Your search keyword '"VISHNURAM, Pradeep"' showing total 2 results

1. Fuzzy-Based Efficient Control of DC Microgrid Configuration for PV-Energized EV Charging Station.

Author

Abraham, Dominic Savio, Chandrasekar, Balaji, Rajamanickam, Narayanamoorthi, Vishnuram, Pradeep, Ramakrishnan, Venkatesan, Bajaj, Mohit, Piecha, Marian, Blazek, Vojtech, and Prokop, Lukas

Subjects

ELECTRIC vehicle charging stations, MICROGRIDS, RENEWABLE energy sources, ELECTRIC vehicles, PHOTOVOLTAIC power systems, ELECTRIC power distribution grids, ELECTRIC automobiles

Abstract

Electric vehicles (EVs) are considered as the leading-edge form of mobility. However, the integration of electric vehicles with charging stations is a contentious issue. Managing the available grid power and bus voltage regulation is addressed through renewable energy. This work proposes a grid-connected photovoltaic (PV)-powered EV charging station with converter control technique. The controller unit is interfaced with the renewable energy source, bidirectional converter, and local energy storage unit (ESU). The bidirectional converter provides a regulated output with a fuzzy logic controller (FLC) during charging and discharging. The fuzzy control is implemented to maintain a decentralized power distribution between the microgrid DC-link and ESU. The PV coupled to the DC microgrid of the charging station is variable in nature. Hence, the microgrid-based charging is examined under a range of realistic scenarios, including low, total PV power output and different state of charge (SOC) levels of ESU. In order to accomplish the effective charging of EV, a decentralized energy management system is created to control the energy flow among the PV system, the battery, and the grid. The proposed controller's effectiveness is validated using a simulation have been analyzed using MATLAB under various microgrid situations. Additionally, the experimental results are validated under various modes of operation. [ABSTRACT FROM AUTHOR]

Published

2023

2. A Comprehensive Review of the Bidirectional Converter Topologies for the Vehicle-to-Grid System.

Author

Panchanathan, Suresh, Vishnuram, Pradeep, Rajamanickam, Narayanamoorthi, Bajaj, Mohit, Blazek, Vojtech, Prokop, Lukas, and Misak, Stanislav

Subjects

*ELECTRIC vehicle batteries, *ELECTRIC utility costs, *ELECTRIC power distribution grids, *ELECTRICAL load, *POWER semiconductors, *FUEL cell vehicles, *ELECTRIC vehicles

Abstract

Over the past decade, there has been a great interest in the changeover from cars powered by gasoline to electric vehicles, both within the automotive industry and among customers. The electric vehicle–grid (V2G) technology is a noteworthy innovation that enables the battery of an electric vehicle during idling conditions or parked can function as an energy source that can store or release energy whenever required. This results in energy exchange between the grid and EV batteries. This article reviews various bidirectional converter topologies used in the V2G system. Additionally, it can reduce the cost of charging for electric utilities, thus increasing profits for EV owners. Normally electric grid and the battery of an electric vehicle can be connected through power electronic converters, especially a bidirectional converter, which allows power to flow in both directions. The majority of research work is carried out over the converters for V2G applications and concerns utilizing two conversion stages, such as the AC-DC conversion stage used for correcting the power factor and the DC-DC conversion stage for matching the terminal voltage. Furthermore, a bidirectional conversion can be made for an active power transfer between grid–vehicle (G2V) and V2G effectively. This review explores and examines several topologies of bidirectional converters which make it possible for active power flow between the grid and the vehicle and vice versa. Moreover, different types of charging and discharging systems, such as integrated/non-integrated and on/off board, etc., which have been used for electric vehicle applications, are also discussed. A comparison study is carried out based on several other factors that have been suggested. The utilization of semiconductors in power converters and non-conventional resources in charging and discharging applications are the two improving technologies for electric vehicles. [ABSTRACT FROM AUTHOR]

Published

2023