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张之梁

作者: 审核人: 访问量:3736发布时间:2022-07-08

姓名:张之梁性别:职务:
职称:教授导师类别:博士生导师办公室:自动化学院电气楼310
研究领域:高频电压调节模块、高频低功率芯片、电力电子数字控制技术和电力电子在新能源变换中应用
电话:13301583525Email:zlzhang@nuaa.edu.cn
个人简介:

 围绕航空航天电源系统国产化,坚持“宽禁带高频/超高频电力电子”研究。入选斯坦福大学John P.A.Ioannidis教授团队发布的全球前2%顶尖科学家2021榜单,受邀在2018年第一届亚洲宽禁带器件国际会议做大会报告,并分别在2018和2019担任IEEE JESTPE宽禁带器件谐振软开关特刊和宽禁带器件系统集成特刊的特邀副主编。获得宽禁带器件高频应用相关国家、省部级项目13项;与华为开展SiC双向高功率模组研究;并获得民航、航天航空、军工研究所和上市公司项目支持;与中国电科13所联合研发抗辐照FPGA全国产化芯片数字卫星电源系统,解决美国对中国高端辐照芯片卡脖子问题,成果在航天航空、雷达系统多个型号产品中得到应用,获国防科学技术进步二等奖、2021中国电子科技集团有限公司科技进步奖三等奖、2022年度中国雷达行业协会科技进步三等奖。

    在IEEE电力电子领域顶级期刊发表论文66篇;发表IEEE APEC, ECCE等国际会议论文62篇;论文累计他引3000余次 (Google Scholar), H指数29;单篇最高他引186次,引用人包括IEEE Fellow 29人,IEEE电力电子期刊副主编50人。申请人所提寄生分布参数“CSD损耗模型和通用设计方法”,被同行专家作为“器件高频损耗模型”被他引1000余次;与Yan-Fei Liu导师合作,以第一作者身份撰写功率器件高频驱动专著 High Frequency MOSFET Gate Drivers: Technologies and Applications (IET出版);第一届亚洲宽禁带器件2018国际会议做大会报告;获授权美国专利1项、发明专利25项。

    2017年入选国家优秀青年科学基金;获江苏省杰出青年基金、教育部霍英东青年基金;入选“江苏省333工程”、“江苏省六大人才高峰”;主持国家级项目4项、省部级项目9项;参与国家重点研发计划1项,主持军工与企业研发类项目20余项。与华为开展SiC双向高功率密度能量模组研究,大幅降低企业测试成本。获江苏省科学技术二等奖(排名第一)、美国联合技术公司“容闳”科教奖、第十八届中国国际高新技术成果交易会“优秀产品”奖。

    所提多项技术在中国电子科工集团14所雷达电源系统、13所合作航空XX型无人机电源、航天五院 XX型卫星电源系统、XX型超轻陀螺电源系统中应用。与中航、中船等研究所紧密合作,成功转化多项航空航天电源技术。与国内知名上市公司上能电气、致远电子、世纪金光半导体(国内SiC器件制造商)、珠海英诺赛科公司(国内GaN芯片器件制造商)、南京康尼机电、广州金升阳等紧密合作,转化多项宽禁带高频电力电子技术,服务国内电力电子产业界,解决高端电源产品被欧美垄断的问题,实现国产化和核心技术自主化可控,获国防科学技术进步二等奖1项。

    为IEEE高级会员;担任IEEE Power Control Core 委员/ 秘书;IEEE ECCE, APEC分会主席、分组委会委员、IEEE新兴电力电子技术副主编、IEEE JESTPEL 谐振宽禁带器件集成特刊副主编、宽禁带器件谐振变换器特刊副主编、IET高频中压变换器特刊副主编、《电源学报》编委、CPSS Trans. on PE编委、中国电源学会青年委员会荣誉委员。连续五年被评为《中国电机工程学报》优秀审稿专家。

    项目组目前包括硕士生15名,博士生4名,本科生6人;硕士毕业生24人,毕业去向包括:中电28所、55所、13所、国家电网、上海航天八院、中国航发、华为、大疆、美国国家仪器、台达电子、美国田纳西大学、美国加州大学圣芭芭拉分校、加拿大女皇大学等业内知名企业及高校。欢迎有志于从事电力电子相关事业的同学加入,请与本人直接联 zlzhang@nuaa.edu.cn。


获奖:


1) 美国联合技术公司“容闳”科教奖, “United Technologies Corporation Rong Hong Endowment” by United Technologies, 1999.

