张恒运

发布者:唐子夏发布时间:2020-04-24浏览次数:11888


个人信息:

姓名:张恒运                              职称:教授

专业:车辆工程                         学历层次:博士

办公室地点:松江区龙腾路3338B515                 办公电话:无

电子邮箱:zhanghengyun@sues.edu.cn

研究方向:新能源汽车电池测控与热管理,相变储能,集成电路散热等

主讲课程:热力学基础,热工基础,新能源汽车技术

   

个人简介:(教育背景、工作经历)

博士生导师,上海高校特聘教授,IEEE高级会员,松江区拔尖人才。1994年获得中国科技大学热科学与能源工程系本科学位,2001年获得新加坡南洋理工大学机械与制造工程博士学位,先后在新加坡微电子研究所、美国超微半导体等公司担任高级工程师与研究员,2014年聘任上海工程技术大学教授。担任ASME MNHMT 2016IEEE EPTC2014-2023ISLBFS2021-2023国际会议技术委员会成员,主持和主要参与国家自然科学、上海科委项目、企业项目20多项。撰写专著1部,发表论文150篇,Google Scholar 引用率2700多次,申请专利40多项。获得中国发明协会创业创新奖二等奖、ICEPT 2010杰出论文奖、ITHERM 2004最佳论文奖。指导硕士研究生34人、博士生3人,获得上海市优秀毕业生、上海市工程热物理学会优秀学位论文奖、互联网+大赛上海市铜奖等荣誉。入选全球2%顶尖科学家“终身科学影响力”和“2022年度科学影响力”榜单(斯坦福大学和爱思唯尔联合发布)。

   

主要科研成果:代表性论文、专利、著作等)

著作

[1]H.Y. Zhang, F.X. Che, T. Lin, W.S. Zhao, Modeling, analysis, design and tests for electronics packaging beyond Moore [M], 2020, 十三五国家重点图书, Elsevier 与化工出版社联合出版.  

论文与专利

[1]Jiaxing Yang, Hengyun Zhang#, Yidong Xu, Peichao Li, Analysis of heat generation in lithium-ion battery components and voltage rebound based on electrochemical and thermal coupled model, J. Energy Storage 2023, 72: 108554.

[2] Xiaobin Xu, JiaJun Zhu, Hengyun Zhang#, Zhaozang Yi, Xiaolin Wang, Gang Zhao, Low cost energy-efficient preheating of battery module integrated with air cooling based on a heat spreader plate, Applied Thermal Engineering, 2023, 232: 121024.

[3]Hong Yu, Hengyun Zhang#, Jinghe Shi, Shunbo Liu, Zhaozang Yi, Shen Xu, Xinwei Wang, Thermal parameters of cylindrical power batteries: Quasi-steady state heat guarding measurement and thermal management strategies, Applied Thermal Engineering,2023, 231: 120959.  

[4] Zhaozang Yi, Peng Wei, Hengyun Zhang#, Haitao Sun, Shuzhen Zeng, Hong Yu, Wide range temperature thermal performance of power battery module with double-sided thermoelectric device system with high energy efficiency, Applied Thermal Engineering, 2023, 227: 120375.

[5]Xiaojun Wang, Hengyun Zhang#, Zhaozang Yi, Xinghua Huang, Hui Guo, Shunliang Zhu, Thermal characteristics of refrigerant flow boiling in two mini-channel heat sinks of different aspect ratios for battery thermal management, Applied Thermal Engineering 2022, 217: 119173.

[6]Jiajun Zhu, Hengyun Zhang#, Guoping Wu, Shunliang Zhu, Wei Liu, Thermal performance of cylindrical battery module with both axial and radial thermal paths: numerical simulation and thermal resistance network analysis, J. Energy Storage 2022, 49: 104197.

[7] X. Xu, Y. Xu, H. Zhang#, S. Zhu, H. Wang. Balanced structural optimization of air-cooling battery module with single-layer sleeved heat spreader plate. Int. J. Energy Res. 2022, 46:3458–3475.  

[8]Dezhu Huang, Hengyun Zhang,# Xiaojun Wang, Xinghua Huang, Haifeng Dai, Experimental investigations on the performance of mini-channel evaporator refrigeration system for thermal management of power batteries,  Int. J. Refrig. 2021, 130: 117–127.  

[9]Yefei Xu, Hengyun Zhang#, Xiaobin Xu, Xiaolin Wang, Numerical analysis and surrogate model optimization of air-cooled battery modules using double-layer heat spreading plates, Int. J. Heat Mass Transfer, 2021, 176: 121380.  

[10] Shunbo Liu, Hengyun Zhang#, Xiaobin Xu, A study on the transient heat generation rate of lithium-ion battery based on full matrix orthogonal experimental design with mixed levels, J. Energy Storage, 2021, 36: 102446.

