amjs澳金沙门欢迎您

师资队伍

teaching staff

站内搜索

姓 名 刘志春 性 别
职 称 教授(博导) 毕业学校
个人主页 http://tsl.energy.hust.edu.cn
联系方式 027-87542618
邮 箱 zcliu@hust.edu.cn
通讯地址 amjs澳金沙门线路首页动力楼318
个人资料简介
刘志春,华中科技大学二级教授,博士生导师,入选国家级高层次人才计划,amjs澳金沙门线路首页工程热物理系主任,兼任工程热物理系实验室主任。2006年毕业于华中科技大学工程热物理专业,获得博士学位。2011年11月至2012年12月在MIT机械系陈刚教授课题组访学。2014年11月晋升为教授。学术兼职:兼任中国工程热物理学会传热传质分会青年工作委员会委员、中国工程热物理学会热管专业组委员、中国复合材料学会导热复合材料专业委员会委员,中国机械工程学会压力容器分会换热器委员会委员,《节能技术》、《Processes》编委,国家自然科学基金地区合作项目会评专家,国家自然科学基金通讯评议专家等。主要研究方向:电子器件散热与控制技术、传热强化理论与技术、质子交换燃料电池中的水、热管理以及微纳尺寸下能量传递与转换。科研方面,主持或完成包括国防预研项目、国家自然科学基金、国家重点研发计划子课题项目以及“863”重点项目子课题等国家或者省部级课题10余项,以及包括航天一院、航天八院、中船701所、中电29所、华为、中兴、格力电器、申菱空调等企业和科研院所合作项目十余项,作为技术骨干主要参与了包括国家“973”计划子课题、国家自然科学基金重点等国家及省部级项目十余项。获授权发明专利22项,在国内外重要期刊及会议上发表240余篇学术论文,其中SCI收录190余篇。获国家自然科学二等奖(2020,排名2),教育部科技进步一等奖1项(2016,排名3),湖北省自然科学一等奖(2019,排名2),青岛市科技进步二等奖2项(2017,排名3;2007,排名5),山东省科技进步三等奖1项(2008, 排名5)。

教育及工作经历

    2011年12月~2012年12月:美国MIT机械系访问学者,合作教授为陈刚教授;
    2014年11月~至今:amjs澳金沙门线路首页,教授
    2009年11月~2014年10月:amjs澳金沙门线路首页,副教授;
    2006年5月~2009年11月:amjs澳金沙门线路首页教师;
    2002.9~2006.6:amjs澳金沙门线路首页,工程热物理专业,攻读博士学位;1999.9~2002.6:青岛科技大学机械工程学院,化工过程机械,攻读硕士学位;
    1995.9~1999.6:石油大学(华东)机械系,化工设备与机械,本科

研究方向

    电子器件散热与控制技术;传热强化理论与技术;质子交换燃料电池中的水、热管理;微纳尺寸下能量传递与转换。

科研项目

    [1]国家重点研发计划项目课题,多物理场耦合规律及宽域快响应水热管理技术,2022.12-2025.11,360万,主持,在研
    [2]中船719所,电力变换设备散热设计优化研究,2023.5-2023.12,89万元,主持
    [3]航天一院,多目标多参数热管理系统仿真方法与结构换热一体化样机研究,2022年,75万,主持,在研
    [4]KZ“十三五”YY项目,XXX热管技术;2019.1-2021.6,200万,主持
    [5]国家自然科学基金面上项目,基于微纳多孔介质相变的高性能低品位热传输及转换系统研究,52076088,2021-2024,58万,主持,在研
    [6]湖北迪峰换热器股份有限公司,高效换热器智能化设计软件,160万,2021年
    [7]佛山市顺德区核心技术攻关项目,VOCs冷凝回收高端装备换热技术研究与应用,50万元,华中科技大学负责人,2021年
    [8]佛山市顺德区核心技术攻关项目,高密度电气器件平板环路热管间接散热系统,35万,华中科技大学负责人,2020年
    [9]国家自然科学基金面上项目,基于新型高效掺杂物和3D-1D-2D/3D定向成型的高导热聚合物材料的热输运机理探究与实验研究,51776079  2018/01-2021/12,61万,主
    [10]国家重点研发计划子课题项目:基于大颗粒掺混/微细粉体二次泳动耦合的直接传热强化技术,2017-2020,50万,主持,在研
    [11]GF横向课题,电气XXXX冷却装置研制,255.5万,2020-2021,主持
    [12]中兴通讯股份公司产学研项目,XXX自动化仿真技术,2019.07-2020.5,45万,主持,结题
    [13]中车青岛四方车辆研究所有限公司, XXX两相流换热系统设计、仿真与优化,2019.9-2021.12, 44.8万,主持
    [14]中船重工701所,XXX冷却装置研制,71万,在研,主持
    [15]中船重工701所,热管XXXX模拟研究,52万,在研,主持
    [16]中船重工701所,XXX模拟装置,18万,在研,主持
    [17]中国运载火箭研究院,相变蓄热与半导体制冷散热系统集成研究,39万,在研,主持
    [18]国家自然科学基金重点项目:基于斯特林热机的能量转换与传递过程基础问题研究,2018-2022,292万,参加,在研
    [19]国家自然科学基金面上项目,51376069,基于减阻与耗散理论的聚合物材料换热器及其传热元件的优化设计理论与实验研究,80万,20114/01-2017/12,主持,结题
    [20]国家“863”计划重点项目子课题,2012AA1106016,34.8万,燃料电池中的传热传质模拟研究,2012/01-2014/12,主持,已结题
    [21]航天支撑技术基金项目,6万,高性能小型双蒸发器平板式环路热管系统的理论和实验研究,2014/01-2016.12,主持,已结题
    [22]国家自然科学基金青年项目,50906026,20万,双孔径多孔介质相变传热与流动机理分析及其散热系统研究,主持,已结题
    [23]国家自然科学基金面上项目,51276071,85万,泵辅助毛细回路的机理与实验研究,2013/01-2016/12,参加,已结题
    [24]国家自然科学基金重点项目,51036003,235万,先进传热强化理论及机理研究,参加,2011/01-2015/12,参加,已结题
    [25]国家重点基础研究计划“973”计划,2013CB228302,229万,余热能级及梯级利用-的定量化原则及其在热力系统中的应用,2013/01-2017/07,学术骨干,已结题
    [26]华为公司项目:散热系统研究,主持,已结题
    [27]微通道过冷核沸腾机理研究,横向,主持,已结题
    [28]拜耳法生产氧化铝溶出工艺的计算机辅助设计,横向,主持,已结题

代表性论文与专利


    代表性论文与专利
    论文:
    2023年
    [1]Yifan Zhang, Ji Li, Zikang Zhang, Wei Liu, Zhichun Liu. Enhancing Thermo-Osmotic Low-Grade Heat Recovery by Applying a Negative Pressure to the Feed. Global Challenges,2023,7:2200238.
    [2]Yifan Zhang, Yongxiang Fan, Zhichun Liu, Wei Liu. Experimental and numerical study on two-phase minichannel cold plate for high-power device. Applied Thermal Engineering,2023,230:120704
    [3]Shan Gao, Jian Qu, Zhichun Liu, Weigang Ma. Sequential self-propelled morphology transitions of nanoscale condensates enable a cascade jumping-droplet condensation. Nano Energy,2023,113:108558.
    [4]S.C. Zhao, Zikang Zhang, Runze Zhao, Tong Wu, Xiaoyu Zhang, Z.C. Liu, Wei Liu. An R1234ze(E) loop heat pipe with flat-plate evaporator for cooling electronic devices. Thermal Science and Engineering Progress,2023,42:101935
    [5]Lu Wang, Yanan Zhao, Xi Chen, Rui long, Zhichun Liu, Wei Liu. Experimental study on the effects of salt solution pH on the performance of reverse electrodialysis stack. Process Safety and Environmental Protection, 2023,170:728-737
    [6]Minghui Zhang, Minjie Yu, Zhichun Liu, Zhengkai Tu, Wei Liu. Moisture migration in the cathode GDL of PEMFC under variable physical parameters based on a modified two-fluid model. International Journal of Hydrogen Energy. https://doi.org/10.1016/j.ijhydene.2023.01.055
    [7]Zikang Zhang, Runze Zhao, Shuaicheng Zhao, Hao Zou, Zhichun Liu, Xiaobing Luo, Wei Liu. Performance characteristics of a two-phase pump-assisted loop heat pipe with dual-evaporators in parallel. Thermal Science and Engineering Progress,2023,38:101657. https://doi.org/10.1016/j.tsep.2023.101657
    [8]Zhimin Dong, Qinglin Du, Peng Liu, Zhichun Liu, Wei Liu. A numerical investigation and irreversibility optimization of constantly grooved solar air heates. Renewable Energy,2023,207:629-646. https://doi.org/10.1016/j.renene.2023.03.055
    [9]H.C. Cui, C.Y. Shi, M.J. Yu, Z.K. Zhang, Z.C. Liu, W. Liu. Optimal parameter design of a slot jet impingement/microchannel heat sink base on multi-objective optimization algorithm. Applied Thermal Engineering,2023,227:120452.
    [10]Yancong Qiao, Wei Liu, Zhichun Liu*. Design and optimization study of discrete inclined ribs enhanced bend tube based on “Diamond” active cooling thermal protection systems of hypersonic aircraft. Applied Thermal Engineering,2023,228:120526.