2) 2017年 江苏省科学技术奖 二等奖 (排名第一),“高效、高可靠性模块化智能集成储能系统关键技术及应用”

3) 2020 国防科学技术进步奖 二等奖, “飞行器电力作动永磁电机驱动系统关键技术及应用”

3) 第十八届中国国际高新技术成果交易会“优秀产品”奖 (电动汽车电力电子总成)

4) “Certificate for Teaching Assistants: Scholarship”, Program in University Teaching and Learning, Center for Teaching and Learning, Queen’s University, 2006.

5) 2016年中国高校电力电子与电力传动学术年会“优秀论文”

6) 南京市第九届自然科学优秀学术论文奖,三等奖,排名第一,2011年

7)  2015年《电机工程学报》优秀审稿人

8) 2016年江苏省电工技术学会先进工作者

9) 2016年度 江苏省电工科学技术一等奖 “规模化高性能储能系统关键技术”


荣誉与称号:

1) 2017年 国家优秀青年科学基金

2) 2016年 获江苏省杰出青年基金

3) 2016年 获教育部霍英东基金

4) 2016年入选“江苏省333工程”

5) 2016年入选“江苏省六大人才高峰”

6) 2015年度《中国电机工程学报》优秀审稿专家

7) 2015年江苏省电工技术学会“优秀工作者”荣誉称号

8) 入选2013年南京市“321海外领军型科技创新创业人才”


学术成果:

IEEE Trans on Power Electron. 论文 (SCI一区)

[1] Zhiliang Zhang, K. Yao, Z. Gao, G. Ke, Y. Wang, X. Chen, X. Ren and Q. Chen, “SiC MOSFETs gate driver with minimum propagation delay time and auxiliary power supply with wide input voltage range for high temperature applications, ” IEEE Trans. Journal of Emerging and Selected Topics in Power Electronics, Vol. 8, No. 8, pp. 417–428, Mar., 2020.

[2] Zhiliang Zhang, K. Xu, Z. W. Xu, J. Xu, X. Ren and Q. Chen, “1-kV Input 1-MHz GaN Stacked Bridge LLC Converters,” IEEE Trans. Industrial Electron., IEEE Trans. Power Electron., Vol. 67, No. 11, pp. 9227–9237, Nov., 2020.

[3] Zhiliang Zhang, K. Xu, Z. W. Xu, J. Xu, X. Ren and Q. Chen, “GaN VHF converters with integrated air-core transformers,” IEEE Trans. Power Electron., Vol. 34, No. 4, pp. 3504–3515, Apr., 2019.

[4] Zhiliang Zhang, B. He, D. Hu, X. Ren and Q. Chen, “Common-mode noise modeling and reduction for 1-MHz eGaN multi-output DC-DC converters,” IEEE Trans. Power Electron., Vol. 34, No. 4, pp. 3239–3254, Apr., 2019.

[5] Zhiliang Zhang, B. He, D. Hu, X. Ren and Q. Chen, “Multi-winding configuration optimization of multi-output planar transformers in GaN active forward converters for satellite applications,” IEEE Trans. Power Electron., Vol. 34, No. 5, pp. 4465–4479, May 2019.

[6] S. Wang, H. Li, Zhiliang Zhang, M. Li, J. Zhang, X. Ren and Q. Chen, “Multi-function capability of SiC bidirectional portable chargers for Electric Vehicles,” IEEE Trans. Journal of Emerging and Selected Topics in Power Electronics, accepted.

[7] H. Li, Zhiliang Zhang, S. Wang, J. Zhang, M. Li, Z. Gu, X. Ren and Q. Chen, “Bidirectional synchronous rectification on-line calculation control for high voltage applications in SiC bidirectional LLC portable chargers,” IEEE Trans. Power Electron., accepted.

