Simulation of Ni-MH Batteries via an Equivalent Circuit Model for Energy Storage Applications

Advances in Physical Chemistry Pub Date : 2016-03-16 DOI:10.1155/2016/4584781

Y. Zhu, Wenhua H. Zhu, Zenda Davis, B. Tatarchuk

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引用次数: 11

Abstract

Impedance measurement was conducted at the entire cell level for studying of the Ni-MH rechargeable batteries. An improved equivalent circuit model considering diffusion process is proposed for simulation of battery impedance data at different charge input levels. The cell capacity decay was diagnosed by analyzing the ohmic resistance, activation resistance, and mass transfer resistance of the Ni-MH cells with degraded capacity. The capacity deterioration of this type, Ni-MH cell, is considered in relation to the change of activation resistance of the nickel positive electrodes. Based on the report and surface analysis obtained from the energy dispersive X-ray spectroscopy, the composition formula of metal-hydride electrodes can be closely documented as the AB5 type alloy and the “A” elements are recognized as lanthanum (La) and cerium (Ce). The capacity decay of the Ni-MH cell is potentially initiated due to starved electrolyte for the electrochemical reaction of active materials inside the Ni-MH battery, and the discharge product of Ni(OH)2 at low state-of-charge level is anticipated to have more impeding effects on electrode kinetic process for higher power output and efficient energy delivery.

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基于等效电路模型的镍氢电池储能仿真

为了研究镍氢可充电电池，在整个电池层进行了阻抗测量。提出了一种考虑扩散过程的改进等效电路模型，用于模拟不同电荷输入水平下电池阻抗数据。通过分析容量下降的镍氢电池的欧姆电阻、活化电阻和传质电阻，诊断电池容量衰减。这种类型的镍氢电池的容量退化被认为与镍正极活化电阻的变化有关。根据能量色散x射线光谱的报告和表面分析，金属氢化物电极的组成公式可以很好地证明为AB5型合金，“A”元素为镧(La)和铈(Ce)。镍氢电池的容量衰减可能是由于镍氢电池内部活性物质电化学反应所需电解质的缺乏而引起的，而低充电状态下的Ni(OH)2放电产物预计会对电极动力学过程产生更大的阻碍作用，从而实现更高的功率输出和高效的能量传递。

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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Advances in Physical Chemistry

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