Energy Conversion And Management, cilt.257, ss.1-9, 2022 (SCI-Expanded)
This study deals with the development and assessment of a new charging station, which is driven by solar energy and integrated with hydrogen production, storage, and utilization systems. A thermodynamic analysis based on energy and exergy approaches is performed to analyze the system and assess its performance. The system works under two operational periods: solar-powered charging points for power output and hydrogen production during the daytime and power generation via hydrogen fuel cells during periods when solar energy is not adequate enough. The present work is, in this regard, unique and is conducted based on some parametric and case studies. Furthermore, it is observed that hydrogen is a promising fuel option and carbon-free energy storage medium. The energy needed for hydrogen storage process which covers both compression and cooling is relatively lower than the energy demand of the charging station. Thus, it is possible to develop a solar-driven off-grid charging station with the integration of hydrogen. The need for grid power reduces with the increase in the PV surface area. In order to achieve an off-grid power supply, the amounts of hydrogen required for the charging station capacities of 100, 200, 300, 400 and 500 kW are 51.8, 125.8, 234.1, 370.9 and 507.7 kg, respectively. In order to have grid-independent and dedicated charging stations at the capacities of 100, 200, 300, 400 and 500 kW, the total PV surface area is needed to be 2560 m2, 4860 m2, 6580 m2, 10790 m2 and 15575 m2, respectively.
This study deals with the development and assessment of a new charging station, which is driven by solar energy and integrated with hydrogen production, storage, and utilization systems. A thermodynamic analysis based on energy and exergy approaches is performed to analyze the system and assess its performance. The system works under two operational periods: solar-powered charging points for power output and hydrogen production during the daytime and power generation via hydrogen fuel cells during periods when solar energy is not adequate enough. The present work is, in this regard, unique and is conducted based on some parametric and case studies. Furthermore, it is observed that hydrogen is a promising fuel option and carbon-free energy storage medium. The energy needed for hydrogen storage process which covers both compression and cooling is relatively lower than the energy demand of the charging station. Thus, it is possible to develop a solar-driven off-grid charging station with the integration of hydrogen. The need for grid power reduces with the increase in the PV surface area. In order to achieve an off-grid power supply, the amounts of hydrogen required for the charging station capacities of 100, 200, 300, 400 and 500 kW are 51.8, 125.8, 234.1, 370.9 and 507.7 kg, respectively. In order to have grid-independent and dedicated charging stations at the capacities of 100, 200, 300, 400 and 500 kW, the total PV surface area is needed to be 2560 m2, 4860 m2, 6580 m2, 10790 m2 and 15575 m2, respectively.