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具有增强被动隔热性能的新型水泥基建筑围护结构的热机械性能分析

Thermomechanical Performance Analysis of Novel Cement-Based Building Envelopes with Enhanced Passive Insulation Properties.

作者信息

Marin-Montin Jorge, Roque Eduardo, Xu Yading, Šavija Branko, Serrano-Ruiz Juan Carlos, Montero-Chacón Francisco

机构信息

Materials and Sustainability Group, Department of Engineering, Universidad Loyola Andalucía, Avenida de las Universidades, s/n, 41704 Sevilla, Spain.

Microlab, Faculty of Civil Engineering and Geosciences, Delft University of Technology, 2628 CN Delft, The Netherlands.

出版信息

Materials (Basel). 2022 Jul 15;15(14):4925. doi: 10.3390/ma15144925.

DOI:10.3390/ma15144925
PMID:35888393
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9323229/
Abstract

The design of new insulating envelopes is a direct route towards energy efficient buildings. The combinations of novel materials, such as phase-change (PCM), and advanced manufacturing techniques, such as additive manufacturing, may harness important changes in the designing of building envelopes. In this work we propose a novel methodology for the design of cement-based building envelopes. Namely, we combined the use of a multiscale, multiphysical simulation framework with advanced synthesis techniques, such as the use of phase-change materials and additive manufacturing for the design of concrete envelopes with enhanced insulation properties. At the material scale, microencapsulated PCMs are added to a cementitious matrix to increase heat storage. Next, at the component level, we create novel designs for the blocks, here defined as HEXCEM, by means of additive manufacturing. The material and component design process is strongly supported on heat transfer simulations with the use of the finite element method. Effective thermal properties of the mixes can be obtained and subsequently used in macroscale simulations to account for the effect of the volume fraction of PCMs. From the experimental and numerical tests, we report an increase in the the thermal inertia, which results in thermal comfort indoors.

摘要

新型保温围护结构的设计是实现节能建筑的直接途径。新型材料(如相变材料)与先进制造技术(如增材制造)的结合,可能会给建筑围护结构设计带来重大变革。在这项工作中,我们提出了一种用于水泥基建筑围护结构设计的新方法。具体而言,我们将多尺度、多物理场模拟框架与先进的合成技术相结合,例如使用相变材料和增材制造来设计具有增强隔热性能的混凝土围护结构。在材料层面,将微胶囊化相变材料添加到水泥基体中以增加蓄热能力。接下来,在构件层面,我们通过增材制造为砌块(此处定义为HEXCEM)创建新颖的设计。材料和构件设计过程在很大程度上借助了使用有限元方法的传热模拟。可以获得混合料的有效热性能,并随后将其用于宏观模拟,以考虑相变材料体积分数的影响。通过实验和数值测试,我们报告了热惯性的增加,这带来了室内的热舒适性。

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