ZHONG, Qing ( Professor, Ph. D.)
E-mail: epqzhong@scut.edu.cn
School of Electrical Power, South China University of Technology, 381#, Wushan road, Guangzhou, 510640, China
Brief Introduction
Qing Zhong received B. Sc degree in Electrical Engineering from North China University of Technology, Beijing, China in 1997 and M. Sc and Ph. D degrees in Electrical Engineering from South China University of Technology, Guangzhou, China in 2000 and 2003 respectively. From 2002 to 2003, he worked as Research Assistant in The Hong Kong Polytechnic University, Hong Kong, China. The main research project was the control strategies of active power filters. From 2003 to 2004, he worked as a chief engineer in the power supply divisions, Guangzhou Zhiguang Electric Co., Ltd. He took charge of the R&D of the static var compensators (SVC). From 2004 to 2006, he was a Postdoctoral Fellow in South China University of Technology, Guangzhou, China. He is currently the professor and doctoral supervisor in School of Electric Power, South China University of Technology. In 2013, he finished one project sponsored by Industry-Education-Research Programs of Guangdong: R&D and applications of the integrated control and protection instrument in smart distribution network. In 2016, he finished one project sponsored by NSFC of China: Studies on Harmonics of Distribution Network with Multiple Voltage Source Converters. He has untaken and finished several projects sponsored by China southern power grid. He has participated several national projects sponsored by the Ministry of Science and Technology of China, such as two National Sci-Tech Support Plans of China. He published his first paper in 2001 and has published more than 60 technical journals and conference papers until now. He focuses on the harmonic of VSC in recent years. He finished the harmonic analysis model, equivalent circuit models of VSC. He proposed the deterministic designation approach of LCL filter for the VSC. He was the first person who applied the dynamic phasor sequence component into the harmonic analysis of voltage source converter. He has attended 3 Chinese national standards about the survey the power quality cost in China. His main research interests include voltage source converter (adjust speed drive, active power filter, dynamic voltage regulator, etc), power quality analysis and control (harmonics, super harmonics, voltage sags, etc) and power system operation and control.
Qing Zhong is an IEEE member, CSEE member and CPSS member in China. He is currently the Vice Secretary-General of Asia Power Quality Initiative (APQI).
Detail information
Personal Information | §Date of Birth: 1st,Oct. 1978 §Place of Birth: Longnan, Jiangxi, China |
2000/10-2003/7, Ph.D., Electrical Engineering, South China University of Technology, Guangzhou, China | |
1998/9-2000/10, M.S., Electrical Engineering, South China University of Technology, Guangzhou, China | |
1993/9-1997/7, B.S., Electrical Engineering, North China University of Technology, Beijing, China | |
Professional experience | 2006/10~now, Professor, School of Electrical Power, South China University of Technology, Guangzhou, China |
2004/9~2006/10, Post-doctoral Researcher, School of Electrical Power, South China University of Technology, Guangzhou, China | |
2003/7~2004/8, R&D Engineer, Guangzhou Zhiguang Electrical Ltd. Co. 2002.7~2003.3, Research Assistant, Department of Electrical Engineering, The Hong Kong Polytechnic University, Hong Kong | |
Projects in charge | 1.China southern power grid project, #GZGD20160301020336, Research on the safeguard measurement of power supply for the elevator in the urban high-rise building, 2016/12-2017/12 2.China southern power grid project, #GZGD20160303240239, Experimental test of voltage sag tolerance for the sensitive devices and installations. 2016/12-2018/10 3.China southern power grid project, Research on the algorithms and models of experts system for the voltage deviation in the low voltage areas, 2016/8-2016/12 4.China southern power grid project, Diagnosis of voltage deviation in the low voltage areas, 2015/3-2015/12 5.NSFC of China, #51307061, Studies on harmonics of distribution network with multiple voltage source converters, 2014.1-2016.12 6.China southern power grid project, Analysis of different power quality demand for the power customers. 2013/4-2013/12 7.Industry-Education-Research Programs of Guangdong, #2011A09020 0074, Developments and applications of protect and control for the smart distribution network, 2011/3-2013/3 8.China southern power grid project, Research on the 3rd harmonic voltage in the Foshan grid. 2010/7-2012/12 9.China southern power grid project, Research on the impact of voltage sags on the power customers in Guangzhou. 2010/7-2012/12 10.China southern power grid project, Comprehensive technical procedures for the power loss reduction in the Shaoguan distribution network. 2005/7-2006/7 |
