Aerogels for thermal insulation in high-performance textiles

IF 2.1 Q2 MATERIALS SCIENCE, TEXTILES
M. Venkataraman, R. Mishra, T. Kotresh, J. Militký, H. Jamshaid
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引用次数: 56

Abstract

ABSTRACT For many garment applications where protection is needed against hostile environments, part of the requirement is for insulation to shield the wearer from extremes of temperature. For an insulating garment to be fully effective, it needs to allow the wearer to move freely so that they can carry out their intended activity efficiently. Traditional materials achieve their insulation by trapping air within the structure thereby not only limiting heat loss by convection but also making good use of the low thermal conductivity of air to cocoon the wearer within a comfortable environment. To achieve effective protection with conventional textiles, it is usually necessary to have a thick fibrous layer, or series of layers, to trap a sufficient quantity of air to provide the required level of insulation. Several disadvantages arise as a result. For example, thick layers of insulating textile materials reduce the ability of the wearer to move in a normal manner so that the conduct of detailed manual tasks can become very difficult; the layers lose their insulating capacity when the trapped air is lost as they are compressed; the insulating capacity falls rapidly as moisture collects within the fibrous insulator – it does not have to become sensibly wet for this to happen; just 15% moisture regain can give a dramatic reduction in insulating capacity. Not surprisingly therefore, there has been continued interest in developing insulators that might be able to overcome the disadvantages of conventional textile materials and improve the mobility of the wearer by allowing the use of only a very thin layer of extremely-high insulating performance to provide the required thermal protection. One class of materials from which suitable candidates might be drawn is aerogels; their attractiveness derives from the fact that they show the highest thermal insulation capacity of any materials developed so far. Despite sporadic high levels of interest, commercialisation has been slow. Aerogels have been found to possess their own set of disadvantages such as fragility; rigidity; dust formation during working and cumbersome, expensive, batch-wise manufacturing processes. They may well have been destined to become a product of minor interest, confined to very specialist applications where cost was of little concern. However, methods have been developed to combine aerogels and fibres in composite structures which maintain extremely high insulating capacity whilst demonstrating sufficient flexibility for use in garments. Ways have been found to prevent the formation of powder as aerogel composite fabrics are worked. Most significant though, is the achievement, arising from a project supported by the Korean Government, of a simplified one-step production process developed with the express aim of providing a substantial reduction in the cost of aerogels. Suitably-priced aerogel is now available and this should provide fresh stimulus for research and development teams to engage in new product development work utilising aerogels in textiles and garments for thermal insulation. The mechanisms through which aerogels achieve their outstanding thermal insulating ability is unconventional, at least in terms of materials used in textiles. This issue of Textile Progress therefore includes detail about thermal transport in aerogels before reviewing the various forms in which aerogels can now be made, some of their applications and the research priorities that are now beginning to emerge.
用于高性能纺织品隔热的气凝胶
对于许多需要对恶劣环境进行保护的服装应用,部分要求是绝缘,以保护穿着者免受极端温度的影响。为了使隔热衣完全有效,它需要允许穿着者自由活动,以便他们能够有效地进行预期的活动。传统材料通过在结构中捕获空气来实现其绝缘,从而不仅限制了对流的热量损失,而且还充分利用了空气的低导热性,使穿着者在舒适的环境中保持茧状。为了用传统纺织品实现有效的保护,通常需要有一层厚的纤维层,或一系列的纤维层,以捕获足够数量的空气来提供所需的绝缘水平。结果产生了一些不利因素。例如,绝缘纺织材料的厚层降低了穿着者以正常方式移动的能力,因此进行详细的手动任务可能变得非常困难;当这些层在被压缩的过程中被困住的空气丢失时,它们就失去了绝缘能力;当水分在纤维绝缘体内聚集时,绝缘能力迅速下降-它不必变得明显潮湿才能发生这种情况;仅15%的回潮就能使绝缘容量急剧下降。因此,毫不奇怪,人们一直对开发绝缘体感兴趣,这种绝缘体可能能够克服传统纺织材料的缺点,并通过允许使用一层非常薄的极高绝缘性能来提供所需的热保护,从而提高穿着者的机动性。可以从中提取合适候选材料的一类是气凝胶;它们的吸引力源于这样一个事实,即它们显示出迄今为止开发的任何材料中最高的隔热能力。尽管偶尔会有很高的兴趣,但商业化一直很缓慢。人们发现气凝胶也有自己的缺点,比如易碎;刚度;在工作和繁琐、昂贵、批量生产过程中形成的粉尘。它们很可能注定会成为一种小众产品,局限于非常专业的应用,在这些应用中,成本几乎不受关注。然而,已经开发出将气凝胶和纤维结合在复合结构中的方法,这些复合结构保持极高的绝缘能力,同时显示出用于服装的足够的灵活性。已经找到了防止气凝胶复合织物在加工过程中形成粉末的方法。最重要的是,韩国政府支持的一个项目取得了一项成就,该项目开发了一种简化的一步生产工艺,其明确目标是大幅降低气凝胶的成本。价格合适的气凝胶现已上市,这将为研究和开发团队提供新的刺激,以从事新产品开发工作,利用气凝胶在纺织品和服装中进行隔热。气凝胶实现其出色的隔热能力的机制是非常规的,至少在纺织品中使用的材料方面。因此,这一期的《纺织进展》在回顾气凝胶的各种形式、它们的一些应用和现在开始出现的研究重点之前,详细介绍了气凝胶中的热传输。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
TEXTILE PROGRESS
TEXTILE PROGRESS MATERIALS SCIENCE, TEXTILES-
CiteScore
4.90
自引率
6.70%
发文量
1
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