An experimental study of the behavior of intumescent coatings under localized fires

This paper presents an experimental study of the behavior of intumescent coatings exposed to localized fires. The main objective is to assess the extent to which thermal properties of intumescent coatings obtained under uniform heating can be applied for localized fire exposures. The experiments use...

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Bibliographic Details
Published inFire safety journal Vol. 115; pp. 103003 - 20
Main Authors Xu, Qing, Li, Guo-Qiang, Wang, Yong C., Bisby, Luke
Format Journal Article
LanguageEnglish
Published Lausanne Elsevier Ltd 01.07.2020
Elsevier BV
Subjects
Coatings
Columns (structural)
Effective constant thermal conductivity
Expansion ratio
Fires
Heating
Intumescent coating
Localized heating
Pool fires
Reactive region
Steel
Steel beams
Steel temperature
Thermal properties
Thermodynamic properties
Vapor phases
Reactive region
Steel temperature
Expansion ratio
Effective constant thermal conductivity
Intumescent coating
Localized heating
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Summary:This paper presents an experimental study of the behavior of intumescent coatings exposed to localized fires. The main objective is to assess the extent to which thermal properties of intumescent coatings obtained under uniform heating can be applied for localized fire exposures. The experiments used two types of specimens representing protected steel beams and columns. Localized pool fires were placed underneath horizontal specimens or beside vertical specimens. Solvent-based and waterborne intumescent coatings were applied to the specimens. Measurements were made of temperatures of the steel specimens and the adjacent gas phase, as was coating expanded thicknesses at several locations. Depending on their location relative to fires, the intumescent coatings were variably unreacted, melted, partially expanded, or fully expanded (corresponding to steel temperatures of about less than 100 °C, 100–300 °C, 300–400 °C, and above 400 °C, respectively). The appearances and expansion ratios for various regions of coatings under localized fires were consistent with those under uniform heating from previously obtained furnace test results. Steel temperatures of the specimens were calculated using thermal conductivities of coatings derived from furnace tests, and were found to agree reasonably with the experimental results, thus indicating that it may be feasible to apply thermal conductivities derived from furnace tests to predict steel temperatures under localized heating scenarios.
ISSN:0379-7112
1873-7226
DOI:10.1016/j.firesaf.2020.103003