[8] Q. Yang, M. He, , Zhiliang Zhang, J. Xu, X. Li, J. Zhu, X. Ren and Q. Chen, “Wide input voltage DC electronic load architecture with SiC MOSFETs for high efficiency energy recycling,” IEEE Trans. Power Electron., accepted

[9] X. Zhu, Zhiliang Zhang, Y. Yang, S. Wang, H. Li, X. Ren and Q. Chen, “A sensorless model-based digital driving scheme for synchronous rectification in 1-kV input 1-MHz GaN LLC Converters,” IEEE Trans. Power Electron., accepted

[10] H. Li, Zhiliang Zhang, S. Wang, M. He, J. Tang, X. Ren and Q. Chen, “A 300-kHz 6.6-kW SiC bidirectional LLC on-board charger,” IEEE Trans. Industrial Electron., Vol. 67, No. 2, pp. 1435-1445, Feb., 2020.

[11] X. Ren, Z. W. Xu, Zhiliang Zhang, H. Li, M. He, J. Tang, and Q. Chen, “A 1-kV input SiC LLC converter with split resonant tanks and matrix transformers,” IEEE Trans. Power Electron., Vol. 34, No. 11, pp. 10446-10457, Nov. 2019.

[12] X. Ren, Z. W. Xu, K. Xu, Zhiliang Zhang and Q. Chen, “Stack-capacitor SiC converters for pulse applications,” IEEE Trans. Power Electron., Vol. 34, No. 5, pp. 4450–4464, May 2019.

[13] Zhiliang Zhang, Y. Q. Wu, D. J. Gu, X. Ren and Q. Chen, “Current ripple mechanism with quantization in digital LLC converters for battery charging applications,” IEEE Trans. Power Electron., Vol. 33, No. 2, pp. 1303–1312, Feb. 2018.

[14] Zhiliang Zhang, X. Cheng, Z. Y. Lu and D. J. Gu, “SOC estimation of lithium-ion battery pack considering balancing current,” IEEE Trans. Power Electron., Vol. 33, No. 3, pp. 2216–2226, Mar. 2018.

[15] Zhi-Liang Zhang, X. Cheng, Z. Y. Lu and D. J. Gu, “SOC estimation of lithium-ion batteries with AEKF and Wavelet Transform Matrix,” IEEE Trans. Power Electron., Vol. 32, No. 10, pp. 7626–7634, 2017.

[16] Zhi-Liang Zhang, Z. Dong, X. W. Zou, D. Hu, and X. Ren, “A digital adaptive driving scheme for eGaN HEMTs in VHF converters,” IEEE Trans. Power Electron., Vol. 32, No. 8, pp. 6197–6205, 2017.

[17] Zhi-Liang Zhang, Z. Dong, D. D. Hu, X. W. Zou, and X. Ren, “Three-level gate drivers for eGaN HEMTs in resonant SEPIC converters, ” IEEE Trans. Power Electron., Vol. 32, No. 7, pp. 5527–5538, 2017.

[18] Zhiliang Zhang, X. W. Zou, Y. Zhou, Z. Dong and X. Ren, “A 10-MHz eGaN isolated Class-Ф2 DCX, ” IEEE Trans. Power Electron., Vol. 32, No. 3, pp. 2029–2040, Mar. 2017.

[19] Zhiliang Zhang, H. D. Gui, D. J. Gui, Y. Yang and X. Ren, “A hierarchical active balancing architecture for lithium-ion batteries, ” IEEE Trans. Power Electron., Vol. 32, No. 4, pp. 2757-2768, Dec. 2017.

[20] Zhiliang Zhang, Y. Y. Cai, Y. Zhang and Y. F. Liu, “A distributed architecture based on micro-bank modules with self-reconfiguration control to improve the energy efficiency in the battery energy storage system,” IEEE Trans. Power Electron., Vol. 31, No. 1, pp. 304–317, Jan. 2016.

[21] Zhiliang Zhang, J. Y. Lin, Y. Zhou and X. Ren, “Analysis and decoupling design of a 30 MHz resonant SEPIC converter, ”  IEEE Trans. Power Electron., Vol. 31, No. 6, pp. 4536-4548, Jun. 2016.

