团队成员
丁磊
发布时间:2021年06月29日 11:04    作者:    点击:[]

个人信息:

丁磊,山东临沂人,1980年生。


学术身份:

教授,博导,泰山学者特聘专家。现为IEEE高级会员,3308维多利亚优惠大厅新型电力系统研究中心主任山东电机工程学会副理事长,全国短路电流计算标委会委员,中国电机工程学会中国电源学会中国自动化学会专委会委员,CIGRE B5.57工作组、C4/B5.61工作组、IEC SC 8A工作组专家。SCI期刊Int. J. Electr. Power Energy Syst. 编委持国家重点研发计划项目课题1项、国家自然科学基金课题2项、国家电网总部科技项目多项,并参与多项国家973和科技部攻关计划课题,参与制定国家标准1项。在IEEE Trans. Power Syst.等期刊发表SCI/EI论文50余篇,申请和授权发明专利30余项。2018年获中国电力优秀青年科技人才奖。



工作经历:

2022.1至今 3308维多利亚优惠大厅院长 党委副书记

2018.4-2022.13308维多利亚优惠大厅副院长

2015.9至今3308维多利亚优惠大厅教授

2010.4-2015.8 3308维多利亚优惠大厅副教授

2009.11-2011.7 英国曼彻斯特大学电气与电子工程学院 Research Associate

2008.1-2009.11 清华大学电机工程与应用电子技术系博士后/助理研究员


研究方向:

低惯量电力系统运行控制,新能源发电并网控制电力系统主动解列


学术著作(部分)

部分已发表的期刊论文如下:

[1]Ding L, Guo Y, Wall P, et al. Identifying the Timing of Controlled Islanding Using a Controlling UEP Based Method[J]. IEEE Transactions on Power Systems, 2018,33(6): 5913-5922

[2]Ding L, Ma Z, Wall P, et al. Graph Spectra Based Controlled Islanding for Low Inertia Power Systems[J]. IEEE Transactions on Power Delivery, 2017,32(1): 302-309

[3]Ding L, Guo Y, Wall P. Performance and Suitability Assessment of Controlled Islanding Methods for Online WAMPAC Application[J]. International Journal of Electrical Power and Energy Systems,2017,84: 252-260

[4]Ding L, Wall P, Terzija V. Constrained Spectral Clustering Based Controlled Islanding[J]. International Journal of Electrical Power and Energy Systems, 2014,63: 687-694

[5]Ding L, Wall P, Terzija V, et al. Two-Step Spectral Clustering Controlled Islanding Algorithm[J].IEEE Transactions on Power Systems, 2013,28(1): 75-84.

[6]Faraji R, Ding L, Rahimi T, et al. Application of Soft-Switching Cell with Inherent Redundancy Properties for Enhancing the Reliability of Boost-Based DC-DC Converters[J]. IEEE Transactions on Power Electronics, 2021,36(11): 12342-12354.

[7]Rahimi T, Ding L, Abadifard A, et al. Unbalanced currents effect on the thermal characteristic and reliability of parallel connected power switches[J]. Case Studies in Thermal Engineering, 2021,26.

[8]Rahimi T, Ding L, Faraji R, et al. Performance Improvement of a Three-Phase Interleaved DC-DC Converter without Requiring Antisaturation Control for Postfault Conditions[J]. IEEE Transactions on Power Electronics,2021,36(7): 7378-7383.

[9]Wang X, Ding L, Ma Z, et al. Perturbation-Based Sensitivity Analysis of Slow Coherency with Variable Power System Inertia[J]. IEEE Transactions on Power Systems,2021,36(2):1121-1129.

[10]Kheshti M, Ding L, Askarian-Abyaneh H, et al. Improving frequency regulation of wind-integrated multi-area systems using LFA-fuzzy PID control[J]. International Transactions on Electrical Energy Systems,2021,31(3).

[11]Faraji R, Ding L, Rahimi T, et al. Efficient Multi-Port Bidirectional Converter with Soft-Switching Capability for Electric Vehicle Applications[J]. IEEE Access,2021,9: 107079-107094.

[12]Rahimi T, Ding L, Kheshti M, et al. Inertia Response Coordination Strategy of Wind Generators and Hybrid Energy Storage and Operation Cost-Based Multi-Objective Optimizing of Frequency Control Parameters[J]. IEEE Access,2021,9: 74684-74702.

[13]Faraji R, Ding L, Rahimi T, et al. Soft-Switched Three-Port DC-DC Converter with Simple Auxiliary Circuit[J]. IEEE Access,2021,9: 66738-66750.

[14]Kheshti M, Ding L, Bao W, et al. Toward Intelligent Inertial Frequency Participation of Wind Farms for the Grid Frequency Control[J].IEEE Transactions on Industrial Informatics,2020,16(11): 6772-6786.

[15]Bao W, Ding L, Liu Z, et al. Analytically derived fixed termination time for stepwise inertial control of wind turbines—Part I: Analytical derivation[J]. International Journal of Electrical Power and Energy Systems,2020,121.

