继电保护研究所

学术身份

教授，博导，齐鲁青年学者。现为IEEE高级会员，IEEE PES济南分会秘书长，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。

工作经历

2015.9至今山东大学电气工程学院，教授

2010.4-2015.8 山东大学电气工程学院，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

个人信息

姓名

丁磊

性别

男

出生日期

1980.1

籍贯

山东临沂

职称

教授

职务

院长 党委副书记

电话

0531-81696111

Email

dinglei@sdu.edu.cn

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, 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.

[8] 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.

[9] 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.

[10] 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.

[11] 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

[12] 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

[13] 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.

[14] 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.

[15] 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.

[16] 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

[17] 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

[18] 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.

[19] 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

[20] 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

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，ZL201911137050.3，2020.04.23

[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，ZL201911088121.5，2020.02.02

[4] 单dq控制结构双馈风机正、负序转子电流控制方法及系统，ZL202010790352.7，2020.12.28

[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，ZL202010467590.4，2020.12.21

[6] 风电机组协同调频最优退出时间的确定方法，ZL201610976478.7，2019.01.04

[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，ZL201510509286.0，2017.10.27

[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.X，2017.03.29

[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，ZL201110173468.7，2014.01.01

[10] 双馈风机故障穿越的优化虚拟阻抗控制方法及系统，ZL202010435460.2，2021.10.22

[11] 双馈风机故障穿越的优化灭磁控制方法及系统，ZL202010435455.1，2021.11.02

[12] 风储交流微电网自动功率平衡控制方法及系统，ZL201910637213.8，2020.09.25

[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.X，2021.12.17

[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.X，2020.07.31

[15] 风储协调的直驱风电机组控制方法及系统，ZL202210221146.3，2022.06.14

承担科研项目

[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 2018.7-2021.6

[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，国网总部科技项目 2019.6-2021.12

[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 2019.1-2021.12

学术类型

学术型、专业型