Enhancing photovoltaic hosting capacity—A stochastic approach to optimal planning of static var compensator devices in distribution networks

Enhancing photovoltaic hosting capacity—A stochastic approach to optimal planning of static var compensator devices in distribution networks

•A novel static var compensator devices planning model is proposed for photovoltaic hosting capacity improvement.•The proposed planning model is under the framework of two-stage stochastic programming.•The uncertainties of photovoltaic output and load demand are taken into consideration.•A Benders d...

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Bibliographic Details
Published in:Applied energy 2019-03, Vol.238, p.952-962
Main Authors: Xu, Xu, Li, Jiayong, Xu, Zhao, Zhao, Jian, Lai, Chun Sing
Format: Article
Language:eng
Subjects:
Benders decomposition
Photovoltaic hosting capacity
Static var compensator planning model
Two-stage stochastic programming
Uncertainty scenarios
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Summary:•A novel static var compensator devices planning model is proposed for photovoltaic hosting capacity improvement.•The proposed planning model is under the framework of two-stage stochastic programming.•The uncertainties of photovoltaic output and load demand are taken into consideration.•A Benders decomposition based solution method is developed to efficiently solve the proposed two-stage planning problem.•The trade-off between planning cost of static var compensator and photovoltaic hosting capacity is studied. To improve photovoltaic hosting capacity of distribution networks, this paper proposes a novel optimal static var compensator planning model which is formulated as a two-stage stochastic programming problem. Specifically, the first stage of our model determines the static var compensator planning decisions and the corresponding photovoltaic hosting capacity. In the second stage, the feasibility of the first stage results is evaluated under different uncertainty scenarios of load demand and photovoltaic output to ensure no constraint violations, especially no voltage constraint violations. In addition, we simultaneously consider the minimization of static var compensator planning cost and the maximization of photovoltaic hosting capacity by formulating a multi-objective function. To improve the computational efficiency, a solution method based on Benders decomposition is developed by decomposing the two-stage problem into a master problem and multiple subproblems. The effectiveness of the proposed model and solution method is validated on modified IEEE 37-node and 123-node distribution systems. Last, our results show that the proposed model can significantly improve the photovoltaic hosting capacity. The case studies also demonstrate that the PV hosting capacity becomes insensitive to the additional SVC planning cost when the total cost exceeds about $175,000.
ISSN:0306-2619
1872-9118