姓　　名：吴永佳
性　　别：男
职　　称：教授
系　　所：建筑环境与能源应用工程系
学　　历：博士
学　　位：工学博士
电 话：**
邮　　箱：yjwu2019@whut.edu.cn
研究兴趣：建筑太阳能利用；热电发电和制冷；能源俘获和利用；热功能材料和设计；超高热流密度电子器件散热；太阳能热气流；MEMS热和微流体传感器
教育经历
2015.08-2019.05 弗吉尼亚理工大学（Virginia Tech）
2013.09-2015.07 华中科技大学
2009.09-2013.07 华中科技大学
工作经历：
2015.08-2019.05 弗吉尼亚理工大学机械工程系科研助理
2016.01-2016.05 弗吉尼亚理工大学机械工程系助教
2019.08-至今 武汉理工大学土木工程与建筑学院教师
奖励与荣誉
2019.02 弗吉尼亚理工大学 工程院年度最佳博士研究生提名
2018.12 教育部 国家优秀自费留学生奖学金
2018.07 美国机械工程师协会 IDETC/CIE Best Paper Award
2018.03 弗吉尼亚理工大学 校年度研究生提名
2017.03 弗吉尼亚理工大学 工程院年度最佳博士研究生提名
个人简介：
吴永佳，男，博士。2013和2015年先后从华中科技大学能源与动力工程学院本科和硕士学位，2019年5月获得美国弗吉尼亚理工大学机械工程博士学位。2019年8月起在武汉理工大学土木工程与建筑学院建筑环境与能源应用工程系任教。主要进行热学和流体科学与工程研究，研究方向涉及宏观/微观传热传质、热电能量收集、激光3D打印和高精度MEMS 热和微流体传感器设计和制备。参与完成美国国家自然科学基金和美国能源部项目 4 项，中国国家自然科学基金 1 项，湖北省自然科学基金1项。在国际知名杂志上发表学术论文 30 余篇，其中 SCI 论文 20 余篇，参与编著英文学术专著 1 部。受邀为Energy, Applied Physics Letters等国际知名SCI期刊审稿。获美国机械工程师协会（ASME）IDETC/CIE会议2018年度最佳论文奖，2018 年度国家留学基金管理委员会优秀自费留学生奖金，2017和2018年度弗吉尼亚理工大学工程院机械系最佳博士生提名等荣誉。目前为美国机械工程师协会(ASME)和核科学协会(ANS)会员。
本科教学：
传热学
科研项目：
（1）美国能源部项目（DOE NEUP Project 16-10884），Self-powered Wireless Through-wall Data Communication for Nuclear Environments (the main project)，$1,000,000，2016.10-2019.05，参与；
（2）美国自然科学基金项目（#**-GOALI）: Energy Harvesting Nano-rods Enhanced MEMS Temperature Insensitive Gas Sensor for Combustion Monitoring and Control
（3）美国自然科学基金项目（#** - IDBR）: Development of Ultrasensitive, Superfast, and Microliter-Volume Differential Scanning Nanocalorimeter for Direct Characterization of Biomolecular Interactions
nanocalorimeter
（4）美国能源部项目: Self-powered Wireless Dual-mode Langasite Sensor for Pressure & Temperature Monitoring of Nuclear Reactors

发表的代表性论著：
专著与教材：
[1] Tingzhen Ming, Wei Liu, Yongjia Wu, Jinle Gui, Keyuan Peng, Tao Pan. “Chapter One: Introduction” in Solar Chimney Power Plant Generating Technology, Elsevier Academic Press and Zhejiang University Press. 2016.
学术论文：
期刊论文
2020
[1] Yongjia Wu, Tingzhen Ming, Renaud de_Richter, Rüdiger H?ffer, Hans-Jürgen Niemann. Large-scale freshwater generation from the humid air using the modified solar chimney. Renewable Energy, 2020, 146: 1325-1336.
2019
[2] Yongjia Wu, Shifeng Yu, Lei Zuo. Large eddy simulation analysis of the heat transfer enhancement using self-oscillating fluidic oscillators. International Journal of Heat and Mass Transfer, 2019, 131: 463-471.
[3] Yongjia Wu, Jackson Klein, Hanchen Zhou, Lei Zuo. Energy harvesting for wireless communications in nuclear environment. Annals of Nuclear Energy, 2019, 126: 376-388.
[4] Shifeng Yu, Yongjia Wu, Shuyu Wang, Ming Lu, Lei Zuo. Thermodynamic analysis of a MEMS based differential scanning calorimeter. Sensors & Actuators: A. Physical, 2019, 291:150-155.
