Permeation of Different Gases Through Foils used as Envelopes for Vacuum Insulation Panels

Journal of Thermal Envelope and Building Science Pub Date : 2005-04-01 DOI:10.1177/1097196305051791

H. Schwab, U. Heinemann, A. Beck, H. Ebert, J. Fricke

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引用次数: 69

Abstract

Vacuum insulation panels (VIPs) are distinguished by their outstandingly low thermal conductivity. In the evacuated state, the VIPs being examined in this study (which have fumed silica as a core material) have a thermal conductivity of 4 10 3 W/(m K). Gases (N2, O2, H2O,...), which penetrate the foil cover cause an increase in pressure and water content and hence, an increase in the thermal conductivity. To determine these increases, VIPs have been manufactured with laminated aluminum foils (AlF) and aluminum-coated multilayer foils (MFs). The pressure and mass increases are determined at various temperatures, humidity, and with various panel formats. Large differences in the rates of pressure increases (1 -70 mbar/yr) and in the rates of mass increases (0.02-4 mass%/yr) are recorded, depending on the foil type, climatic conditions, and panel formats. From these measurements, the air and vapor transmission rates of the foil covers and their dependence on temperature, relative humidity, and panel size are derived. Using these gas transmission rates, it is possible to estimate which pressure increases are to be expected for panel formats and climatic conditions occurring in building applications. With laminated Al foils and selected Al-coated multilayer foils, rates of pressure increases below 1-2 mbar/yr are achieved. The rates of mass increase for typical climatic conditions for laminated Al foils are significantly below 0.1 mass%/yr, while with Al-coated multilayer foils, depending on the foil quality, mass increases per time of up to 1 mass%/yr are recorded. Increases in gas pressure per time of 1 -2 mbar/yr lead to relatively small increases in thermal conductivity, allowing applications in the construction sector, where service lives of several decades are required. With respect to the humidity-related increase in thermal conductivity, one has to know the climatic conditions, which have a strong influence on the increase in mass, and, above all, the precise dependence of the thermal conductivity on the humidity in the VIP.

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不同气体通过用作真空绝热板包皮的箔片的渗透

真空绝热板(vip)的特点是其显著的低导热性。在真空状态下，本研究中检测的vip(以气相二氧化硅为核心材料)的导热系数为4103w /(m K)。气体(N2, O2, H2O，…)穿透箔盖，导致压力和含水量增加，因此导热系数增加。为了确定这些增加，vip被制造与层压铝箔(AlF)和铝涂层多层箔(MFs)。压力和质量的增加是在不同的温度、湿度和不同的面板格式下确定的。压力增加速率(1 -70毫巴/年)和质量增加速率(0.02-4质量%/年)的差异很大，这取决于箔类型、气候条件和面板格式。从这些测量，空气和蒸汽的透射率箔盖和他们的依赖温度，相对湿度，和面板尺寸导出。利用这些气体传输速率，可以估计出在建筑应用中出现的面板格式和气候条件下预期的压力增加。使用层压铝箔和选定的镀铝多层箔，压力增加率低于1-2毫巴/年。在典型的气候条件下，层压铝箔的质量增加率明显低于0.1质量%/年，而对于镀铝多层箔，根据箔质量的不同，每次增加的质量可达1质量%/年。每次增加1 -2毫巴/年的气体压力，导热系数的增加相对较小，可以应用于需要几十年使用寿命的建筑行业。关于与湿度相关的热导率的增加，必须了解气候条件，这对质量的增加有很大的影响，最重要的是，热导率对VIP中湿度的精确依赖。

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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Journal of Thermal Envelope and Building Science

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