, 124778. Shi, L.; Hu, C.; Yi, C.; Lyu, J.; Bai, M.; Tang, D., A study of interface evolution-triggering different nucleate boiling heat transfer phenomenon on the structured surfaces. International Journal of Heat and Mass Transfer 2022, 190, 122754. Shi, L.; Hu, C. Z.; Yi, C. L.; Bai, M. L.; Lyu, J. Z.; Gao, L. S., A study of how solid-liquid interactions affect flow resistance and heat transfer at different temperatures based on molecular dynamics simulations. Physical Chemistry Chemical Physics 2022, 25 (1), 813-821. Yin, X.; Hu, C.; Bai, M.; Lv, J., Effects of depositional nanoparticle wettability on explosive boiling heat transfer: A molecular dynamics study. International Communications in Heat and Mass Transfer 2019, 109, 104390. Yin, X.; Hu, C.; Bai, M.; Lv, J., Molecular dynamic simulation of rapid boiling of nanofluids on different wetting surfaces with depositional nanoparticles. International Journal of Multiphase Flow 2019, 115, 9-18. Yin, X.; Bai, M.; Hu, C.; Lv, J., Molecular dynamics simulation on the effect of nanoparticle deposition and nondeposition on the nanofluid explosive boiling heat transfer. Numerical Heat Transfer, Part A: Applications 2018, 73 (8), 553-564. Hu, C.; Tang, D.; Lv, J.; Bai, M.; Zhang, X., Molecular dynamics simulation of frictional properties of Couette flow with striped superhydrophobic surfaces under different loads. Physical Chemistry Chemical Physics 2019, 21 (32), 17786-17791. Yin, X.; Hu, C.; Bai, M.; Lv, J., An investigation on the heat transfer characteristics of nanofluids in flow boiling by molecular dynamics simulations. International Journal of Heat and Mass Transfer 2020, 162, 120338. Lyu, J.; Gao, L.; Zhang, Y.; Bai, M.; Li, Y.; Gao, D.; Hu, C., Dynamic spreading characteristics of droplet on the hydrophobic surface with microstructures. Colloids and Surfaces a-Physicochemical and Engineering Aspects 2021, 610. Yi, C.; Hu, C.; Shi, L.; Bai, M.; Lv, J., Wettability of complex Long-Chain alkanes droplets on Pillar-type surfaces. Applied Surface Science, 2021; Vol. 566, p 150752. Sun, M.; Hu, C.; Zha, L.; Xie, Z.; Yang, L.; Tang, D.; Song, Y.; Zhao, J., Pore-scale simulation of forced convection heat transfer under turbulent conditions in open-cell metal foam. Chemical Engineering Journal 2020, 389, 124427. Li, H.; Hu, C.; He, Y.; Tang, D.; Wang, K.; Hu, X., Visualized-experimental investigation on the energy storage performance of PCM infiltrated in the metal foam with varying pore densities. Energy 2021, 237, 121540. Li, H.; Hu, C.; He, Y.; Tang, D.; Wang, K.; Hu, X., Influence of model inclination on the melting behavior of graded metal foam composite phase change material: A pore-scale study. J. Energy Storage 2021, 44, 103537. Li, H.; Hu, C.; He, Y.; Tang, D.; Wang, K.; Huang, W., Effect of perforated fins on the heat-transfer performance of vertical shell-and-tube latent heat energy storage unit. J. Energy Storage 2021, 39, 102647. Li, H. Y.; Hu, C. Z.; He, Y. C.; Tang, D. W.; Wang, K. M., Influence of fin parameters on the melting behavior in a horizontal shell-and-tube latent heat storage unit with longitudinal fins. J. Energy Storage 2021, 34, 11 Sun, M.; Li, M.; Hu, C.; Yang, L.; Song, Y.; Tang, D.; Zhao, J., Comparison of forced convective heat transfer between pillar and real foam structure under high Reynolds number. Applied Thermal Engineering 2021, 182, 116130. Sun, M.; Yang, L.; Hu, C.; Zhao, J.; Tang, D.; Song, Y., Simulation of forced convective heat transfer in Kelvin cells with optimized skeletons. International Journal of Heat and Mass Transfer 2021, 165, 120637. Li, H.; Hu, C.; He, Y.; Sun, Z.; Yin, Z.; Tang, D., Emerging surface strategies for porous materials-based phase change composites. Matter 2022, 5 (10), 3225-3259. Li, H.; Hu, C.; He, Y.; Wang, K.; Tang, D., Pore-scale study on Rayleigh-Bénard convection formed in the melting process of metal foam composite phase change material. International Journal of Thermal Sciences 2022, 177, 107572.= Li, H.; Hu, C.; He, Y.; Zhu, J.; Liu, H.; Tang, D., A synergistic improvement in heat storage rate and capacity of nano-enhanced phase change materials. International Journal of Heat and Mass Transfer 2022, 192, 122869. Li, H.; Hu, C.; Wang, H.; He, Y.; Hu, X.; Tang, D., Thermal effect of nanoparticles on the metal foam composite phase change material: A pore-scale study. International Journal of Thermal Sciences 2022, 179, 107709. Sun, M.; Yan, G.; Ning, M.; Hu, C.; Zhao, J.; Duan, F.; Tang, D.; Song, Y., Forced convection heat transfer: A comparison between open-cell metal foams and additive manufactured kelvin cells. International Communications in Heat and Mass Transfer 2022, 138, 106407. Sun, M.; Zhang, L.; Hu, C.; Zhao, J.; Tang, D.; Song, Y., Forced convective heat transfer in optimized kelvin cells to enhance overall performance. Energy 2022, 242, 122995. Li, H.; Hu, C.; Jiang, Y.; He, Y.; Tang, D., Improved body-centered cubic unit for accurately predicting the melting characteristics of metal foam composite phase change material. International Journal of Heat and Mass Transfer 2023, 201, 123635. Sun, M.; Yan, G.; Hu, C.; Zhao, J.; Duan, F.; Song, Y., Thermal and hydraulic behaviours of Kelvin cells from metallic three-dimensional printing. Applied Thermal Engineering 2023, 219.