Achieving Passive Thermal Runaway Propagation Resistance in Li-ion Battery Packs

被引：0

作者：

Quinn, Alexander ^{[1
]}

Darst, Jacob ^{[2
]}

Keyser, Matthew ^{[3
]}

Coman, Paul T. ^{[4
]}

Barrera, Thomas P. ^{[5
]}

Shearing, Paul R. ^{[6
,7
]}

Petrushenko, David ^{[2
]}

Finegan, Donal P. ^{[3
]}

Darcy, Eric ^{[2
]}

机构：

[1] MIT, Cambridge, MA 02139 USA

[2] NASA Johnson Space Ctr, Houston, TX USA

[3] NREL, Golden, CO USA

[4] Univ South Carolina, Columbia, SC USA

[5] Lithium Ion Battery LIB X Consulting, Long Beach, CA USA

[6] Univ Oxford, Dept Engn Sci, Oxford, England

[7] Univ Oxford, ZERO Inst, Oxford, England

来源：

ELECTROCHEMICAL SOCIETY INTERFACE | 2024年 / 33卷 / 03期

关键词：

LIB thermal runaway; battery safety in space; passive thermal runaway resistance; thermorunaway propagation; Li-ion battery packs; INTERNAL SHORT-CIRCUIT; NAIL-PENETRATION; CELLS; MANAGEMENT; ABUSE; SAFETY; ISSUES; STATE; OXIDE;

D O I：

10.1149/2.F08243IF

中图分类号：

O646 [电化学、电解、磁化学];

学科分类号：

081704 ;

摘要：

Because of their high specific and volumetric energy density, lithium-ion cells are popular in energy storage systems with strict mass and volume restrictions. Such applications include electric vehicles, power tools, consumer electronics, all-electric aircraft, as well as high-reliability military and crewed spacecraft. Next-generation rechargeable lithium cell designs are characterized by higher specific energy which further increases the severity of thermal runaway (TR) safety hazards. Even with carefully controlled high-quality manufacturing processes, TR can occur unpredictably due to latent defects inside the cells causing internal short circuits. This work elaborates on the lessons learned from cell and battery pack safety research for crewed spacecraft applications.

引用

页码：55 / 62

页数：8

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