Prefabricated thermally-activated fiber-polymer composite building slab P-TACS: Toward the multifunctional and pre-fabricated structural elements in buildings

IF 1.8 4区 工程技术 Q3 CONSTRUCTION & BUILDING TECHNOLOGY
D. Khovalyg, Alexandre Mudry, T. Keller
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引用次数: 1

Abstract

The traditional sequential design of building elements, where every element performs only one dedicated function, carries significant embodied energy. Thus, modular pre-fabricated load-bearing elements could overcome the disadvantages of the current carbon-intensive construction practice and go beyond; as such, lightweight glass fiber-polymer composite profiles could be more advantageous in performance. Cellular structures of such profiles can be advantageous for adding water channels for active heating and cooling indoors and for fire protection. Therefore, the development of such a modular active building slab referred to as P-TACS (Prefabricated Thermally-Activated Fiber-Polymer Composite Slab) is explored in this work. The structural performance of a proposed P-TACS design is verified in terms of serviceability and ultimate limit states. The addition of local carbon fiber inclusions allows for an increase in the span of the slab to 10 m and a more uniform surface temperature. Thermal performance of the structurally optimized geometrical configuration is analyzed by, first of all, determining water parameters based on the 1D approach partially adopted from the standard radiant systems analysis and, secondly, by a detailed 2D thermal analysis using ANSYS Fluent numerical simulations. The hydraulic and thermal performance comparison of the novel P-TACS design with two standard radiant systems (ESS Type A and RCP) reveals that the P-TACS design outperforms the standard embedded surface system ESS Type A, both for floor heating and cooling case. In addition, the response time of P-TACS is three times faster compared to the ESS response time. The main advantage of the P-TACS is in lower mean water temperature, compared to traditional embedded radiant systems (e.g., EES type), required for conditioning the space, potentially resulting in lower operational energy use. The fire outbreak scenario is considered to complete the analysis, and the measures to switch water flow from nominal to fire scenario are proposed.
预制热活化纤维-聚合物复合建筑板P-TACS:面向建筑中的多功能预制结构构件
传统的建筑元素的顺序设计,每个元素只执行一个专用功能,承载着重要的体现能量。因此,模块化预制承重元件可以克服目前碳密集型建筑实践的缺点,并超越;因此,轻质玻璃纤维-聚合物复合型材在性能上更有优势。这种型材的蜂窝状结构对于增加用于室内主动加热和冷却以及用于防火的水通道是有利的。因此,在这项工作中,我们探索了这种被称为P-TACS(预制热活化纤维-聚合物复合板)的模块化活性建筑板的发展。提出的P-TACS设计的结构性能在可用性和极限状态方面进行了验证。局部碳纤维夹杂物的添加允许将板的跨度增加到10米,并且表面温度更均匀。对结构优化后的几何构型进行热性能分析,首先基于部分采用标准辐射系统分析的一维方法确定水参数,然后利用ANSYS Fluent数值模拟进行详细的二维热分析。新型P-TACS设计与两种标准辐射系统(ESS A型和RCP)的水力和热性能比较表明,P-TACS设计在地板采暖和冷却情况下都优于标准嵌入式表面系统ESS A型。此外,P-TACS的反应时间比ESS的反应时间快3倍。与传统的嵌入式辐射系统(例如EES类型)相比,P-TACS的主要优点是平均水温较低,从而降低了空间调节所需的操作能耗。考虑了火灾情景来完成分析,并提出了从名义流向火灾情景转换的措施。
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
Journal of Building Physics
Journal of Building Physics 工程技术-结构与建筑技术
CiteScore
5.10
自引率
15.00%
发文量
10
审稿时长
5.3 months
期刊介绍: Journal of Building Physics (J. Bldg. Phys) is an international, peer-reviewed journal that publishes a high quality research and state of the art “integrated” papers to promote scientifically thorough advancement of all the areas of non-structural performance of a building and particularly in heat, air, moisture transfer.
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