Suuberg, E.
, Milosavljevic, I.
and Lilly, W.
(1994),
Behavior of Bare and Aspirated Thermocouples in Compartment Fires., Grant/Contract Reports (NISTGCR), National Institute of Standards and Technology, Gaithersburg, MD, [online], https://tsapps.nist.gov/publication/get_pdf.cfm?pub_id=916776
(Accessed May 7, 2024)
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Behavior of Bare and Aspirated Thermocouples in Compartment Fires.
Published
Author(s)
E M. Suuberg, I Milosavljevic, W D. Lilly
Abstract
The focus of this study was the behavior of thick charring solids in fire situations. Clearly one of the most important parameters governing the fire phenomenon is the rate of release of combustible volatiles into the gas phase, in which they actually burn. Over the years, fire researchers have learned how to model the processes in the gas phase, so that the rate of heat feedback to the solid surface can be reasonably well predicted. Likewise, there exists the ability to model the heat transfer processes at the solid surface and within the solid itself. Finally, there is a large literature on the laboratory-scale pyrolysis of various charring polymers. It might appear that predicting the course of the fire would involve carefully coupling these different models together. There have unfortunately not been any successful demonstrations of the ability to do this, though in broad stroke, some models capture the key features of the processes. This study was concerned with the possibility that the inability to come to complete closure on the charring polymer fire problem might derive from difficulties in applying laboratory scale kinetics to actual fire conditions. Specifically, we were concerned about how well small scale laboratory experiments used to derive the kinetics of pyrolysis could be used to predict the behavior of charring solids in fire situations.Citation
Grant/Contract Reports (NISTGCR) - 94-645
Report Number
94-645
NIST Pub Series
Pub Type
NIST Pubs
Download Paper
Keywords
char, cellulose, cellulosic materials, char depth, fire research, model studies, pyrolysis
Citation
Created June 1, 1994, Updated August 11, 2014