[22] X. Ren, Yuan Zhou, D. Wang, X. Zou and Zhiliang Zhang, “A 10-MHz isolated synchronous Class-Φ2 resonant converter,” IEEE Trans. Power Electron., Vol. 31, No. 12, pp. 8317-8328, Dec. 2016.

[23] Zhiliang Zhang, F. F. Li and Y. F. Liu, “A high-frequency dual-channel isolated resonant gate driver with low gate drive loss for ZVS full-bridge converters,” IEEE Trans. Power Electron., Vol. 29, No. 6, June 2014, pp. 3077 -3090.

[24] Zhiliang Zhang, C. Xu and Y. F. Liu, “Digital adaptive discontinuous current source driver for high frequency interleaved boost PFC converter,” IEEE Trans. Power Electron, Vol. 29, No. 3, Mar. 2014, pp. 1298-1310.

[25] Zhiliang Zhang, X. F. He and Y. F. Liu, “An optimal control method for photovoltaic grid-tied interleaved flyback micro-inverters to achieve high efficiency in wide load range,” IEEE Trans. Power Electron, Vol. 28, No. 11, Nov. 2013, pp. 5074-5087.

[26] Zhiliang Zhang, P. Xu and Y. F. Liu, “Adaptive continuous current source drivers for 1-MHz boost PFC converters,” IEEE Trans. Power Electron., Vol.28, No.5, May 2013, pp. 2457-2467.

[27] Zhiliang Zhang, J. Fu, Y. F. Liu and P. C. Sen, “Adaptive current source drivers for efficiency optimization of high frequency synchronous buck converters,” IEEE Trans. Power Electron., Vol.27, No.5, May 2012, pp. 2462-2470.

[28] Zhiliang Zhang, J. Zhen, Y. F. Liu and P. C. Sen, “Switching loss analysis considering parasitic loop inductance with current source drivers for buck converters,” IEEE Trans. Power Electron., Letters, Vol.27, No.7, Jul. 2011, pp. 1815-1819.

[29] Zhiliang Zhang, E. Myer, Y. F. Liu and P. C. Sen, “A non-isolated ZVS self-driven current tripler topology for low voltage and high current applications,” IEEE Trans. Power Electron., Vol. 26, No. 2, Feb. 2011, pp. 512 -522.

[30] Zhiliang Zhang, J. Fu, Y. F. Liu and P. C. Sen, “Discontinuous current source drivers for high frequency power MOSFETs,” IEEE Trans. Power Electron., Vol. 25, No. 7, Jul. 2010, pp. 1863-1876.

[31] Zhiliang Zhang, W. Eberle, Y. F. Liu and P. C. Sen, “A 1-MHz, 12-V ZVS non-isolated full-bridge VRM with gate energy recovery,” IEEE Trans. Power Electron., Vol. 25, No. 3, Mar. 2010, pp. 624-636.

[32] Zhiliang Zhang, W. Eberle, Y. F. Liu and P. C. Sen, “A nonisolated ZVS asymmetrical buck voltage regulator module with direct energy transfer,” IEEE Trans. Ind. Electron., Vol. 56, No. 8, Aug. 2009, pp. 3096-3105.

[33] Zhiliang Zhang, W. Eberle, P. Lin, Y. F. Liu and P. C. Sen, “A 1-MHz high efficiency 12V buck voltage regulator with a new current-source gate driver,” IEEE Trans. Power Electron., Vol. 23, No. 6, Nov. 2008, pp. 2817-2827.

[34] Zhiliang Zhang, W. Eberle, Z. Yang, Y. F. Liu and P. C. Sen, “Optimal design of resonant gate driver for buck converter based on a new analytical loss model,” IEEE Trans. Power Electron., Vol. 23, No. 2, Mar. 2008, pp. 653 -666.

[35] Y. Wu, X. Ren, Y. Zhou, Q. Chen and Zhiliang Zhang, “Dynamic AC line frequency response method for LUT-based variable on-time control in 360 Hz-800 Hz CRM boost PFC converter,”  IEEE Trans. Power Electron., accepted

[36] Y. Wu, Q. Chen, X. Ren and Zhiliang Zhang, “Efficiency Optimization Based Parameter Design Method for the Capacitive Power Transfer System,” IEEE Trans. Power Electron., Early Press

[37] B. Zhang, Q. Chen, G. Ke, L. Xu, X. Ren and Zhiliang Zhang, “Coil positioning based on DC pre-excitation and magnetic sensing for wireless EV charging,” IEEE Trans. Industrial Electron., accepted, 2019.