    2022年
    [11]Song He, Zhengyuan Ma, Weizhong Deng, ZiKang Zhang, Ziqi Guo, Wei Liu, Zhichun Liu, Experimental investigation on the start-up performance of a novel flat loop heat pipe with dual evaporators, Energy Reports, 8:7500-7507, 2022.
    [12]Y. Wang, P. Liu, H. Xiao, Z. Liu, W. Liu,Design and optimization on symmetrical wing longitudinal swirl generators in circular tube for laminar flow, International Journal of Heat and Mass Transfer, 193:122961, 2022.
    [13]Li, M., Zhao, Y., Long, R., Liu, Z., Liu, W. Computational fluid dynamic study on the adsorption-based desalination and cooling system (2022) Applied Thermal Engineering, 213:118724, .
    [14]Zhang, J., Wang, J., Li, W., Liu, Z., Kabelac, S., Tao, Z., Ma, L., Tang, W., Sherif, S.A. R410A flow boiling in horizontal annular channels of enhanced tubes, part I: Pressure drop (2022) International Journal of Refrigeration, 137: 70-79.
    [15]Zhao, Y., Li, M., Long, R., Liu, Z., Liu, W. Review of osmotic heat engines for low-grade heat harvesting (2022) Desalination, 527:115571, .
    [16]Chen, X., Luo, Z., Long, R., Liu, Z., Liu, W. Impacts of transmembrane pH gradient on nanofluidic salinity gradient energy conversion (2022) Renewable Energy, 187:440-449.
    [17]Cui, H.C., Xie, J.H., Zhao, R.Z., Wang, M.Z., Liu, Z.C., Liu, W. Thermal-hydraulic performance analysis of a hybrid micro pin–fin, jet impingement heat sink with non-uniform heat flow (2022) Applied Thermal Engineering, 208:118201.
    [18]Li, M., Zhao, Y., Long, R., Liu, Z., Liu, W. Metal foam packed adsorbent bed boosting the performance of the adsorption-based desalination and cooling system (2022) Energy Conversion and Management, 254:115250, .
    [19]Yu, M., Shi, C., Xie, J., Liu, P., Liu, Z., Liu, W. Constructal design of a circular micro-channel Stirling regenerator based on exergy destruction minimization (2022) International Journal of Heat and Mass Transfer, 183:122240, .
    [20]Wu, J., Liu, P., Yu, M., Liu, Z., Liu, W. Thermo-hydraulic performance and exergy analysis of a fin-and-tube heat exchanger with sinusoidal wavy winglet type vortex generators (2022) International Journal of Thermal Sciences, 172:107274, .
    [21]Xie, J.H., Cui, H.C., Liu, Z.C., Liu, W. Optimization design of helical micro fin tubes based on exergy destruction minimization principle (2022) Applied Thermal Engineering, 200:117640, .
    [22]Gao, S., Qu, J., Liu, Z., Liu, W. Nanoscale Thin-Film Boiling Processes on Heterogeneous Surfaces (2022) Langmuir.
    [23]Zhao, R.Z., Li, J., Zhang, Z.K., Long, R., Liu, W., Liu, Z.C. Harvesting net power and desalinating water by pressure-retarded membrane distillation (2022) Science China Technological Sciences, 65 (1):214-220.
    2021年
    [24]Xiaotian Lai , Rui Long, Zhichun Liu, Wei Liu. Solar energy powered high-recovery reverse osmosis for synchronous seawater desalination and energy storage. Energy Conversion and Management,2021,228:113665.
    [25]Minjie Yu, Xiaotian Lai, Hui Xiao, Zhichun Liu, Wei Liu. A study on flow and heat transfer characteristics of a constructal bifurcation filler in the circular tube. Applied Thermal Engineering,2021,183:116205.
    [26]Hui Xiao , Zhichun Liu , Wei Liu. Conjugate heat transfer enhancement in the mini-channel heat sink by realizing the optimized flow pattern.Applied Thermal Engineering,2021,182:116131.
    [27]Yunmin Liang, Biwei Liu, Bo Zhang, Zhichun Liu, Wei Liu. Effects and mechanism of filler surface coating strategy on thermal conductivity of composites: A case study on epoxy/SiO2-coated BN composites. International Journal of Heat and Mass Transfer,2021,163:120533.
    [28]Hui Xiao, Peng Liu, Zhichun Liu, Wei Liu. Performance analyses in parabolic trough collectors by inserting novel inclined curved-twisted baffles. Renewable Energy,2021,165:14-27.
    [29]Zikang Zhang, Runze Zhao, Zhichun Liu, Wei Liu. Application of biporous wick in flat-plate loop heat pipe with long heat transfer distance. Applied Thermal Engineering.
    [30]Minjie Yu, Feng Xin, Xiaotian Lai, Hui Xiao, Zhichun Liu, Wei Liu. Study of oscillating flows through a novel constructal bifurcation Stirling regenerator. Applied Thermal Engineering,2021,184:116413.
    [31]Rui Long, Xiaoxiao Xia, Yanan Zhao, Song Li, Zhichun Liu, Wei Liu. Screening metal-organic frameworks for adsorptiondriven osmotic heat engines via grand canonical Monte Carlo simulations and machine learning. iScience,2021,24:101914.
    [32]Peng Liu, Zhimin Dong, Hui Xiao, Zhichun Liu, Wei Liu. Thermal-hydraulic performance analysis of a novel parabolic trough receiver with double tube for solar cascade heat collection. Energy,2021,219:119566.
    [33]H.C. Cui, X.T. Lai, J.F. Wu, M.Z. Wang, W. Liu, Z.C. Liu. Overall numerical simulation and experimental study of a hybrid oblique-rib and submerged jet impingement/microchannel heat sink. International Journal of Heat and Mass Transfer,2021,167:120839.
    [34]Rui Long, Fan Wu, Xiyu Chen, Zhichun Liu, Wei Liu. Temperature-depended ion concentration polarization in electrokinetic energy conversion. International Journal of Heat and Mass Transfer,2021,168:120842.
    [35]Bo Zhang, Yunmin Liang, Wei Liu, Zhichun Liu. Effects of the Filler Property, Electron-Phonon Coupling on Thermal Conductivity, and Strain Rate on the Mechanical Property of Polyethylene Nanocomposites. The Journal of Physical Chemistry C,2020,124,26001-26011.
    [36]Mingliang Li, Yanan Zhao, Rui Long, Zhichun Liu, Wei Liu. Computational fluid dynamic study on adsorption-based desalination and cooling systems with stepwise porosity distribution. Desalination,2021,508:115048
    [37]Zhimin Dong, Peng Liu, Hui Xiao, Zhichun Liu, Wei Liu. A study on heat transfer enhancement for solar air heaters with ripple surface. Renewable Energy,2021,172:477-487.
    [38]Rui Long, Mingliang Li, Xi Chen, Zhichun Liu, Wei Liu. Synergy analysis for ion selectivity in nanofluidic salinity gradient energy harvesting. International Journal of Heat and Mass Transfer,2021,171:121126.
    [39]Ji Li, Zikang Zhang, Runze Zhao, Bo Zhang, Yunmin Liang, Rui Long, Wei Liu, Zhichun Liu. Stack Thermo-Osmotic System for Low-Grade Thermal Energy Conversion. ACS Applied Materials and Interfaces, 2021,13:21371-21378
    [40]Yanan Zhao, Mingliang Li, Rui Long, Zhichun Liu, Wei Liu. Dynamic modeling and analysis of an advanced adsorption-based osmotic heat engines to harvest solar energy. Renewable Energy, 2021,175:638-649
    [41]Yunmin Liang, Bo Zhang, Zhichun Liu, Wei Liu. Electroless deposition surface engineering of boron nitride sheets for enhanced thermal conductivity and decreased interfacial thermal resistance of epoxy composites. International Journal of Heat and Mass Transfer, 2021,174:121306.
    [42]Chunyu Shi, Miaozhi Wang ,Jun Yang, Wei Liu, Zhichun Liu. Performance analysis and multi-objective optimization for tubes partially filled with gradient porous media. Applied Thermal Engineering, 2021,188:116530.
