研究非标准加热条件下膨胀涂层性能的新方法

Angus Elliott, A. Temple, C. Maluk, L. Bisby
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引用次数: 26

摘要

膨胀涂层(也称为活性涂层)广泛用于结构钢的防火保护。这些薄涂层在加热时膨胀,形成高度绝缘的炭,保护钢构件,防止它们达到可能导致它们失效的临界温度。与大多数结构材料和组件的情况一样,用于建筑物的膨胀涂层通常是根据标准的纤维素耐火测试,通过在防火测试炉中暴露来开发和认证的。依靠炉内测试是昂贵的,不具有实际火灾条件的代表性,而且在收集反应性涂层在全范围设计火灾下的详细性能信息方面也不够全面,这些信息可能在合理的、基于性能的设计评估中被考虑。本文提出了一种新的测试方法,用于研究反应性涂层在非标准加热条件下的性能。新方法使用炉内测试数据进行了校准和验证,并在可靠性、可重复性、多功能性、速度和成本方面比炉内测试具有相当大的优势。一项调查,然后提出了研究有效的可变导热系数的市售反应涂层时,受到不同的时间历史的热通量。研究表明,涂层的加热速率和干膜厚度不会显著影响基材温度下有效导热性的发展,因此提出了一种简化方法,用于指定涂层要求和/或在设计非标准加热制度时执行传热设计计算。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Novel Testing to Study the Performance of Intumescent Coatings under Non-Standard Heating Regimes
Intumescent coatings (also called reactive coatings) are widely used to protect structural steel from fire. These thin coatings swell on heating to form a highly insulating char, protecting steel members and preventing them from reaching critical temperatures that could cause them to fail. As is the case for most structural materials and assemblies, intumescent coatings for use in buildings are typically developed and certified solely according to the standard cellulosic fire resistance test by exposure within a fire testing furnace. Reliance on furnace testing is expensive, non-representative of realistic fire conditions, and insufficiently versatile to gather detailed performance information on the response of reactive coatings under the full range of design fires which might be considered during a rational, performance-based design assessment. This paper presents a novel testing methodology for studying the performance of reactive coatings when subjected to non-standard heating regimes. The new approach is calibrated and validated using furnace test data, and is shown to offer considerable advantages over furnace testing in terms of reliability, repeatability, versatility, speed and cost. An investigation is then presented to study the effective variable thermal conductivity of a commercially available reactive coating when subjected to various timehistories of heat flux. It is shown that the heating rate and dry film thickness of the coating do not drastically affect the development of effective thermal conductivity with substrate temperature, leading to a proposal for a simplified method for specifying coating requirements and/or performing heat transfer design calculations when designing to non-standard heating regimes.
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