ANÁLISE DE CARREGADOR BIDIRECIONAL MONOFÁSICO PARA VEÍCULOS ELÉTRICOS COM CARREGAMENTO NÍVEL 2

Abstract

The growing pursuit of more efficient and sustainable traction systems has driven the electrification of the global automotive fleet. Several countries have set ambitious short- and medium-term targets to replace internal combustion vehicles with hybrid or fully electric models. This movement is driven both by the need to reduce greenhouse gas emissions and the scarcity of fossil fuels. In addition to benefiting the environment, electrification offers numerous research and development opportunities for industry and academia, focusing on improving energy efficiency and reducing costs. With this context in mind, the present project aims to develop a computational simulation model for the study of converter systems dedicated to vehicle battery charging, specifically the 7.5 kW Level 2 bidirectional on-board charger. The chosen charger model consists of two stages connected by a DC bus, with the first stage comprising a fully controlled Full-Bridge converter responsible for interfacing with the charger's grid, allowing bidirectional power flow between the grid and the DC bus. The Dual Active Bridge was selected to compose the second stage of the system, with the function of managing the power flow of the battery, controlling the charging and discharging process. As a result, the model showed low harmonic distortion and a unity power factor. Additionally, it achieved the goals of efficient operation for the electric vehicle battery.