姓名:张翔宇
职称:副教授,硕士生导师
所在院系(所):电气与电子工程学院先进输电研究所
研究方向(Focus Area):
Ø柔性直流输电装备 (Flexible DC Transmission Equipment)
Ø大功率电力电子组部件 (High-Power Power Electronic Modules)
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-),《iEnergy》期刊青年编委(2024-)。
主要从事高压大容量电力电子技术前沿工作,重点围绕柔直换流阀、直流断路器等多类高压柔性输电装备共性基础组件开展系列研究。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目前容量最大的500kV/25kA直流断路器,并在张北柔性直流电网中成功应用。目前正深度参与到拟建的±800kV藏东南新能源外送工程(世界容量最大的柔性直流输电)中8GW柔直换流阀与50kA直流断路器的研制工作中,持续支撑国产尖端柔性输电装备攻关。
主持国家自然科学基金项目2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100余万。近五年以第一/通讯作者身份发表SCI顶级论文40余篇(1区论文38篇,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16项,1项获中国专利优秀奖。获中国能源研究会能源创新奖(2022,排名1)、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、教学与人才培养情况
1.教学课程
《电力电子技术》(本科生必修课程),2022年起,48学时
2.学生培养
协助指导7名博士生获国家奖学金、1名博士获华北电力大学优秀博士论文、1名博士生获北京市优秀毕业生、3名博士生获第十一届直流输电与电力电子创新杯大赛三等奖,指导1名硕士生获国家奖学金、1名硕士生获北京市优秀毕业生、2名硕士生获华北电力大学优秀硕士论文,指导1名本科生获华北电力大学百篇优秀毕业设计(论文)。
三、主要科研项目情况
[1] 国家自然科学基金面上项目,52577196,“高压大容量IGCT-IGBT混合器件载流-开关特性重构与集成调控方法”,2026.01-2029.12,65万,负责人。
[2] 国家自然青年科学基金C类,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] 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。
[4] 台达科教基金重点项目,“面向柔性直流换流阀的IGCT-IGBT复合开关组件构造与性能提升方法”,2025.08-2027.08,65万,负责人。
[5] 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。
[6] 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。
[7] 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。
[8] 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、主要获奖
[1] 中国能源研究会能源创新奖(2022,排名1)
[2] 中国专利优秀奖(2022,排名3)
[3] 日内瓦国际发明展览会银奖(2022,排名5)
[4] 获首届“中国电工技术学会优秀博士学位论文”(2021,全国5人)
[5] 清华大学第二十四届“学术新秀”(2020,全校10人)
[6] 清华大学优秀博士论文(2020,排名前2%)
[7] 清华大学优秀毕业生(2020,排名前2%)
五、代表性论文
[1] J. Wang; L. Chen; X. Zhang*; J. Liu; B. Zhao; Z. Yu, "Enhancing Turn-Off Performance in IGCT-Based High Power Applications—Part I: Anomalous High Current Turn-Off Mode and Safe Operating Area Expansion at Ultra-Low Voltage," in IEEE Transactions on Power Electronics, vol. 40, no. 4, pp. 5309-5318, Apr. 2025.
[2] L. Chen; J. Wang; X. Zhang*; L. Wang; Z. Chen; B. Zhao; J. Wu; Z. Yu; L. Qi, "Enhancing Turn-off Performance in IGCT-Based High Power Applications—Part II: Hybrid Switch with IGBT Integration and Experimental Validation," in IEEE Transactions on Power Electronics, vol. 40, no. 2, pp. 3168-3176, Feb. 2025.
[3] T. Yang; X. Zhang*; Z. He; H. Shen; Z. Dongye; L. Qi; X. Cui, "A High-Performance DC Controllable Arrester With Flexible Operation Based on Semicontrolled and Fully-Controlled Hybrid Bypass Switch," in IEEE Transactions on Power Electronics, vol. 40, no. 8, pp. 10945–10956, Apr. 2025.
