Finite element analysis of lightweight concrete-filled LSF walls exposed to realistic design fire

IF 0.9 Q4 CONSTRUCTION & BUILDING TECHNOLOGY
I. Upasiri, Chaminda Konthesingha, A. Nanayakkara, K. Poologanathan, Gatheeshgar Perampalam, D. Perera
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引用次数: 2

Abstract

PurposeLight-Gauge Steel Frame (LSF) structures are popular in building construction due to their lightweight, easy erecting and constructability characteristics. However, due to steel lipped channel sections negative fire performance, cavity insulation materials are utilized in the LSF configuration to enhance its fire performance. The applicability of lightweight concrete filling as cavity insulation in LSF and its effect on the fire performance of LSF are investigated under realistic design fire exposure, and results are compared with standard fire exposure.Design/methodology/approachA Finite Element model (FEM) was developed to simulate the fire performance of Light Gauge Steel Frame (LSF) walls exposed to realistic design fires. The model was developed utilising Abaqus subroutine to incorporate temperature-dependent properties of the material based on the heating and cooling phases of the realistic design fire temperature. The developed model was validated with the available experimental results and incorporated into a parametric study to evaluate the fire performance of conventional LSF walls compared to LSF walls with lightweight concrete filling under standard and realistic fire exposures.FindingsNovel FEM was developed incorporating temperature and phase (heating and cooling) dependent material properties in simulating the fire performance of structures exposed to realistic design fires. The validated FEM was utilised in the parametric study, and results exhibited that the LSF walls with lightweight concrete have shown better fire performance under insulation and load-bearing criteria in Eurocode parametric fire exposure. Foamed Concrete (FC) of 1,000 kg/m3 density showed best fire performance among lightweight concrete filling, followed by FC of 650 kg/m3 and Autoclaved Aerated Concrete (AAC) 600 kg/m3.Research limitations/implicationsThe developed FEM is capable of investigating the insulation and load-bearing fire ratings of LSF walls. However, with the availability of the elevated temperature mechanical properties of the LSF wall, materials developed model could be further extended to simulate the complete fire behaviour.Practical implicationsLSF structures are popular in building construction due to their lightweight, easy erecting and constructability characteristics. However, due to steel-lipped channel sections negative fire performance, cavity insulation materials are utilised in the LSF configuration to enhance its fire performance. The lightweight concrete filling in LSF is a novel idea that could be practically implemented in the construction, which would enhance both fire performance and the mechanical performance of LSF walls.Originality/valueLimited studies have investigated the fire performance of structural elements exposed to realistic design fires. Numerical models developed in those studies have considered a similar approach as models developed to simulate standard fire exposure. However, due to the heating phase and the cooling phase of the realistic design fires, the numerical model should incorporate both temperature and phase (heating and cooling phase) dependent properties, which was incorporated in this study and validated with the experimental results. Further lightweight concrete filling in LSF is a novel technique in which fire performance was investigated in this study.
轻质LSF混凝土墙在实际设计火灾中的有限元分析
目的轻型钢框架(LSF)结构由于其重量轻、易于安装和可施工的特点,在建筑施工中受到欢迎。然而,由于钢唇通道截面具有负面的防火性能,LSF配置中使用了空腔隔热材料来提高其防火性能。在实际设计火灾暴露条件下,研究了轻质混凝土填充作为LSF空腔隔热材料的适用性及其对LSF防火性能的影响,并将结果与标准火灾暴露进行了比较。设计/方法/方法开发了一个有限元模型(FEM)来模拟暴露在现实设计火灾中的轻钢框架(LSF)墙的防火性能。该模型是利用Abaqus子程序开发的,以实际设计火灾温度的加热和冷却阶段为基础,结合材料的温度相关特性。所开发的模型与现有的实验结果进行了验证,并纳入了一项参数研究,以评估在标准和现实的火灾暴露下,与轻质混凝土填充的LSF墙相比,传统LSF墙的防火性能。Findings开发了一种新的有限元法,结合了与温度和相位(加热和冷却)相关的材料特性,模拟了暴露在现实设计火灾中的结构的防火性能。在参数研究中使用了经过验证的有限元法,结果表明,在欧洲规范参数火灾暴露条件下,轻质混凝土LSF墙在隔热和承载标准下表现出更好的防火性能。密度为1000 kg/m3的泡沫混凝土(FC)在轻质混凝土填充中表现出最佳的防火性能,其次是650 kg/m3的FC和600 kg/m3的蒸压加气混凝土(AAC)。研究局限性/含义所开发的有限元法能够研究LSF墙的隔热和承载防火等级。然而,随着LSF墙高温力学性能的可用性,材料开发的模型可以进一步扩展,以模拟完整的火灾行为。LSF结构由于其重量轻、易于架设和可施工性等特点,在建筑施工中广受欢迎。然而,由于钢唇通道截面具有负面的防火性能,LSF配置中使用了空腔绝缘材料来提高其防火性能。轻质混凝土填充LSF是一种可以在建筑中实际应用的新理念,它将提高LSF墙的防火性能和力学性能。独创性/价值有限的研究调查了暴露在现实设计火灾中的结构元件的防火性能。这些研究中开发的数值模型考虑了与模拟标准火灾暴露的模型类似的方法。然而,由于实际设计火灾的加热阶段和冷却阶段,数值模型应包含与温度和相位(加热和冷却阶段)相关的特性,这一特性已纳入本研究,并通过实验结果进行了验证。在LSF中进一步填充轻质混凝土是本研究中研究耐火性能的一种新技术。
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来源期刊
Journal of Structural Fire Engineering
Journal of Structural Fire Engineering CONSTRUCTION & BUILDING TECHNOLOGY-
CiteScore
2.20
自引率
10.00%
发文量
28
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