Nowadays, the challenge of reducing air pollutants, which passes through increasingly stringent regulations on emissions, is also central in the maritime sector. A possible solution to overcome these limits could be the introduction of alternative propulsion systems to classic diesel engines. In the present work, the performance of a Hybrid Propulsion System (HPS) in marine, consisting of an internal combustion engine and a Vanadium Redox Flow Battery (VRFB) allowing an independent power and capacity sizing, was analyzed. Specifically, through a dynamic modeling, a daily work cycle has been simulated based on a real load request. The possibility of implementing a hybrid system independent from a ground-based charging system was evaluated, in relation to the analyzed work cycle, by identifying the size of the battery (70 kW/ 5.8 kWh) and its minimum charging power (23 kW) necessary for the autonomous operation. Together with the results of the dynamic analysis, experimental results are provided. Tests were performed over a VRFB real scale short-stack prototype of the innovative concept design.
Vanadium Redox Flow Battery Integration in On-Board Electric Systems for Hybrid Marine Applications
Longo M.;Zaninelli D.;
2024-01-01
Abstract
Nowadays, the challenge of reducing air pollutants, which passes through increasingly stringent regulations on emissions, is also central in the maritime sector. A possible solution to overcome these limits could be the introduction of alternative propulsion systems to classic diesel engines. In the present work, the performance of a Hybrid Propulsion System (HPS) in marine, consisting of an internal combustion engine and a Vanadium Redox Flow Battery (VRFB) allowing an independent power and capacity sizing, was analyzed. Specifically, through a dynamic modeling, a daily work cycle has been simulated based on a real load request. The possibility of implementing a hybrid system independent from a ground-based charging system was evaluated, in relation to the analyzed work cycle, by identifying the size of the battery (70 kW/ 5.8 kWh) and its minimum charging power (23 kW) necessary for the autonomous operation. Together with the results of the dynamic analysis, experimental results are provided. Tests were performed over a VRFB real scale short-stack prototype of the innovative concept design.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.