Determination of elevated temperature material properties by ANN-based FE model

IF 0.9 Q4 CONSTRUCTION & BUILDING TECHNOLOGY
I. Upasiri, Chaminda Konthesingha, A. Nanayakkara, K. Poologanathan
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引用次数: 0

Abstract

PurposeElevated temperature material properties are essential in predicting structural member's behavior in high-temperature exposures such as fire. Even though experimental methodologies are available to determine these properties, advanced equipment with high costs is required to perform those tests. Therefore, performing those experiments frequently is not feasible, and the development of numerical techniques is beneficial. A numerical technique is proposed in this study to determine the temperature-dependent thermal properties of the material using the fire test results based on the Artificial Neural Network (ANN)-based Finite Element (FE) model.Design/methodology/approachAn ANN-based FE model was developed in the Matlab program to determine the elevated temperature thermal diffusivity, thermal conductivity and the product of specific heat and density of a material. The temperature distribution obtained from fire tests is fed to the ANN-based FE model and material properties are predicted to match the temperature distribution.FindingsElevated temperature thermal properties of normal-weight concrete (NWC), gypsum plasterboard and lightweight concrete were predicted using the developed model, and good agreement was observed with the actual material properties measured experimentally. The developed method could be utilized to determine any materials' elevated temperature material properties numerically with the adequate temperature distribution data obtained during a fire or heat transfer test.Originality/valueTemperature-dependent material properties are important in predicting the behavior of structural elements exposed to fire. This research study developed a numerical technique utilizing ANN theories to determine elevated temperature thermal diffusivity, thermal conductivity and product of specific heat and density. Experimental methods are available to evaluate the material properties at high temperatures. However, these testing equipment are expensive and sophisticated; therefore, these equipment are not popular in laboratories causing a lack of high-temperature material properties for novel materials. However conducting a fire test to evaluate fire performance of any novel material is the common practice in the industry. ANN-based FE model developed in this study could utilize those fire testing results of the structural member (temperature distribution of the member throughout the fire tests) to predict the material's thermal properties.
基于神经网络有限元模型的高温材料性能测定
目的高温材料特性对于预测结构构件在高温暴露(如火灾)下的行为至关重要。尽管有实验方法可以确定这些特性,但进行这些测试需要高成本的先进设备。因此,频繁地进行这些实验是不可行的,数值技术的发展是有益的。本研究提出了一种数值技术,利用基于人工神经网络(ANN)的有限元(FE)模型的火灾试验结果来确定材料的温度相关热性能。设计/方法/方法在Matlab程序中开发了一个基于人工神经网络的有限元模型,以确定材料的高温热扩散率、热导率以及比热和密度的乘积。将从火灾试验中获得的温度分布输入到基于人工神经网络的有限元模型中,并预测材料特性以匹配温度分布。结果:利用所建立的模型预测了正常重量混凝土、石膏板和轻质混凝土的高温热性能,并与实验测量的实际材料性能吻合良好。所开发的方法可用于通过火灾或传热试验期间获得的足够的温度分布数据,以数字方式确定任何材料的高温材料特性。独创性/价值与温度相关的材料特性对于预测暴露在火灾中的结构元件的行为非常重要。本研究开发了一种利用人工神经网络理论确定高温热扩散率、热导率以及比热和密度乘积的数值技术。实验方法可用于评估材料在高温下的性能。然而,这些测试设备既昂贵又复杂;因此,这些设备在实验室中不受欢迎,导致新型材料缺乏高温材料性能。然而,进行防火测试以评估任何新型材料的防火性能是该行业的常见做法。本研究中开发的基于人工神经网络的有限元模型可以利用结构构件的火灾测试结果(整个火灾测试过程中构件的温度分布)来预测材料的热性能。
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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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