Abstract
The disturbance of integrated power will increase while the rotational inertia that can restrain the change of system frequency will decrease when large-scale renewable energy is integrated to the power grid. This produces new problems and challenges for AGC Control. Based on the model of sub operating area, this paper proposed the fundamental principle of AGC control when large-scale renewable energy, thermal and hydro units are participating in the process of frequency regulation. These three types of resources can undertake the total ARR (Area Regulation Requirement) of the whole operating area by equal proportional regulation capacity ratio strategy or priority coordinated control strategy. Besides, this paper also described how to track inner stable tie-lines and how to coordinate with upper level load dispatch center to jointly regulate system frequency. These research results are helpful for practical applications of AGC regulation.
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Hu Z, Luo H (2018) Research status and prospect of automatic generation control with integration of large-scale renewable energy. Autom Electr Syst 42(8):2–15
Li X, Huang J et al (2016) Review on large-scale involvement of energy storage in power grid fast frequency regulation. Power Syst Prot Control 44(7):145–153
Liu H, Shi H, Teng X (2009) Hydro-thermal AGC generators coordinated optimization control strategy in Yunnan power grid. Autom Electr Power Syst 33(20):96–99
Zhou W, Qiao Z, Si F (2010) Multi-objective load optimal dispatch and decision-making guidance of power plant. Proc CSEE 30(2):29–34
Ding M, Wang W et al (2014) A review on the effect of large-scale PV generation on power systems. Proc CSEE 34(1):1–14
Sun H, Liu X, Ben C et al (2018) Multi-objective risk scheduling model of power system containing power station with integrated wind power and energy storage. Autom Electr Power Syst 42(5):94–101
Zhu D, Liu W, Cai W et al (2018) Load-source coordinated dispatch method for program wind power accommodation based on rolling optimization of energy and power. Autom Electr Power Syst 42(5):80–85
Chen D, Zhang L et al (2016) Control strategy of energy storage for frequency regulation and evaluation of investment income. Mod Electr Power 33(1):80–86
Hu Z, Xu X, Zhang F et al (2014) Research on automatic generation control strategy incorporating energy storage resources. Proc CSEE 34(29):5080–5087
Xu J, Tang X, Xu Q et al (2018) Frequency control considering deep and fast load changing capability of thermal power units. Autom Electr Power Syst 42(8):74–82
Niu Y, Zhang Y, Zhang H et al (2016) Optimal control strategy and capacity planning of hybrid energy storage system for improving AGC performance of thermal power units. Autom Electr Power Syst 40(10):38–45
Yin G, Li X, Guo L et al (2015) Application of hybrid energy storage system on wind/solar hybrid microgrid. Proc CSU-EPSA 27(1):49–53
Teng X, Gao Z et al (2015) Requirements analysis and key technologies for automatic generation control for smart grid dispatching and control systems. Autom Electr Power Syst 39(1):81–87
Zhao B, Xiao C et al (2017) Penetration based accommodation capacity analysis on distributed photovoltaic connection in regional distribution network. Autom Electr Power Syst 41(21):105–111
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Wang, J., Zhang, H. (2020). Power Frequency Coordination Control Method for High Penetration Renewable Energy Resources. In: Xue, Y., Zheng, Y., Rahman, S. (eds) Proceedings of PURPLE MOUNTAIN FORUM 2019-International Forum on Smart Grid Protection and Control. Lecture Notes in Electrical Engineering, vol 585. Springer, Singapore. https://doi.org/10.1007/978-981-13-9783-7_23
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DOI: https://doi.org/10.1007/978-981-13-9783-7_23
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