柔性直流输配电、中高压DC-DC功率变换、电力电子变压器、大功率定制化器件
zhao-biao@tsinghua.edu.cn
北京市海淀区清华大学西主楼2区110室
现为清华大学电机系副教授,博士生导师。2009年本科毕业于大连理工大学,后保送进入清华大学,2014年获博士学位;2014年至2016年在清华大学电机系从事博士后研究,2016年至2017年在美国弗吉尼亚理工大学CPES中心从事博士后研究;2017年9月加入清华大学电机系,主要从事柔性直流输配电、高压大容量功率变换等领域研究工作。近5年主持或参与科研项目10余项,其中主持国家自然科学基金项目2项、中国博士后科学基金2项、国家重点实验室基金项目1项。近年来,在国内外期刊及会议上发表SCI/EI论文50余篇,他引2000余次,3篇论文入选ESI Highly Cited Paper,1篇论文入选F5000中国精品科技期刊顶尖学术论文;以第一作者出版国内专著1部,参编国际专著1部,申请及授权专利30余项。曾获:TPEL’s Outstanding Reviewer,GE基金会科技创新奖,HYOSUNG Global Thesis Competition Grand Prize Paper,清华大学优秀博士论文一等奖,清华大学“学术新秀”,清华大学特等奖学金等。
个人简历:
2018.12–至今, 清华大学,电机系,副教授,博士生导师
2017.09 – 2018.12, 清华大学,电机系, 助理教授,博士生导师
2016.08 - 2017. 08,美国弗吉尼亚理工大学,CPES,博士后
2014.7 - 2016.7, 清华大学,电机系,博士后
2009.9 - 2014.7, 清华大学,电力系统自动化, 博士
2005.9 - 2009.7, 大连理工大学, 电气工程及其自动化, 学士
个人荣誉与获奖:
2017年F5000中国精品科技期刊顶尖学术论文
2017年中国电机工程学会直流输电“创新杯”一等奖
2016 Outstanding Reviewer of IEEE Transactions on Power Electronics
2015年《中国电机工程学报》优秀作者
2014年清华大学优秀博士学位论文一等奖
2013年清华大学“学术新秀”
2012年清华大学特等奖学金
2011 The 2nd HYOSUNG Global Thesis Competition: Grand Prize
2011 GE Foundation TECH AWARD
1、研究生课程:
能源互联网中的能量转换与互联设备,32学时,秋季学期
1、纵向项目
2019.01~2022.12, 国家自然科学基金面上项目, “基于开关电容的电流源型直流变压器构造机理及关键技术研究”(**)
2016.01~2019.12, 国家自然科学基金面上项目, “主动利用环流和电容电压波动的MMC控制方式研究”(**)
2016.01~2016.12, 国家自然科学基金青年项目, “基于模块化多电平变换原理的高频链直流变压器研究”(**)
2015.01-2018.12,国家863计划项目,“紧凑化多端柔性直流配电网控制保护关键技术” (2015AA050103)
2、横向项目
2018.01-2020.12,国家电网公司,“适用于电磁暂态仿真的交直流设备仿真建模及初始化技术研究”
2018.09-2019.06,国家能源局,“大规模海上风电直流汇入电网系统规范研究”
2018.08-2019.05,中国能源建设集团广东省电力设计研究院有限公司,“支持能源消费革命的城市-园区双级“互联网+”智慧能源示范工程物理层项目”
2018.02-2018.12,中国工程院,“我国未来电网格局研究-课题四”
2014.05-2015.12,深圳供电局有限公司,“基于柔性直流的智能配电关键技术研究与应用”
2011.06-2013.06,清华罗姆联合研究计划,“基于碳化硅器件的智能功率变换系统的研制”
在国内外期刊及会议上发表SCI/EI论文50余篇,他引2000余次,Google Scholar H-index为20;以第一作者出版国内专著1部,参编国际专著1部;申请及授权专利30余项。
1、专著
1)赵彪;宋强,双主动全桥DC-DC变换器的理论和应用技术,科学出版社,2017
2)B. Zhao, R. Zeng, Q. Song, Z. Yu and L. Qu. Medium-voltage dc power distribution technology. Chapter 6 in The Energy Internet. Elsevier, 2018.
2、国际期刊论文选
1)G. Lv, C. Zhuang, J. Liu, B. Zhao, Z. Yu, and R. Zeng, “Optimization for cell arrangement design of gate-commutated thyristors based on whole wafer model and Tabu search,” IEEE Trans. Electron Devices., vol. 65, no. 11, pp. 4938–4946, Nov. 2018.
