Topology and Efficiency Analysis of Utility-Scale Battery Energy Storage Systems

A. Parlikar, H. Hesse, A. Jossen
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引用次数: 5

Abstract

Energy storage is an important flexibility measure to stabilize and secure the electrical energy supply system. Lithium-ion battery energy systems (BESS) are, owing to their characteristics, uniquely poised to support and augment the functioning of the energy supply system. It is crucial to identify and analyze the factors which play a role in their efficient and effective operation. This paper identifies and analyses three such major factors application scenarios, power electronics with power distribution strategies, and battery parameters which influence the efficiency of a BESS. The applications analyzed are primary control reserve and peak shaving. Two Power electronics topologies and their load distribution strategies are presented, with their influence on the conversion efficiency being evaluated subsequently. Two commercial lithium-ion technologies a Lithium Iron Phosphate cathode/Graphite anode cell and a Lithium Nickel Manganese Cobalt Oxide cathode/Graphite anode cell are also simulated for two states of health (SOH). The aged cells are considered to possess a capacity equal to 80% of original nominal capacity and a cell resistance twice that of the new cells. It is found that the system conversion efficiency can be greatly improved in applications with low active chargebased and high temporal utilization ratios by deploying a suitable power electronics topology and load distribution strategy. For applications with high active charge-based and low temporal utilization ratios, the battery resistance and the serial-parallel combination play an important role.
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公用事业规模电池储能系统的拓扑结构与效率分析
储能是保证电力供应系统稳定和安全的重要柔性措施。锂离子电池能源系统(BESS)由于其独特的特性,可以支持和增强能源供应系统的功能。识别和分析影响其高效运行的因素是至关重要的。本文确定并分析了影响BESS效率的三个主要因素:应用场景、电力电子与配电策略以及电池参数。主要应用于一次控制储备和调峰。提出了两种电力电子拓扑结构及其负载分配策略,并评估了它们对转换效率的影响。两种商用锂离子技术磷酸铁锂阴极/石墨阳极电池和锂镍锰钴氧化物阴极/石墨阳极电池也模拟了两种健康状态(SOH)。老化的电池被认为具有等于原始标称容量的80%的容量和新电池的两倍的电池电阻。研究发现,在低有功电荷基础和高时间利用率的应用中,通过适当的电力电子拓扑和负载分配策略,可以大大提高系统的转换效率。对于高活性电荷基和低时间利用率的应用,电池电阻和串并联组合起着重要的作用。
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