Abstract
The inclusion of microgrids (MGs) in power systems, especially distribution-substation-level MGs, significantly affects power systems because of the large volumes of import and export power flows. Consequently, power dispatch has become complicated, and finding an optimal solution is difficult. In this study, a three-stage optimal power dispatch model is proposed to solve such dispatch problems. In the proposed model, the entire power system is divided into two parts, namely, the main power grid and MGs. The optimal power dispatch problem is resolved on the basis of multi-area concepts. In stage I, the main power system economic dispatch (ED) problem is solved by sensitive factors. In stage II, the optimal power dispatches of the local MGs are addressed via an improved direct search method. In stage III, the incremental linear models for the entire power system can be established on the basis of the solutions of the previous two stages and can be subjected to linear programming to determine the optimal reschedules from the original dispatch solutions. The proposed method is coded using Matlab and tested by utilizing an IEEE 14-bus test system to verify its feasibility and accuracy. Results demonstrated that the proposed approach can be used for the ED of power systems with MGs as virtual power plants.
Highlights
IntroductionEconomic dispatch (ED), and greenhouse gas emissions are major issues associated with utilities
Energy efficiency, economic dispatch (ED), and greenhouse gas emissions are major issues associated with utilities
Effective and fast three-stage ED model and approach are proposed to solve the problem of modern power systems considering MGs as virtual power plants (VPPs)
Summary
Economic dispatch (ED), and greenhouse gas emissions are major issues associated with utilities. Electrical energy has been used for over one hundred years since the first electric network was established in 1882 at the Pearl Street Station in New York by Thomson Edison [1], the development of power systems has evolved into generation, transmission, and distribution with a vertical system architecture. Carbon dioxide and other greenhouse gas emissions caused by thermal power plants exacerbate global warming because of the usage of carbon-based fuels in such plants. The electrical energy produced is delivered through transmission and distribution systems until it reaches customers. Electrical energy losses during transmission are considerable. Such losses affect the environment, and reduce the overall system efficiency
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