2)B. Zhao, R. Zeng, Z. Yu, Q. Song, Y. Huang, Z. Chen, and T. Wei, “A prospective look on IGCT for flexible high-voltage high-power dc grid: a promising choice,” IEEE Industrial Electronics Magazine., vol. 12, no. 3, pp. 6–18, Sep. 2018.
3)Q. Song, B. Zhao, J. Li, and W. Liu, “An improved dc solid state transformer based on switched capacitor and multiple-phase-shift shoot-through modulation for integration of LVDC energy storage system and MVDC distribution grid,” IEEE Trans. Industrial Electronics. , vol. 65, no. 8, pp. 6719–6729, August. 2018.
4)B. Zhao, Q. Song, J. Li, X. Xu, and W. Liu, “Comparative analysis of multilevel-high-frequency-link and multilevel-dc-link dc-dc transformers based on MMC and dual-active bridge for MVDC application,” IEEE Trans. Power Electronics., vol. 33, no. 3, pp. 2035–2049, March. 2018.
5)B. Zhao, Q. Song, J. Li, and W. Liu, “A modular-multilevel-dc-link front-to-front dc solid state transformer based on high-frequency dual active phase-shift for HVDC grid integration,” IEEE Trans. Industrial Electronics. , vol. 64, no. 11, pp. 8919–8927, Nov. 2017.
6)B. Zhao, Q. Song, J. Li, Q. Sun, and W. Liu, “Full-process operation, control and experiments of modular High-frequency-link dc transformer based on dual-active-bridge for flexible MVDC distribution: a practical tutorial,” IEEE Trans. Power Electronics., vol. 32, no. 9, pp. 6751–6766, Sep. 2017.
7)B. Zhao, Q. Song, J. Li, Y. Wang, and W. Liu, “High-frequency-link modulation methodology of dc-dc transformer based on modular multilevel converter for HVDC application: comprehensive analysis and experimental verification,” IEEE Trans. Power Electronics., vol. 32, no. 5, pp. 3413–3424, May. 2017.
8)B. Zhao, Q. Song, J. Li, Y. Wang, and W. Liu, “Modular multilevel high-frequency-link dc transformer based on dual active phase-shift principle for medium-voltage dc power distribution application,” IEEE Trans. Power Electronics., vol. 32, no. 3, pp. 1779–1791, March. 2017.
9)B. Zhao, Q. Song, J. Li, W. Liu, G. Liu, and Y. Zhao, “High-frequency-link dc transformer based on switched capacitor for medium-voltage dc power distribution application,” IEEE Trans. Power Electronics., vol. 31, no. 7, pp. 4766–4777, July. 2016.
10)B. Zhao, Q. Song, W. Liu, and Y. Zhao, “Transient dc bias and current impact effects of high-frequency-isolated bidirectional dc-dc converter in practice,” IEEE Trans. Power Electronics., vol. 31, no. 04, pp. 3203–3216, April. 2016.
11)B. Zhao, Q. Song, W. Liu, G. Liu, and Y. Zhao, “University high-frequency-link characterization and practical fundamental-optimal strategy for dual-active-bridge dc-dc converter under PWM plus phase-shift control,” IEEE Trans. Power Electronics., vol. 30, no. 12, pp. 6488–6494, Dec. 2015.
12)B. Zhao, Q. Song, and W. Liu, “A practical solution of high-frequency-link bidirectional solid-state transformer based on advanced components in hybrid micro-grid,” IEEE Trans. Industrial Electronics., vol. 62, no. 7, pp. 4587–4597, July. 2015.
13)B. Zhao, Q. Song, W. Liu, and Y. Sun, “A synthetic discrete design methodology of high-frequency isolated bidirectional dc-dc converter for grid-connected battery energy storage system using advanced components,” IEEE Trans. Industrial Electronics., vol. 61, no. 10, pp. 5402–5410, Oct. 2014.
14)B. Zhao, Q. Song, W. Liu, and Y. Sun, “Overview of dual-active-bridge isolated bidirectional dc-dc converter for high-frequency-link power-conversion system,” IEEE Trans. Power Electronics., vol. 29, no. 8, pp. 4091–4106, Aug. 2014.
15)B. Zhao, Q. Song, and W. Liu, “Dead-time effect of the high-frequency isolated bidirectional full-bridge dc-dc converter: comprehensive theoretical analysis and experimental verification,” IEEE Trans. Power Electronics., vol. 29, no. 4, pp. 1667–1680, April. 2014.
