李冉 助理研究员、研究生导师
联系电话:13161102479
E-mail:liran@bjut.edu.cn
通讯地址:朝阳区平乐园100号威尼斯wns.8885556能源楼306
教育背景
2011年9月-2015年6月 中国石油大学(北京),本科,石油工程
2015年9月-2020年6月 中国石油大学(北京),博士,油气井工程
2018年9月-2019年9月 美国麻省理工学院联合培养,核科学与工程
工作经历
2020年7月-至今 威尼斯wns.8885556,环境与能源工程学院,助理研究员
研究方向
电子器件热管理技术
纳米孔内液体蒸发传热机理
液体蒸发的分子动力学模拟
课程教学
《Basics of Molecular Gas Dynamics and Kinetic Theory》研究生选修课
《能源利用综合实验》本科生选修课
奖项荣誉
2012年,大学生英语竞赛全国二等奖
2012年,本科生国家奖学金
2013年,中国石油大学(北京)科技创新先进个人
2017年,博士生国家奖学金
主要科研项目
中国博士后科学基金面上项目《基于非均匀纳米多孔薄膜自吸蒸发的芯片近结冷却技术研究》,主持,2021.11-2022.12
国家自然科学基金青年基金项目《含不凝气条件下过渡区纳米孔内液体蒸发传热机理的研究》,主持,2023.01-2025.12
主要论文论著
[1]Li, R., Xia, G. Improved heat dissipation performance of nano-porous wicking evaporator by structural modification: A numerical study. Applied Thermal Engineering. 2022, 212: 118604. IF=6.465
[2]Li, R., Xia, G., Wang, J. Two-dimensional kinetic evaporation by direct simulation Monte Carlo (DSMC) with independently controlled downstream boundary conditions. International Journal of Heat and Mass Transfer. 2022, 194: 123075. IF=5.431
[3]Li, R., Wang, J., Xia, G. New model for liquid evaporation and vapor transport in nanopores covering the entire Knudsen regime and arbitrary pore length. Langmuir. 2021, 37(6): 2227-2235. IF=4.331
[4]Li, R., Wang, J., Xia, G. Theoretical and numerical study of nanoporous evaporation with receded liquid surface: effect of Knudsen number. Journal of Fluid Mechanics. 2021, 928: A9. IF=4.245
[5]Wang, J., Xia, G., Li, R. Numerical analysis of evaporation from nanopores using the direct simulation Monte Carlo method. Journal of Molecular Liquids. 2022, 347: 118348. IF=6.633
[6]Wang, J., Xia, G., Li, R., Ma, D., Zhou, W., Wang, J. Numerical simulation and microchannels parameters optimization for thermal management of GaN HEMT devices. International Journal of Numerical Methods for Heat & Fluid Flow. 2021, 31(9): 2841-2861. IF=5.181
[7]王佳豪, 夏国栋, 李冉, 马丹丹. 基于纳米多孔薄膜的蒸发特性. 航空动力学报. 2022, 37(5): 1113-1120.
[8]黄中伟, 杨睿月, 武晓光, 李冉.《液氮射流应用基础研究》, 科学出版社, 2021.
[9]Li, R., Zhang, C., Huang, Z. Quenching and rewetting of rock in liquid nitrogen: Characterizing heat transfer and surface effects. International Journal of Thermal Sciences. 2020, 148: 106161. IF=4.779
[10]Li, R., Yan, Y., Huang, Z. Thermal and mechanical analysis of LN2 jet impinging on rock surface. Applied Thermal Engineering. 2020, 178: 115581. IF=6.465
[11]Li, R., Wu, X., Huang, Z. Jet impingement boiling heat transfer from rock to liquid nitrogen during cryogenic quenching. Experimental Thermal and Fluid Science. 2019, 106: 255-264. IF=3.37
[12]Li, R., Huang, Z., Wu, X., Yan, P., Dai, X. Cryogenic quenching of rock using liquid nitrogen as a coolant: Investigation of surface effects. International Journal of Heat and Mass Transfer. 2018, 119: 446-459. IF=5.431
[13]Li, R., Huang, Z. Estimating the transient thermal boundary conditions with an improved space marching technique. International Journal of Heat and Mass Transfer. 2018, 127: 59-67. IF= 5.431
[14]Li, R., Huang, Z. A new CHF model for enhanced pool boiling heat transfer on surfaces with micro-scale roughness. International Journal of Heat and Mass Transfer. 2017, 109: 1084-1093. IF=5.431
[15]Li, R., Huang, Z., Li, G., Wu, X., Yan, P. Study of the conductive heat flux from concrete to liquid nitrogen by solving an inverse heat conduction problem. Journal of Loss Prevention in the Process Industries. 2017, 48: 48-54. IF=3.916
[16]Li, R., Huang, Z., Li, G., Wu, X., Yan, P. A modified space marching method using future temperature measurements for transient nonlinear inverse heat conduction problem. International Journal of Heat and Mass Transfer. 2017, 106: 1157-1163. IF=5.431