[38] X. Ren, Y. Zou, Z. Guo, Y. Wu, Zhiliang Zhang and Q. Chen, “Analysis and improvement of capacitance effects in 360-800Hz variable on-time controlled CRM boost PFC converters,” IEEE Trans. Power Electron., accepted, 2019

[39] G. Ke, Q. Chen, L. Xu, X. Ren and Zhiliang Zhang, “Analysis and optimization of a double-sided S-LCC hybrid converter for high misalignment tolerance,” IEEE Trans. Industrial Electron., 2019, accepted.

[40] X. Ren, Y. Zhou, Z. Guo, Y. Wu, Zhiliang Zhang and Q. Chen, “Simple analog-based accurate variable on-time control for critical conduction mode boost power factor correction converters, ” IEEE Trans. Journal of Emerging and Selected Topics in Power Electronics, Vol. 8, No. 1, pp. 4025-4036, Dec., 2020.

[41] X. Ren, L. Bai, Zhiliang Zhang and Q. Chen, “Single-phase AC-DC converter with SiC shared active storage unit for pulse load applications,” IEEE Trans. Journal of Emerging and Selected Topics in Power Electronics, Vol. 8, No. 1, pp. 517–528, Mar., 2020.

[42] G. Ke, Q. Chen, W. Gao, S.C. Wang, M. Tse and Zhiliang Zhang, “Research on IPT resonant converters with high misalignment tolerance using multi-coil receiver set” IEEE Trans. Power Electron., accepted, 2019.

[43] X. Ren, Y. Wu, Z. Guo, Zhiliang Zhang and Q. Chen, “Accurate operation analysis based variable on-time control for 360Hz-800Hz CRM boost PFC converters,” IEEE Trans. Industrial Electron., accepted, 2019.

[44] J. Hou, Q. Chen, Zhiliang Zhang, S.C. Wang and M. Tse, “Analysis of output current characteristics for higher order primary compensation in inductive power transfer systems,” IEEE Trans. Power Electron., Vol. 33, No. 8, 2018, pp. 6807 -6821.

[45] X. Ren, Z. Guo, Y. Wu, Zhiliang Zhang, and Q. Chen, “Adaptive LUT-based variable on-time control for CRM boost PFC converters,” IEEE Trans. Power Electron., Vol. 33, No. 9, Sep. 2018, pp. 8123 -8136.

[46] X. Ren, Y. Wu, Z. Guo, Zhiliang Zhang and Q. Chen, “An online monitoring method of circuit parameters for variable on-time control in CRM boost PFC Converters, ” IEEE Trans. Power Electron., accepted

[47] G. He, Q. Chen, X. Ren, S.C Wong and Zhiliang Zhang, “Modeling and design of contactless sliprings for rotary application,” IEEE Trans. Ind. Electron., Vol. 66, No. 5, 2019, pp. 4130 -4140.

[48] P. Shen, Q. Chen, Zhiliang Zhang and X. Ren, “Model reconstruction for body-mounted solar arrays of satellites based on limited information,” IEEE Trans. Energy Conversion, accepted, 2019.

[49] J. Zhen, Zhiliang Zhang, Y. F. Liu and P. C. Sen, “MOSFET switching loss model and optimal design of a current source driver considering the current diversion problem,” IEEE Trans. Power Electron., vol. 27, no. 2, pp. 998-1012, Feb. 2012.

[50] J. Zhen, Zhiliang Zhang, Y. F. Liu and P. C. Sen, “A new high efficiency current source driver with bipolar gate voltage,” IEEE Trans. Power Electron., vol. 27, no. 2, pp. 985-997, Feb. 2012.

[51] E. Meyer, Zhiliang Zhang and Y. F. Liu, “Digital charge balance controller to improve the loading/ unloading transient response of buck converters,” IEEE Trans. Power Electron., vol. 27, no. 3, pp. 1314-1326, Mar. 2012.

