姓名:张永昌
职称:教授、博士生导师
所在院系:williamhill威廉希尔官网
研究方向:
电力电子与电力传动(power electronics and electric drives)
规模化储能技术(large scale energy storage technology)
新能源发电(renewable energy generation)
快速控制原型系统(rapid control prototype system)
联系方式:
办公地址:主A432、教五D103
电子邮箱:zyc@ncepu.edu.cn; 招生咨询:kj18568060768@163.com
办公电话:61771634
一、个人简介及主要荣誉称号:
张永昌,男,教授,博士生导师。主要从事电力电子与电力传动、新能源发电与并网、规模化储能系统控制的研究工作。入选国家级青年人才计划、爱思唯尔中国高被引学者、IET Fellow、北京市高创计划领军人才和**人才、北京市长城学者、北京市**、北京市科技新星和北京市委组织部**人才,享受国务院政府特殊津贴。担任中国电工技术学会理事、中国电源学会变频专委会副秘书长、北京电力电子学会理事和青工委主任、多个国际期刊的编委和客座编辑。近年来出版专著2部、译著3部,发表第一/通讯作者SCI论文57篇(IEEE汇刊48篇),先后有10篇入选ESI论文,2篇入选ESI热点论文。主持国家重点研发计划课题1项、国家自然科学基金3项(已优秀结题2项)、北京市科技专项6项以及多项横向课题,作为第一完成人获得北京市科技奖、中国产学研合作创新奖、IET期刊最佳论文奖和多个国际会议最佳论文奖等奖励。
二、教学与人才培养情况:
1.教学课程:
电机学2,2021,32学时,3个班
新能源变换与控制,2017-2020,48学时,2个班(本人讲32学时)
光伏发电并网技术,2014-2016,32学时,2个班
2.学生培养
在读博士:蒋涛、王兴、刘想、王宇彬、周陈辉、陈晗、王泽庭、刘家利
毕业硕士:谢伟、魏香龙、杨海涛、曲昌琦、章勤、彭玉宾、高素雨、刘家利、高基豪、夏波、徐东林、白宇宁、刘杰、蔡倩、焦健、黄兰兰、张博越、金家林、黄朋、于永吉、李冰玉、蒋涛、王兴、刘想、姜皓、赵继乾、张昊男
3. 学生获得荣誉
杨海涛,北京市普通高等学校优秀毕业生(硕士),2015,导师:张永昌
杨海涛,国家奖学金,2014,导师:张永昌
谢伟,国家奖学金,2013,导师:张永昌
夏波,国家奖学金,2016,导师:张永昌
三、主要科研项目情况
[1] 国家重点研发计划储能与智能电网专项,2021YFB2400702,规模化储能与多类型电源联合运行和稳定支撑技术,2021/12-2024/11,982.5万元,在研,主持
[2] 中组部****人才项目,交流电机模型预测控制理论与应用,2020/09-2023/12,170万元,在研,主持
[3] 国家自然科学基金面上项目,52077002,畸变电网下的级联无刷双馈风力发电机无位置传感器鲁棒预测控制,2021/01-2024/12,60万元,在研,主持
[4] 华能集团海上风电与智慧能源系统科技专项,永磁直驱海上风力发电系统高性能控制技术研究,2020/11-2023/12,100万,在研,主持
[5] 云南电科院2022年典型并网点多类新能源机组级并网指标研究及控制策略优化,2022/5-2024/5,113万,在研,主持
[6] 苏州汇川技术有限公司委托项目,中压三电平异步电机模型预测控制算法研究,2020/07-2021/05,80万,在研,主持
[7] 广州视琨电子科技有限公司委托项目,2kW永磁同步电机无电解电容空调变频器研制,2020/11-2021/04,80万,在研,主持
[8] 国家自然科学基金面上项目,51577003,非理想电网下的瞬时功率理论及PWM整流器运行机理和优化控制研究,2016/01-2019/12,65万元,优秀结题,主持
[9] 国家自然科学基金青年项目,51207003,异步电机无速度传感器模型预测控制关键技术研究,2013/01-2015/12,26万元,优秀结题,主持
[10] 国家自然科学基金主任项目,51347004,大功率三电平PWM整流器优化控制和电网不平衡运行研究,2014/01-2014/12,15万元,优秀结题,项目实际负责人
[11] 北京市自然科学基金项目,3162012,大功率三电平传动模型预测控制关键技术研究,2016/01-2018/12,18万元,已结题,主持
四、主要获奖
中组部****人才(2020)
中国高被引学者(2019-2021)
IET Fellow (2019)
中国产学研合作创新奖(2019)
北京市科技奖励三等奖(2018)
北京市高创计划“领军人才”(2018)
IET Electric Power Applications Premium Award (2017)
北京市长城学者(2017)
北京市**(2017)
国务院政府特殊津贴专家(2016)
北京市高创计划“**人才”(2015)
北京市委组织部“**人才”(2014)
北京市科技新星(2013)
五、代表性论著(2020年以来)
[1] 张永昌,《感应电机模型预测控制》(电气自动化新技术丛书),机械工业出版社,2020.5
[2] 张永昌,宋文祥,徐伟,《大功率变换器及工业传动模型预测控制》(国际电气工程先进技术译丛),机械工业出版社,2019.3
[3] 张永昌,张虎,李正熙,《异步电机无速度传感器高性能控制技术》(电力电子新技术丛书),机械工业出版社,2015.1
[4] 张永昌,李正熙等,《电机传动系统控制》(国际电气工程先进技术译丛),机械工业出版社,2013.10
[5] X. Wang, Y. Zhang*, and H. Yang, “An improved deadbeat predictive current control for induction motor drives,” IET Power Electronics, vol. 15, pp. 753-763, 2022.
