Economic Dispatch of Power System Including Electric Vehicle and Wind Farm

被引:0
|
作者
Pan Hua [1 ]
Liang Zuo-fang [1 ]
Xue Qiang-zhong [1 ]
机构
[1] Shanghai Univ Elect Power, Sch Econ & Management, Shanghai 200090, Peoples R China
来源
2017 IEEE CONFERENCE ON ENERGY INTERNET AND ENERGY SYSTEM INTEGRATION (EI2) | 2017年
关键词
electric vehicle; wind farm; economic dispatch; cuckoo search algorithm;
D O I
暂无
中图分类号
TE [石油、天然气工业]; TK [能源与动力工程];
学科分类号
0807 ; 0820 ;
摘要
Based on the measured data, the uncertainty of electric vehicle charging is considered. The time distribution of the charging load of the electric vehicle is obtained by the charging start time and the duration. The objective function aims at getting the lowest cost of coal consumption and the cost of valve point. The penalty function method is used to introduce the partial constraints into the objective function, and the optimal scheduling model with the electric vehicle and wind farm is established. Finally, the cuckoo search algorithm is used to solve the model, and the correctness of the model and algorithm is verified. The results show that the spontaneous charging of electric vehicle increases the peak-valley difference of the load, and wind farms can reduce costs.
引用
收藏
页码:181 / 185
页数:5
相关论文
共 50 条
  • [31] Short-term wind power output forecasting model for economic dispatch of power system incorporating large-scale wind farm
    Yuan, Tie-Jiang
    Chao, Qin
    Li, Yi-Yan
    Toerxun, Yibulayin
    [J]. Zhongguo Dianji Gongcheng Xuebao/Proceedings of the Chinese Society of Electrical Engineering, 2010, 30 (13): : 23 - 27
  • [32] Economic environmental dispatch of combined wind and thermal power system
    Kar, Sangita R.
    Dash, Deba P.
    Sharma, Renu
    [J]. JOURNAL OF STATISTICS AND MANAGEMENT SYSTEMS, 2023, 26 (01) : 1 - 12
  • [33] Environmental/economic power dispatch with wind power
    Jin, Jingliang
    Zhou, Dequn
    Zhou, Peng
    Miao, Zhuang
    [J]. RENEWABLE ENERGY, 2014, 71 : 234 - 242
  • [34] Multi-ojective power system dispatch with wind power and electric vehicles
    Zhu, Yongsheng
    Qiao, Baihao
    Qu, Boyang
    Yan, Li
    Yang, Lu
    Li, Chao
    [J]. Taiyangneng Xuebao/Acta Energiae Solaris Sinica, 2019, 40 (06): : 1722 - 1730
  • [35] Active Power Economic Dispatch of Wind Farm Cluster Based on Integer Linear Programming
    Lin, Li
    Zhu, Chenchen
    Wang, Qian
    Zeng, Jie
    [J]. 2013 IEEE GRENOBLE POWERTECH (POWERTECH), 2013,
  • [36] Quantum genetic algorithm for dynamic economic dispatch with valve-point effects and including wind power system
    Lee, Jia-Chu
    Lin, Whei-Min
    Liao, Gwo-Ching
    Tsao, Ta-Peng
    [J]. INTERNATIONAL JOURNAL OF ELECTRICAL POWER & ENERGY SYSTEMS, 2011, 33 (02) : 189 - 197
  • [37] Impact of aggregated model-based optimization for wind farm and electric vehicle on power system stability
    Bhukya, Jawaharlal
    Singh, Neeraj Kumar
    Mahajan, Vasundhara
    [J]. COMPUTERS & ELECTRICAL ENGINEERING, 2023, 105
  • [38] Dispatch Analysis of Power System Considering Carbon Quota for Electric Vehicle
    Chen, Zhong
    Lu, Yu
    Xing, Qiang
    Chen, Xuan
    Leng, Zhaoying
    [J]. Dianli Xitong Zidonghua/Automation of Electric Power Systems, 2019, 43 (16): : 44 - 51
  • [39] Research on Economic Operation Optimization of Electric System Including Wind Power Based on Interruptible Load
    Wu, Qianhong
    Su, Yunche
    Wang, Ying
    [J]. INDUSTRIAL DESIGN AND MECHANICS POWER II, 2013, 437 : 945 - 949
  • [40] Economic Emission Dispatch of Wind Power Integrated Combined Heat and Power System
    Adhvaryyu, Pradosh Kumar
    Chattopadhyay, Pranab Kumar
    Bhattacharjya, Aniruddha
    [J]. 2014 EIGHTEENTH NATIONAL POWER SYSTEMS CONFERENCE (NPSC), 2014,
12345