[52] E. Meyer, Zhiliang Zhang and Y. F. Liu, “Controlled auxiliary circuit to improve the unloading transient response of buck converters,” IEEE Trans. Power Electron., Vol. 25, No. 4, Apr. 2010, pp. 806-819.

[53] W. Eberle, Zhiliang Zhang, Y. F. Liu and P. C. Sen, “A practical switching loss model for buck voltage regulators,” IEEE Trans. Power Electron., Vol. 24, No. 3, Mar. 2009, pp. 700-713.

[54] E. Meyer, Zhiliang Zhang and Y. F. Liu, “An optimal control method for buck converters using a practical capacitor charge balance technique,” IEEE Trans. Power Electron., Vol. 23, No. 4, Jul. 2008, pp. 1802 -1812.

[55] W. Eberle, Zhiliang Zhang, Y. F. Liu and P. C. Sen, “A current source gate driver achieving switching loss savings and gate energy recovery at 1-MHz,” IEEE Trans. Power Electron., Vol. 23, No. 2, Mar. 2008, pp. 678 -691.


专利:

1) Zhiliang Zhang and Yan-Fei Liu, “Current Source Gate Drivers,” U. S. Patent No. 8, 085, 083

2) Yan-Fei Liu, Zhiliang Zhang and Jizhen Fu, “Current Source Gate Driver with Negative Gate Voltage,” US Patent 20120068683 A1

3) 张之梁,胥鹏程,蔡卫,发明专利,“电流源驱动电路及其自适应控制方法与应用”,授权号 ZL 201110143223X

4) 张之梁,蔡勇勇,发明专利,“一种基于单体蓄电池组的蓄电池储能系统及控制方法”,专利号 ZL 2013100005405

5) 桂涵东,张之梁,张玥,“一种优化分布式变换器系统效率的功率分配控制策略”,专利号:ZL 2014101094275

6) 张之梁、董舟、徐志巍、许可、胡栋栋、任小永,“氮化镓器件的超高频门极驱动及控制方法”,授权号:ZL201610368366.3

7) 周嫄,任小永,张之梁,邹学文,余凤兵, “超高频功率变换器的3D集成架构”,专利号:ZL201510353635.4

8) 张之梁,邹学文,董舟,任小永,余凤兵,“一种超高频隔离谐振变换器”,专利号:ZL201410339755.4

9) 邹学文,张之梁,董舟,任小永,余凤兵,“VHF电路的控制方法、VHF电路及其电源扩展架构”,专利号:ZL 201510566195.0

10) 张之梁,程祥,陆舟宇,顾东杰,杨阳,“一种带有均衡电路的串连电池组SOC估算方法”, 专利号:ZL201610470569.3

11) 顾东杰,张之梁,程祥,王栋,利用车载充电机辨识电池参数的电池荷电状态估计方法,专利号:ZL201510412775.4

12) 桂涵东,王栋,顾东杰,张之梁,“基于串联电池组的分层式均衡电路系统及混合控制方法”,专利号:ZL201610013348.3

13) 张之梁,姚恺奇,唐家承,徐志巍,朱文铭,任小永,陈乾宏,适应快速负载突变的LLC变换器最优状态轨迹控制方法,申请号:201910658737.5

14) 张之梁,何铭协,徐佳华,李想,朱靖,任小永,魏小忠,陈乾宏,一种高压、宽电压输入范围回馈式直流电子负载电路,申请号:201910455172.0

15) 张之梁,李浩然,任小永,李建飞,陈乾宏,朱靖,隔离型双向充电机控制方法及控制电路,专利号:201810853726.8

16) 顾占彪,张之梁,成诗鹏,xx, xx, 等,任小永,一种飞跨电容变换器电容电压平衡控制方法,专利号:

