Abstract
Microgrid is a community-based power generation and distribution system that interconnects smart homes with renewable energy sources (RESs). Microgrid efficiently and economically generates power for electricity consumers and operates in both islanded and grid-connected modes. In this study, we proposed optimization schemes for reducing electricity cost and minimizing peak to average ratio (PAR) with maximum user comfort (UC) in a smart home. We considered a grid-connected microgrid for electricity generation which consists of wind turbine and photovoltaic (PV) panel. First, the problem was mathematically formulated through multiple knapsack problem (MKP) then solved by existing heuristic techniques: grey wolf optimization (GWO), binary particle swarm optimization (BPSO), genetic algorithm (GA) and wind-driven optimization (WDO). Furthermore, we also proposed three hybrid schemes for electric cost and PAR reduction: (1) hybrid of GA and WDO named WDGA; (2) hybrid of WDO and GWO named WDGWO; and (3) WBPSO, which is the hybrid of BPSO and WDO. In addition, a battery bank system (BBS) was also integrated to make our proposed schemes more cost-efficient and reliable, and to ensure stable grid operation. Finally, simulations were performed to verify our proposed schemes. Results show that our proposed scheme efficiently minimizes the electricity cost and PAR. Moreover, our proposed techniques, WDGA, WDGWO and WBPSO, outperform the existing heuristic techniques.
Highlights
Increasing energy consumption has been observed around the globe
The smart home we proposed is equipped with a rooftop PV generation system, as solar energy is less costly than other renewable energy sources (RESs) and available everywhere
The heuristic algorithms genetic algorithm (GA), grey wolf optimization (GWO), binary particle swarm optimization (BPSO), and wind-driven optimization (WDO) as well as proposed wind-driven GA (WDGA), wind-driven GWO (WDGWO) and wind-driven BPSO (WBPSO) were used to evaluate the performance of our proposed scheme in terms of electricity cost, peak to average ratio (PAR) and appliances waiting time (AWT) with and without RES integration
Summary
Increasing energy consumption has been observed around the globe. Presently, most power is produced from fossil fuels that increase carbon emissions. The large-scale installation of RESs to the existing conventional power system will increase the vulnerability of already heavily loaded power system [1] For this purpose, the transform of the current electric power system to the smart grid, i.e., the unification of advanced information and communication technologies (ICTs) with conventional power grid, is one of the best solutions [2]. The transform of the current electric power system to the smart grid, i.e., the unification of advanced information and communication technologies (ICTs) with conventional power grid, is one of the best solutions [2] These technologies exploit the Energies 2018, 11, 1002; doi:10.3390/en11041002 www.mdpi.com/journal/energies
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