    [43]Peng Liu, Zhimin Dong ,Hui Xiao ,Zhichun Liu ,Wei Liu. A novel parabolic trough receiver by inserting an inner tube with a wing-like fringe for solar cascade heat collection. Renewable Energy, 2021,170:327-340.
    [44]Feng Xin, Minjie Yu, Wei Liu, Zhichun Liu. Heat transfer characteristics of enhanced cooling tube with a helical wire under oscillatory flow in Stirling engine. International Journal of Thermal Sciences, 2021,168:107063.https://linkinghub.elsevier.com/retrieve/pii/S1290072921002271
    [45]Runze Zhao, Zikang Zhang, Shuaicheng Zhao, Haichuan Cui, Zhichun Liu, Wei Liu. Experimental study of flat-disk loop heat pipe with R1233zd(E) for cooling terrestrial electronics. Applied Thermal Engineering, 2021,197:117385.
    [46]Mingliang Li, Yanan Zhao, Rui Long, Zhichun Liu, Wei Liu. Field synergy analysis for heat and mass transfer characteristics in adsorption-based desalination and cooling systems. Desalination, 2021,517:115244.
    [47]Bing Cai, Weizhong Deng, Tong Wu, Tingting Wang, Zhengyuan Ma, Wei Liu, Lei Ma, Zhichun Liu. Experimental Study of a Loop Heat Pipe with Direct Pouring Porous Wick for Cooling Electronics. Processes, 2021,9,1332.
    [48]Feng Shan, Siyang Qin, Yao Xiao, A. Watanabe, M. Kano, F.Y. Zhou, Z.C. Liu, W. Liu and Y. Tsuji3. Large-scale energetic coherent structures and their effects on wall mass transfer rate behind orifice in round pipe. Journal of Fluid Mechanics, 2021,927.
    [49]Runze Zhao, Ji Li, Zikang Zhang, Rui Long, Wei Liu & ZhiChun Liu*. Harvesting net power and desalinating water by pressure-retarded membrane distillation. SCIENCE CHINA Technological Sciences, 2021.
    2020年
    [50]Ji Li, Rui Long, Bo Zhang, Ronggui Yang, Wei Liu, and Zhichun Liu. Nano Heat Pump Based on Reverse Thermo-osmosis Effect. The Journal Of Physical Chemistry Letters,2020,11,9856-9861.
    [51]Hui Xiao, Zhichun Liu, Wei Liu. Turbulent heat transfer enhancement in the mini-channel by enhancing the original flow pattern with v-ribs. International Journal of Heat and Mass Transfer,2020,163:120378.
    [52]Shicheng Wang, Biao Xiao, Ya Ge, Lin He, Xiang Li, Wei Liu, Zhichun Liu. Optimization design of slotted fins based on exergy destruction minimization coupled with optimization algorithm. International Journal of Thermal Sciences,2020,147:106133.
    [53]Biao Xiao, Weizhong Deng, Zhengyuan Ma, Song He, Lin He, Xiang Li, Fang Yuan, Wei Liu, Zhichun Liu.Experimental investigation of loop heat pipe with a large squared evaporator for multi-heat sources cooling. Renewable Energy,2020,147:239-248.
    [54]Rui Long, Zuoqing Luo, Zhengfei Kuang, Zhichun Liu, Wei Liu. Effects of heat transfer and the membrane thermal conductivity on the thermally nanofluidic salinity gradient energy conversion. Nano Energy,2020,67:104284
    [55]Liangsuo Shu, Xiaokang Liu, Kaifeng Cui, Zhichun Liu, Wei Liu. Fluctuation and inertia. Nuclear Physics B,2020,950:114873.
    [56]Genchun Cai, Yunmin Liang, Zhichun Liu, Wei Liu. Design and optimization of bio-inspired wave-like channel for a PEM fuel cell applying genetic algorithm. Energy,2020,192:116670.
    [57]Rui Long, Yanan Zhao, Zhengfei Kuang, Zhichun Liu, Wei Liu. Hydrodynamic slip enhanced nanofluidic reverse electrodialysis for salinity gradient energy harvesting. Desalination,2020,477:114263.
    [58]J.Y. Lv, Z.C. Liu, W. Liu. Active design for the tube insert of center-connected deflectors based on the principle of exergy destruction minimization. International Journal of Heat and Mass Transfer,2020,150:119260.
    [59]Hao Zhang, Chi Jiang, Zikang Zhang, Zhichun Liu, Xiaobing Luo, Wei Liu. A study on thermal performance of a pump-assisted loop heat pipe with ammonia as working fluid. Applied Thermal Engineering,2020,175:115342.
    [60]Zikang Zhang, Hao Zhang, Xiaotian Lai, Zhichun Liu, Wei Liu. Numerical study on thermohydraulic behavior in compensation chamber of a loop heat pipe with flat evaporator. Applied Thermal Engineering 2020,171:115073
    [61]Zikang Zhang, Hao Zhang, Zhenyuan Ma, Zhichun Liu, Wei Liu. Experimental study of heat transfer capacity for loop heat pipe with flat disk evaporator. Applied Thermal Engineering,2020,173:115183.
    [62]Yanan Zhao, Zuoqing Luo, Rui Long, Zhichun Liu, Wei Liu. Performance evaluations of an adsorption-based power and cooling cogeneration system under different operative conditions and working fluids. Energy,2020,204:117993.
    [63]Hui Xiao, Zhimin Dong, Zhichun Liu, Wei Liu. Heat transfer performance and flow characteristics of solar air heaters with inclined trapezoidal vortex generators. Applied Thermal Engineering,2020,179:115484.
    [64]Peng Liu, Zhimin Dong, Jinyi Lv, Feng Shan, Zhichun Liu, Wei Liu. Numerical study on thermal-hydraulic performance and exergy analysis of laminar oil flow in a circular tube with fluid exchanger inserts. International Journal of Thermal Sciences,2020,153:106365.
    [65]Bo Zhang, Yunmin Liang, Biwei Liu, Wei Liu and Zhichun Liu. Enhancing the Thermo-Mechanical Property of Polymer by Weaving and Mixing High Length–Diameter Ratio Filler. Polymers,2020,12:1255.
    [66]Yanan Zhao, Mingliang Li, Rui Long, Zhichun Liu, Wei Liu. Dynamic modelling and analysis of an adsorption-based power and cooling cogeneration system. Energy Conversion and Management,2020,222:113229.
    [67]Fang Yuan, Wengang Dong, Guangfeng Shen, Yi Li, Wei Liu. Energy flow-based method for analysis and optimization of evaporative cooling and ventilation systems. International Journal of Heat and Mass Transfer,2020,146:118865.
    [68]Si-Yang Qin, Hui Xiao, Yao Xiao, Peng Liu, Fang-Yuan Zhou, Wei Liu, Zhi-Chun Liu, Feng Shan. Experimental investigation of the coherent structures in a spirally corrugated pipe. International Journal of Heat and Fluid Flow,2020,84:108601.
    [69]Song He, Ping Zhou, Zhengyuan Ma, Weizhong Deng, Hao Zhang, Zhaokun Chi, Wei Liu, Zhichun Liu. Experimental study on transient performance of the loop heat pipe with a pouring porous wick. Applied Thermal Engineering,2020,164:114450
    2019年
    [70]Peng Liu, Nianben Zheng, Zhichun Liu, Wei Liu. Thermal-hydraulic performance and entropy generation analysis of a parabolic trough receiver with conical strip inserts. Energy Conversion and Management, 2019, 179:30-45.
    [71]Ping Zhou, Wei Liu, Zhichun Liu. Lattice Boltzmann simulation of nucleate boiling in micro-pillar structured surface. International Journal of Heat and Mass Transfer, 2019,131:1-10.
    [72]Ya Ge, Shicheng Wang, Zhichun Liu, Wei Liu. Optimal shape design of a minichannel heat sink applying multi-objective optimization algorithm and three-dimensional numerical method. Applied Thermal Engineering, 2019,148:120-128.
    [73]Yifan Wang, Peng Liu, Feng Shan, Zhichun Liu, Wei Liu. Effect of longitudinal vortex generator on the heat transfer enhancement of a circular tube. Applied Thermal Engineering, 2019,148:1018-1028
    [74]Xinting Wang, Yunmin Liang, Yue Sun, Zhichun Liu, Wei Liu. Experimental and numerical investigation on shell-side performance of a double shell-pass rod baffle heat exchanger. International Journal of Heat and Mass Transfer, 2019,132:631-642.
