Optimal allocation of distributed generation units and fast electric vehicle charging stations for sustainable cities
Isaac Prempeh, Albert K. Awopone, Patrick Nyaaba Ayambire, Ragab A. El‐Sehiemy
Abstract
The rise of electric vehicles (EVs) in sustainable cities has fuelled interest in Distributed Generation (DG) units allocation. A well-planned and efficient charging infrastructure is required for effective e-mobility. The paper examined the single-objective frameworks of optimal simultaneous allocation of DG units and fast EV charging stations (EVCS). The applications are employed on the IEEE 69 bus network and a real part of the Ghana network in the Ashanti region. The optimization tasks are carried out by using Particle swarm optimization (PSO) and artificial bee colony (ABC) algorithms. The impact of optimal placement on the networks was analysed. The results show that with high penetration levels of DG units (up to 40%) and fast EVCS, PSO, and ABC can achieve a significant power loss reduction that reaches 68%. Furthermore, PSO outperforms ABC in relation to the voltage deviation index on both the test network and the 33 kV Ashanti region network, while still satisfying the IEC standards' 5% margins. The results indicate that PSO and ABC are viable swarm algorithms for mitigating active power loss and enhancing the voltage profile of a system through concurrent allocation. • The study focuses on simultaneous allocation of distributed generation (DG) and electric vehicle charging stations (EVCS). • Conducted on the IEEE 69 bus network and a real part of Ghana's network. • Particle Swarm Optimization (PSO) and Artificial Bee Colony (ABC) algorithms are used for optimal placement. • PSO and ABC demonstrate reduced power loss by up to 68% with high penetration levels of DG units (up to 40%) and EVCS.