Projects Participated | 1.China southern power grid project, #CSGTRC2016K16622B04, Fault analysis and reliability evaluation for the power grid with interaction of DC grid. 2016/9-2019/5 2.NSFC of China, #51477057, Research on the fault space-time characteristic and protection of the distribution network with DES. 2015/01-2018/12 3.NSFC of China, #51307063, Reliability evaluation of complex distribution network with DES and interaction of customers. 2014/1-2016/12 4.National Sci-Tech Support Plan of China, #2013BAA01B00,Comprehensive demonstration of regional smart grid integration with high penetration of intermittent energies. 2013/1-2015/12 5.National Sci-Tech Support Plan of China. # 2006BAA02A17, Coordinated recovery strategies of multi-HVDC systems including UHVDC. 2006/1-2008/12 |
Social positions | 1.Member of CSEE, CPSS and APQI 2.Reviewer of IEEE Trans. on Power Delivery, IET GTD, IET Control & Applications, IEEE PES General Meeting, IEEE POWERCON. |
List of Publicaitons
Journal papers
[1]Qin Wu, Qing Zhong, Gang Wang, Haifeng Li. Multi–machine Equivalent Approach of Wind Farm Based on Fuzzy C-means Clustering. Modern Electric Power, 2016, 33(6): 27-32. (in Chinese)
[2]Qing Zhong, Jinfang To, Xinhua Ma, Gang Wang, Haifeng Li. Deterministic Design of LCL Filter for Voltage Source Converter. High Voltage Engineering, 2016, 42(10): 3068-3074. (in Chinese)
[3]Qing Zhong, Feng Liu, Gang Wang, Haifeng Li. Middle Distance Clustering of Power Quality Monitor Data. Proceedings of the CSU-EPSA, 2016, 28(8): 69-73. (in Chinese)
[4]Qing Zhong, Wang Xiaomin,Wang Gang, et al. Analysis of the Harmonic Generation Mechanisms of Voltage Source Converters with Path Sets. High Voltage Engineering, Jan. 2016, 42(1): 26-32. (in Chinese)
[5]Qing Zhong, Lingxue Lin, Gang Wang, Yao Zhang, Zhigang Wu. Harmonic analysis model for voltage source converter under unbalanced conditions. IET Gener. Transm. Distrib. Jan. 2015, 9(1): 12-21.
[6]Lidan Chen, Yongquan Nie, Qing Zhong. A Model for Electric Vehicle Charging Load Forecasting Based on Trip Chains. Transactions of China Electrotechnical Society, 2015, 30(4): 216-225. (in Chinese)
[7]Qing Zhong, Xinhua Ma, Gang Wang, Yao Zhang. Static Equivalent Circuit Models of Voltage Source Converter. High Voltage Engineering, 2014, 40(8): 2485-2489. (in Chinese)
[8]Qing Zhong, Huang Kai, Wang Gang, etc. Harmonic analysis and elimination strategy for voltage source converter under unbalanced three-phase voltage. Automation of Power System, Feb. 2014, 38(4): 79-85.(in Chinese)
[9]Haitao Chen, Qing Zhong, Yao Zhang. Simulation and analysis on the immunity degree of voltage sag for sensitive equipment. Journal of Electric Power Science and Technology, 2013, 28(3): 65-71. (in Chinese)
[10]Kai Huang, Qing Zhong. Interconnection inverter controller of distributed generations based on IEC61850. Power System Protection and Control, 2013, 41(6): 123-127. (in Chinese)
[11]Hongde Xiong, Qing Zhong, Yu Yang, Da Xu. Research on simulation of coordinated control between UHVDC converter station SVC and its reactive power compensation devices. Power System Protection and Control, 2012, 40(10): 144-148. (in Chinese)
[12]Taoliang Tan, Yao Zhang, Qing Zhong. Limit induced bifurcation due to converter transformer tap and DC controller limit. Acta Phys. Sin., 2012, 61(2):020501. (in Chinese)
[13]Taoliang Tan, Yao Zhang, Qing Zhong. Multi-parameter bifurcation analysis of AC / DC power system. Electric Power Automation Equipment, 2012, 32(2):23-28. (in Chinese)
[14]Qing Zhong, Lingxue Lin, Yang Yi, Yao Zhang, Zhigang Wu. Study on the Evaluation Index of Voltage Sags I: Unsubstantial Location Index. Proceedings of the CSU-EPSA, 2012, 24(1): 110-114. (in Chinese)
[15]Qing Zhong, Lingxue Lin, Yang Yi, Yao Zhang, Zhigang Wu. Study on the Evaluation Index of Voltage Sags II: Device Tripping Possibility Index. Proceedings of the CSU-EPSA, 2012, 24(3): 72-76. (in Chinese)
[16]Qing Zhong, Lingxue Lin, Yang Yi, Yao Zhang, Zhigang Wu. Comparisons Among the Monto-Carlo Simulation Models of Voltage Sags. Proceedings of the CSU-EPSA, 2010, 22(6): 144-147. (in Chinese)
[17]Qing Zhong, Yao Zhang, J. Yang, J. Wu. Non-linear auto-disturbance rejection control of parallel active power filters. IET Control Theory Appl., 2009, 3(7): 907–916.