17) 任小永,朱昕昳,张之梁,陆懿晨,李加明,杨勇,陈乾宏, 宽范围双向变换拓扑及控制,申请号:201911340580.8

18) 任小永,陈乾宏,阮新波,氮化镓功率晶体管的三电平驱动方法, 授权号:ZL201210071969.9

19) 任小永,张强,陈乾宏,庞振进,高效率多路输出直直变换器及其控制方法,授权号:ZL201310119223.5

20) 任小永,庞振进,张强,陈乾宏,张之梁,“输入串联输出准并联的多路输出变换器的开机控制方法”,专利号:ZL201410090993.6

21) 任小永,郭哲辉、吴羽、陈乾宏、张之梁,自适应优化THD的高频CRM升压型PFC变换器,专利号: ZL201610522189.X

22) 任小永,陈旭东,陈乾宏,张之梁,童丹,适用于Vienna整流器的输出电压动态响应优化控制,专利号: ZL201610825768.1

23) 任小永,吴羽,郭哲辉,陈乾宏,张之梁,CRM升压型PFC变换器变化导通时间的优化控制,专利号: ZL2016109939353

24) 陈乾宏,高伟,柯光洁、耿玉川,徐立刚,张斌,任小永,张之梁,一种非接触电能传输装置的柔性行波激励方法,专利号:ZL201810209877.X

25) 陈乾宏,李志斌,张帅,张之梁,任小永, 一种兼顾电路优化和炉盘高效加热的电磁炉线圈盘, 发明专利,申请号:201910103737.9

26) 张斌、陈乾宏、徐立刚、温振霖、任小永、张之梁. 弱磁场激励三线圈检测装置, 发明专利,申请号:201910310870.1

27) 陈乾宏,郭明达,陈欣,徐立刚,温振霖,任小永,张之梁,一种基波-谐波并行传能的多通道非接触供电系统, 发明专利,申请号:201910763076.2

28) 陈乾宏,张帅,李志斌,徐立刚,温振霖,任小永,张之梁. 一种非接触单管谐振变换器, 发明专利,申请号:201910575234.1

29) 柯光洁,陈乾宏,高伟,朱星宇,徐立刚,温振霖,任小永,张之梁. 一种具有高抗偏移特性的无线电能传输系统, 发明专利,申请号:201910620368.0

30) 陈乾宏,徐立刚,柯光洁,朱星宇,张斌,温振霖,任小永,张之梁. 一种从原边辨识参数的非接触电能传输装置, 发明专利,申请号:201910669747.9

31) 柯光洁,陈乾宏,铁昳雪,徐立刚,温振霖,任小永,张之梁. 一种实现恒流恒压输出切换的感应式无线电能传输系统, 发明专利,申请号:201910766479.2




承担项目:

主持或参加科研项目及人才基金项目情况

(一)基金项目

1)  国家自然科学基金 优秀青年科学基金,“GaN超高频电力电子系统”,2018/01-2020/12,在研,主持

2)  国家自然科学基金 面上项目,项目主持,“超高频(30 MHz-300 MHz)功率变换与系统集成”,2014/01-2017/12,在研,主持

3) 国家自然科学基金 青年科学基金,51007036,“超高频自适应电流源驱动的研究”,2010/01-2013/12,已结题,评为“优秀”,主持

4) 国家自然科学基金 面上项目,“基于恢复效应的分布式微模块自重组电池储能系统与控制”,2016/01-2019/12,在研,主持

5) 教育部霍英东青年教师基金,“基于GaN器件的超高频电力电子系统”,2016/05-2019/05,在研,主持

6) 江苏省杰出青年基金,“GaN超高频电力电子系统”,2016/08-2019/08,在研,主持

7) 江苏省“333高层次人才培养工程”项目,“电动汽车宽襟带器件高功率密度电力电子集成系统”,2017/08-2019/08,主持

8) 江苏省前瞻性联合研究项目, BY2015003-04,“基于SiC IGBT的高性能电力电子变压器系统”,2015/07-2017/06,已结题,主持

9) 江苏省自然科学基金, SBK201123015,“超高频MOSFET数字化自适应混合驱动关键技术的研究”,2011/01-2014/07,已结题,主持

10) 江苏省科技成果转化专项资金项目,“基于柔性成组技术的兆瓦级储能系统研发及产业化”,2018/04-2021/03,主持

11) 江苏省重点研发计划(产业前瞻与关键核心技术-竞争项目),BE2019113,“电动汽车便携式SiC高效双向充电系统关键技术及应用”,2019/06-2022/06