[4] J. Yang; X. Zhang*; R. Chang; Z. Wu; X. Mu; B. Gu; L. Qi, "A Novel Method for Identifying the Reverse Recovery State of Thyristors Based on Gate Voltage," in IEEE Transactions on Industrial Electronics, vol. 72, no. 8, pp. 8694-8698, Aug. 2025.
[5] Yan Shi; X. Zhang*; Lvyang Chen; Wei Li; Lei Qi, "Analysis and Optimization for Current Overload Capability of Hybrid Transformers Under Grid Voltage Sag," in IEEE Transactions on Industrial Electronics, vol. 72, no. 3, pp. 2313-2324, Mar. 2025.
[6] Xiaoyu Shen; X. Zhang*; Hong Shen; Zhonghao Dongye; Bowen Gu; Lei Qi, "Identification of the Early Degradation of Bond Wire via Multidimensional Data Fusion Based on RMT," in IEEE Transactions on Instrumentation and Measurement, vol. 74, pp. 1-13, 2025, Art no. 3503713.
[7] Y. Shi, X. Zhang*, Y. Wu, W. Li and L. Qi, "Application Expansion of DC Bias Suppression for Hybrid Transformers in Flexible AC Grid Regulation," in IEEE Transactions on Power Electronics, vol. 39, no. 12, pp. 15398-15402, Dec. 2024.
[8] B. Zhang, X. Zhang*, T. Shan, J. Luo, W. Li and L. Qi, "A High-Performance Low-Cost Resonant DC Load Switch Exclusively Utilizing Semi-Controlled Devices," in IEEE Transactions on Power Delivery, vol. 39, no. 5, pp. 2880-2893, Oct. 2024.
[9] B. Zhang, X. Zhang*, S. Wu, L. Zhan and L. Qi, "A Novel Dual-LC Resonant DC Circuit Breaker Employing Soft-Switching Technique for Enhanced Performance," in IEEE Transactions on Industrial Electronics, vol. 71, no. 8, pp. 9023-9033, Aug. 2024.
[10] S. Wu, X. Zhang*, Z. He, M. Jin and L. Qi, "An Economical Concentrated DC Chopper Based on Thyristors With Resonant Self-Turn-Off Ability for Offshore Wind VSC-HVdc System," in IEEE Transactions on Industrial Electronics, vol. 71, no. 8, pp. 9951-9955, Aug. 2024.
[11] 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," in IEEE Transactions on Industrial Electronics, vol. 71, no. 3, pp. 2375-2384, Mar. 2024.
[12] X. Zhang, J. Yang, Z. Wu, B. Zhang and L. Qi, "A Novel Thyristor-Controlled Voltage Source Based Forced Resonant Mechanical DC Circuit Breaker," in IEEE Transactions on Power Electronics, vol. 38, no. 11, pp. 14563-14572, Nov. 2023.
[13] 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," in IEEE Transactions on Power Electronics, vol. 38, no. 9, pp. 10569-10573, Sep. 2023.
[14] X. Zhang, X. Chen, L. Qi and W. Li, "High-Performance and Economical Forced Resonant DC Circuit Breaker: Topology, Design, and Development," in IEEE Industrial Electronics Magazine, vol. 17, no. 1, pp. 46-54, Mar. 2023.
[15] X. Zhang, L. Zhan, L. Qi, "Performance Enhancement Method for Power Electronic Switch in Hybrid DC Circuit Breaker Based on Partial Precooling," in IEEE Transactions on Power Electronics, vol. 38, no. 1, pp. 118-122, Jan. 2023.
[16] 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," in IEEE Transactions on Power Electronics, vol. 37, no. 3, pp. 2465-2469, Mar. 2022.
[17] 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," in IEEE Transactions on Power Electronics, vol. 36, no. 11, pp. 12202-12206, Nov. 2021.
[18] 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," in IEEE Industrial Electronics Magazine, vol. 14, no. 2, pp. 15-27, Jun. 2020.
[19] 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," in IEEE Transactions on Industrial Electronics, vol. 67, no. 6, pp. 4485-4495, Jun. 2020.
[20] 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," in IEEE Transactions on Power Electronics, vol. 35, no. 2, pp. 1165-1170, Feb. 2020.