[11]L Sheng, Z Zhang, L Su#, Hengyun Zhang#, H Zhang, et al, A calibration calorimetry method to investigate the thermal characteristics of a cylindrical lithium-ion battery. International J. Thermal Sciences, 2021, 165: 106891.  

[12] Fengze Hou, Hengyun Zhang#, Dezhu Huang, et al, Microchannel Thermal Management System with Two-Phase Flow for Power Electronics over 500 W/cm2 Heat Dissipation, IEEE Trans. Power Electronics, 2020, 35(10): 10592-10600.

[13]Fengze Hou, Wenbo Wang, Hengyun Zhang#, et al, Experimental evaluation of a compact two-phase cooling system for high heat flux electronic packages, Applied Thermal Engineering, 2019, 163: 114338.

[14]Le Jiang, Hengyun Zhang#, Junwei Li, Peng Xia, Thermal performance of a cylindrical battery module impregnated with PCM composite based on thermoelectric cooling, Energy 2019, 188: 116048.  

[15] Hengyun Zhang#, Qingyu Wu, Shen Xu, Experimental Investigation of Thermal Performance of Large-Sized Battery Module Using Hybrid PCM and Bottom Liquid Cooling Configuration, Applied Thermal Engineering, 2019, 159: 113968.

[16]Lei Sheng, Lin Su#, Hengyun Zhang#, Experimental determination on thermal parameters of prismatic lithium ion battery cells, Int. J. Heat Mass Transfer, 2019, 139: 231–239.    

[17]Limin Song, Hengyun Zhang#, Chun Yang, Thermal analysis of conjugated cooling configurations using phase change material and liquid cooling techniques for a battery module, Int. J. Heat Mass Transfer, 2019, 133: 827–841. (他引60次)

[18]Lei Sheng, Lin Su#, Hengyun Zhang#, et al, An improved calorimetric method for characterizations of the specific heat and the heat generation rate in a prismatic lithium-ion battery cell, Energy Conversion and Management, Energy Conversion and Management, 2019 180: 724–732.

[19]Huan Yang, Hengyun Zhang#, et al, Numerical analysis and experimental visualization of phase change material melting process for thermal management of cylindrical power battery, Applied Therm. Engineering, 2018,128: 489-499. (他引30次)

[20]Hengyun Zhang#, Zhaoqiang Wang, Cross-Flow Heat Exchanger: Volume Averaging Formulation of a Unit Cell Model and Thermal Performance Analysis, ASME J. Heat Transfer 2017,139(05): 051801.

[21]Zhiwei Wang, Hengyun Zhang#, Xin Xia, Experimental investigation on the thermal behavior of cylindrical battery with composite paraffin and fin structure, Int. J. Heat Mass Transfer, 2017, 109: 958-970. (他引60)

[22]H. Y. Zhang et al, Analysis of thermoelectric cooler performance for high power electronic packages, Applied Thermal Engineering 2010, 30:561-568.(他引108次)

[23]李俊伟, 张恒运#, 吴笑宇,王影,基于热电制冷的动力电池模组散热性能研究,储能科学与技术,202096): 1790-1797.  

[24]吴笑宇,张恒运#,朱泽华,宋利民,电池模组轴向-径向协同散热的数值分析,工程热物理学报,2020417):1784-1791.      

[25]吴青余, 张恒运#, 李俊伟. 校准量热法测量锂电池比热容和生热率. 汽车工程, 2020, 42(1): 59-65.

[26]张恒运,邓宇晨,严晓,陈浩,王岩松,一种带翅片和泡沫导热结构的复合散热装置,发明专利授权ZL201510705796.5.

[27]张恒运,王之伟,夏欣,金光灿,一种动力电池的散热装置,发明专利授权ZL201610078011.0.

[28]张恒运,王兆强,许莎,王之伟,一种强制对流动力电池散热装置,发明专利授权ZL201610296577.0.

[29]张恒运,隋杨,龚元明,牛甜甜,一种基于热电效应的电池模组热管理方法和装置, 发明专利授权ZL201610944434.6.

[30]张恒运,刘顺波,吴国平,李培超,徐屾,黄兴华,郭韵,刘飞,一种测量圆柱电池轴向导热系数与比热的方法与装置,发明专利授权 ZL2020111806036.

[31]张恒运,徐晓斌,刘顺波等,基于内阻测试的动力电池瞬态产热率的测算方法,发明专利授权 ZL2021105712178.

[32]张恒运,徐晓斌,刘顺波等,基于车辆行驶工况的动力电池瞬态产热率的测算方法,发明专利授权ZL202110571229.0.