Evaluation of high power energy storage devices for use in compact pulsed power systems

B. Shrestha, P. Novak, D. Wetz
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Abstract

Summary form only given. The desire and need to field more compact pulsed power systems continues to grow with each passing day for use in many different applications. In the past, many pulsed power systems have been developed which use rechargeable batteries for the source of their prime power. In the time since the development of most of those systems, the demand for portable electronics and the growing desire to field hybrid electric vehicles has provided researchers with the resources needed to drastically improve the lifetime, safety, energy density, and power density of rechargeable batteries to technology levels only previously dreamed of. Improvements in these properties enable the development of prime power sources for pulsed power systems that are much more efficient and compact than those previously implemented. In these applications, where size is critical, the batteries are required to source currents at rates much higher than they are designed for in a high frequency, pulsed mode of operation. It is unclear how this extreme mode of operation impacts the size of the prime power system as well as how the capacity of the batteries will degrade compared to when they are discharged at their rated current. To gain a better understanding of the impact, the University of Texas at Arlington (UTA) is conducting experiments in which high power cells are pulsed discharged at an elevated rate. In the experiments presented here, a 3 Ah, lithium-ion battery has been discharged at a 100C rate, 300 A, using a switching frequency of 10 kHz and 50% duty cycle. The cell is periodically cycled at its rated current and the capacity fade and impedance variations are being evaluated and compared against a second identical cell which is being cycled under rated conditions. The test conditions, results collected thus far, and an analysis of how new technologies improves the size and efficiency of the prime power source will be presented. The results obtained are used to develop the model for the cell which shows the change in ESR and capacity as the cycle continues.
用于紧凑型脉冲电源系统的高功率储能装置的评价
只提供摘要形式。在许多不同的应用中,对更紧凑的脉冲电源系统的需求不断增长。在过去,许多脉冲电源系统已经开发使用可充电电池作为其主要电源。在大多数这些系统开发之后,对便携式电子设备的需求以及对混合动力汽车日益增长的需求为研究人员提供了所需的资源,以大幅提高可充电电池的寿命、安全性、能量密度和功率密度,达到以前梦寐以求的技术水平。这些特性的改进使脉冲功率系统的主要电源的开发比以前实施的更高效和紧凑。在这些应用中,尺寸是至关重要的,电池被要求以远高于其在高频脉冲操作模式下设计的速率提供电流。目前还不清楚这种极端的操作模式如何影响主要电力系统的大小,以及电池的容量将如何下降,与他们在额定电流下放电时相比。为了更好地了解这种影响,位于阿灵顿的德克萨斯大学(UTA)正在进行一项实验,在实验中,高功率电池以较高的速率脉冲放电。在这里展示的实验中,一个3 Ah的锂离子电池以100℃、300 a的速率放电,使用10 kHz的开关频率和50%的占空比。电池在其额定电流下周期性循环,并评估其容量衰减和阻抗变化,并与在额定条件下循环的第二个相同电池进行比较。将介绍测试条件、迄今收集的结果以及新技术如何改善主要电源的尺寸和效率的分析。获得的结果用于开发电池模型,该模型显示了随着循环的继续,ESR和容量的变化。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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