HYBRID CHARGING STATION
Mohite Madhuri Eknath1, Jamadar Alfaj Dilawar2, Lohar Shubham Gajanan3 ,Patole Akshay Ankush4 , Oza Prathmesh Mohan5 , Nikam Akshay Sanjay6 , Kutwal Mayur Namdev7 , Shinde Mayur Dipak8 , Ms. S.M. Shinde9 , Mr. S.H. Mali10
1,2,3,4,5,6,7,8 P.G. Student, Department Of Electrical Engineering, Shree Santkrupa Institute Of Engineering & Technology, Ghogaon Karad, India.
9,10 Assistant Professor, Department Of Electrical Engineering, Shree Santkrupa Institute Of Engineering & Technology, Ghogaon Karad, India.
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Abstract - In an attempt to decarbonize the transportation sector, among many countries, is option for emobility as an optimal solution, to create a greener, cleaner, and more affordable future for everyone. However, it is missing a crucial prerequisite, which is a strong EV charging infrastructure. The various EVCS types, technologies, techniques, and equipment. It also includes the design of a charging station for small EVs for on campus use, with a solar energy system input. Next, a mechanical 3D design for the final product. As well as a proof-of- concept implementation. Lastly, some conclusions, limitations, and recommendations for further research. Creating a sustainable future through e-mobility is indeed a crucial step in combatting climate change. However, the success of this transition heavily relies on the development of a robust EV charging infrastructure. This infrastructure encompasses various types, technologies, techniques, and equipment to support the growing fleet of electric vehicles (EVs). To address the need for a charging station on campus, especially for small EVs, integrating solar energy systems can significantly enhance sustainability. Designing such a station involves careful consideration of factors like location, power capacity, and user accessibility. Mechanical 3D design plays a pivotal role in visualizing the final product, ensuring optimal functionality and integration with existing infrastructure. Proof-of-concept implementation is essential to validate the feasibility and effectiveness of the proposed charging station. This involves testing the charging process, efficiency of solar energy utilization, and user experience. Through this phase, potential challenges can be identified and addressed, paving the way for broader deployment.
Key Words: Sunlight, Solar Panel, Charging Station, EV charging etc.