Abstract
Efficient alternatives in energy production and consumption are constantly being investigated and conducted by increasingly strict policies. Buildings have a significant influence on electricity consumption, and their management may contribute to the sustainability of the electricity sector. Additionally, with growing incentives in the distributed generation (DG) and electric vehicle (EV) industries, it is believed that smart buildings (SBs) can play a key role in sustainability goals. In this work, an energy management system is developed to reduce the power demands of a residential building, considering the flexibility of the contracted power of each apartment. In order to balance the demand and supply, the electrical power provided by the external grid is supplemented by microgrids such as battery energy storage systems (BESS), EVs, and photovoltaic (PV) generation panels. Here, a mixed binary linear programming formulation (MBLP) is proposed to optimize the scheduling of the EVs charge and discharge processes and also those of BESS, in which the binary decision variables represent the charging and discharging of EVs/BESS in each period. In order to show the efficiency of the model, a case study involving three scenarios and an economic analysis are considered. The results point to a 65% reduction in peak load consumption supplied by an external power grid and a 28.4% reduction in electricity consumption costs.
Highlights
Due to it great potential to be exploited, there has been a significant increase in investments in distributed generation (DG) ventures worldwide
This paper aimed to model an optimization problem, considering energy resources in a residential building, such as photovoltaic (PV), electric vehicle (EV), and battery energy storage systems (BESS), and considering the contracted power flexibility of each apartment to reduce the building power demand
It was assumed that the actual data of PV, total building electrical energy consumption, trips, and initial values of state of charge (SOC) for the batteries of the EVs and BESS are known [7,8]
Summary
Due to it great potential to be exploited, there has been a significant increase in investments in distributed generation (DG) ventures worldwide. This is noticeable in the increase in programs that are aimed at popularizing the implementation of renewable energy sources (RES) in addition to investments in research and development (R&D) and publications of works in this field [1]. In 1994, the Japanese government subsidized 50% of the investment for installation of photovoltaic generators on about 70,000 roofs [2]. In Europe, the German government in 1999 launched the 100,000 Roofs Solar Program aimed at installing photovoltaic generators on 100,000 roofs with.
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