A Time and Cost Effective Method for Entropic Coefficient Determination of a Large Commercial Battery Cell

TL;DR

This paper introduces a quick, cost-effective method using Fourier analysis of square pulse currents to determine the entropic coefficient of large commercial lithium-ion battery cells, facilitating thermal modeling in practical applications.

Contribution

It presents a novel Fourier-based pulse current method for entropic coefficient determination, reducing cost and time compared to traditional techniques.

Findings

Results agree well with traditional methods

Method is cost-efficient and quick

Applicable to cells in assembled packs

Abstract

The entropic coefficient of a lithium-ion battery cell is used to calculate the reversible heat of a battery during operation, which is a non-negligible part for the battery thermal modelling. The contribution of this article is to propose a novel method to establish the entropic coefficient profile of a 26 Ah commercial pouch cell, and compare the results with those obtained from the traditional potentiometric and calorimetric methods, and all are found to be in a good agreement. The originality of this work is to use a method which consists of supplying a square pulse current wave form at a certain frequency and thus the resulting heat variation could be successfully linked to the input current using Fourier analysis. The current magnitude used were 1 C and 1.5 C, which are representative for the normal operation current in an electrified vehicle application. The method proposed is found to be cost efficient with a short experiment time and simple experiment setup. In fact, it can be used to characterize cells that are already mounted in a pack without the access to a climate chamber or calorimeter.