王天虎
时间: 2019-11-21 来源:
姓名:王天虎
技术职务:讲师
办公地点:主楼G650
办公电话:010-61772277
通讯地址:华北电力大学主楼G650
教育背景
2010~2014 华北电力大学动力工程及工程热物理,博士
工作履历
2014~至今 华北电力大学能源动力与机械学院,讲师
学术兼职
l 国家自然科学基金评审专家(2016-2019年)
l 国际期刊审稿专家:Nanoscale, PLOS ONE, Canadian Journal of Physics等
l Advances in Mechanical Engineering Guest Editor,SAGE Publications Ltd.,SCI收录期刊:IF=0.500,2014年
研究方向
l 超级电容器电化学储能
l 高热流密度电子芯片热管理
l 半导体热电光电材料与器件
l 微能源系统中的能量转换与存储
科研项目
1. 国家自然科学基金青年基金. 项目名称:基于离子风冷却的LED集成系统耦合建模及性能优化研究, 项目编号:51406053, 起止日期:2015.1-2017.12,负责人;
2. 国家自然科学基金面上项目. 项目名称:纳米多孔碳电极/离子液体界面离子输运特性及选择性储能机理, 项目编号:51876059, 起止日期:2019.1-2022.12,负责人
代表性论文专著
1. Meng J H, Wu H C, Wang T H*. Optimization of two-stage combined thermoelectric device by three-dimensional multiphysics model and multi-objective genetic algorithm. Energies 12 (2019) 2832. (SCI) IF= 2.676
2. Li X Y, Wang S L, Wang X D*, Wang T H*. Selected porous-ribs design for performance improvement in double-layered microchannel heat sinks. International Journal of Thermal Sciences 137 (2019) 616-626. (SCI/EI) IF=3.361
3. Wang Y B, Wang X D*, Wang T H, Yan W M*. Asymmetric heat transfer characteristics of a double droplet impact on a moving liquid film. International Journal of Heat and Mass Transfer 126 (2018) 649-59. (SCI/EI) IF=3.891
4.Wang T H, Peng M, Wang X D* Yan W M*. Investigation of heat transfer enhancement by electrohydrodynamics in a double-wall-heated channel. International Journal of Heat and Mass Transfer 113 (2017) 373-383. (SCI/EI) IF=3.891
5. Wang B B, Wang X D*, Wang T H, Lu G., Yan W M*. Enhancement of boiling heat transfer of thin water film on an electrified solid surface. International Journal of Heat and Mass Transfer 109 (2017) 410-416. (SCI/EI) IF=3.891
6. Wang B B, Wang X D*, Wang T H, Yan W M*. Electrocoalescence behavior of two identical droplets with various droplet radii. Applied Thermal Engineering 111 (2017) 1464-1469. (SCI/EI) IF= 3.771
7. Wang B B, Wang X D*, Wang T H, Lu G, Yan W M*. Electro-coalescence of two charged droplets under constant and pulsed DC electric fields. International Journal of Heat and Mass Transfer 98 (2016) 10-16. (SCI/EI) IF=3.891
8. Peng M, Wang T H, Wang X D*. Effect of longitudinal electrode arrangement on EHD-induced heat transfer enhancement in a rectangular channel. International Journal of Heat and Mass Transfer 93 (2016) 1072-1081. (SCI/EI) IF=3.891
9. Lv H, Wang X D*, Meng J H, Wang T H, Yan W M*. Enhancement of maximum temperature drop across thermoelectric cooler through cascade design and transient supercooling effect. Applied Energy 175 (2016) 285-292. (SCI/EI) IF= 7.900
10. Lv H, Wang X D*, Wang T H, Cheng C H. Improvement of transient supercooling of thermoelectric coolers through variable semiconductor cross-section. Applied Energy 164 (2016) 501-508. (SCI/EI) IF= 7.900
11. Leng C, Wang X D*, Yan W M*, Wang T H. Heat transfer enhancement of microchannel heat sink using transcritical carbon dioxide as the coolant. Energy Conversion and Management 110 (2016) 154-164. (SCI/EI) IF=6.377
12. Wang T H, Wang Q H, Leng C, Wang X D*. Parameter analysis and optimal design for two-stage thermoelectric cooler. Applied Energy 154 (2015) 1-12. (SCI/EI) IF= 7.900
13. Wang T H, Xu J L*. Advantage of InGaN-based light-emitting diodes with trapezoidal electron blocking layer. Materials Science in Semiconductor Processing 29 (2015) 95-101. (SCI/EI) IF=2.593
14. Lv H, Wang X D*, Wang T H, Meng J H. Optimal pulse current shape for transient supercooling of thermoelectric cooler. Energy 83 (2015) 788-796. (SCI/EI) IF=4.968
15. Kim C B, Leng C, Wang X D*, Wang T H, Yan W M*. Effects of slot-jet length on the cooling performance of hybrid microchannel/slot-jet module. International Journal of Heat and Mass Transfer 89 (2015) 838-845. (SCI/EI) IF=3.891
