This project investigates the experience of physiological discomfort during travel through an urban environment such as London or New York in winter. The over and underground networks that lace a current metropolis, form vital passages that lead the traveller though a multitude of spaces each defined by unique temperature, humidity and activity level. It is impossible to predict possible eventualities and consequently accommodate in a selection of clothing to ensure physiological comfort.ududModular clothing assemblies are currently employed for the management of physiological comfort to adjust the insulation and ventilation properties of a clothing system and rely on combinations of behavioural methods and textile properties. This method is compromised by factors such as limited availability of space and wearer’s ability to detect and respond to the onset of discomfort sensations. ududCurrent smart systems rely on temperature as a stimulus for actuation.udExperimental work suggests that humidity is a more suitable trigger. Botanical mechanisms that employ hygroscopic expansion/contraction for seed and spore deployment were identified as paradigms for the development of a smart textile system. ududBiomimetic analysis of these natural mechanisms inspired the design of a textile prototype able to adapt its water vapour resistance in response to humidity changes in the microclimate of the clothing system. The resulting structure decreases its permeability to air by 20% gradually as relative humidity increases from 60% to 90%.
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机译:该项目调查了冬季穿越伦敦或纽约等城市环境时生理不适的经历。环绕着当前大都市的地面和地下网络形成了重要的通道,引导旅客穿越多个空间,每个空间都由独特的温度,湿度和活动水平来定义。无法预测可能的情况并因此无法容纳选择的衣服以确保生理舒适。 ud ud模块化服装组件目前用于管理生理舒适性,以调节服装系统的隔热和通风特性,并依赖于组合的行为方法和纺织品特性。由于空间的有限性以及佩戴者检测并响应不适感的能力等因素,该方法受到了损害。 ud ud当前的智能系统依靠温度作为促动因素。 ud实验工作表明,湿度是更合适的触发因素。使用吸湿性膨胀/收缩来播种种子和孢子的植物机制被确定为开发智能纺织品系统的范例。对这些自然机制的仿生分析启发了纺织品原型的设计,该原型能够根据服装系统微气候中的湿度变化来适应其耐水蒸气性。随着相对湿度从60%增加到90%,所得结构逐渐降低了其对空气的渗透性20%。
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