16)B. Zhao, Q. Song, and W. Liu, “Experimental comparison of isolated bidirectional dc-dc converters based on all-Si and all-SiC power devices for next-generation power conversion application,” IEEE Trans. Industrial Electronics., vol. 61, no. 3, pp. 1389–1393, March. 2014.
3、国际会议论文选
1)T. Wei, Q. Song, J. Li, B. Zhao, et al, “Experimental evaluation of IGCT converters with reduced di/dt limiting inductance,” in Proc. 2018 IEEE Applied Power Electronics Conference and Exposition (APEC)., 2018, pp. 1710–1760.
2)B. Zhao, Q. Song, W. Liu, and Y. Sun, “Characterization and application of next-generation SiC power devices for high-frequency isolated bidirectional dc-dc converter,” in Proc. 38th (IECON)., 2012, pp. 281–286.
4、国内期刊论文选
1)曾嵘,赵宇明,赵彪, 钟庆,童亦斌,等. 直流配用电关键技术研究与应用展望. 中国电机工程学报, 2018, 38(23): 6791-6801.
2)曾嵘,赵彪, 余占清,宋强,等. IGCT在直流电网中的应用展望. 中国电机工程学报, 2018, 38(15): 4307-4318.
3)李建国,赵彪, 宋强,刘文华. 适用于中高压直流电网的开关电容接入式直流变压器. 电工技术学报, 2018, 33(2): 817-825.
4)李建国,赵彪, 宋强,黄永章,等. 适用于中压直流电网的多电平直流链固态变压器. 中国电机工程学报, 2016, 36(14): 3717-3726.
5)李建国,赵彪, 宋强,黄永章,刘文华. 直流配电网中高频链直流变压器的电压平衡控制策略研究. 中国电机工程学报, 2016, 36(2): 327-334.
6)刘国伟,赵彪,赵宇明,王一振, 等. 中压柔性直流配电技术在深圳电网的应用框架. 南方电网技术, 2015, 9(09): 1-10.
7)王一振, 赵彪, 袁志昌,付娇, 等. 柔性直流技术在能源互联网中的应用探讨. 中国电机工程学报, 2015, 35(14): 3551-3560.
8)赵彪, 赵宇明, 王一振, 刘国伟, 等. 基于柔性中压直流配电的能源互联网系统. 中国电机工程学报, 2015, 35(19): 4843-4851.
9)赵彪, 宋强, 刘文华, 刘国伟, 等. 用于柔性直流配电的高频链直流固态变压器. 中国电机工程学报, 2014, 34(25): 4295-4303.
10)宋强,赵彪, 刘文华, 赵宇明. 智能电网中的新一代高频隔离功率转换技术. 中国电机工程学报, 2014, 34(36): 6369-6379.
11)宋强, 赵彪, 刘文华, 曾嵘. 智能直流配电网研究综述. 中国电机工程学报, 2013, 33(25): 9-20.
5、授权专利选
1)曾嵘,宋强,赵彪,余占清, 一种基于IGCT的高压大容量模块化多电平换流器, 2018.08, 中国, ZL3.8
2)陈政宇,曾嵘,余占清,赵彪,宋强, 应用于GCT器件门极驱动的电源管理电路, 2018.08, 中国, ZL8.8
3)赵彪,李建国,宋强,曾嵘,余占清, 他励启动自励供电的级联子模块电源系统, 2018.08, 中国, ZL2.6
4)赵彪,宋强,曾嵘,李建国, 一种高压大容量直流变压器, 2018.06, 中国, ZL2.5
5)赵彪,宋强,刘文华,刘国伟,赵宇明,姚森敬, 一种用于中低压直流配电的高频链多电平直流变压器, 2018.02, 中国, ZL2.9
6)赵彪,宋强,刘文华,刘国伟,赵宇明,姚森敬, 一种开关电容接入的高频链双向直流变压器及其控制方法, 2017.07, 中国, ZL1.0
7)赵彪,赵宇明,刘国伟,李建国,宋强,刘文华,姚森敬, 一种用于楼宇建筑的双极多层低压直流配电系统, 2017.02, 中国, ZL7.3
8)赵彪,宋强,刘文华,刘国伟,赵宇明,姚森敬, 一种用于双主动全桥直流变换器的软启动控制方法, 2017.01, 中国, ZL7.7
9)赵彪,宋强,刘文华,刘国伟,赵宇明,姚森敬, 一种用于双主动全桥直流变换器的暂态移相控制方法, 2017.01, 中国, ZL3.0
10)赵彪,宋强,刘文华, 一种用于双主动全桥直流变换器的混合移相控制方法, 2015.08, 中国,ZL8.4
