Primary Frequency Control Ancillary Service in Distribution Network by Coordinated Scheduling of Wind Power and Demand Response

被引:1
作者
Khojasteh, Meysam [1 ]
Faria, Pedro [1 ]
Vale, Zita [1 ]
机构
[1] Polytech Porto, Porto, Portugal
来源
2020 17TH INTERNATIONAL CONFERENCE ON THE EUROPEAN ENERGY MARKET, EEM | 2020年
关键词
Demand response; distribution network; primary frequency control; wind power; uncertainty; SYSTEM;
D O I
10.1109/EEM49802.2020.9221891
中图分类号
X [环境科学、安全科学];
学科分类号
08 ; 0830 ;
摘要
Frequency is the main parameter that reflects the stability of power system, and mismatches between generation and consumption. Increasing the penetration level of renewable energy resource in distribution network, and their noticeable participation level to provide the required electricity lead to a new challenge for the distribution system operators (DSO). The variable nature of renewable resources is inevitable, and this uncertainty can lead to instability of power systems. Therefore, DSO shall use more flexible and schedulable resource to maintain the security of network in the acceptable level. In this work, Demand response (DR) program is proposed as the backup resource for compensating the wind power uncertainty in primary frequency control (PFC). The proposed model specifies the required capacity of DR resource to maintain the frequency of grid in the allowable region, based on the uncertainty of wind generation. The performance of proposed model will be investigated by a case study.
引用
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页数:5
相关论文
共 16 条
[1]  
Ackermann T, 2005, WIND POWER IN POWER SYSTEMS, P1, DOI 10.1002/0470012684
[2]   Demand Response Based on Kalman-Filtering for the Frequency Control [J].
Bao, Yu-Qing ;
Shen, Cheng ;
Wang, Qi ;
Zhang, Jin-Long .
JOURNAL OF ELECTRICAL ENGINEERING & TECHNOLOGY, 2019, 14 (03) :1087-1094
[3]   Demand response for frequency control of multi-area power system [J].
Bao, Yu-Qing ;
Li, Yang ;
Wang, Beibei ;
Hu, Minqiang ;
Chen, Peipei .
JOURNAL OF MODERN POWER SYSTEMS AND CLEAN ENERGY, 2017, 5 (01) :20-29
[4]   Application of Stochastic Decentralized Active Demand Response (DADR) System for Load Frequency Control [J].
Benysek, Grzegorz ;
Bojarski, Jacek ;
Smolenski, Robert ;
Jarnut, Marcin ;
Werminski, Szymon .
IEEE TRANSACTIONS ON SMART GRID, 2018, 9 (02) :1055-1062
[5]   Smart Demand for Frequency Regulation: Experimental Results [J].
Douglass, Philip J. ;
Garcia-Valle, Rodrigo ;
Nyeng, Preben ;
Ostergaard, Jacob ;
Togeby, Mikael .
IEEE TRANSACTIONS ON SMART GRID, 2013, 4 (03) :1713-1720
[6]   Aggregation and Remuneration of Electricity Consumers and Producers for the Definition of Demand-Response Programs [J].
Faria, Pedro ;
Spinola, Joao ;
Vale, Zita .
IEEE TRANSACTIONS ON INDUSTRIAL INFORMATICS, 2016, 12 (03) :952-961
[7]   Cooperation of Wind Power and Battery Storage to Provide Frequency Regulation in Power Markets [J].
He, Guannan ;
Chen, Qixin ;
Kang, Chongqing ;
Xia, Qing ;
Poolla, Kameshwar .
IEEE TRANSACTIONS ON POWER SYSTEMS, 2017, 32 (05) :3559-3568
[8]   A hybrid control approach for regulating frequency through demand response [J].
Malik, Anam ;
Ravishankar, Jayashri .
APPLIED ENERGY, 2018, 210 :1347-1362
[9]   Optimizing a Battery Energy Storage System for Frequency Control Application in an Isolated Power System [J].
Mercier, Pascal ;
Cherkaoui, Rachid ;
Oudalov, Alexandre .
IEEE TRANSACTIONS ON POWER SYSTEMS, 2009, 24 (03) :1469-1477
[10]   Distributed energy resources management using plug-in hybrid electric vehicles as a fuel-shifting demand response resource [J].
Morais, H. ;
Sousa, T. ;
Soares, J. ;
Faria, P. ;
Vale, Z. .
ENERGY CONVERSION AND MANAGEMENT, 2015, 97 :78-93