    [75]Henan Sun, Ya Ge, Wei Liu, Zhichun Liu. Geometric optimization of two-stage thermoelectric generator using genetic algorithms and thermodynamic analysis. Energy, 2019,171:37-48.
    [76]W. Liu, P. Liu, Z.M. Dong, K. Yang, Z.C. Liu. A study on the multi-field synergy principle of convective heat and mass. International Journal of Heat and Mass Transfer, 2019,134:722-734.
    [77]Zhengfei Kuang, Dijing Zhang, Yuemin Shen, Rui Long, Zhichun Liu, Wei Liu. Bioinspired fractal nanochannels for high-performance salinity gradient energy conversion. Journal of Power Sources, 2019,418:33-41.
    [78]Rui Long, Xiaotian Lai, Zhichun Liu, Wei Liu. Pressure retarded osmosis: Operating in a compromise between power density and energy efficiency. Energy, 2019,172:592-598.
    [79]Liangsuo Shu, Kaifeng Cui, Xiaokang Liu, Zhichun Liu, and Wei Liu. Surface Tension of the Black Hole Horizon. Fortschritte der Physik, 2019,1800076:1-5.
    [80]Hui Xiao, Junbo Wang, Zhichun Liu, Wei Liu. Turbulent heat transfer optimization for solar air heater with variation method based on exergy destruction minimization principle. International Journal of Heat and Mass Transfer, 2019,136:1096-1105.
    [81]Peng Liu, Jinyi Lv, Feng Shan, Zhichun Liu, Wei Liu. Effects of rib arrangements on the performance of a parabolic trough receiver with ribbed absorber tube. Applied Thermal Engineering, 2019,156:1-13.
    [82]Dongdong Dai, Zhichun Liu, Fang Yuan, Rui Long, Wei Liu. Finite time thermodynamic analysis of a solar duplex Stirling refrigerator. Applied Thermal Engineering, 2019,156:597-605.
    [83]Song He, Zhichun Liu, DongDong Wang, Wei Liu, Jinguo Yang. Effect of different charge ratios on transient performance of a flat type of the LHP with a shared compensation chamber. International Journal of Heat and Mass Transfer, 2019,138:1075-1081.
    [84]Ya Ge, Feng Xin, Yao Pan, Zhichun Liu. Optimal arrangement design of a tube bundle in cross-flow using computational fluid dynamics and multi-objective genetic algorithm. Journal of Heat Transfer, 2019,141,071801.
    [85]Henan Sun, Sergio Uson Gil, Wei Liu, Zhichun Liu. Structure optimization and exergy analysis of a two-stage TEC with two different connections. Energy, 2019,180:175-191.
    [86]Xiaotian Lai, Minjie Yu, Rui Long, Zhichun Liu, Wei Liu. Clean and stable utilization of solar energy by integrating dish solar Stirling engine and salinity gradient technology. Energy, 2019,182:802-813.
    [87]Wei Tian, Song He, Zhichun Liu, Wei Liu.Experimental investigation of a miniature loop heat pipe with eccentric evaporator for cooling electronics. Applied Thermal Engineering, 2019,159,113982.
    [88]Xiaotian Lai, Minjie Yu, Rui Long, Zhichun Liu, Wei Liu. Dynamic performance analysis and optimization of dish solar Stirling engine based on a modified theoretical model. Energy, 2019,183:573-583.
    [89]Ping Zhou, Zhichun Liu, Wei Liu, Xili Duan. LBM simulates the effect of sole nucleate site geometry on pool boiling. Applied Thermal Engineering, 2019,160:114027.
    [90]Jun Shen, Liping Zeng, Zhengkai Tu, Zhichun Liu & Wei Liu. Numerical investigation of temperature distribution of proton exchange membrane fuel cells at high current density. Journal of Porous Media, 2019,22(7):813-829.
    [91]Dongdong Dai, Zhichun Liu, Rui Long, Fang Yuan, Wei Liu. An irreversible Stirling cycle with temperature difference both in non-isothermal and isochoric processes. Energy, 2019,186,115875.
    [92]Bo Zhang, Ji Li, Shan Gao, Wei Liu, and Zhichun Liu. Comparison of thermomechanical properties for weaved polyethylene and its nanocomposite based on the CNT junction by molecular dynamics simulation. The Journal of Physical Chemistry C, 2019,123:19412-19420.
    [93]Yunmin Liang, Peng Liu, Nianben Zheng, Feng Shan, Zhichun Liu, Wei Liu. Numerical investigation of heat transfer and flow characteristics of laminar flow in a tube with center-tapered wavy-tape insert. Applied Thermal Engineering, 2019,148:557-567.
    [94]Biao Xiao, Weizhong Deng, Zhengyuan Ma, Song He, Lin He, Xiang Li, Fang Yuan, Wei Liu, Zhichun Liu.Experimental investigation of loop heat pipe with a large squared evaporator for multi-heat sources cooling. Renewable Energy,2019,147:239-248
    [95]Ji Li, Shan Gao, Rui Long, Wei Liu, Zhichun Liu. Self-pumped evaporation for ultra-fast water desalination and power generation. Nano Energy, 2019,65,104059
    [96]Bo Zhang, Peng Mao, Yunming Liang, Yan He, Wei Liu, Zhichun Liu. Modulating Thermal Transport in Polymers and Interfaces: Theories, Simulations, and Experiments. Energy & Environment,2019,5,37-55
    2018年
    [97]Liu P, Zheng N, Shan F, Liu Z, Liu W. An experimental and numerical study on the laminar heat transfer and flow characteristics of a circular tube fitted with multiple conical strips inserts. International Journal of Heat and Mass Transfer, 2018, 117:691-709.
    [98]Ge Y, Shan F, Liu Z, Liu W. Optimal Structural Design of a Heat Sink With Laminar Single-Phase Flow Using Computational Fluid Dynamics-Based Multi-Objective Genetic Algorithm. Journal of Heat Transfer, 2018, 140(2):022803.
    [99]Shan Gao, Quanwen Liao, Wei Liu, Liu Zhichun. Coalescence-Induced Jumping of Nanodroplets on Textured Surfaces. The Journal of Physical Chemistry Letters, 2018, 9:13-18.
    [100]Hui Xiao, Junbo Wang, Zhichun Liu, Wei Liu. A consistent SIMPLE algorithm with extra explicit prediction — SIMPLEPC. International Journal of Heat and Mass Transfer, 2018, 120:1255-1265
    [101]Rui Long, Zhichun Liu, Wei Liu. Performance analysis for minimally nonlinear irreversible refrigerators at finite cooling power. Physica A, 2018, 496:137-146. ‍
    [102]Ya Ge, Zhichun Liu, Henan Sun, Wei Liu. Optimal design of a segmented thermoelectric generator based on three-dimensional numerical simulation and multi-objective genetic algorithm. Energy, 2018, 147:1060-1069.
    [103]Xiaotian Lai, Rui Long, Zhichun Liu, Wei Liu. A hybrid system using direct contact membrane distillation for water production to harvest waste heat from the proton exchange membrane fuel cell. Energy, 2018, 147:578-586.
    [104]D.D. Dai, F. Yuan, R. Long, Z.C. Liu, W. Liu. Imperfect regeneration analysis of Stirling engine caused by temperature differences in regenerator. Energy Conversion and Management, 2018, 158:60-69.
    [105]W. Liu, P. Liu, J.B. Wang, N.B. Zheng, Z.C. Liu. Exergy destruction minimization: A principle to convective heat transfer enhancement. International Journal of Heat and Mass Transfer, 2018, 122:11-21.
    [106]Rui Long, Xiaotian Lai, Zhichun Liu, Wei Liu. Direct contact membrane distillation system for waste heat recovery: Modelling and multi-objective optimization. Energy, 2018, 148:1060-1068
    [107]Xinting Wang, Nianben Zheng, Zhichun Liu, Wei Liu. Numerical analysis and optimization study on shell-side performances of a shell and tube heat exchanger with staggered baffles. International Journal of Heat and Mass Transfer, 2018, 124:247-259