[18]Rouyi Chen, Yao Zhang, Qing Zhong, Li Guo. Decentralized Robust Control of Uncertain Interconnected Power Systems. Transactions of China Electrotechnical Society, 2009, 24(10): 139-146. (in Chinese)
[19]S.W. Zhao, N.C. Cheung, W.C. Gan, J.M. Yang, Q. Zhong. Passivity-based control of linear switched reluctance motors with robustness consideration. IET Electr. Power Appl., 2008, 2(3): 164–171.
[20]Jianshe Zhang, Qing Zhong, Zhigang Wu, Lingxue Lin, Yao Zhang. Block Division in RTDS System Based on Subgraph Isomorphism. Automation of Power System, 2009, 33(12): 53-57. (in Chinese)
[21]Rouyi Chen, Yao Zhang, Qing Zhong, Guanglin Cai. Analysis and Control of Post-fault Inter-area Oscillations by Multi-area Single Machine Equivalent Method. Proceedings of the CSEE, 2009, 29(16): 21-27. (in Chinese)
[22]Rouyi Chen, Yao Zhang, Qing Zhong, Guanglin Cai. Application of Decentralized H∞ Controller to Damping Control of Power System. Journal of South China University of Technology (Natural Science Edition), 2008, 37(2): 118-126. (in Chinese)
[23]Rouyi Chen, Yao Zhang, Qing Zhong, Li Guo. Control Parameter Optimization Considering Damping Assessment Post-fault. Proceedings of the CSEE, 2008, 28(22): 69-74. (in Chinese)
[24]Qing Zhong, Yang Yi, Zhigang Wu, Yao Zhang, Jie Luo. Analysis and Simulations of the Voltage Sags in Power Customer. Proceedings of the CSU-EPSA, 2008, 20(6): 103-108. (in Chinese)
[25]Qing Zhong, Yao Zhang, Jie Wu, Jinming Yang, Zhigang Wu. Passivity-based modulation of hybrid AC-DC transmission systems. Control Theory & Applications, 2008, 25(4): 777-780. (in Chinese)
[26]Yang Yi, Yao Zhang, Qing Zhong. Assessment of Voltage Sags in Large Power Consumer Based on Monte-Carlo Method. Power System Technology, 2008, 32(6): 57-61. (in Chinese)
[27]Lu Yue, Yao Zhang, Qing Zhong, Zhe Wang. Mid-long term load forecasting based on fuzzy logic clustering neural network approach. Journal of North China Electric Power University, 2008, 35(2): 42-46. (in Chinese)
[28]Yang Yi, Yao Zhang, Qing Zhong, Jie Luo. Research on the simulation of voltage sags based on HyperSIM. Electric Power, 2008, 41(3): 23-28. (in Chinese)
[29]Lingxue Lin, Yao Zhang, Qing Zhong, Zhigang Wu. Fault Diagnosis of Commutation Failures in the HVDC System Based on a Method of Wavelet Energy Statistics. Automation of Power System, 2007, 31(23): 61-64. (in Chinese)
[30]Jie Luo, Qing Zhong, Zhigang Wu, Rui Li, Yao Zhang. Analysis of the Power Quality in the High and New Technology Enterprises. Power System Technology, 2007, 31(sp1): 61-63. (in Chinese)
[31]Yao Zhang, Lingxue Lin, Qing Zhong. Fault Diagnosis Based on Wavelet for Commutation Failures in HVDC. Journal of South China University of Technology (Natural Science Edition), 2007, 35(10): 172-177. (in Chinese)
[32]Qing Zhong, Yao Zhang, Jie Zhao, Jianshe Zhang. Research on the sensitivity analysis of supply support in China South Power Grids. Electric Power, 2007, 40(1): 32-35. (in Chinese)
[33]Qian Chen, Yao Zhang, Qing Zhong, Haijun Wang. Simulation of ±800 kV UHVDC system under different operation modes. Relay, 2007, 35(16): 27-32. (in Chinese)
[34]Lingxue Lin, Yao Zhang, Qing Zhong, Zhigang Wu. Commutation failure analysis of HVDC systems using Hypersim. Electric Power Automation Equipment, 2007, 27(8): 33-37. (in Chinese)
