涂料对高性能耐热纺织品窗帘性能的影响

Volume 3: Advanced Materials: Design, Processing, Characterization, and Applications Pub Date : 2021-11-01 DOI:10.1115/imece2021-73307

M. Vilarinho, P. Araújo, J. Teixeira, Elisabete Silva, Dionísio Silveira, D. Soares, M. Paiva, Daniel Ribeiro, Marisa Branco

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引用次数: 0

摘要

在所有形式的活动中，对人的生命和财产的保护日益受到关注。防火和防烟帘作为物理屏障，防止火灾在空间之间蔓延，并阻止烟雾和热量传递到邻近区域，同时造成最小的干扰。通常，窗帘是基于纤维结构，可以涂覆以增强其防护能力。此外，纤维结构可以发展成2D和3D螺纹的复杂图案，可以使用单一或多种材料进行定制以优化其性能。隔热和防火性能取决于纤维、织物图案和涂层。本文报道了用于防火窗帘的新型纤维涂层结构的发展。玄武岩纤维和玻璃纤维是纱线的原料。根据认证标准，通过测量样品提供的温差来评估样品的耐热性，同时评估样品的完整性。样品被置于压力下，试图模拟其在使用时的重量效应。使用放置在织物两侧的热电偶来监测温度，并通过织物破裂的发生以及由其劣化引起的烟雾和/或气味释放来评估完整性参数。对于未包覆的样品，双向玻璃纤维组成的样品表现出最好的热性能。氧化铝涂层的加入显著提高了所有样品的性能。然而，当氧化铝层较薄(0.05 μm)时，经向和纬向玻璃纤维样品的性能都较好，而当氧化铝层较厚(0.3 μm)时，玻璃纤维和玄武岩样品的性能都较好。在这两种情况下，氧化铝涂层的应用导致梯度温度(窗帘内外温度之间)增加约38.0%(310.0°C vs. 427.0°C, 386.0°C vs. 526.0°C)。

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Influence of Coating on High Performance Heat Resistant Textile Curtains

The protection of human life and goods assumes a growing concern in all forms of activities. The fire and smoke curtains act as a physical barrier to prevent the fire from spreading between spaces as well as to staunch the smoke and heat transfer to adjacent areas, while causing minimal interference. Usually, curtains are based on fiber structures that can be coated to enhance their protective capabilities. Also, the fiber structure can be developed into a complex pattern of 2D and 3D threads, with single or multiple materials that can be tailored to optimize its behavior. The thermal and fire protection depends on the fibers, fabric pattern and coatings. The present paper reports the development of novel coated structures of fibers used for fire protection curtains. Basalt and glass fibers are used as yarn materials. Following the certification standards the samples were assessed for their thermal resistance by measuring the temperature differential they provide while their integrity is evaluated. The sample is placed under stress in an attempt to mimic its own weight effect when in service. The temperature is monitored using thermocouples which are placed at both sides of the fabric and the integrity parameter is assessed through the occurrence of fabric rupture and smoke and/or odor release motivated by its deterioration. Regarding the uncoated samples, the one composed of glass-fiber in both directions presents the best thermal performance. The addition of an alumina coating significantly improves the performance of all samples. However, while a thinner (0.05 μm) alumina layer provides better results for the sample with glass-fiber in both warp and weft directions, the behavior of samples composed of glass-fiber and basalt is superior when a thicker (0.3 μm) alumina layer is used. In both cases, an alumina coating application results in an increase of the gradient temperature (between curtain inside/outside temperatures) of about 38.0% (310.0 °C vs. 427.0 °C for the first and 386.0 °C vs. 526.0 °C for the latter.

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Volume 3: Advanced Materials: Design, Processing, Characterization, and Applications

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