    [108]Rui Long, Baode Li, Zhichun Liu, Wei Liu. Reverse electrodialysis: Modelling and performance analysis based on multi-objective optimization. Energy, 2018, 151:1-10
    [109]Rui Long, Zhengfei Kuang, Zhichun Liu, Wei Liu. Reverse electrodialysis in bilayer nanochannels: salinity gradient-driven power generation. Physical Chemistry Chemical Physics, 2018, 20:7295-7302
    [110]Rui Long, Xiaotian Lai, Zhichun Liu, Wei Liu. A continuous concentration gradient flow electrical energy storage system based on reverse osmosis and pressure retarded osmosis. Energy, 2018, 152:896-905
    [111]Rui Long, Baode Li, Zhichun Liu, Wei Liu. Performance analysis of reverse electrodialysis stacks: Channel geometry and flow rate optimization. Energy, 2018, 158:427-436
    [112]Rui Long, Zhengfei Kuang, Zhichun Liu, Wei Liu. Temperature regulated reverse electrodialysis in charged nanopores. Journal of Membrane Science, 2018, 561:1-9
    [113]Shan Gao, Quanwen Liao, Wei Liu, Zhichun Liu. Nanodroplets Impact on Rough Surfaces: A Simulation and Theoretical Study. Langmuir, 2018, 34:5910-5917
    [114]Feng Xin, Zhichun Liu, Nianben Zheng, Peng Liu, Wei Liu. Numerical study on flow characteristics and heat transfer enhancement of oscillatory flow in a spirally corrugated tube. International Journal of Heat and Mass Transfer, 2018, 127:402-413
    [115]Peng Liu, Nianben Zheng, Feng Shan, Zhichun Liu, Wei Liu. Heat transfer enhancement for laminar flow in a tube using bidirectional conical strip inserts. International Journal of Heat and Mass Transfer, 2018, 127:1064-1076.
    [116]Feng Xin, Zhichun Liu, Si Wang, Wei Liu. Study of heat transfer in oscillatory flow for a Stirling engine heating tube inserted with spiral spring. Applied Thermal Engineering, 2018, 143:182-192.
    [117]Shan Gao, Quanwen Liao, Wei Liu, Zhichun Liu. Self-Removal of Multiple and Multisize Coalescing Nanodroplets on Nanostructured Surfaces. The Journal of Physical Chemistry C, 2018, 122:20521-20526
    [118]He Song, Zhao Jing, Liu Zhi-chun, Tian Wei, Yang Jin-guo, Liu Wei. Experimental investigation of loop heat pipe with a large squared evaporator for cooling electronics. Applied Thermal Engineering, 2018, 144:383-391
    [119]Jun Shen, Lingping Zeng, Zhichun Liu, Wei Liu. Performance investigation of PEMFC with rectangle blockages in Gas Channel based on field synergy principle. Heat and Mass Transfer, 2018
    [120]Ping Zhou, Lei Ma, Wei Liu, and Zhichun Liu. Study on thermal conductivities of Si thin films and porous Si structures based on a modified lattice Boltzmann method, 2018, Journal of Applied Physics, 124,10:104302.
    [121]Dongdong Dai, Fang Yuan, Rui Long, Zhichun Liu, Wei Liu. Performance analysis and multi-objective optimization of a Stirling engine based on MOPSOCD. International Journal of Thermal Sciences, 2018, 124:399-406
    [122]J Shen, Z Liu, F Liu, W Liu, Numerical Simulation of Water Transport in a Proton Exchange Membrane Fuel Cell Flow Channel, Energies 11 (7), 1770
    [123]Z Liu, R Tu, Q Liao, H Hu, J Yang, Y He, H Bian, L Ma, W Liu, High Thermal Conductivity of Flake Graphite Reinforced Polyethylene Composites Fabricated by the Powder Mixing Method and the Melt-Extruding Process, Polymers 10 (7), 693
    2017年
    [124]Zhang Y, Wang J, Liu W, Liu Z. Heat transfer and pressure drop characteristics of R134a flow boiling in the parallel/tandem microchannel heat sinks. Energy Conversion and Management, 2017, 148:1082-1095
    [125]Zheng N, Liu P, Wang X, Shan F, Liu Z, Liu W. Numerical simulation and optimization of heat transfer enhancement in a heat exchanger tube fitted with vortex rod inserts. Applied Thermal Engineering, 2017, 123: 471-484.
    [126]Jiang C, Liu W, Liu Z, Yang J, Duan B, Luo X. Startup characteristics of pump-assisted capillary phase change loop. Applied Thermal Engineering,2017, 126: 1115-1125
    [127]Zheng N, Liu P, Shan F, Liu Z, Liu W. Sensitivity analysis and multi-objective optimization of a heat exchanger tube with conical strip vortex generators. Applied Thermal Engineering, 2017, 122: 642-652
    [128]Zheng N, Liu P, Liu Z, Liu W. Numerical simulation and sensitivity analysis of heat transfer enhancement in a flat heat exchanger tube with discrete inclined ribs. International Journal of Heat and Mass Transfer, 2017,112: 509-520
    [129]Shan Gao, Quanwen Liao, Wei Liu, Zhichun Liu. Effects of Solid Fraction on Droplet Wetting and Vapor Condensation: A Molecular Dynamic Simulation Study. Langmuir, 2017, 33:12379-12388
    [130]Liu Z, Zeng X, Ge Y, Shen J, Liu W. Multi-objective optimization of operating conditions and channel structure for a proton exchange membrane fuel cell. International Journal of Heat and Mass Transfer, 2017, 111: 289-298.
    [131]Tu R, Liao Q, Zeng L, Liu Z, Liu W, Impact of torsion and stretching on the thermal conductivity of polyethylene strands, Applied Physics Letters, 2017, 110 (10):101905.
    [132]Liu W, Wang J, Liu Z, A method of fluid dynamic analysis based on Navier-Stokes equation and conservation equation on fluid mechanical energy, International Journal of Heat and Mass Transfer, 2017, 109:393-396.
    [133]Liu Z, Zhu S, Ge Y, Shan F, Zeng L, Liu W. Geometry optimization of two-stage thermoelectric generators using simplified conjugate-gradient method. Applied Energy, 2017, 190:540-552.
    [134]Wang X, Zheng N, Liu P, Liu Z, Liu W. Numerical investigation of shell side performance of a double shell side rod baffle heat exchanger. International Journal of Heat and Mass Transfer, 2017, 108:2029-39.
    [135]Long R, Li B, Liu Z, Liu W. Hybrid membrane distillation-reverse electrodialysis electricity generation system to harvest low-grade thermal energy. Journal of Membrane Science, 2017, 525:107-115.
    [136]Li P, Liu P, Liu Z, Liu W. Experimental and numerical study on the heat transfer and flow performance for the circular tube fitted with drainage inserts[J]. International Journal of Heat and Mass Transfer, 2017, 107: 686-696.
    [137]Zheng N, Liu P, Shan F, Liu Z, Liu W. Turbulent flow and heat transfer enhancement in a heat exchanger tube fitted with novel discrete inclined grooves [J]. International Journal of Thermal Sciences. 2017,111:289-300.
    [138]Zeng Xiangbing, Ge Ya, Shen Jun, Zeng Lingping, Liu Zhichun, Liu Wei. The optimization of vhannels for a proton exchange membrane fuel cell applying genetic algorithm[J]. International Journal of Heat and Mass Transfer, 2017, 105: 81-89.
    [139]李保德,隆瑞,刘伟,刘志春.废热温差发电器驱动的电化学制冷系统研究[J].工程热物理学报,2017,38(12):2515-2521.
    [140]高山,刘伟,刘志春.结构表面水蒸气凝结分子动力学模拟[J].工程热物理学报,2017,38(08):1772-1776.
    [141]涂润春,廖全文,刘志春,刘伟.扭转作用对聚乙烯链导热性能的影响[J].化工学报,2017,68(S1):60-65.
    [142]廖全文,涂润春,刘志春,刘伟.原子质量修饰对碳链聚合物热导率的影响[J].工程热物理学报,2017,38(03):619-624.
    2016年
    [143]Liao Q, Zeng L, Liu Z, Liu W. Tailoring Thermal Conductivity of Single-stranded Carbon-chain Polymers through Atomic Mass Modification [J]. Scientific Reports. 2016, 6:34999
    [144]He S, Liu Z, Zhao J, Jiang C, Yang J, Liu W. Experimental study of an ammonia loop heat pipe with a flat plate evaporator[J]. International Journal of Heat and Mass Transfer, 2016, 102: 1050-1055.
