Abstract
Distributed generation (DG) and capacitor bank (CB) allocation in distribution systems (DS) has the potential to enhance the overall system performance of radial distribution systems (RDS) using a multiobjective optimization technique. The benefits of CB and DG injection in the RDS greatly depend on selecting a suitable number of CBs/DGs and their volume along with the finest location. This work proposes applying a hybrid enhanced grey wolf optimizer and particle swarm optimization (EGWO-PSO) algorithm for optimal placement and sizing of DGs and CBs. EGWO is a metaheuristic optimization technique stimulated by grey wolves. On the other hand, PSO is a swarm-based metaheuristic optimization algorithm that finds the optimal solution to a problem through the movement of the particles. The advantages of both techniques are utilized to acquire mutual benefits, i.e., the exploration ability of the EGWO and the exploitation ability of the PSO. The proposed hybrid method has a high convergence speed and is not trapped in local optimal. Using this hybrid method, technical, economic, and environmental advantages are enhanced using multiobjective functions (MOF) such as minimizing active power losses, voltage deviation index (VDI), the total cost of electrical energy, and total emissions from generation sources and enhancing the voltage stability index (VSI). Six different operational cases are considered and carried out on two standard distribution systems, namely, IEEE 33- and 69-bus RDSs, to demonstrate the proposed scheme’s effectiveness extensively. The simulated results are compared with existing optimization algorithms. From the obtained results, it is observed that the proposed EGWO-PSO gives distinguished enhancements in multiobjective optimization of different conflicting objective functions and high-level performance with global optimal values.
Highlights
Minor improvement of voltage stability index (VSI) compared to existing techniques, significant minimization of real power losses shrinks the negligible effects of voltage deviation index (VDI) and VSI
A hybrid enhanced grey wolf optimizer (EGWO)-particle swarm optimization (PSO) algorithm has been proposed as a multiobjective framework for optimal placement and sizing of combined distributed generation (DG)/capacitor bank (CB) in radial distribution systems (RDS)
It is applied to two standard test systems such as IEEE 33-bus and 69-bus to validate its effectiveness for three key objectives: technical, economic, and environmental
Summary
The growing consumption of electric energy mainly produced by burning fossil fuels leads to various environmental and financial issues [1]. The installation and integration of DGs in distribution systems can offer numerous technical, economic, and environmental advantages [3,6] It can be achieved by selecting the optimal site and size of DG units. Optimal size and placement of capacitor banks (CBs) in the distribution system need static or switchable capacitors for reactive power compensation at strategically identified locations in the distribution system that resolves the power quality issues It provides numerous technical and economic advantages such as the reduction in power loss, improved load-bus voltage, improved power factor, and reduced reactive power demand from the supply side [4,5,10]. Efficient and optimal planning for reactive power compensation is mandatory to cope with the ever-growing energy demand and technical and economic issues of distribution networks [4,6,10]
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