Optimization of shared energy storage configuration for village-level photovoltaic systems considering vehicle charging management

Distributed renewable energy is more abundant in rural areas, and a large amount of distributed photovoltaic grid-connected power brings challenges to the stable of the power grid. How to promote the self-generation and self-consumption of distributed renewable energy has become an urgent problem. I...

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Published in:Energy (Oxford) Vol. 311; p. 133373
Main Authors: Wang, Haifeng, Liao, Yate, Zhang, Jiarui, Cai, Ziwen, Zhao, Yun, Wang, Weijun
Format: Journal Article
Language:English
Published: Elsevier Ltd 01.12.2024
Subjects:
Charge management
Electric vehicle
energy
Energy storage configuration planning
Improved particle swarm algorithm
income
power generation
solar energy
Village-level distributed photovoltaic systems
Village-level distributed photovoltaic systems
Electric vehicle
Energy storage configuration planning
Improved particle swarm algorithm
Charge management
ISSN:0360-5442
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Abstract Distributed renewable energy is more abundant in rural areas, and a large amount of distributed photovoltaic grid-connected power brings challenges to the stable of the power grid. How to promote the self-generation and self-consumption of distributed renewable energy has become an urgent problem. In this paper, a village-level distributed photovoltaic power generation system including energy storage and electric vehicles is constructed. With the goal of minimizing the photovoltaic grid-connected power and maximizing the annual comprehensive revenue, the planning model of energy storage capacity allocation for village-level distributed power generation system is constructed. Considering the charging management for different numbers of electric vehicles, the optimal energy storage capacity allocation strategy is solved using the improved particle swarm algorithm.Five scenarios are set up as examples to be analyzed.The conclusions are:(1)After the configuration of a reasonable energy storage,the grid-connected generation of the system is significantly reduced,and the annual comprehensive revenue of the system is significantly increased.(2)After considering charging management for different numbers of electric vehicles, the capacity and power of the energy storage configuration can be significantly reduced, thus reducing the energy storage investment cost and operation and maintenance cost, and further significantly improving the annual comprehensive revenue of this system. •Constructed photovoltaic systems incorporating energy storage and electric vehicles.•Constructed a dual-objective energy storage capacity planning model for rural areas.•Considering the charging time management for different numbers of electric vehicles.•Photovoltaic grid connection declines and overall system revenue increases greatly.
AbstractList Distributed renewable energy is more abundant in rural areas, and a large amount of distributed photovoltaic grid-connected power brings challenges to the stable of the power grid. How to promote the self-generation and self-consumption of distributed renewable energy has become an urgent problem. In this paper, a village-level distributed photovoltaic power generation system including energy storage and electric vehicles is constructed. With the goal of minimizing the photovoltaic grid-connected power and maximizing the annual comprehensive revenue, the planning model of energy storage capacity allocation for village-level distributed power generation system is constructed. Considering the charging management for different numbers of electric vehicles, the optimal energy storage capacity allocation strategy is solved using the improved particle swarm algorithm.Five scenarios are set up as examples to be analyzed.The conclusions are:(1)After the configuration of a reasonable energy storage,the grid-connected generation of the system is significantly reduced,and the annual comprehensive revenue of the system is significantly increased.(2)After considering charging management for different numbers of electric vehicles, the capacity and power of the energy storage configuration can be significantly reduced, thus reducing the energy storage investment cost and operation and maintenance cost, and further significantly improving the annual comprehensive revenue of this system.
Distributed renewable energy is more abundant in rural areas, and a large amount of distributed photovoltaic grid-connected power brings challenges to the stable of the power grid. How to promote the self-generation and self-consumption of distributed renewable energy has become an urgent problem. In this paper, a village-level distributed photovoltaic power generation system including energy storage and electric vehicles is constructed. With the goal of minimizing the photovoltaic grid-connected power and maximizing the annual comprehensive revenue, the planning model of energy storage capacity allocation for village-level distributed power generation system is constructed. Considering the charging management for different numbers of electric vehicles, the optimal energy storage capacity allocation strategy is solved using the improved particle swarm algorithm.Five scenarios are set up as examples to be analyzed.The conclusions are:(1)After the configuration of a reasonable energy storage,the grid-connected generation of the system is significantly reduced,and the annual comprehensive revenue of the system is significantly increased.(2)After considering charging management for different numbers of electric vehicles, the capacity and power of the energy storage configuration can be significantly reduced, thus reducing the energy storage investment cost and operation and maintenance cost, and further significantly improving the annual comprehensive revenue of this system. •Constructed photovoltaic systems incorporating energy storage and electric vehicles.•Constructed a dual-objective energy storage capacity planning model for rural areas.•Considering the charging time management for different numbers of electric vehicles.•Photovoltaic grid connection declines and overall system revenue increases greatly.
ArticleNumber 133373
Author Wang, Weijun
Zhao, Yun
Zhang, Jiarui
Wang, Haifeng
Liao, Yate
Cai, Ziwen
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Keywords Village-level distributed photovoltaic systems
Electric vehicle
Energy storage configuration planning
Improved particle swarm algorithm
Charge management
Language English
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Snippet Distributed renewable energy is more abundant in rural areas, and a large amount of distributed photovoltaic grid-connected power brings challenges to the...
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SubjectTerms Charge management
Electric vehicle
energy
Energy storage configuration planning
Improved particle swarm algorithm
income
power generation
solar energy
Village-level distributed photovoltaic systems
Title Optimization of shared energy storage configuration for village-level photovoltaic systems considering vehicle charging management
URI https://dx.doi.org/10.1016/j.energy.2024.133373
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