    [145]Ge Y, Liu Z, Liu W. Multi-objective genetic optimization of the heat transfer for tube inserted with porous media [J]. International Journal of Heat and Mass Transfer. 2016, 101:981-987.
    [146]Shan F, Liu Z, Liu W,Tsuji Y. Effects of the orifice to pipe diameter ratio on orifice flows[J]. Chemical Engineering Science, 2016, 152: 497-506.
    [147]Shan F, Liu Z, Liu W, Tsuji Y. On flow structures associated with large wall mass transfer coefficients in orifice flows[J]. International Journal of Heat and Mass Transfer, 2016, 102: 1-9.
    [148]Li B, Long R, Liu Z, Liu W. Performance analysis of a thermally regenerative electrochemical refrigerator [J]. Energy. 2016, 112: 43-51.
    [149]Wang J, Liu Z, Liu W. Evaluation of convective heat transfer in a tube based on local exergy destruction rate[J]. Sci China Tech Sci, 2016.
    [150]He S, Liu Z, Wang D, Zhao J, Liu W, Yang J. Investigation of the flat disk-shaped LHP with a shared compensation chamber [J]. Applied Thermal Engineering. 2016, 104: 139–145.
    [151]Liao Q, Liu Z, Yang N, Liu W. Spontaneous Migration of Polyethylene Molecule Sheathed inside Single-Walled Carbon Nanotube for Nano-Heat Pipe [J]. Scientific Reports. 2016, 6:26441.
    [152]Liao Q, Liu Z, Yang J, Liu W. Thermal conductivity of single polyethylene chain dependence on length, temperature and mechanical strain using molecular dynamics simulations [J]. International Journal of Energy for a Clean Environment. 2014,15:1–9.
    [153]Long R, Li B, Liu Z, Liu W. Performance analysis of a dual loop thermally regenerative electrochemical cycle for waste heat recovery [J]. Energy. 2016,107: 388-95.
    [154]Long R, Li B, Liu Z, Liu W. Ecological analysis of a thermally regenerative electrochemical cycle [J]. Energy, 2016, 107:95-102.
    [155]Liu P, Zheng N, Shan F, Liu Z, Liu W. Numerical study on characteristics of heat transfer and friction factor in a circular tube with central slant rods[J]. International Journal of Heat and Mass Transfer, 2016, 99: 268-282.
    [156]Zheng N, Liu P, Shan F, Liu Z, Liu W. Numerical investigations of the thermal-hydraulic performance in a rib-grooved heat exchanger tube based on entropy generation analysis [J]. Applied Thermal Engineering, 2016, 99: 1071–1085.
    [157]Zheng N, Liu P, Shan F, Liu Z, Liu W. Effects of rib arrangements on the flow pattern and heat transfer in an internally ribbed heat exchanger tube[J]. International Journal of Thermal Sciences, 2016, 101: 93-105.
    [158]Zheng N, Liu P, Shan F, Liu Z, Liu W. Heat transfer enhancement in a novel internally grooved tube by generating longitudinal swirl flows with multi-vortexes[J]. Applied Thermal Engineering, 2016, 95: 421-432.
    [159]Zheng N, Liu P, Shan F, Liu J, Liu Z, Liu W. Numerical studies on thermo-hydraulic characteristics of laminar flow in a heat exchanger tube fitted with vortex rods[J]. International Journal of Thermal Sciences, 2016, 100: 448-456.
    [160]Long R, Li B, Liu Z, Liu W. Performance analysis of a solar-powered electrochemical refrigerator[J]. Chemical Engineering Journal, 2016, 284: 325-332.
    [161]江驰,刘志春,杨金国,段斌,罗小兵,刘伟.泵辅助毛细相变回路的启动性能研究[J].工程热物理学报,2016,37(11):2457-2462.
    [162]何松,刘志春,汪冬冬,刘伟,杨金国,张晓屿.双面蒸发器环路热管的瞬态特性[J].化工学报,2016,05:1778-1783.
    [163]陈奔,王俊,涂正凯,潘牧,沈俊,刘志春,刘伟.基于高氢气利用率的质子交换膜燃料电池运行特性研究[J].工程热物理学报,2016,02:372-377.
    [164] 谢攀,隆瑞,刘政,刘志春,刘伟.低温工业余热利用ORC工质选择[J].工程热物理学报,2016(09):1834-1837.
    [165] 王新婷,郑年本,刘鹏,刘志春,刘伟.波形折流杆换热器的流动与传热性能分析[J].工程热物理学报,2016(08):1758-1762.   
    [166]王俊博,谢攀,刘志春,刘伟.最小火用损优化方法在椭圆换热管内的应用[J].化工学报,2016(S1):307-311.
    [167]王敬韬,周昌宁,王云亭,刘志春,刘伟,杨金国.微通道过冷沸腾实验研究[J].工程热物理学报,2016(07):1549-1554.
    [168]李保德,刘鹏,郑年本,刘志春,刘伟.丁胞强化传热管内的流动与传热性能研究[J].工程热物理学报,2016(06):1261-1267.
    [169]郑年本,刘志春,刘伟.圆管内插入螺旋片强化传热数值模拟及(火积)耗散分析[J].工程热物理学报,2016(01):155-159.
    [170]隆瑞,李保德,谢攀,刘志春,刘伟.具有回热的电化学制冷机的性能分析[J].工程热物理学报,2016(10):2043-2047.   
    [171]刘伟, 包予佳, 谢攀,等. 余热资源的能级及其与ORC工质的匹配[J]. 科学通报, 2016(17):1889-1896.   
    2015年
    [172]Wang J, Liu W, Liu Z. The application of exergy destruction minimization in convective heat transfer optimization[J]. Applied Thermal Engineering, 2015, 88: 384-390. dx.doi.org/10.1016/j.applthermaleng.2014.09.076
    [173]Long R, Li B, Liu Z, Liu W. Performance analysis of a solar-powered solid state heat engine for electricity generation[J]. Energy, 2015, 93: 165-172.
    [174]Long R, Li B, Liu Z, Liu W. Multi-objective optimization of a continuous thermally regenerative electrochemical cycle for waste heat recovery[J]. Energy, 2015, 93: 1022-1029.
    [175]Long R, Li B, Liu Z, Liu W. A hybrid system using a regenerative electrochemical cycle to harvest waste heat from the proton exchange membrane fuel cell[J]. Energy, 2015, 93: 2079-2086.
    [176]Jin Z, Liao Q, Fang H, Liu Z, Liu W, Ding Z, Luo T, Yang N. A Revisit to High Thermoelectric Performance of Single-layer MoS2[J]. Scientific Reports,2015, 5: 18342.
    [177]Liao Q, Liu Z, Liu W, Deng C, Yang N. Extremely High Thermal Conductivity of Aligned Carbon Nanotube-Polyethylene Composites[J]. Scientific Reports, 2015, 5: 16543.
    [178]Wang D, Liu Z, Shen J, Liu W. lattice boltzmann simulation of effective thermal conductivity of porous media with multiphase[J]. Journal of Porous Media, 2015, 18(10): 929-939.
    [179]Jiang C, Liu Z, Wang D, Yang J, Wang H, Li J, Liu W. Effect of liquid charging process on the operational characteristics of pump-assisted capillary phase change loop[J]. Applied Thermal Engineering, 2015, 91: 953-962.
    [180]Ge Y, Liu Z, Liu W, Chen G. Active optimization design theory and method for heat transfer unit and its application on shape design of cylinder in convective heat transfer [J]. International Journal of Heat and Mass Transfer, 2015, 90: 702-709.
    [181]Zheng N, Liu W, Liu Z, Liu P, Shan F. A numerical study on heat transfer enhancement and the flow structure in a heat exchanger tube with discrete double inclined ribs [J]. Applied Thermal Engineering, 2015, 90: 232-241.
    [182]Wang J, Liu Z, Yuan F, Liu W, Chen G. Convective heat transfer optimization in a circular tube based on local exergy destruction minimization [J]. International Journal of Heat and Mass Transfer, 2015, 90: 49-57.
    [183]Wang D, Liu Z, He S, Yang J, Liu W. Operational characteristics of a loop heat pipe with a flat evaporator and two primary biporous wicks [J]. International Journal of Heat and Mass Transfer, 2015, 89: 33-41.
    [184]Long R, Li B, Liu Z, Liu W. Performance analysis of a thermally regenerative electrochemical cycle for harvesting waste heat[J]. Energy, 2015, 87: 463-469
    [185]Liu Z, Wang D, Jiang C, Yang J, Liu W. Experimental study on loop heat pipe with two-wick flat evaporator[J]. International Journal of Thermal Sciences, 2015, 94: 9-17.
    [186]Li P, Liu Z, Liu W, Chen G. Numerical study on heat transfer enhancement characteristics of tube inserted with centrally hollow narrow twisted tapes[J]. International Journal of Heat and Mass Transfer, 2015, 88: 481-491.
