王雷个人简介
一、个人概况
王雷,87978797威尼斯老品牌,教授,博导
智能感知与电子新技术研究所 所长
2012年新加坡南洋理工大学访问学者
2004年浙江大学控制系获博士学位
2000年87978797威尼斯老品牌87978797威尼斯老品牌获硕士学位
1993年山东工业大学控制系获学士学位
主要兼职:
中国自动化学会
中国计量测试学会
中国仪器仪表学会
中国制冷学会
中国海洋学会
二、主要研究领域
智能感知、人工智能、氢能源、燃料电池、海水淡化、多相流检测
三、承担课题
1、承担纵向课题
(1)军工重点:***研制
(2)科技部重点研发计划:车用燃料电池喷射式氢气再循环泵研发
(3)山东省重大创新工程:高效低成本热法海水淡化关键技术与应用示范
(4)国家自然科学基金:汽车废热驱动喷射式制冷系统建模与优化控制研究
(5)山东省自然科学基金:冷链物流废热制冷系统双层预测控制研究
(6)山东中青年科学家奖励基金:中央空调多模型控制研究
(7)87978797威尼斯老品牌交叉学科培育计划:多模废热驱动汽车空调关键技术研究
2、承担横向课题
(1)济南军区后勤部档案馆智能化集成项目
(2)高铁济南西客站智能化集成系统
(3)寿光市商务小区建筑智能化系统工程
(4)寿光广电大厦建筑智能化及中央空调节能设计
(5)潍坊市高新区创新大厦智能化及中央空调系统优化控制
(6)寿光市交通大厦中央空调系统节能优化设计
(7)潍坊市阳光大厦中央空调系统优化控制及能源管理
(8)安庆海军医院中央空调系统优化控制设计
(9)潍坊高新区加速器智能化集成项目
(10)潍坊十笏园智能化项目
(11)昌乐检察院智能化集成项目
(12)兖州检察院智能化集成项目
(13)黄金时代一期与二期智能化集成项目
(14)上海交通大学空调节能实验室项目
(15)潍坊医药孵化器智能化集成项目
(16)新加坡-美国加州大学伯克利分校联合节能建筑示范项目SingBest绿色建筑中央空调控制系统项目
(17)新加坡南洋理工大学B-star智能建筑集成管理系统开发项目
四、研究成果
期刊文章(标*号的为通讯作者)
[1]Jiapeng Liu, Lei Wang*, Lei Jia, Xinli Wang. The influence of the area ratio on ejector efficiencies in the MED-TVC desalination system. Desalination, 2017, 413: 166-175. (SCI,IF=9.501)
[2]Chen Wang, Lei Wang*, Xinli Wang, Hongxia Zhao. Design and numerical investigation of an adaptive nozzle exit position ejector in multi-effect distillation desalination system. Energy, 2017, 140: 673-681. (SCI,IF=7.147)
[3]Lei Wang*, Jiapeng Liu, Tao Zou, Jingwei Du, Fengze Jia. Auto-tuning ejector for refrigeration system. Energy. 2018, 161: 536-543. (SCI,IF=7.147)
[4]Lei Wang, Wenjiang Cai*, Hongxia Zhao, Chen Lin, Jia Yan. Experimentation and cycle performance prediction of hybrid A/C system using automobile exhaust waste heat. Applied Thermal Engineering,2016, 94: 314-323. (SCI,IF=4.725)
[5]Jiapeng Liu, Lei Wang*, Lei Jia. A control oriental model for combined compression-ejector refrigeration system. Energy Conversion and Management, 2017, 135: 538-546. (SCI,IF=9.709)
[6]Jiapeng Liu, Lei Wang*, Lei Jia. A predictive model for the performance of the ejector in refrigeration system. Energy Conversion and Management, 2017, 150: 269-276. (SCI,IF=9.709)
[7]Lei Wang, Jia Yan. Numerical study on optimization of ejector primary nozzle geometries. International journal of refrigeration, 2017, 76: 219-229. (SCI,IF=3.629)
[8]Lei Wang, Chen Wang, Wenxiu Hou, Hongxia Zhao, Hailun Zhang. Experimental investigation on ejector performance near critical back pressure. International Journal of Refrigeration, 2017, 80: 158-168. (SCI,IF=3.629)
[9]JiaPeng Liu, Lei Wang*, Lei Jia, Xinli Wang. Thermodynamic model for all modes performance analysis of supersonic ejector considering non-uniform distribution of flow field. International Journal of Refrigeration. 2018, 96: 17-24. (SCI,IF=3.629)
[10]JiaPeng Liu, Lei Wang*, Lei Jia. Thermodynamic modeling and sensitivity analysis of ejector in refrigeration system. International Journal of Heat and Mass Transfer. 2018, 126: 485-492. (SCI,IF=5.584)
[11]Chen Wang, Lei Wang*, Hongxia Zhao, Zhongyong Du, Zhaoqiu Ding. Effects of Superheated Steam on Non-equilibrium Condensation in Ejector Primary Nozzle. International journal of refrigeration, 2016, 67: 214-226. (SCI,IF=3.461)