[16]Li X, Ding L, Zhu G, et al. Transient Instability Detection Method Based on Multi-source Trajectory Information[J]. International Journal of Electrical Power and Energy Systems, 2019,113: 897-905

[17]Kheshti M, Ding L, Nayeripour M,et al. Active Power Support of Wind Turbines for Grid Frequency Events Using a Reliable Power Reference Scheme[J]. Renewable Energy, 2019,139: 1241-1254

[18]Liu P, Zhu G, Ding L, et al. High-voltage ride-through strategy for wind turbine with fully-rated converter based on current operating range[J]. International Journal of Electrical Power & Energy Systems, 2022, 141: 108101.

[19]Zhang G, Zhang F, Ding L, et al. Wind Farm Level Coordination for Optimal Inertial Control With a Second-Order Cone Predictive Model[J]. IEEE Transactions on Sustainable Energy,in press.

[20]Bao W, Wu Q, Ding L,et al. A Hierarchical Inertial Control Scheme for Multiple Wind Farms with BESSs Based on ADMM[J]. IEEE Transactions on Sustainable Energy,2021,12(2):751-761.

[21]Bao W, Wu Q, Ding L, et al. Synthetic Inertial Control of Wind Farm with BESS Based on Model Predictive Control[J]. IET Renewable Power Generation,2020,14(13): 2447-2455

[22]Guo Y, Bao W, Ding L, et al. Analytically Derived Fixed Termination Time for Stepwise Inertial Control of Wind Turbines—Part II: Application Strategy[J]. International Journal of Electrical Power & Energy Systems,2020,121

[23]Zhang F, Fu A, Ding L, et al. MPC Based Control Strategy for Battery Energy Storage Station in a Grid with High Photovoltaic Power Penetration[J].  International Journal of Electrical Power and Energy Systems, 2020,115.

[24]Zhu Z,Hou M,Ding L,et al.Optimal Photovoltaic Array Dynamic Reconfiguration Strategy Based on Direct Power Evaluation[J]. IEEE Access,2020,8: 210267-210276

[25]Zhang F, Fu A, Ding L,et al. Optimal Sizing of ESS for Reducing AGC Payment in a Power System with High PV Penetration[J]. International Journal of Electrical Power and Energy Systems, 2019,110: 809-818

[26]Phadke A.G, Wall P, Ding L, et al. Improving the Performance of Power System Protection Using Wide Area Monitoring Systems[J]. Journal of Modern Power Systems and Clean Energy, 2016,4(3): 319-331

[27]Quirós-Tortós J, Wall P, Ding L, et al. Determination of Sectionalising Strategies for Parallel Power System Restoration: A Spectral Clustering-Based Methodology[J]. Electric Power Systems Research, 2014,116: 381-390


部分已授权专利如下:

[1] 双馈风机虚拟惯量调频的动态转速保护方法及系统,ZL201911135568.3,2020.04.02

[2] 基于超速风机释放功率提升的风电调频控制方法及系统,ZL201911137050.32020.04.23

[3] 弃风参与电网调频的电转气-储气-燃气轮机容量优化配置方法及系统,ZL201911088121.52020.02.02

[4] dq控制结构双馈风机正、负序转子电流控制方法及系统,ZL202010790352.72020.12.28

[5] 直驱风机不对称故障直流母线二倍频电压抑制方法及系统,ZL202010467590.42020.12.21

[6] 风电机组协同调频最优退出时间的确定方法,ZL201610976478.72019.01.04

[7] 一种双馈风力机组惯性调频主动转速保护控制系统与方法,ZL201510509286.02017.10.27

[8] 模拟惯性与超速相结合的双馈风机有功频率控制器及方法,ZL201510334000.X2017.03.29

[9] 基于归一化谱聚类和约束谱聚类的两阶段主动解列方法,ZL201110173468.72014.01.01

[10] 双馈风机故障穿越的优化虚拟阻抗控制方法及系统,ZL202010435460.22021.10.22

[11] 双馈风机故障穿越的优化灭磁控制方法及系统,ZL202010435455.12021.11.02

[12] 风储交流微电网自动功率平衡控制方法及系统,ZL201910637213.82020.09.25

[13] 无信号传输线路中实现非通信高速距离中继的方法及装置,ZL201910373023.X2021.12.17

[14] 基于WAMS实测轨迹的电力系统暂态稳定综合判别方法及系统,ZL201810846533.X2020.07.31

[15] 风储协调的直驱风电机组控制方法及系统,ZL202210221146.32022.06.14


科研项目:

[1]电网故障下风电机组电压/频率暂态主动支撑技术,国家重点研发计划课题,2018-2021

[2]计及暂态稳定约束和群特性的主动解列策略研究,国家自然科学基金面上项目,2015-2018

[3]基于谱聚类方法的电力系统主动解列研究,国家自然科学基金青年项目,2012-2014

[4]含高比例可再生能源的电网频率协同控制技术研究,国家电网总部科技项目,2019-2020

[5] 高比例新能源接入电力系统分散集群控制,国网总部科技项目,2019-2021

[6]智能电网自愈控制关键技术研究,首批3308维多利亚优惠大厅青年学者未来计划,2015-2020

*更多科研项目见团队概况科研项目


联系方式:dinglei@sdu.edu.cn





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