    [187]Liu Z, Shen J, Pei H, Tu Z, Wang J, Wan Z, Liu W. Effect of humidified water vapor on heat balance management in a proton exchange membrane fuel cell stack[J]. International Journal of Energy Research, 2015, 39: 504-515.     
    [188]Liu J J, Liu Z C, Liu W. 3D numerical study on shell side heat transfer and flow characteristics of rod-baffle heat exchangers with spirally corrugated tubes[J]. International Journal of Thermal Sciences, 2015, 89: 34-42.     
    [189]朱世平,刘志春,葛亚,刘伟.基于简化共轭梯度法的多级热电材料发电系统优化[J].工程热物理学报,2015,04:847-851.
    2014年
    [190]Pei H, Shen J, Cai Y,Tu Z, Wan Z, Liu Z, Liu W. Operation characteristics of air-cooled proton exchange membrane fuel cell stacks under ambient pressure[J]. Applied Thermal Engineering, 2014, 63(1): 227-233.     
    [191]Wang D, Liu Z, Shen J, Jiang C, Chen B B, Yang J G, Tu Z K, Liu W. Experimental study of the loop heat pipe with a flat disk-shaped evaporator[J]. Experimental Thermal and Fluid Science, 2014, 57: 157-164.     
    [192]Jia H, Liu Z C, Liu W, Nakayama A. Convective heat transfer optimization based on minimum entransy dissipation in the circular tube[J]. International Journal of Heat and Mass Transfer, 2014, 73: 124-129.     
    [193]Long R, Liu Z, Liu W. Performance optimization of minimally nonlinear irreversible heat engines and refrigerators under a trade-off figure of merit[J]. Physical Review E, 2014, 89(6): 062119.     
    [194]Jiang C, Liu W, Wang H C, Wang D D, Yang J G, Li J Y, Liu Z C. Experimental investigation of pump-assisted capillary phase change loop[J]. Applied Thermal Engineering, 2014, 71(1): 581-588.     
    [195]Wang Y, Zhou B, Liu Z, Tu Z,Liu W. Numerical study and performance analyses of the mini-channel with discrete double-inclined ribs[J]. International Journal of Heat and Mass Transfer, 2014, 78: 498-505.     
    [196]沈俊,周兵, 邱子朝, 涂正凯, 刘志春, 刘伟. 质子交换膜燃料电池强化传质[J]. 化工学报, 2014, 65(S1).     
    [197]罗琴, 王俊, 涂正凯, 潘牧, 万忠民, 刘志春, 刘伟. 质子交换膜冻结温度的理论与实验研究[J]. 工程热物理学报, 2014, 35(4).     
    [198]裴后昌, 涂正凯, 刘志春, 沈俊, 邱子朝, 刘帆, 刘伟. 低流速燃料电池重力辅助排水[J]. 化工学报, 2014, 65(S1).     
    [199]贾晖, 刘伟, 刘志春. 传热效率-强化传热的新评价指标[J]. 工程热物理学报, 2014, 35(2).     
    2013年
    [200]Tang H, Luo Z, Pei H, Liu Z, Liu W. Water distribution and removal along the flow channel in proton exchange membrane fuel cells[J]. Journal of Wuhan University of Technology-Mater. Sci. Ed., 2013, 28(2): 243-248.   
    [201]Liu W, Jia H, Liu Z C, Fang H S, Yang K. The approach of minimum heat consumption and its applications in convective heat transfer optimization[J]. International Journal of Heat and Mass Transfer, 2013, 57(1): 389-396.    8、   
    [202]Pei H, Liu Z, Zhang H, Yu Y, Tu Z, Wan Z, Liu W. In situ measurement of temperature distribution in proton exchange membrane fuel cell I a hydrogen-air stack[J]. Journal of Power Sources, 2013, 227: 72-79.     
    [203]Wan Z, Liu J, Luo Z, Tu Z, Liu Z, Liu W. Evaluation of self-water-removal in a dead-ended proton exchange membrane fuel cell[J]. Applied Energy, 2013, 104: 751-757.     
    [204]Zhang X, Liu Z, Liu W. Numerical studies on heat transfer and friction factor characteristics of a tube fitted with helical screw-tape without core-rod inserts[J]. International Journal of Heat and Mass Transfer, 2013, 60: 490-498.     
    [205]万忠民, 沈俊, 裴后昌, 刘靖, 万军华, 涂正凯, 刘志春, 刘伟. 质子交换膜燃料电池堆散热特性研究[J]. 工程热物理学报, 2013, 34(10).     
    [206]张晓屿, 刘志春, 刘伟, 周路遥. 圆管内插入多个螺旋片的传热与流动的数值模拟研究[J]. 工程热物理学报, 2013, 34(2).     
    2012年
    [207]BB Chen, W Liu, ZC Liu, H Li, JG Yang. Experimental investigation of loop heat pipe with flat evaporator using biporous wick[J]. Applied Thermal Engineering, 2012, 42: 34-40.     
    [208]Chen B B, Liu Z C, Liu W, Yang J G, Li H, Wang D D. Operational characteristics of two biporous wicks used in loop heat pipe with flat evaporator[J]. International Journal of Heat and Mass Transfer, 2012, 55(7): 2204-2207.     
    [209]Jia H, Liu W, Liu Z. Enhancing convective heat transfer based on minimum power consumption principle[J]. Chemical Engineering Science, 2012, 69(1): 225-230.  
    [210]Li H, Liu Z C, Chen B B, Liu W, Li C, Yang J. Development of biporous wicks for flat-plate loop heat pipe[J]. Experimental Thermal and Fluid Science, 2012, 37: 91-97.     
    [211]Liu W, Liu Z C, Ma L. Application of a multi-field synergy principle in the performance evaluation of convective heat transfer enhancement in a tube[J]. Chinese Science Bulletin, 2012, 57(13): 1600-1607.     
    [212]Liu Z C, Li H, Chen B B, Yang J G, Liu W. Operational characteristics of flat type loop heat pipe with biporous wick[J]. International Journal of Thermal Sciences, 2012, 58: 180-185.     
    [213]Tu Z, Pan M, Liu W, Liu Z, Wang Z. Modeling of stability of the condensing interface in a capillary pumped loop[J]. International Journal of Heat and Mass Transfer, 2012, 55(5): 1709-1715.     
    [214]Wan Z M, Wan J H, Liu J, Tu Z K, Pan M, Liu Z C, Liu W. Water recovery and air humidification by condensing the moisture in the outlet gas of a proton exchange membrane fuel cell stack[J]. Applied Thermal Engineering, 2012, 42: 173-178.   
    [215]Zhang X, Liu Z, Liu W. Numerical studies on heat transfer and flow characteristics for laminar flow in a tube with multiple regularly spaced twisted tapes[J]. International Journal of Thermal Sciences, 2012, 58: 157-167.   
    [216]贾晖, 刘志春, 刘伟. 最小煅耗优化在椭圆管换热中的应用[J]. 工程热物理学报, 2012, 33(6).
    [217]刘志春, 涂正凯, 周兵, 刘伟. 质子交换膜燃料电池阴极气场设计优化[J]. 工程热物理学报, 2012, 33(8).     
    [218]陈彬彬, 刘志春, 刘伟, 杨金国, 汪冬冬. 平板式不锈钢一氨环路热管的实验研究[J]. 工程热物理学报, 2012, 33(10).  
    [219]王英双, 张晓屿, 刘志春, 黄素逸, 刘伟. 花格板换热器的流动与传热[J]. 化工学报, 2012, 63(S1).  
    [220]马雷, 王英双, 杨杰, 刘志春, 刘伟. 变截面折流杆换热器的流动与传热分析[J]. 工程热物理学报, 2012, 33(1).     
    [221]涂正凯, 潘牧, 丁刚强, 刘志春, 刘伟. PEMFC尾气冷凝的自增湿运行[J]. 工程热物理学报, 2012, 33(12).     
    [222]黄望梅,刘莉娜,刘志春,陈德,阳志洪,刘伟.拜耳法生产氧化铝溶出工艺CAD软件系统的开发[J].有色金属(冶炼部分),2012,06:19-23.
    [223]丁刚强,唐和清,裴后昌,刘志春,刘伟.风冷电堆材料特性对电池性能的影响[J].电源技术,2012,09:1298-1300.
    [224]汪震,潘姣,裴后昌,刘志春,涂正凯.质子交换膜燃料电池低温启动研究现状[J].电池工业,2012,06:375-381.
    2011年
    [225]Liu W, Liu Z C, Jia H, Fan H, Nakayama A. Entransy expression of the second law of thermodynamics and its application to optimization in heat transfer process[J]. International Journal of Heat and Mass Transfer, 2011, 54(13): 3049-3059.     
    [226]Liu Z, Gai D, Li H, Liu W, Yang J, Liu M. Investigation of impact of different working fluids on the operational characteristics of miniature LHP with flat evaporator[J]. Applied Thermal Engineering, 2011, 31(16): 3387-3392.     
    [227]Wang Y, Liu Z, Huang S, Huang S, Liu W, Li W. Experimental investigation of shell-and-tube heat exchanger with a new type of baffles[J]. Heat and mass transfer, 2011, 47(7): 833-839.     
    [228]马雷, 王英双, 杨杰, 刘志春, 刘伟. 折流杆换热器的数值模拟及优化设计[J]. 工程热物理学报, 2011, 32(3),462-464.     
    [229]陈彬彬, 刘志春, 刘伟. 圆管内插入螺旋片状多孔介质的换热性能及场协同分析[J]. 工程热物理学报.2011, 32(8), 1371-1374.     
    [230]陈彬彬, 刘伟, 刘志春, 杨金国, 李欢, . 平板式小型环路热管的实验研究[J]. 宇航学报, 2011, 32(4), 953-958.     
    [231]陈彬彬, 刘志春, 刘伟, 杨金国, 李欢. 平板式mLHP实验的稳定性分析[J]. 工程热物理学报, 2011, 32(4), 675-678.     
