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Grid–source coordinated dispatching based on heterogeneous energy hybrid power generation.

Authors :
Zhang, Xinshuo
Huang, Weibin
Chen, Shijun
Xie, Diya
Liu, Dexu
Ma, Guangwen
Source :
Energy. Aug2020, Vol. 205, pN.PAG-N.PAG. 1p.
Publication Year :
2020

Abstract

Cascade hydropower stations have good regulation and storage capacity and they can be used as a regulatory and compensatory "medium" to compensate for the instability of wind–photovoltaic power generation. This paper presents a short-term multi-objective coordinated dispatching model based on wind–photovoltaic–hydro heterogeneous energy hybrid power generation. The multi-objectives of the model included accepting new energy for power generation to the greatest possible extent, tracing the load curve of the grid with minimum differences, and minimizing the discarded water volume of the cascade reservoirs. To reduce the complexity of the problem, the model was decomposed into two-stage optimization model and solved by using the firefly algorithm. This model was applied to a national-level wind–photovoltaic–hydro complementary power generation base in China. The research results verified the validity of the model and showed that it was feasible to compensate for the wind–photovoltaic power output fluctuation by the cascade hydropower stations and to supply power to the grid by bundling these three power sources. During this process, the cascade hydropower stations certainly made some sacrifices and increased the amount of discarded water. The new operational strategy proposed in this paper can promote the low-carbon power dispatching and optimization of the energy structure. • A framework for a heterogeneous energy complementary power system was proposed. • A new grid–source coordinated dispatching model was developed. • A two-stage decoupled optimization model was built for a multi-objective solution. • The developed framework and the method were assessed in Yalong River in China. [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
03605442
Volume :
205
Database :
Academic Search Index
Journal :
Energy
Publication Type :
Academic Journal
Accession number :
144408565
Full Text :
https://doi.org/10.1016/j.energy.2020.117908