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Fire Technology
Published in: Fire Technology 4/2016

01-07-2016

Experimental Study on Near-Limiting Burning Behavior of Thermoplastic Materials with Various Thicknesses Under Candle-Like Burning Configuration

Authors: Yuji Nakamura, Koki Kizawa, Shohei Mizuguchi, Aki Hosogai, Kaoru Wakatsuki

Published in: Fire Technology | Issue 4/2016

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Abstract

We studied the near-limiting behavior of various thicknesses of thermoplastic materials under a candle-like burning configuration; followed by an ISO 4589-2 protocol. The motivation for this work is to understand the sensitivity of the sample thickness on the limiting oxygen concentration in the range from 0.5 mm to 10 mm. In the first place, the effect of heating time on successive ignition was discussed. Through a simple analysis, it was suggested that a 30 s heating time, regulated in ISO 4589-2, might be insufficient to achieve a successful ignition when the specimen becomes thicker. Second, the effect of the thickness of the test specimen (PMMA, ABS) on the limiting oxygen concentration was examined. Flames formed over thicker PMMA (>4.0 mm thickness in this study) at near-limiting condition displayed a flickering motion, which then suddenly extinguished when the critical condition was achieved due to temporal acceleration of the surrounding flow. While the flame behavior with a thinner sample (<4.0 mm thickness in this study) at the limiting condition was found to be stationary, a gentle extinction was experienced as approached to the limit. This fact suggests that the key to leading extinction is different between thicker and thinner sample. Third, the temperature distribution over the 4.0 mm PMMA at the near-limiting condition was measured and a strategy to model/predict the limiting behavior is then proposed.
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Footnotes
1
In ISO 4585-2 [1], two ways to achieve the successful ignition of the sample (procedures A and B) are provided. Procedure A is so called “top-surface ignition” as described in the body of this paper and procedure B is so called “propagating ignition”. For procedure B, not only the sample surface, but approximately 6 mm of depth of the sample is heated by subjecting the direct flame contact. Transition of the mode from ignition to spread might be considered and 10 mm from the top surface is considered to be the location where successful ignition is achieved.
 
2
In the same manner, not only by varying the thickness of specimen, exactly the same problem would occur when other materials are adopted (likely other values of \( a_{s} \), \( \rho_{S} \), \( H_{l} \), \( C_{s} \) are imposed). For instance, imagine that very large \( a_{s} \) is assumed (say, solid specimen includes high-thermal conductivity material along the depth direction, likely electric wire as the tested specimen), it prevents to increase the temperature at he exposed surface so that no chance to achieve gasification is given.
 
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Metadata
Title
Experimental Study on Near-Limiting Burning Behavior of Thermoplastic Materials with Various Thicknesses Under Candle-Like Burning Configuration
Authors
Yuji Nakamura
Koki Kizawa
Shohei Mizuguchi
Aki Hosogai
Kaoru Wakatsuki
Publication date
01-07-2016
Publisher
Springer US
Published in
Fire Technology / Issue 4/2016
Print ISSN: 0015-2684
Electronic ISSN: 1572-8099
DOI
https://doi.org/10.1007/s10694-016-0567-5

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