姓名:张翔宇
职称:副教授、硕士生导师
所在院系(所):16877太阳集团安全入口
研究方向(Focus Area):
Ø柔性直流输电装备
Ø大功率电力电子组部件
联系方式:
办公地址:主楼A431
电子邮箱:zhangxiangyu@ncepu.edu.cn
一、个人简介及主要荣誉称号
张翔宇,男,1992年11月生。2015年在清华大学电气工程及其自动化专业获得工学学士学位,2020年在清华大学电气工程专业获得工学博士学位。2022年12月华北电力大学博士后出站,2023年被聘为副教授,同年被聘为硕士生导师。入选第八届中国科协青年人才托举工程(2023年),担任中国电机工程学会电工理论与新技术专业委员会副秘书长(2022-),《IET Power Electronics》期刊编委(2022-),《Frontiers in Electronics》期刊评审编辑(2022-),第18届交直流输电国际会议(IET ACDC)分会主席(2022),《IEEE Transactions on Power Electronics》、《IEEE Transactions on Power Delivery》、《CSEE Journal of Power and Energy Systems》、《High Voltage》等期刊审稿人。
主要从事柔性直流输电装备与大功率电力电子组部件的相关研究工作,所提半导体开关技术方案被多个由院士牵头的鉴定委员会评价为“国际领先”水平,并被写入CIGRE直流断路器工作组报告与多个国家/能源行业标准中。作为主研人成功研制500kV直流断路器及多个中压断路器装备并应用于张北柔性直流电网等实际工程。主持国家自然科学基金青年项目1项,博士后特别资助1项(电气学科每批次约10人),博士后面上项目1项,作为子课题负责人承担国家重点研发计划1项,作为核心骨干(课题联系人)参与国家重点研发计划1项,纵向经费共180余万。近三年以第一/通讯作者身份发表SCI论文20余篇(均为1区,平均影响因子大于7)、中国电机工程学会优秀论文1篇,授权发明专利7项。获日内瓦国际发明展览会银奖(2022,排名5)、中国专利优秀奖(2022,排名3)、首届“中国电工技术学会优秀博士学位论文”(2021,全国5人)、清华大学第二十四届“学术新秀”(2020,全校10人),清华大学优秀博士论文与优秀毕业生(2020,排名前2%)等荣誉。
二、教学与人才培养
教学课程:
《电力电子技术》(本科生必修课),2022年起,48学时,53人。
三、主要科研项目情况
[1]中国科协青年人才托举工程,2022QNRC001,“大容量半导体开关新技术”,2022-2024. 30万,负责人。
[2]青年科学基金项目,52107004,“高压半导体开关的新型非线性电路构造及性能提升方法”,2022.01-2024.12,30万,负责人。
[3]国家重点研发计划课题,2021YFB1507003,“中压大容量紧凑型直流断路器技术”,2022.07-2025.06,125万,子课题负责人。
[4]国家重点研发计划课题,2021YFB2400602,“海上柔性直流系统过电压绝缘配合及电磁兼容关键技术”,2021.12-2025.11,530万,课题牵头单位联系人。
[5]中国博士后科学基金会面上资助,2021T140201,“基于新型限压电路的半导体开关电压利用效率提升方法研究”,2021.06-2022.08,18万,负责人。
[6]中国博士后科学基金会面上资助,2020M680484,“面向直流开断的经济型复合式电力电子开关关键技术研究”,2020.11-2022.08,8万,负责人。
四、代表性论文
[1] X. Zhang, J. Yang, Z. Wu, B. Zhang and L. Qi, “A Novel Thyristor-Controlled Voltage Source Based Forced Resonant Mechanical DC Circuit Breaker,”, IEEE Transactions on Power Electronics. (Early Access)
[2] X. Zhang, T. Shan, J. Luo; Y. Zhang, T. Zhan, L. Qi, "Development of a Thyristor-Assisted Hybrid DC Circuit Breaker for Reduced Cost and Size,” IEEE Transactions on Power Electronics. (Early Access)
[3] X. Zhang, L. Zhan; L. QI; "Performance Enhancement Method for Power Electronic Switch in Hybrid DC Circuit Breaker Based on Partial Precooling,” IEEE Transactions on Power Electronics, 2023, 38(1): 118-122.
[4] X. Zhang, X. Chen, L. Qi and W. Li, "High-Performance and Economical Forced Resonant DC Circuit Breaker: Topology, Design, and Development," IEEE Industrial Electronics Magazine, 2023, 17(1): 46-54.
[5]L. Chen, X. Zhang*, Y. Shi and L. Qi, "A Novel Mixture-Devices-Based Submodule for MMC by Using Low On-State Voltage IGCT and High di/dt Ability IGBT,”IEEE Transactions on Industrial Electronics. (Early Access)
[6]Y. Lu, X. Zhang*, H. Shen, W. Zhang, and Lei Qi, "A Segmented Rogowski Coils based Non-Invasive Monitoring Method of Current Imbalance in Press Pack IGBTs ,”IEEE Transactions on Power Electronics. (Early Access)
[7] X. Zhang, X. Yan, L. Qu and Z. Yu, "A Novel High-Power Hybrid DC Breaker Based on Compound Power Electronic Switch With Integrated Commutation Ability,”IEEE Transactions on Power Electronics, 2022, 37(3): 2465-2469.
[8] L. Qi, X. Chen, X. Qu, L. Zhan, X. Zhang* and X. Cui, "A Novel Forced Resonant Mechanical DC Circuit Breaker by Using Auxiliary Oscillation Switch for Zero-Crossing," IEEE Transactions on Power Electronics, 2021, 36(11): 12202-12206.
[9] X. Zhang, et al, "A State-of-the-Art 500-kV Hybrid Circuit Breaker for a dc Grid: The World's Largest Capacity High-Voltage dc Circuit Breaker," IEEE Industrial Electronics Magazine, 2020, 14(2): 15-27.
[10] X. Zhang et al, "A Novel Mixture Solid-State Switch Based on IGCT With High Capacity and IGBT With High Turn-off Ability for Hybrid DC Breakers," IEEE Transactions on Industrial Electronics, 2020, 67(6): 4485-4495.
[11] X. Zhang, Z. Yu, Z. Chen, B. Zhao and R. Zeng, "Optimal Design of Diode-Bridge Bidirectional Solid-State Switch Using Standard Recovery Diodes for 500-kV High-Voltage DC Breaker," IEEE Transactions on Power Electronics, 2020, 35(2): 1165-1170.