[6] H. Yang, Y. Zhang*, and W. Shen, “Predictive Current Control and Field-weakening Operation of SPMSM Drives without Motor Parameters and DC Voltage,” in IEEE Journal of Emerging and Selected Topics in Power Electronics, 2022
[7] S. Fan, Y. Zhang*, J. Jin, X. Wang, and C. Tong, “Deadbeat Predictive Current Control of PMSM Drives With an Adaptive Flux-Weakening Controller,” IET Power Electronics, vol. 15, pp. 753-763, 2022.
[8] Y. Zhang*, and Z. Min, “Model-Free Predictive Current Control of a PWM Rectifier Based on Space Vector Modulation under Unbalanced and Distorted Grid Conditions,” IEEE Journal of Emerging and Selected Topics in Power Electronics, vol. 10, no. 2, pp. 2319-2329, 2022.
[9] Y. Zhang*, S. Zhang, J. Jiao, and T. Jiang, “A Modified Model-Free Predictive Current Control Method Based on an Extended Finite Control Set for DFIGs Applied to a Nonideal Grid,” IEEE Trans. Ind. Appl., vol. 58, no. 2, pp. 2527-2536, 2022.
[10] Y. Zhang*, and T. Jiang, “Robust Predictive Rotor Current Control of a Doubly Fed Induction Generator under an Unbalanced and Distorted Grid,” IEEE Trans. Energy Convers., vol. 37, no. 1, pp. 433-442, 2022.
[11] X. Liu, Y. Zhang*, H. Yang, and J. Rodriguez, “Robust Predictive Current Control of PWM Rectifiers with LCL Filters under Unbalanced and Distorted Network Conditions,” IET Power Electronics, vol. 15, pp. 226-236, 2022.
[12] Y. Zhang*, and T. Jiang, “Robust Predictive Stator Current Control Based on Prediction Error Compensation for Doubly Fed Induction Generator under Non-ideal Grids,” IEEE Trans. Ind. Electron., vol. 69, no. 5, pp. 4398-4408, 2022.
[13] J. Liu, and Y. Zhang*, “Current Pulsation Suppression Method Based on Power Current Closed-Loop Control for a PMSM Under Fluctuating DC-Link Voltage,” IEEE Trans. Power. Electron., vol. 37, no. 1, pp. 761-770, 2022.
[14] Y. Zhang, H. Jiang, and H. Yang*, “Model Predictive Control of PMSM Drives Based on a General Discrete Space Vector Modulation,” IEEE Trans. Energy Convers., vol. 36, no. 2, pp. 1300-1307, 2021.
[15] J. Liu, Y. Zhang*, H. Yang, “Improved Position Signal Demodulation Method for Sensorless Control Based on HF Sinusoidal Pulsating Voltage Injection,” IET Electric Power Applications, vol. 14, no. 14, pp. 2780-2787, 2021.
[16] Y. Zhang*, X. Liu, B. Li, and J. Liu, “Robust Predictive Current Control of PWM Rectifier Under Unbalanced and Distorted Network,” IET Power Electronics, vol. 14, pp. 797-806, 2021.
[17] Y. Zhang*, J. Jin, and L. Huang, “Model-Free Predictive Current Control of PMSM Drives Based on Extended State Observer Using Ultra-Local Model,” IEEE Trans. Ind. Electron., vol. 68, no. 2, pp. 993–1003, 2021.
[18] Y. Zhang*, T. Jiang, and J. Jian, “Model-Free Predictive Current Control of a DFIG Using an Ultra-Local Model for Grid Synchronization and Power Regulation,” IEEE Trans. Energy Convers., vol. 35, no. 4, pp. 2269-2280, 2020.
[19] Y. Zhang*, B. Li, and J. Liu, “Online Inductance Identification of a PWM Rectifier under Unbalanced and Distorted Grid Voltages,” IEEE Trans. Ind. Appl., vol. 56, no. 4, pp. 3879–3888, 2020.
[20] G. Bramerdorfer, G. Lei, A. Cavagnino, Y. Zhang, J. Sykulski and L. David, “More Robust and Reliable Optimized Energy Conversion Facilitated through Electric Machines, Power Electronics and Drives, and Their Control: State-of-the-Art and Trends,” IEEE Trans. Energy Convers., vol. 35, no. 4, pp. 1997-2012, 2020.
[21] H. Yang, Y. Zhang*, and J. Liu, “Frequency-adaptive Virtual Flux Estimator-based Predictive Power Control with Suppression of DC Voltage Ripples Under Unbalanced Network,” IEEE Trans. Ind. Electron., vol. 67, no. 10, pp. 8969–8979, 2020.
[22] Y. Zhang*, T. Jiang, and J. Jian, “Model-Free Predictive Current Control of DFIG Based on Extended State Observer Under Unbalanced and Distorted Grid,” IEEE Trans. Power Electron., vol. 35, no. 8, pp. 8130-8139, 2020.
[23] Y. Zhang*, Z. Wang, J. Jian, and J. Liu, “Grid-voltage Sensorless Model Predictive Control of Three-phase PWM Rectifier under Unbalanced and Distorted Grid Voltages,” IEEE Trans. Power Electron., vol. 35, no. 8, pp. 8663–8672, 2020.
[24] Y. Zhang*, J. Jiao, D. Xu, D. Jiang, Z. Wang, and C. Tong, “Model Predictive Direct Power Control of Doubly Fed Induction Generators Under Balanced and Unbalanced Network Conditions,” IEEE Trans. Ind. Appl., vol. 56, no. 1, pp. 771–786, 2020.