8
[10] Dubaniewicz TH, Barone TL, Brown CB, Thomas
RA (2022). Comparison of thermal runaway pres-
sures within sealed enclosures for nickel manganese
cobalt and iron phosphate cathode lithium-ion cells.
Journal of Loss Prevention in the Process Industries
76:104739.
[11] Morley LA (1990). Mine Power Systems. U.S.
Department of the Interior, Bureau of Mines.
Information Circular 9258.
[12] U.S. Code of Federal Regulations (2023). Title 30,
Part 18, Section 18.31 Enclosures—joints and fas-
tenings Title 30, Part 18, Section 18.62. Tests to
determine explosion-proof characteristics. Retrieved
August 2023 from www.ecfr.gov/current/title-30
/chapter-I/subchapter-B/part-18.
[13] Yuan L, Tang W, Thomas R, Soles J (2023). Evaluation
of different suppression techniques for lithium-
ion battery fires. Proceedings of the 19th North
American Mine Ventilation Symposium, Edited by
Purushotham Tukkaraja, pp. 384-392, CRC Press,
ISBN 978-1-032-55146-3.
[14] Yuan L, Dubaniewicz T, Zlochower I, Thomas R,
Rayyan N (2020). Experimental study on thermal
runaway and vented gases of lithium-ion cells. Process
Safety and Environmental Protection 144:186-192.
[15] Gunter B, Kamboj S (2023). High Energy Battery
Thermal Runaway Alleviation Protection (TRAP)
Flame Arrestor for Mine Safety. NIOSH Contract
No. 75D301-21-C-11477.
[16] Roth, K. and Gunter, W. (2021) Multi-cell Lithium
Ion Battery Safety Enhancement for Underground
Mining Applications via Cell-to-Cell Isolation
During Thermal Runaway. NIOSH Contract No.
75D301-19-C-05904.
[17] Jones K, Bhattacharya S, and Surampudi
B (2021). Safety Enhancing Technologies for
Usage of Multi-Cell Battery Power Systems in
Underground Equipment. NIOSH Contract No.
75D301-19-C-05506
[10] Dubaniewicz TH, Barone TL, Brown CB, Thomas
RA (2022). Comparison of thermal runaway pres-
sures within sealed enclosures for nickel manganese
cobalt and iron phosphate cathode lithium-ion cells.
Journal of Loss Prevention in the Process Industries
76:104739.
[11] Morley LA (1990). Mine Power Systems. U.S.
Department of the Interior, Bureau of Mines.
Information Circular 9258.
[12] U.S. Code of Federal Regulations (2023). Title 30,
Part 18, Section 18.31 Enclosures—joints and fas-
tenings Title 30, Part 18, Section 18.62. Tests to
determine explosion-proof characteristics. Retrieved
August 2023 from www.ecfr.gov/current/title-30
/chapter-I/subchapter-B/part-18.
[13] Yuan L, Tang W, Thomas R, Soles J (2023). Evaluation
of different suppression techniques for lithium-
ion battery fires. Proceedings of the 19th North
American Mine Ventilation Symposium, Edited by
Purushotham Tukkaraja, pp. 384-392, CRC Press,
ISBN 978-1-032-55146-3.
[14] Yuan L, Dubaniewicz T, Zlochower I, Thomas R,
Rayyan N (2020). Experimental study on thermal
runaway and vented gases of lithium-ion cells. Process
Safety and Environmental Protection 144:186-192.
[15] Gunter B, Kamboj S (2023). High Energy Battery
Thermal Runaway Alleviation Protection (TRAP)
Flame Arrestor for Mine Safety. NIOSH Contract
No. 75D301-21-C-11477.
[16] Roth, K. and Gunter, W. (2021) Multi-cell Lithium
Ion Battery Safety Enhancement for Underground
Mining Applications via Cell-to-Cell Isolation
During Thermal Runaway. NIOSH Contract No.
75D301-19-C-05904.
[17] Jones K, Bhattacharya S, and Surampudi
B (2021). Safety Enhancing Technologies for
Usage of Multi-Cell Battery Power Systems in
Underground Equipment. NIOSH Contract No.
75D301-19-C-05506