State Assemblage of EV’s Intelligent Integrated Station Considering the Grid Operating Status

doi:10.3969/j.issn.1000-7229.2015.07.027

Abstract

Abstract:

As a regional active power station， electric vehicle intelligent charging-discharging-storage integrated station can provide auxiliary services for the grid by developing reasonable charging/discharging strategy considering the operating status of the grid. Generally， the grid operates in normal， alert， emergency， collapse， or restorative state， and correspondingly the intelligent integrated station may operate in normal， protective， or isolated state. The proposed standard operating procedures can be applied in different operating conditions. By considering the operating states of both the grid and the intelligent integrated station， we can combine the two systems together and make full use of the integrated station. In this way， the integrated station can provide services such as frequency regulation， reactive power compensation， and harmonic suppression for the grid. As a whole， the state assemblage of the integrated station is helpful to improve the power quality of the grid by considering the operation status of the grid.

Key words: electric vehicle, intelligent integrated station, operating procedure, state assemblage, incremental benefit

CLC Number:

TM 910.6

CHU Haoxiang， XIE Da， ZHANG Yu. State Assemblage of EV’s Intelligent Integrated Station Considering the Grid Operating Status[J]. ELECTRIC POWER CONSTRUCTION, 2015, 36(7): 187-193.

References

［1］Su W， Eichi H， Zeng W， et al. A survey on the electrification of transportation in a smart grid environment［J］. Industrial Informatics， IEEE Transactions on， 2012， 8（1）: 1-10.
［2］Chan C C. The state of the art of electric， hybrid， and fuel cell vehicles［J］. Proceedings of the IEEE， 2007， 95（4）: 704-718.
［3］Clement-Nyns K， Haesen E， Driesen J. The impact of charging plug-in hybrid electric vehicles on a residential distribution grid［J］. Power Systems， IEEE Transactions on， 2010， 25（1）: 371-380.
［4］李惠玲，白晓民.电动汽车充电对配电网的影响及对策［J］. 电力系统自动化，2011，35（17）:38-43.
Li Huiling， Bai Xiaomin. Impacts of electric vehicles charging on distribution grid［J］. Automation of Electric Power Systems， 2011， 35（17）: 38-43.
［5］高赐威，张亮. 电动汽车充电对电网影响的综述［J］. 电网技术， 2011， 35（2）: 127-131.
Gao Ciwei， Zhang Liang. A survey of influence of electrics vehicle charging on power grid［J］. Power System Technology， 2011， 35（2）: 127-131.
［6］Hadley S W， Tsvetkova A A. Potential impacts of plug-in hybrid electric vehicles on regional power generation［J］. The Electricity Journal， 2009， 22（10）: 56-68.
［7］胡泽春，宋永华，徐智威，等. 电动汽车接入电网的影响与利用［J］. 中国电机工程学报， 2012， 32（4）: 1-10.
Hu Zechun， Song Yonghua， Xu Zhiwei， et al. Impacts and utilization of electric vehicles integration into power systems［J］. Proceedings of the Chinese Society of Electrical Engineering， 2012， 32（4）: 1-10.
［8］徐智威，胡泽春，宋永华，等. 充电站内电动汽车有序充电策略［J］. 电力系统自动化， 2012， 36（11）: 38-43.
Xu Zhiwei， Hu Zechun， Song Yonghua， et al. Coordinated charging of plug-in electric vehicles in charging stations［J］. Automation of Electric Power Systems， 2012， 36（11）: 38-43.
［9］Singh M， Kumar P， Kar I. A multi charging station for electric vehicles and its utilization for load management and the grid support［J］. IEEE Transactions on Smart Grid， 2013， 4（2）: 1026-1037.
［10］肖湘宁，温剑锋，陶顺，等. 电动汽车充电基础设施规划中若干关键问题的研究与建议［J］. 电工技术学报， 2014， 29（8）: 1-10.
Xiao Xiangning， Wen Jianfeng， Tao Shun， et al. Study and Recommendations of the Key Issues in Planning of Electric Vehicles’ Charging Facilities［J］. Transactions of China Electrotechnical Society， 2014， 29（8）:1-10.
［11］Etezadi-Amoli M， Choma K， Stefani J. Rapid-charge electric-vehicle stations［J］. Power Delivery， IEEE Transactions on， 2010， 25（3）: 1883-1887.
［12］付学谦，陈皓勇，刘国特，等. 分布式电源电能质量综合评估方法［J］. 中国电机工程学报， 2014， 34（25）: 4270-4276.
Fu Xueqian， Chen Haoyong， Liu Guote， et al. Power quality comprehensive evaluation method for distributed generation［J］. Proceedings of the Csee， 2014， 34（25）: 4270-4276.
［13］Li Y W， Vilathgamuwa D M， Loh P C. A grid-interfacing power quality compensator for three-phase three-wire microgrid applications［J］. Power Electronics， IEEE Transactions on， 2006， 21（4）: 1021-1031.
［14］Vilathgamuwa D M， Loh P C， Li Y. Protection of microgrids during utility voltage sags［J］. Industrial Electronics， IEEE Transactions on， 2006， 53（5）: 1427-1436.
［15］Banakar H， Luo C， Ooi B T. Impacts of wind power minute-to-minute variations on power system operation［J］. Power Systems， IEEE Transactions on， 2008， 23（1）: 150-160.
［16］Enslin J H R， Heskes P J M. Harmonic interaction between a large number of distributed power inverters and the distribution network［J］. Power Electronics， IEEE Transactions on， 2004， 19（6）: 1586-1593.
［17］楚皓翔，解大，娄宇成，等. 电动汽车智能充放储一体化电站无功电压调控策略［J］. 电力自动化设备， 2014， 34（11）: 48-54.
Chu Haoxiang， Xie Da， Lou Yucheng， et al. Strategy of reactive power and voltage control for integrated EV station of intelligent charging， discharging and storage［J］. Electric Power Automation Equipment， 2014， 34（11）: 48-54.
［18］Gao S， Chau K T， Liu C， et al. Integrated Energy Management of Plug-in Electric Vehicles in Power Grid With Renewables［J］. Vehicular Technology IEEE Transactions on， 2014， 63（7）:3019 - 3027.
［19］Xie D， Chu H， Lu Y， Gu C， Li F， Zhang Y. The Concept of EV’s Intelligent Integrated Station and Its Energy Flow. Energies. 2015， 8（5）:4188-4215.
［20］杨敏霞，贾玉健，冯俊淇，等. 电动汽车充放储一体化电站的标准运行规程探讨［J］. 电力科学与技术学报， 2014， 29（1）: 18-23，26.
Yang Minxia， Jia Yujian， Feng Junqi， et al. Discussion on operation procedures for charging-discharging-storage integrated station［J］.Journal of Electric Power Science And Technology，2014（1）:18-23，36.
［21］解大，贾玉健，冯俊淇，等. 一体化电站对电力系统区域控制偏差指标的响应控制策略［J］. 电力建设， 2014， 35（12）: 19-25.
XIE Da， JIA Yujian， FENG Junqi， et al. Integrated station control strategy responding to power system area control error［J］.Electric Power Construction，2014，35（12）: 19-25.

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