Abstract
With recent technology advances and price drop, battery energy storage systems (BESSs) are considered as a promising storage technology in power systems. In this paper, a stochastic BESS planning model is introduced, which determines optimal capacity and durations of BESSs to co-locate utility-scale solar photovoltaic (PV) systems in a high-voltage power system under the uncertainties of renewable resources and electric load. The optimization model minimizing total costs aims to obtain at least 20% electric energy from renewable sources, while satisfying all the physical constraints. Furthermore, two-stage stochastic programming is applied to formulate mathematical optimization problem to find out optimal durations and capacity of BESSs. In scheduling BESSs, chronology needs to be considered to represent temporal changes of BESS states; therefore, a scenario generation method to generate random sample paths with 1-h time step is adopted to explicitly represent uncertainty and temporal changes. The proposed mathematical model is applied to a modified IEEE 300-bus system that comprises 300 electric buses and 411 transmission lines. Optimal BESS durations and capacity are compared when different numbers of scenarios are employed to see the sensitivity to the number of scenarios in the model, and “value of stochastic solution” (VSS) is calculated to verify the impacts of inclusion of stochastic parameters. The results show that the building costs and capacity of BESSs increase when the number of scenarios increases from 10 to 30. By inspecting VSSs, it is observed that an explicit representation of stochastic parameters affects the optimal value, and the impacts become larger when the larger number of scenarios are applied.
Highlights
The results show that the building costs and capacity of battery energy storage systems (BESSs) increase when the number of scenarios increases from 10 to 30
A considerable attention is devoted to the planning and operation of Energy storage systems (ESSs), especially for battery energy storage systems (BESSs) that store electric energy in the form of chemical energy for dealing with the uncertainty and intermittency of increased renewable resources in the power system, as well as shaving the peak load
An individual solar PV has three candidate BESSs with different durations, and optimal capacity of the BESSs can be found with any combination of three candidate BESSs within
Summary
Energy storage systems (ESSs) generally have been used as a means for shifting peak load by supplying electricity during peak load hours with stored energy. A considerable attention is devoted to the planning and operation of ESSs, especially for battery energy storage systems (BESSs) that store electric energy in the form of chemical energy for dealing with the uncertainty and intermittency of increased renewable resources in the power system, as well as shaving the peak load. As of 2018, global installed capacity of BESSs is approximately 170 GW and expected to increase further [1]. The rapidly evolving technology and declining costs of BESSs are the main drivers of the extensive utilization of BESSs. The rapidly evolving technology and declining costs of BESSs are the main drivers of the extensive utilization of BESSs In this context, well-defined simulation tools for planning capacity of BESSs in a power system need to be developed to estimate costs and assess effectiveness of BESS installation. Mathematical optimization models are studied to obtain optimal capacity of BESSs to meet specific criteria of given power systems such as environmental energy policies
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