NASA has traditionally sought to reduce the likelihood of a single cell thermal runaway (TR) in their aerospace batteries to an absolute minimum by employing rigorous screening program of the cells. There was generally a belief that TR propagation resulting in catastrophic failure of the battery was a forgone conclusion for densely packed aerospace lithium-ion batteries. As it turns out, this may not be the case. An increasing number of purportedly TR propagation-resistant batteries are appearing among NASA partners in the commercial sector and the Department of Defense. In the recent update of the battery safety standard (JSC 20793) to address this paradigm shift, the NASA community included requirements for assessing TR severity and identifying simple, low-cost severity reduction measures. Unfortunately, there are no best-practice guidelines for this work in the Agency, so the first project team attempting to meet these requirements would have an undue burden placed upon them. A NASA engineering Safety Center (NESC) team set out to perform pathfinding activities for meeting those requirements. This presentation will provide contextual background to this effort, as well as initial results in attempting to model and simulate TR heat transfer and propagation within battery designs

Button, R.

Iannello, C.

Rickman, S.

Shack, P.

NASA Technical Reports Server

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NASA Battery Workshop 2014
Presented By: 
Rob Button 
Deputy, Electrical Power Technical Discipline, NESC 
https://ntrs.nasa.gov/search.jsp?R=20150000860 2019-08-31T14:01:03+00:00Z
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New Thermal Runaway Propagation 
Requirements 
Note – Batteries are not required to be propagation resistant 
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EVA Batteries addressed are: 
 
LLB – 650 Wh
Long-life Battery: primary power 
for EMU life support, data, comm
80 Cells:   16P-5S config
LREBA – 400 Wh
Li Rechargeable EVA Battery: 
glove heaters, lights, camera, etc. 
45 Cells:     9P-5S config
LPGT - 89 Wh
Li Pistol Grip Tool 
10 Cells:      10S config in use 
                     2P-5S charging 
EVA Battery Overview
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Baseline Designs
LLB – Dense Brick 
LPGT – Loose Brick  
LREBA  –  Planar   
Sub-banks 
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•  A Thermal analysis sub-team has conducted considerable thermal 
analysis, in concert with testing, to understand heat generated 
within a failed cell, and estimate heat transport via conduction, 
convection, and radiation within a network of cells in a battery. 
•  Internal cell thermal analysis and calorimetry testing has provided 
insight on the potential for heat generation, however, measuring 
heat released through venting has been problematicA
•  The eventual goal is for the thermal model to become predictive 
and a tool to explore mitigation measures prior to testing. 
•  Analysis Team 
–  Battery level analysis and mitigations -- Steve Rickman 
–  Internal cell models -- Dr. Ralph White 
–  Analysis of ARC data and mitigations -- Bob Christie 
–  Boeing 787 batteries lessons learned -- Dr. Bruce Drolen 
Thermal Analysis
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Reference 
Chiu, Kuan-Cheng, et al. "An electrochemical modeling of lithium-ion battery nail penetration." Journal of Power Sources 251 
(2014): 254-263. 
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Numerous iterations of 
battery-level thermal 
models  have been 
studied. 
Early models focused on 
original 9P "picket fence" 
configuration with 
adjacent cells in direct 
contact via an adhesive 
fillet.
Analysis indicated 
heating was sufficient to 
trigger adjacent cells into 
thermal runaway. 
Led to separation of cells 
using capture plates. 
Battery-level Thermal Model Evolution 
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Most recent version correlated to test run 53 
in an LREBA enclosure with open vent holes. 
Model represents a segment of LREBA 
enclosure and includes: 
•  internal heat generation 
•  triggering based on jellyroll temperature 
•  mass loss on venting 
•  heat generation due to I2R + chemical 
reactions due to decomposition (scaled 
from cell internal models) 
•  internal air conduction 
•  external convection 
•  internal and external thermal radiation. 
Correlation is very good in some areas and in 
need of improvement in others. 
Battery-level Thermal Models 
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Battery-level Thermal Models – Selected Comparisons 
from Run 53 LREBA Segment Correlation 
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Battery Thermal Model Preliminary Results 
Run 53 correlated LREBA segment thermal model at approximate time of 
maximum Cell 2 temperature -- no TR propagation. 
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ARC testing is used to measure heat release from 
cells during TR 
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•  Self-heating typically began at ~140 °C. 
•  The energy required to raise the average 
temperature of the cell to the observed 
maximum temperature was on the order 
of 13.6 kJ. 
•  Stored electrical energy in cell 
–  2.4 A-hr * 3.75V average = 9.0 W-hr * 
3,600 s/hr = 32.4 kJ


ARC Test Summary 
ARC testing and analysis indicate that a fraction of 
theoretical energy is conducted thru the cell can.  
More work is needed to quantify energy released 
during venting. 
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To date, the analysis, in conjunction with corroborating tests, has informed 
the team on the following: 
•  Direct cell-to-cell contact can lead to propagation of TR via heat 
conduction through the adhesive joining the cells in the cell array. 
•  Effluents from cell venting carry sufficient energy to promote propagation 
of TR; when combustion of the effluents occur, this problem is 
exacerbated. 
•  Heat transfer through any atmosphere present in the LREBA battery 
enclosure is primarily via gas conduction, as characteristic dimensions 
within the enclosure are too small to sustain convective heat transfer. 
•  Heat generated through cell TR that conducts through the cell can is on 
the order of one-half of the cell's total I2R heating; this is supported by 
model correlation, correlation to ARC testing, and examination of cell 
carcass materials posttest.  
Lessons Learned, Thus Far 
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•  Development of analytical models for LPGT and 
LLB and associated TR mitigationsA
•  Analytical support for future ARC tests to quantify 
heat released on venting. 
•  Determine if CFD analysis can be added to the 
model to inform energy distribution when TR vented 
products are not directly vented outside the battery 
enclosure.

Thermal Analysis Next Steps 
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Final Thoughts 


NASA Perspective and Modeling of Thermal Runaway Propagation Mitigation in Aerospace Batteries

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