12) 教育部留学回国人员科研启动基金,“超高频功率变换系统的研究”,2011/07-2012/07,已结题,主持

13) 工业与信息化部“留学人员科技活动项目择优资助-优秀类”,“基于电流源驱动技术Micro-Inverters光伏并网集成系统研究”,2011/12-2012/12,已结题,主持

14) 航空科学基金,2010ZC52037,“超高频MOSFET电流源驱动技术及芯片集成的研究”,2010/12-2012/12,已结题,主持

15) 台达电力电子科教发展基金,“超高频(30 MHz-300 MHz)功率变换拓扑、控制与集成”,2013/07-2015/07,在研,主持

16) 台达电力电子科教发展基金, DREG2010008,“超高频低压大电流变换器MOSFET自适应电流源驱动的研究”,2010/07-2012/07,已结题,主持

17) 光宝科技电力电子产学研科研合作基金,“基于微变换器的分布式自重组电池储能系统”,2014/03—2017/05, 在研,主持

18) 加拿大国家自然基金 基础研究基金 (NSERC, Discovery Grant),“High Efficiency High Power Density Voltage Regulator Module for Next Generation CPU”, 2009/01—2012/12,$145,000加元, 已结题,参与 (主要参与人)

19) 加拿大国家自然基金 基础创新基金 (NSERC, Idea to Innovation),“Technology Development for Current Source MOSFET Driver Chip”, 2008/01—2009/12,$125,000加元, 已结题,参与 (主要参与人)

20) 加拿大安大略省产学研预研基金 (CITO,Market Readiness),“Resonant Gate Drive Circuit for High Efficiency Fast Dynamic Response Computer Power System”, 2006/01—2006/12,$49,000加元, 已结题,参与 (主要参与人)


(二)企业委托项目

1) 华为技术有限公司,“AC/DC双向变换测试技术合作项目”,2020/02/01—2021/0301,在研,主持

2) 北京航天五院控制工程研究所,“高功率密度GaN DC-DC变换器”,2015/01—2016/12, 已结题,主持

3) 北京航天五院控制工程研究所,“多路输出功率系统建模与可靠性优化测试”,2011/03—2012/05, 已结题,主持

4) 北京航天五院控制工程研究所,“高频高效高功率密度陀螺模块电源研究”,2015/12—2016/08,已结题,主持

5) 中国电子科工集团14所,“宽禁带器件的高压雷达电源系统”,2017/01—2017/12,在研,主持

6)  广州金升阳 (Mornsun) 科技有限公司,“电源模块高频化技术合作开发”, 2014/02—2017/02, 在研,主持

7) 上能电气股份有限公司,“大功率车载高频双向SiC集成充电系统的研制”,2016/12—2017/12,在研,主持

8) 中国电子科工集团13所,“高压输入直流电源研制”,2018/08—2019/12,在研,主持

9) 中国电子科工集团13所,“1-MHz GaN FPGA国产化星载电源研发”, 2020/02-2020/12,已结题,主持

10) 中国电子科工集团13所,“GaN 脉冲雷达数字电源系统平台开发”, 2020/02-2020/12,已结题,主持

11) 上能电气股份有限公司,“大功率车载高频双向SiC集成充电系统的研制”,2016/12—2017/12,在研,主持

12) 广州致远电子有限公司,“回馈式直流电子负载研制”,2018/07—2019/07,已结题,主持

13) 南京康尼机电有限公司,“SiC电动汽车充电装置研制”, 2018/10—2019/10,已结题,主持

14)   北京世纪金光半导体有限公司,“SiC功率器件驱动器与智能模块技术开发”,2017/03—2019/12,在研,子课题负责

15) 法国电网EDF(中国)投资有限公司,“电动汽车大功率充电设施技术咨询”,2019/11—2020/01,结题,主持

16) 加拿大安大略省产业联合项目 (OCE / Gold Phoenix Market Readiness),“Technologies for High Efficiency Power Supplies for High End Computers”, 2008/01—2010/12, 已结题,参与 (主要参与人)

17) 加拿大安大PARTEQ公司,“Design and Evaluation of Self Driven ZVS Power Converter”, 2008/01—2009/12, 已结题,参与 (主要参与人)



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