Abstract
This paper proposes a multi-size Split-diesel generator (Split-DG) model with three different sizes of DGs and more switching configurations compared to the existing split-DG models. The proposed multi-size Split-DG system is examined for optimal sizing of remote microgrids with and without renewable-battery system. As a novel concept, multi-size Split-DG is used to reduce contamination, cost, and dumped power by using multiple small DGs to replace the single-size large DG. As another contribution of this study, a practical model is developed by considering the capacity degradation of components, spinning reserve, as well as DG’s and fuel tank’s constraints. The optimization problem is solved using a variable weighting particle swarm optimization (VW-PSO) algorithm. The effectiveness of the proposed Split-DG systems, optimized by the developed VW-PSO, is verified by comparing the results with conventional single-size DG system and the system optimized by conventional PSO. While the formulated optimization problem is general and can be used for any remote microgrids, an aboriginal community in South Australia is examined in this study. For this purpose, realistic data of load and weather, as well as technical and economic data of components, are used. It is found that the Split-DG-PV-WT-BES system has the lowest electricity cost compared to the systems without BES, or without PV and WT.
Highlights
Due to emission concerns, a fully power supply through diesel generators (DGs) is not environmentally friendly compared to the systems with renewable energy (RE) generation
DGs supply the majority of those off-grid regions, some of them have been hybridized with solar generation in the Northern Territory [2]
The main research gaps in existing studies are: (1) split-DG concept was rarely considered for optimal sizing in remote microgrids, (2) real input data were overlooked in several studies, (3) spinning reserve for the remote microgrid with renewable energy was ignored, and (4) the capacity degradation of the PV and battery energy storage (BES) was rarely considered
Summary
Electrification of remote communities is a tough challenge for electricity providers. Due to emission concerns, a fully power supply through diesel generators (DGs) is not environmentally friendly compared to the systems with renewable energy (RE) generation. DGs supply the majority of those off-grid regions, some of them have been hybridized with solar generation in the Northern Territory [2]. This lack of service in isolated areas opens the door to consider new technologies and strategies to produce local electricity at a lower cost. Due to the constant increase of the diesel price and the complex delivery logistic in these regions, the electricity cost is heavily impacted [2].
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