[12]Zhaoqiu Ding, Lei Wang*, Hongxia Zhao, Hailun Zhang, Chen Wang. Numerical Study and Design of a Two-stage Ejector for Subzero Refrigeration. Applied Thermal Engineering, 2016, 108: 436-448. (SCI,IF=4.725)
[13]Hongxia Zhao, Ke Zhang, Lei Wang*.Thermodynamic investigation of a booster-assisted ejector refrigeration system. Applied Thermal Engineering, 2016, 104: 274-281.(SCI, IF=4.725)
[14]Wenxiu Hou, Lei Wang*, Jia Yan, Xianbi Li, Ling Wang. Simulation on the Performance of Ejector in a Parallel Hybrid Ejector-based Refrigerator-freezer Cooling Cycle. Energy Conversion and Management, 2017, 143: 440-447. (SCI,IF=9.709)
[15]Hanrui Zhang, Lei Wang*, Jia Yan, Xianbi Li, Ling Wang. Performance investigation of a novel EEV-based ejector for refrigerator-freezers. Applied Thermal Engineering, 2017, 121: 336-343.(SCI, IF=5.295)
[16]Chen Wang, Lei Wang*, Tao Zou, Hailun Zhang. Influences of area ratio and surface roughness on homogeneous condensation in ejector primary nozzle. Energy Conversion and Management, 2017, 149: 168-174. (SCI,IF=9.709)
[17]Hailun Zhang, Lei Wang*, Lei Jia, Xinli Wang. Assessment and prediction of component efficiencies in supersonic ejector with friction losses. Applied Thermal Engineering, 2018, 129: 618-627. (SCI, IF=5.295)
[18]Hailun Zhang, Lei Wang*, Lei Jia, Hongxia Zhao, Chen Wang. Influence investigation of friction on supersonic ejector performance. International Journal of Refrigeration, 2018, 85: 229-239. (SCI,IF=3.629)
[19]Lei Wang*, Jiapeng Liu, Tao Zou, Jingwei Du, Fengze Jia, Tao Zou. An auto-tuning ejector for refrigeration system. Energy, 2018, 161: 536-543. (SCI,IF=6.082)
[20]Jiapeng Liu, Lei Wang*, Lei Jia, Xinli Wang. Thermodynamic model for all modes performance analysis of supersonic ejector considering non-uniform distribution of flow field. International journal of refrigeration, 2018, 96: 17-24. (SCI,IF=3.461)
[21]Kai Wang, Lei Wang*, Lei Jia, Wenjiang Cai, Rui Gao. Optimization design of steam ejector primary nozzle for MED-TVC desalination system. Desalination, 2019, 471: 114070. (SCI,IF=9.501)
[22]Huijun Ma, Hongxia Zhao, Lei Wang, Zeting Yu, Xiaoan Mao. Modeling and investigation of a steam-water injector. Energy Conversion and Management. 2017, 151: 170-178. (SCI, IF=9.709)
[23]Haoyuan Xue, Lei Wang, Hailun Zhang, Lei Jia, Jianbo Ren. Design and investigation of multi-nozzle ejector for PEMFC hydrogen recirculation. International journal of hydrogen energy. 2020, 45: 14500-14516, (SCI, IF=5.816)
[24]Jiapeng Liu, Lei Wang, Lei Jia, Haoyuan Xue.Thermodynamic analysis of the steam ejector for desalination applications. Applied Thermal Engineering, 2019, 159: 114713.(SCI, IF=5.295)
[25] HaoyuanXue; Lei Wang*; Lei Jia*; Chungang Xie; Qingchun Lv. Design and investigation of a two-stage vacuum ejector for MED-TVC system. Applied Thermal Engineering, 2020, 167: 114713. (SCI, IF=5.295)
[26] Jiapeng Liu; Lei Wang*; Lei Jia*; Haoyuan Xue. Thermodynamic analysis of the steam ejector for desalination applications. Applied Thermal Engineering, 2019, 159. SCI.
