TY - JOUR

T1 - Li-Ion Battery Short-Circuit Protection by Voltage-Driven Switchable Resistance Polymer Layer

AU - Белецкий, Евгений Всеволодович

AU - Алексеева, Елена Валерьевна

AU - Анищенко, Дмитрий Викторович

AU - Левин, Олег Владиславович

N1 - Publisher Copyright: © 2022 by the authors.

PY - 2022/10/9

Y1 - 2022/10/9

N2 - Safety issues with lithium-ion batteries prevent their widespread use in critical areas of technology. Various types of protective systems have been proposed to prevent thermal runaway and subsequent battery combustion. Among them, thermoresistive systems, representing polymer composites that sharply increase their resistance when the temperature rises, have been actively investigated. However, they are triggered only when the heating of the battery has already occurred, i.e., the system undergoes irreversible changes. This paper describes a new type of protective polymer layer based on the intrinsically conducting polymer poly[Ni(CH 3OSalen)]. The response mechanism of this layer is based on an increase in resistance both when heated and when the cell voltage exceeds the permissible range. This makes it possible to stop undesirable processes at an earlier stage. The properties of the polymer itself and of the lithium-ion batteries modified by the protective layer have been studied. It is shown that the introduction of the polymer protective layer into the battery design leads to a rapid increase of the internal resistance at short circuit, which reduces the discharge current and sharply reduces the heat release. The effectiveness of the protection is confirmed by analysis of the battery components before the short circuit and after it.

AB - Safety issues with lithium-ion batteries prevent their widespread use in critical areas of technology. Various types of protective systems have been proposed to prevent thermal runaway and subsequent battery combustion. Among them, thermoresistive systems, representing polymer composites that sharply increase their resistance when the temperature rises, have been actively investigated. However, they are triggered only when the heating of the battery has already occurred, i.e., the system undergoes irreversible changes. This paper describes a new type of protective polymer layer based on the intrinsically conducting polymer poly[Ni(CH 3OSalen)]. The response mechanism of this layer is based on an increase in resistance both when heated and when the cell voltage exceeds the permissible range. This makes it possible to stop undesirable processes at an earlier stage. The properties of the polymer itself and of the lithium-ion batteries modified by the protective layer have been studied. It is shown that the introduction of the polymer protective layer into the battery design leads to a rapid increase of the internal resistance at short circuit, which reduces the discharge current and sharply reduces the heat release. The effectiveness of the protection is confirmed by analysis of the battery components before the short circuit and after it.

KW - Li-ion batteries

KW - safety

KW - thermal runaway

KW - short-circuit protection

KW - conductive polymers

KW - salen complexes

KW - Li-ion batteries

KW - conductive polymers

KW - safety

KW - salen complexes

KW - short-circuit protection

KW - thermal runaway

UR - http://www.scopus.com/inward/record.url?scp=85140464098&partnerID=8YFLogxK

UR - https://www.mendeley.com/catalogue/0311cc91-e434-33fb-9f0e-6768bd3e59c2/

U2 - 10.3390/batteries8100171

DO - 10.3390/batteries8100171

M3 - Article

VL - 8

JO - Batteries

JF - Batteries

SN - 2313-0105

IS - 10

M1 - 171

ER -