    [232]张晓屿, 刘志春, 刘伟. 内置螺旋片的强化传热管的数值模拟研究[J]. 工程热物理学报, 2011, 32(3), 448-450.     
    [233]陈彬彬, 刘伟, 刘志春, 李欢, 杨金国. 负压式平板型环路热管试验[J]. 中国空间科学技术, 2011, (6), 65-72.     
    [234]刘莉娜,黄望梅,刘志春,陈德,阳志洪,刘伟.氧化铝生产中传热系数的研究[J].有色金属(冶炼部分),2011,08:21-24.
    [235]刘莉娜,黄望梅,刘志春,陈德,阳志洪,刘伟.氧化铝溶出工艺中各种套管传热系数的比较[J].有色金属(冶炼部分),2011,10:17-19.
    2010年
    [236]Liu W, Liu Z C, Huang S Y. Physical quantity synergy in the field of turbulent heat transfer and its analysis for heat transfer enhancement[J]. Chinese Science Bulletin, 2010, 55(23): 2589-2597.     
    [237]Tu Z K, Liu W, Liu Z C, Huang X M. Interface stability in a capillary loop undergoing phase changes in non-gravitational conditions[J]. Chinese Science Bulletin, 2010, 55(35): 4069-4073.     
    [238]盖东兴, 刘志春, 刘伟, 杨金国. 重力辅助平板型环路热管实验研究[J]. 热能动力工程, 25(2), 196-203.     
    [239]王英双, 刘志春, 黄素逸, 刘伟. 新型折流杆换热器的流动与传热数值模拟[J]. 化工进展, 29(7), 1205-1208.     
    [240]万忠民, 刘伟, 明廷臻,刘志春. 新型微小型平板CPL蒸发器流动与传热分析[J]. 机械工程学报, 46(4), 99-104.     
    [241]涂正凯, 刘伟, 刘志春, 黄晓明. 无重力条件下毛细相变回路中界面的稳定性研究[J].科学通报, 2010, 55(22), 2252-2256.     
    [242]刘伟, 刘志春, 黄素逸. 湍流换热的场物理量协同与传热强化分析[J]. 科学通报, 2010, 55(3), 281-288.     
    [243]涂正凯, 刘伟, 刘志春, 范爱武. 毛细相变流体回路冷凝界面的稳定性[J]. 中国空间科学技术, 2010, (4), 64-70.     
    [244]贾晖, 刘伟, 刘志春, 范爱武. 换热器管束间添加叶片的数值分析与结构优化[J]. 工程热物理学报. 2010, 31(9), 1547-1550.     
    [245]盖东兴, 刘伟, 刘志春, 黄素逸. 环路热管系统温度波动的机理研究[J]. 工程热物理学报, 2010, 44(3), 26-31.     
    [246]刘志春, 盖东兴, 刘伟, 杨金国. 工质对平板型LHP运行特性影响的实验研究[J]. 工程热物理学报. 2010, 31(3), 487-490.     
    [247]陈良才,江波,蒋茂灿,冯志力,杨博,刘志春.水平管外水膜流型判据与特征长度[J].化工学报,2010,S2:15-19.
    2009年
    [248]Gai D, Liu W, Liu Z C, Yang J G. Temperature oscillation of mLHP with flat evaporator[J]. Heat Transfer Research, 2009, 40(4).     
    [249]Gai D, Liu Z, Liu W, Yang J. Operational characteristics of miniature loop heat pipe with flat evaporator[J]. Heat and mass transfer, 2009, 46(2): 267-275.     
    [250]Liu W, Liu Z C, Guo Z Y. Physical quantity synergy in laminar flow field of convective heat transfer and analysis of heat transfer enhancement[J]. Chinese Science Bulletin, 2009, 54(19): 3579-3586.     
    [251]Wei L, Zhichun L, Tingzhen M, Guo Z. Physical quantity synergy in laminar flow field and its application in heat transfer enhancement[J]. International Journal of Heat and Mass Transfer, 2009, 52(19): 4669-4672.     
    [252]Liu W, Liu Z C, Wang Y S, Huang S Y. Flow mechanism and heat transfer enhancement in longitudinal-flow tube bundle of shell-and-tube heat exchanger[J]. Science in China Series E: Technological Sciences, 2009, 52(10): 2952-2959.     
    [253]Liu W, Liu Z C, Yang K, Tu Z K. Phase change driving mechanism and modeling for heat pipe with porous wick[J]. Chinese Science Bulletin, 2009, 54(21): 4000-4004.     
    [254]Liu Z C, Liu W, Yang J G, Gai D X. Design and experimental research of a flat-plate type CPL with a porous wick in the condenser[J]. Journal of Enhanced Heat Transfer, 2009, 16(2).     
    [255]Zhang X, Liu W, Liu Z C. Criterion for local thermal equilibrium in forced convection flow through porous media[J]. Journal of Porous Media, 2009, 12(11).
    [256]刘伟, 刘志春, 明廷榛, 涂正凯. 相变流体回路中毛细芯内液体气化界面的稳定性分析[J]. 自然科学通报, 2009, 19(7).     
    [257]涂正凯, 刘伟, 黄素逸, 刘志春. 无重力条件下毛细相变流体回路的稳定性研究[J]. 自然科学进展, 2009, 19(12).     
    [258]盖东兴, 刘志春, 刘伟, 杨金国. 平板型小型环路热管的温度波动特性[J]. 化工学报, 2009, 60(6).     
    [259]盖东兴, 刘伟, 刘志春, 杨金国. 平板型MLHP温度波动研究[J]. 中国空间科学技术, 2009, (5).     
    [260]盖东兴, 刘志春, 刘伟, 杨金国. 平板型mLHP实验研究[J]. 制冷学报, 2009, 30(6).     
    [261]盖东兴, 刘志春, 杨金国, 刘伟. 平板式mLHP的仿真与实验研究[J]. 工程热物理学报, 2009, 30(12).     
    [262]刘伟, 刘志春, 杨昆, 涂正凯. 毛细芯热管的相变驱动机制与模型[J]. 科学通报, 2009, 54(13).     
    [263]刘伟, 刘志春, 王英双, 黄素逸. 管壳式换热器纵流管束内的扰流机制与传热强化研究[J]. 中国科学E辑:技术科学, 2009, 39(11).     
    [264]刘伟, 刘志春, 过增元. 对流换热层流流场的物理量协同与传热强化分析[J]. 科学通报,2009, 54(12).     
    2008年
    [265]Liu Z, Liu W, Yang J. Experimental investigation of new flat-plate-type capillary pumped loop[J]. Journal of Thermophysics and Heat Transfer, 2008, 22(1): 98-104.  
    [266]刘志春, 史光, 刘伟, 杨金国. 新型平板式CPL的性能实验[J]. 工程热物理学报, 2008, 29(12).     
    [267]史光, 刘志春, 刘伟, 刘胜. LHP圆盘式蒸发器的强度分析与启动预热分析[J]. 工程热物理学报, 2008, 29(7).   
    2007年
    [268]Liu Z C, Liu W, Nakayama A. Flow and heat transfer analysis in porous wick of CPL evaporator based on field synergy principle[J]. Heat and mass transfer, 2007, 43(12): 1273-1281.     
    [269]万忠民, 刘伟, 盖东兴, 刘志春. 带翅片的小型平板CPL蒸发器相变传热的数值模拟[J]. 化工学报, 2007,58(12).   
    [270]刘志春, 刘伟, 杨金国. CPL毛细芯冷凝器的数值模拟研究[J]. 工程热物理学报, 2007, 28(增刊2).   
    2006年以前
    [271]刘志春, 刘伟, 宰军, 邓芳芳. 平板式CPL蒸发器启动特性研究[J]. 制冷学报, 2006(27).     
    [272]刘志春, 刘伟, 杨金国, 邓芳芳. 蒸发器毛细芯中流动传热的场协同分析[J]. 工程热物理学报, 2006(27).   
    [273]马连湘,刘志春,李庆领.流体攻角对滴形钉头管流体阻力特性的影响[J].华中科技大学学报,2001,11:107-109.
    [274]马连湘,李晨,刘志春,黄素逸.滚动轮胎温度场的有限元模拟计算[J].橡胶工业,2003,08:493-497.
    [275]何燕,马连湘,黄素逸,刘志春,刘纪炎.轮胎橡胶材料生热率的测定及分析[J].橡胶工业,2004,01:53-55.
    [276]何燕,马连湘,黄素逸,刘志春.轮胎橡胶材料导热系数的测定及分析[J].橡胶工业,2004,06:366-368.
    [277]马连湘,刘志春,李庆领.滚动轮胎表面对流换热的萘升华模拟研究[J].橡胶工业,2003,06:329-332.
    [278]李晨,谢雁,刘新民,刘志春,马连湘.MPM复合保温材料导热系数的测定及实验装置的改进[J].青岛科技大学学报(自然科学版),2003,02:149-151.
    发明专利
    [1]刘志春,邓为忠,赵天缘,刘伟,吴桐,蔡冰,一种适用于浇筑式毛细芯的平板式蒸发器,发明专利,授权号:ZL202011204013.2,授权日期:2021.11
    [2]刘志春,邓为忠,何松,赵天缘,刘伟,一种用于大面积散热的矩形分区蒸发器,发明专利,授权号:ZL201911214447.8,授权日期:2020.8
    [3]刘志春,邓为忠,肖彪,刘伟,何松,马钲远,赵天缘,一种用于多热源的平板式蒸发器环路热管系统,发明专利,授权号:ZL201911308617.9,授权日期:2020.12
    [4]刘志春,何松,刘伟,杨金国,一种新型蒸发器结构及其应用,发明专利,授权号:ZL201710636959.8,2019.9
    [5]刘伟,刘鹏,刘志春,杨金国,一种适用于换热管的片状涡发生器插入结构及换热管,发明专利,授权号:ZL 201711122327.6, 2019.6
    [6]刘志春,梁运民,杨金国,刘伟,楔形波浪式插入物及使用其的强化传热管,发明专利,授权号:ZL201710234710.4, 2019.3
    [7]刘志春,张凯,李鹏霄,梁运民,刘伟,杨金国,适用于换热管的插入式强化换热组件及强化换热管,专利号:201610700836.1, 2019.3
    [8]刘志春,何松,刘伟,杨金国,赵靖,一种二次芯蒸发器及其应用,发明专利,授权号:ZL 201510853085.2, 2017.12
    [9]刘伟,王新婷,刘志春,杨金国,一种双壳程折流杆管壳式换热器,发明专利,授权号:ZL 201510673102.4, 2017.7
    [10]刘志春,李鹏霄,刘伟,杨金国,一种换热管内的引流式插入装置,发明专利,授权号:ZL 201510448055.3, 2017.4
    [11]刘志春,赵靖,刘伟,杨金国,何松,一种双毛细芯蒸发器,授权号:ZL 201510824117.6, 2018.3
    [12]李权,王新婷,刘伟,刘志春,吕圣杰,刘光辉,蓝月华,陈瑾,张秀红,全迪锋,导流筒内引流减阻装置、导流筒及管壳式换热器,发明专利,授权号:ZL 201610159504.7,
    [13]江驰, 刘伟, 刘志春, 杨金国, 王恒超, 李佳玉, 泵辅助毛细相变回路系统, 发明专利, 授权号: ZL 201418000105.8
    [14]汪冬冬,刘志春,刘伟,杨金国,一种应用于平板型LHP系统的双毛细芯蒸发器,发明专利,授权号:ZL201310700409.X
    [15]明廷臻,刘伟,刘志春等,一种强化传热管,发明专利,授权号:ZL200810236716.6
    [16]刘志春,刘伟等,纵向扰流管壳式换热器,发明专利,授权号:ZL2008102367170
    [17]刘伟,刘志春等,用于LHP和CPL的平面圆盘式毛细芯蒸发器,发明专利,授权号: ZL200610055641.2
    [18]刘伟,刘志春等,一种用于CPL的平面式毛细芯冷凝器,发明专利,授权号:CN200510019113.7
    [19]刘伟,刘志春等,具有平面式毛细芯蒸发器和冷凝器的CPL系统,发明专利,授权号:CN200510019112.2
    [20]刘伟,杨金国,刘志春等,用于CPL的带有散热片的平面式毛细芯蒸发器,发明专利,授权号:200510019111.8
    [21]刘伟,杨金国,刘志春等,一种用于CPL的平面式毛细芯蒸发器,发明专利,授权号:200510019110.3
    [22]刘伟,杨金国,刘志春等,平板式毛细抽吸两相回路热交换系统,发明专利,授权号:200510001149.2

所获荣誉和奖励

    [1]2020年,国家自然科学二等奖,耗散最小化多场协同对流传热强化理论和方法(位次2)
    [2]2019年,湖北省自然科学一等奖,耗散最小化多场协同对流传热强化理论和方法(位次2)
    [3]2016年教育部科技进步奖一等奖,纵流管壳式换热器的强化传热与工程应用(位次3)
    [4]2017年,青岛市科技进步二等奖,低维碳材料体系构建的关键技术及其产业化应用,青岛市人民政府(位次3)
    [5]2011、2014、2015、2016年湖北省优秀学士论文指导教师
    [6]2019年指导的学生获得第一届全国节能减排大赛一等奖
    [7]2008年指导的学生获得第一届全国节能减排大赛三等奖
    [8]2006年获山东省高等学校自然科学一等奖奖(位次5)
    [9]2007年山东省青岛市科技进步二等奖(位次5)
    [10]2008年获山东省科技进步三等奖(位次5)
    [11]2005年中国工程热物理学会优秀论文奖