Exploring Pack-level Current-Split Strategies for Optimized Energy Distribution in Li-ion Battery Systems

Pack-level current-split strategies play a crucial role in optimizing energy distribution within Li-ion battery systems, thereby enhancing their overall performance and reliability. In this study, we explore various current-split strategies and their impact on battery pack efficiency, energy utilization, and longevity. The efficiency of Li-ion battery systems heavily depends on how effectively current is distributed among individual cells within the battery pack. Traditional current-split strategies, such as passive balancing and uniform current distribution, may lead to suboptimal energy utilization and uneven cell degradation. To address these challenges, advanced current-split strategies, including active balancing, dynamic current allocation, and intelligent energy management algorithms, have been proposed. These strategies leverage real-time monitoring of cell voltages, temperatures, and state of charge (SOC) to dynamically adjust current distribution and ensure balanced cell operation. Additionally, innovative pack-level architectures, such as modular battery packs and multi-level current-split circuits, offer enhanced flexibility and scalability in optimizing energy distribution across large-scale battery systems. Through a comprehensive review of existing literature and case studies, we analyze the performance benefits, technical challenges, and practical considerations associated with different current-split strategies. By providing insights into the design, implementation, and optimization of current-split strategies, this study aims to contribute to the development of more efficient, reliable, and sustainable energy storage solutions for a wide range of applications, including electric vehicles, renewable energy integration, and grid-scale energy storage.