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In Situ Gas Analysis and Fire Characterization of Lithium-Ion Cells During Thermal Runaway Using an Environmental Chamber

作者： Byoungchul Kwon1, Wohan Cui1, Ankit Sharma1, Ya-Ting Liao1, Fumiaki Takahashi1, Daniel Juarez-Robles2, Mohammad Parhizi2, Judith Jeevarajan2 1Department of Mechanical and Aerospace Engineering,Case Western Reserve University, 2UL Research Institutes

简介：

Overview

This article describes a test procedure developed to characterize thermal runaway and fires in lithium-ion cells through in situ measurements. The method aims to simulate catastrophic hazards in a single cell, providing consistent results.

Key Study Components

Area of Science

Battery safety
Thermal runaway
Environmental testing

Background

Thermal runaway can occur due to various causes.
Different causes can lead to varying worst-case outcomes.
Understanding these events is crucial for battery safety.
In situ measurements enhance the reliability of test results.

Purpose of Study

To simulate a catastrophic hazard in lithium-ion batteries.
To provide a consistent testing protocol for thermal runaway.
To measure various parameters in a single test.

Methods Used

Synchronization of data acquisition from multiple sensors.
Use of FDIR (Fault Detection, Isolation, and Recovery).
Video recording of the test events.
Following a standard operating procedure for device operation.

Main Results

The test procedure effectively characterizes transient events.
Data collected provides insights into thermal runaway dynamics.
Results demonstrate the importance of in situ measurements.
Consistency in results supports the reliability of the method.

Conclusions

The developed procedure is a valuable tool for battery safety research.
In situ measurements enhance understanding of thermal events.
Future studies can build on this method for improved battery designs.

Frequently Asked Questions

What is thermal runaway?

Thermal runaway is a condition where a battery cell overheats, potentially leading to fires or explosions.

How does the test procedure work?

The procedure simulates a catastrophic hazard in a single cell while measuring various parameters in situ.

What are the main advantages of this method?

It provides consistent results and comprehensive characterization of thermal runaway events.

What equipment is used in the testing?

Multiple sensors, FDIR systems, and video recording equipment are utilized.

Why is data synchronization important?

Synchronization ensures accurate data collection from all sensors during the test.

Can this method be applied to other battery types?

While designed for lithium-ion cells, the principles may be adapted for other battery technologies.

Here, we describe a test procedure developed to characterize thermal runaway and fires in lithium-ion cells through in situ measurements of various parameters in an environmental chamber.

标签: Lithium-ion Batteries, Thermal Runaway, Gas Analysis, Environmental Chamber, Fire Characterization, Data Acquisition, Transient Events, Sensors Synchronization, Standard Operating Procedure, Thermocouples, Heating Tape, Cell Preparation, Voltage Measurement, Experimental Procedure, Pushkal Kannan, Dr. Ankit Sharma,