DESIGN AND INTEGRATION OF DIODE-BASED POWER CONVERSION CIRCUITS FOR EFFICIENT MECHANICAL BATTERY SYSTEMS

Abstract

This study investigates the design and integration of diode-based power conversion circuits within mechanical battery systems to improve energy efficiency, system reliability, and performance. The research addresses the challenges associated with energy losses, thermal management, and the integration of advanced control algorithms in mechanical energy storage systems, particularly flywheel-based systems. The results demonstrate a significant enhancement in energy conversion efficiency by reducing both conduction and switching losses, compared to conventional power conversion circuits.Power loss reduction throughout the charging and discharging cycles primarily depended on using advanced switching controls together with efficient diodes.  System stability and operating efficiency received additional support when dynamic control algorithms were incorporated for better energy flow regulation.  The research demonstrates through its findings that diode-based circuits offer stable performance over time because they excel at mechanical load regulation alongside temperature management.  Mechanical battery systems would benefit from diode-based power conversion circuits since they offer sustainable and efficient operation with better dependability.  The innovative research approach introduces new storage technology possibilities for broad utilization at scale which strengthens renewable energy system storage capabilities.