Experimental investigation of the influence of electrical contact resistance on lithium-ion battery testing for fast-charge applications

Wassiliadis, Nikolaos; Ank, Manuel; Wildfeuer, Leo; Kick, Michael K.; Lienkamp, Markus

doi:10.1016/j.apenergy.2021.117064

Benutzer: Gast

10.1016/j.apenergy.2021.117064

Dokumenttyp:: Zeitschriftenaufsatz
Autor(en):: Wassiliadis, Nikolaos; Ank, Manuel; Wildfeuer, Leo; Kick, Michael K.; Lienkamp, Markus
Titel:: Experimental investigation of the influence of electrical contact resistance on lithium-ion battery testing for fast-charge applications
Abstract:: With the rising demand for electric vehicles with a fast-charging ability, high currents are applied to lithium-ion batteries to develop accurate battery models and intelligent fast-charging strategies. In order to achieve reliable results for automotive applications, single cell test conditions should be as close as possible to the conditions present in the battery pack of the battery electric vehicle. As cells are irreversibly connected in a battery pack, electrical contact resistance (ECR) is usually in the magnitude of <1 mΩ, and thus far lower than in reversible contacts during lab-testing. An interesting question arises as to whether this ECR has any unintended influence on the battery cell during testing. In this article, various experiments with high charge rates of up to 5 C are performed in order to assess the impact of the ECR of the measurement setup on the cells’ behavior. Two different commercial contact probes with different ECRs are tested on a 18650 lithium-ion battery, and compared to a laser-welded cell as a benchmark. ECRs of the lab-testing setups are measured with a micro ohmmeter, and the temperature evolution of all cells studied is measured at both cell tabs and the cell mantle during cycling. The results show that high peak temperature differences due to parasitic joule heat at the lithium-ion battery tabs occur when applying full charge cycles from 0.5 C to 5 C. Repetitive cycling with a multistage fast-charging strategy indicates a correlation of ECR with peak temperatures and aging spread. As a consequence, high ECRs could negatively affect drawn conclusions of cycle life tests. They should therefore be taken into account and kept low in any examination of fast-charging strategies.
Stichworte:: FTM Komponenten von Elektrofahrzeugen, FTM Elektrische Antriebssysteme
Zeitschriftentitel:: Applied Energy
Jahr:: 2021
Band / Volume:: 295
Seitenangaben Beitrag:: 117064
Nachgewiesen in:: Scopus
Volltext / DOI:: doi:10.1016/j.apenergy.2021.117064
Verlag / Institution:: Elsevier BV
E-ISSN:: 0306-2619
Publikationsdatum:: 01.08.2021
TUM Einrichtung:: Lehrstuhl für Fahrzeugtechnik
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mediaTUM Gesamtbestand Einrichtungen Schools TUM School of Engineering and Design Departments Mobility Systems Engineering Lehrstuhl für Fahrzeugtechnik (Prof. Lienkamp)Publikationen 2021

mediaTUM Gesamtbestand Hochschulbibliographie 2021 Fakultäten Maschinenwesen Lehrstuhl für Fahrzeugtechnik (Prof. Lienkamp)