Investigation on performance of prestressed hollow core slabs exposed to elevated temperatures

IF 0.9 Q4 CONSTRUCTION & BUILDING TECHNOLOGY
T.M. Jeyashree, P. R. Kannan Rajkumar
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Abstract

PurposeThis study focused on identifying critical factors governing the fire response of prestressed hollow-core slabs. The hollow-core slabs used as flooring units can be subjected to elevated temperatures during a fire. The fire response of prestressed hollow-core slabs is required to develop slabs with greater fire endurance. The present study aims to determine the extent to which the hollow-core slab can sustain load during a fire without undergoing progressive collapse under extreme fire and heating scenarios.Design/methodology/approachA finite element model was generated to predict the fire response of prestressed hollow core slabs under elevated temperatures. The accuracy of the model was predicted by examining thermal and structural responses through coupled temperature displacement analysis. A sensitivity analysis was performed to study the effects of concrete properties on prediction of system response. A parametric study was conducted by varying the thickness of the slab, fire and heating scenarios.FindingsThermal conductivity and specific heat of concrete were determined as sensitive parameters. The thickness of the slab was identified as a critical factor at a higher load level. Asymmetric heating of the slab resulted in higher fire resistance compared with symmetric heating.Originality/valueThis is the first study focused on studying the effect of modeling uncertainties on the system response by sensitivity analysis under elevated temperatures. The developed model with a parametric study helps in identifying critical factors for design purposes.
关于暴露在高温下的预应力空心板性能的研究
目的:本研究的重点是确定控制预应力空心板火灾反应的关键因素。用作地板单元的空心核心板在火灾期间可能会受到高温的影响。研究预应力空心芯板的火灾响应是开发具有更大耐火性能的板的必要条件。本研究旨在确定在极端火灾和加热情况下,空心核心板在火灾中承受载荷而不发生渐进倒塌的程度。设计/方法/方法建立了一个有限元模型来预测高温下预应力空心芯板的火灾响应。通过温度位移耦合分析,考察了热响应和结构响应,预测了模型的精度。通过敏感性分析研究了混凝土性能对系统响应预测的影响。通过改变板的厚度、火灾和加热情况进行了参数化研究。结果:确定了混凝土的热导率和比热作为敏感参数。在较高的荷载水平下,板的厚度被确定为一个关键因素。与对称加热相比,不对称加热的板具有更高的耐火性能。独创性/价值本文首次通过敏感性分析研究了高温条件下建模不确定性对系统响应的影响。通过参数化研究开发的模型有助于确定设计目的的关键因素。
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 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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