[5] Tingrui Gong, Yongjia Wu, Lei Gao, Long Zhang, Juntao Lia, Tingzhen Ming. Thermo-mechanical analysis on a compact thermoelectric cooler. Energy, 2019, 172:1211-1224.
[6] Tingrui Gong, Lei Gao, Yongjia Wu, Long Zhang, Shan Yin, Juntao Li, Tingzhen Ming. Numerical simulation on a compact thermoelectric cooler for the optimized design. Applied Thermal Engineering, 2019, 146:815-825.
2018
[7] Yongjia Wu, Haifeng Zhang, Lei Zuo. Thermoelectric energy harvesting for the gas turbine sensing and monitoring system. Energy Conversion and Management, 2018, 157:215-223.
[8] Yongjia Wu, Jihui Yang, Shikui Chen, Lei Zuo. Thermo-element geometry optimization for high thermoelectric efficiency. Energy, 2018, 147:672-680.
[9] Yongjia Wu, Jackson Klein, Hanchen Zhou, Lei Zuo. Thermal and fluid analysis of dry cask storage containers over multiple years of service. Annals of Nuclear Energy, 2018, 112:132-142.
[10]Tao Pan, Tingrui Gong, Wei Yang, Yongjia Wu. Numerical study on the thermal stress and its formation mechanism of a thermoelectric device. Journal of Thermal Science, 2018, 27(3): 249-258.
2017
[11]Tingzhen Ming^#, Yongjia Wu^#, Wei Liu, SA Sherif. Solar updraft power plant system: A brief review and a case study on a new system with radial partition walls in its collector. Renewable and Sustainable Energy Reviews, 2017. (co-first author)
[12]Tingzhen Ming, Tingrui Gong, RK de Richter, Yongjia Wu, Wei Liu. A moist air condensing device for sustainable energy production and water generation. Energy Conversion and Management, 2017.
[13]Tingrui Gong,Tingzhen Ming, Xiaoming Huang, RK de Richter,Yongjia Wu,Wei Liu. Numerical analysis on a solar chimney with an inverted U-type cooling tower to mitigate urban air pollution.Solar Energy,2017, 147: 68-82.
[14]Tingzhen Ming, Wei Yang, Yongjia Wu, Yitian Xiang, Xiaoming Huang, Jiangtao Cheng, Xiaohua Li, Jiyun Zhao. Numerical analysis on the thermal behavior of a segmented thermoelectric generator. International Journal of Hydrogen Energy, 2017, 42(5): 3521-3535.
[15]Tingzhen Ming, Wei Yang, Xiaoming Huang, Yongjia Wu, Xiaohua Li, Jun Liu. Analytical and numerical investigation on a new compact thermoelectric generator. Energy conversion and management, 2017, 132: 261-271.
2016
[16]Yongjia Wu, Lei Zuo, Jie Chen, Jackson Klein. A model to analyze the device level performance of thermoelectric generator, Energy, 2016, 115: 591-603.
[17]Jie Chen, Lei Zuo, Yongjia Wu, Jackson Klein. Modeling, experiments and optimization of an on-pipe thermoelectric generator. Energy Conversion and Management, 2016, 122: 298-309.
[18]Jie Chen, Jackson Klein, Yongjia Wu, Lei Zuo. A Thermoelectric Energy Harvesting System for Powering Wireless Sensors in Nuclear Power Plants. IEEE Transactions on Nuclear Science, 2016, 63(5): 2738-2746.

会议论文
[1] Yongjia Wu, Lei Zuo, Kan Sun. Modeling the selective laser melting of multi-component thermoelectric powders. 2018 IDETC/CIE. Quebec. Canada.
[2] Yongjia Wu, Jackson Klein, Hanchen Zhou, Lei Zuo. Energy harvesting for nuclear waste sensing and monitoring. 2018 IDETC/CIE. Quebec. Canada. (Best paper award)
[3] Yongjia Wu, Lei Zuo, Suresh Kaluvan, Haifeng Zhang, Nance Ericson, Kyle Reed, Roger Kisner. Self-powered Wireless Through-wall Data Communication for Nuclear Environments. 11th Nuclear Plant Instrumentation, Control and Human-Machine Interface Technologies 2019. Orlando FL.
[4] Kan Sun, Yongjia Wu, Huan Qi, Zhiwei Wu, Lei Zuo. Direct energy deposition 3d printing of thermoelectric materials: simulation and experiments. 2019 IDETC/CIE. Anaheim CA.