[27] Wending Gu; Xinli Wang*; Lei Wang; Xiaohong Yin; Hongbo Liu. Performance investigation of an auto-tuning area ratio ejector for MED-TVC desalination system. Applied Thermal Engineering, 2019, 155: 470-479. (SCI, IF=5.295)
[28] Zhiqiang Du; Qiang Liu; Xinli Wang; Lei Wang*. Performance investigation on a coaxial-nozzle ejector for PEMFC hydrogen recirculation system. Hydrogen Energy,2021,46:38026-38039. (SCI, IF=5.816)
[29] Yajie Song; Xinli Wang*; Lei Wang; Fengwen Pan; Wenmiao Chen; Fuqiang Xi. A twin-nozzle ejector for hydrogen recirculation in wide power operation of polymer electrolyte membrane fuel cell system. Applied Energy, 2021,300:117442. (SCI,IF=9.746)
发明专利
序号 |
授权日期 |
名称 |
专利号 |
类别 |
发明人 |
1 |
2017.10.13 |
一种喷射器临界工作点引射比预测优化方法 |
PCT/CN2017/106075 |
国际专利 |
王雷 |
2 |
2017.10.13 |
喷嘴位置可调的喷射器及装置 |
PCT/CN2017/106069 |
国际专利 |
王雷 |
3 |
2017.10.13 |
一种喷射器运行区间的优化控制方法 |
PCT/CN2017/106079 |
国际专利 |
王雷 |
4 |
2017.10.13 |
一种可自动调节的喷射器 |
PCT/CN2017/106084 |
国际专利 |
王雷 |
5 |
2016.02.10 |
一种换热量可控的汽车尾气换热器及其工作方法 |
ZL 2015 1 0061624.9 |
发明专利 |
王雷 赵红霞 石亚东 |
6 |
2017.01.25 |
一种改进的双级喷射式制冷系统 |
ZL 2014 1 0783823.6 |
发明专利 |
赵红霞 王雷 韩吉田 |
7 |
2016.06.29 |
一种可变换热量的热管换热器及工作方法 |
ZL 2015 1 0057921.6 |
发明专利 |
王雷 赵红霞石亚东 |
8 |
2016.08.17 |
一种冷藏车废热驱动双蒸发器喷射式制冷系统 |
ZL 2015 1 0087662.1 |
发明专利 |
王雷 赵红霞 丁兆秋 |
9 |
2017.12.19 |
一种冷藏车废热驱动引流式喷射式制冷系统 |
ZL 2015 1 0943112.5 |
发明专利 |
王雷 丁兆秋 赵红霞 |
10 |
2016.10.05 |
一种用于废热驱动的冷链物流喷射式制冷系统的喷射器 |
ZL 2014 1 0784672.6 |
发明专利 |
王雷 赵红霞 丁兆秋 |
11 |
2018.01.23 |
一种低品位热源驱动喷射式制冷系统及制冷方法 |
ZL 2015 1 0861547.5 |
发明专利 |
王雷 张海伦 赵红霞 |
六、联系方式
个人主页:https://www.researchgate.net/profile/Lei_Wang438/publications
http://faculty.sdu.edu.cn/wanglei1/zh_cn/index.htm
电子邮箱:leiwang@sdu.edu.cn
联系电话:
邮 编:250061
通讯地址:87978797威尼斯老品牌千佛山校区87978797威尼斯老品牌创新大厦602室