Reliability modeling and assessment of a community microgrid with electric vehicle charging station as a critical load

•The primary focus is on physical component failure in micro-grids, which are viewed as "systems," and how these failures affect the micro-grid's function to meet reliability objectives, such as supporting a critical load.•The different estimating techniques presented in this work can be employed to improve the reliability of the micro-grid system during the design phase. Since each approach has unique qualities, they can fill in the gaps between each method's capabilities and the other while analyzing micro-grid reliability. Rather than offering quantitative solutions to microgrid reliability evaluation or prediction.•The key objective of this paper is to demonstrate how micro-grids can be treated as systems for reliability purposes, opening up a system-theoretic and reliability-theoretic door for micro-grid reliability modelling and analysis. Microgrids are constituted of interconnected loads and dispersed energy resources. They increase the reliability of the power supply, decrease the cost of the per unit energy and support the green environment concept. Microgrids have gained importance due to their ability to deliver reliable energy and operate in both grid-connected and off-grid/island modes. Renewable energy sources such as photovoltaic (PV) and wind can be connected to the microgrid system to generate green energy. An electric vehicle charging station (EVCS) can be deployed in microgrids powered by renewable energy sources. An effective way to handle the rapidly rising load demand of electric vehicles (EVs) is to integrate EV recharge stations into microgrids. Due to the intermittent nature of solar PV and EV load's reliability, an evaluation of microgrids becomes challenging. Assessment of the components’ failure and their impact on the system reliability is proposed using different methods. Reliability Block Diagram (RBD), Markov Reliability Modeling (MRM) and Fault Tree Analysis (FTA) - Monte Carlo simulation are used for the Reliability Modeling of a community microgrid considering EVCS as a critical load. The mean time to failure (MTTF) is computed for the entire microgrid which includes PV, wind and fuel cell systems integrated into the grid with associated power electronic devices, transmission lines, transformers and point of common coupling (PCC). MATLAB software was used to program and study the reliability aspects of the microgrid. Using the FTA MCS technique and grid functions for 45 years with 20 % reliability, significant results wer