[35]Qing Zhong, Yao Zhang, Dongyang Rui. Automatic reactive power compensator in distribution system. Power Automation Equipment, 2007, 27(2): 71-74. (in Chinese)
[36]Huifan Xie, Yao Zhang, Qing Zhong, Li Guo. Programmable realization of a visual distribution management system. Electric Power, 2006, 39(8): 72-76. (in Chinese)
[37].Qing Zhong, Yao Zhang, K W Eric Cheng, Jinming Yang. Optimal selection of output inductance in active power filters. Electric Power Automation Equipment, 2006, 26(10): 17-20.
[38]Lingxue Lin, Yao Zhang, Qing Zhong, Xiuhong Zong. A Survey on Commutation Failures in Multi-infeed HVDC Transmission Systems. Power System Technology, 2006, 30(17): 40-46. (in Chinese)
[39]Qing Zhong, Yao Zhang, Jinming Yang, Zhigang Wu, Xiong Wen. Review on application and development of modern control technologies in HVDC systems. Relay, 2006, 34(9): 80-86. (in Chinese)
[40]Qing Zhong, Yao Zhang, Jinming Yang, Zhigang Wu. The research on the simulation of hybrid AC /DC power transmission systems based on Matlab. Relay, 2006, 34(8): 40-44. (in Chinese)
[41]Qing Zhong, Dongyang Rui, Jianzhong Mei, Xueming Liu. Discussion on intelligence of prefabricated substations. Guangdong Electric Power, 18(4): 32-35.
[42]Qing Zhong, Jie Wu, K W Eric Cheng, Jinming Yang. The application of active power filter based on DSP. Relay, 2004, 32(11): 37-40. (in Chinese)
[43]Qing Zhong, Jie Wu, Jinming Yang, K W Eric Cheng. Overview of modern control theories in active power filters. Electric Power Automation Equipment, 2004, 24(3): 88-94. (in Chinese)
[44]Qing Zhong, Jie Wu, Jinming Yang. Passivity-based control of the shunt active power filters. Control and Decision, 2004, 19(1): 77-80. (in Chinese)
[45]Qing Zhong, Jie Wu, Jinming Yang. Application of passivity-based control in active power filters. Control Theory & Applications, 2003, 20(5): 713-718.
[46]Qing Zhong, Jie Wu, Danhong Zhong. Integrated load forecasting method based on system approach. Electric Power Automation Equipment, 2002, 22(10): 1-5. (in Chinese)
[47]Qing Zhong, Jie Wu, Zheng Xu. Application of the automatic disturbance controller in the shunt active power filter. Automation of Power System, 2002, 26(16): 22-26. (in Chinese)
[48]Qing Zhong, Jie Wu, Wuzhong Huang, Dejian Kong. Application of dynamic programming for investment decision in electric power construction. Power System Technology, 2002, 26(8): 48-51. (in Chinese)
[49]Qing Zhong, Jie Wu. A Generalized Predictive Pole Placement Controller Using Delta Operators. Journal of South China University of Technology (Natural Science Edition), 2002, 30(4): 40-43. (in Chinese)
[50]Qing Zhong, Jie Wu, Li Wu, Wuzhong Huang. Subarea load forecasting based on system dynamics. Power System Technology, 2001, 25(3): 51-55. (in Chinese)
[51]Jinming Yang, Jie Wu, Qing Zhong. Analysis of Stable Operation Range and Frequency Acquisition Process for PLL Speed Control System with Sample2and2hold Phase Detector. Transactions of China Electrotechnical Society, 2001, 16(4): 20-25. (in Chinese)
Conference papers
[1]Qing Zhong; Zhe Zhang; Feng Liu; Gang Wang; Longjun Wang. Self-organized criticality characteristics of unplanned power failures in distribution network. 2016 IEEE International Conference on Power System Technology (POWERCON), 2016, Sept. 28 2016-Oct. 1 2016, Wollongong, NSW, Australia, pp: 1-5.