16. Si C, Wang X D*, Yan W M*, Wang T H. A Comprehensive Review on Measurement and Correlation Development of Capillary Pressure for Two-Phase Modeling of Proton Exchange Membrane Fuel Cells. Journal of Chemistry 2015 (2015) 876821. (SCI) IF=1.726
17. Leng C, Wang X D*, Wang T H, Yan W M*. Optimization of thermal resistance and bottom wall temperature uniformity for double-layered microchannel heat sink. Energy Conversion and Management 93 (2015) 141-150. (SCI/EI) IF=6.377
18. Leng C, Wang X D*, Wang T H. An improved design of double-layered microchannel heat sink with truncated top channels. Applied Thermal Engineering 79 (2015) 54-62. (SCI/EI) IF= 3.771
19. Leng C, Wang X D*, Wang T H, Yan W M*. Multi-parameter optimization of flow and heat transfer for a novel double-layered microchannel heat sink. International Journal of Heat and Mass Transfer 84 (2015) 359-369. (SCI/EI) IF=3.891
20. Leng C, Wang X D*, Wang T H, Yan W M*. Fluid flow and heat transfer in microchannel heat sink based on porous fin design concept. International communications in heat and mass transfer 65 (2015) 52-57. (SCI/EI) IF=4.463
21. Wang B B, Wang X D*, Yan W M*, Wang T H. Molecular dynamics simulations on coalescence and non-coalescence of conducting droplets. Langmuir 31 (2015) 7457-7462. (SCI/EI) IF=3.789
22. Wang B B, Wang X D*, Wang T H, Lee D J. Size control mechanism for bio-nanoparticle fabricated by electrospray deposition. Drying Technology 33 (2015) 406-413. (SCI/EI) IF=2.219
23. Wang X D*, Zhang X, Xu J L, Yan Y Y, Liu D, Wang T H. Special Issue on advances in micro/nanoscale fluid flow and heat transfer. Advances in Mechanical Engineering (Special Issue Editorial), 2015, 7: 1-2. (SCI) IF=0.848
24. Wang B B, Wang X D*, Wang T H. Microscopic mechanism for the effect of adding salt on electrospinning by molecular dynamics simulations. Applied Physics Letters, 2014, 105: 121906. (SCI/EI) IF=3.495
25. Wang T H, Xu J L*, Wang X D*. Self-heating-dependent characteristic of GaN-based light-emitting diodes with and without AlGaInN electron blocking layer. Chinese Science Bulletin (known as “Science Bulletin” since 2015), 2014, 59: 2460-2469. (SCI) IF= 4.136
26. Xu J L*, Wang T H. Efficiency droop improvement for InGaN-based light-emitting diodes with gradually increased In-composition across the active region. Physica E: Low-dimensional Systems and Nanostructures, 2013, 52: 8-13. (SCI/EI) IF= 2.399
27. Wang T H, Xu J L*, Wang X D*. Efficiency improvement of light-emitting diodes with a developed electron blocking layer structure and its optimization. Physica E: Low-dimensional Systems and Nanostructures, 2013, 47: 51-58. (SCI/EI) IF= 2.399
28. Wang T H, Xu J L*. Advantage of InGaN-based light-emitting diodes using AlGaInN electron blocking layer coupled with inserting InGaN layer. Optik - International Journal for Light and Electron Optics, 2013, 124: 5866-5870. (SCI/EI) IF=1.191
29. Wang T H, Xu J L*. Improved performance of InGaN light-emitting diodes with a novel sawtooth shaped electron blocking layer. Chinese Physics B, 2013, 22: 088504. (SCI/EI) IF= 1.321
30. Wang T H, Xu J L*. Improved efficiency droop characteristics in InGaN/GaN light-emitting diodes with a novel designed last barrier structure. Chinese Physics B, 2012, 21: 128504. (SCI/EI) IF= 1.321
31. Wang T H, Xu J L*, Wang X D*. The effect of multi-quantum barrier structure on light-emitting diodes performance by a non-isothermal model. Chinese Science Bulletin (known as “Science Bulletin” since 2015), 2012, 57: 3937-3942. (SCI) IF= 4.136
奖励与荣誉
北京市优秀毕业生;
博士研究生国家奖学金;
华北电力大学校长奖学金;
中国工程热物理学会青年优秀论文二等奖
招生信息
招收热爱科学研究的本科生/硕士研究生