[2]Qing Zhong, Member IEEE, Quan Shi, Gang Wang, Haifeng Li. Short Circuit Analysis of PV Inverter under Unbalanced Conditions with Dynamic Phasor Sequence Components. IEEE PES General Meeting, 2016, Boston, U.S. July, 2016.
[3]Q Zhong,XM Wang,G Wang,HF Li. The impact of simulation time step on harmonic analysis of voltage source converters [C]. Conference: 10th International Conference on Advances in Power System Control, Operation & Management (APSCOM 2015), 2015, Hongkong, China.
[4]Qing Zhong, Wei Huang, Shun Tao, Xiangning Xiao. Survey on Assessment of Power Quality Cost in Shanghai China. IEEE PES General Meeting, 2014, Washington DC, U.S. July, 2014.
[5]Qing Zhong, Lingxue Lin, Yao Zhang, Zhigang Wu. Study on the Control Strategies and Dynamic Performance of DC Distribution Network. IEEE PES General Meeting, 2012, Detroit Renaissance Center, Detroit, MI, USA
[6]Qing Zhong, Zhang Yao, Lingxue Lin, Zhigang Wu, Jinming Yang. Study on the unsubstantial locations index for voltage sags. DRPT 2011, 4th International Conference on Electric Utility Deregulation and Restructuring and Power Technologies, Weihai, Shandong, China, p 410-416.
[7]Qing Zhong, Zhigang Wu, Lingxue Lin, Yao Zhang, Jianshe Zhang. Computing resources assignment in RTDS simulators with subgraph isomorphism based on genetic algorithm. DRPT 2011, 4th International Conference on Electric Utility Deregulation and Restructuring and Power Technologies, Weihai, Shandong, China, p 1144-1149.
[8]Qing Zhong, Yao Zhang, Lingxue Lin, Qian Chen, Zhigang Wu . Study of HVDC light for its enhancement of AC/DC interconnected transmission systems. IEEE Power and Energy Society General Meeting, 2008, Pittsburg, US, p 4596003.
[9]Qing Zhong, Yao Zhang, Lingxue Lin. Diagnosis of commutation failure in HVDC systems based on wavelet transforms. 3rd International Conference on Deregulation and Restructuring and Power Technologies, DRPT 2008, 3rd International Conference on Deregulation and Restructuring and Power Technologies, DRPT 2008, Nanjing, China, 2008, p 1712-1717.
[10]Zhigang Wu, Qing Zhong, Yao Zhang., State Transition Graph of Cascading Electrical Power Grids, Proceedings of the IEEE PES General Meeting, Tampa, 2007
[11]Qing Zhong, Yao Zhang, Jianshe Zhang, Zhigang Wu. Voltage Sensitivity Analysis in Voltage Support of the China Southern Power Grid. IEEE PES PowerCon, ChongQing, 2006.
[12]Lingxue Lin, Yao Zhang, Qing Zhong, Zhiwei Liao. Studies of Commutation Failures in HVDC System Based on Hypersim. IEEE PES PowerCon, ChongQing, 2006.
[13]Qing Zhong, Yao Zhang, Jinming Yang, et al. Constructive Nonlinear Control of the Parallel AC/DC Transmission System. IEEE PES General Meeting, Montreal, 2006.
[14]Qing Zhong, K.W. Eric Cheng, N. C. Cheung, Jianfei Pan, JieWu. Passivity-Based Control of the Shunt Active Power Filters. EPE 2003, 2-4 Sep, Toulouse, France
National Standard
[1]GB/T 32880.1-2016, Economic evaluation of power quality—Part 1: Economic evaluation method for the end-users.
[2]GB/T 32880.2-2016, Economic evaluation of power quality—Part 2: Economic Evaluation Method For the distribution network.
[3]GB/T 32880.3-2016, Economic evaluation of power quality—Part 3: Method for collecting data.