Parametric study on the residual compressive strength of RC columns subjected to different standard fire durations and load ratios

IF 0.9 Q4 CONSTRUCTION & BUILDING TECHNOLOGY
Sara Mirzabagheri, O. Salem
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引用次数: 0

Abstract

PurposeSince columns are critical structural elements, they shall withstand hazards without any considerable damage. In the case of a fire, although concrete has low thermal conductivity compared to other construction materials, its properties are changed at elevated temperatures. Most critically, the residual compressive strengths of reinforced concrete columns are significantly reduced after fire exposure. Validation of the worthiness of rehabilitating concrete structures after fire exposure is highly dependent on accurately determining the residual strengths of fire-damaged essential structural elements such as columns.Design/methodology/approachIn this study, eight reinforced-concrete columns (200 × 200 × 1,500 mm) that were experimentally examined in a prior related study have been numerically modelled using ABAQUS software to investigate their residual compressive strengths after exposure to different durations of standard fire (i.e. one and two hours) while subjected to different applied load ratios (i.e. 20 and 40% of the compressive resistance of the column). Outcomes of the numerical simulations were verified against the prior study's experimental results.FindingsIn a subsequent phase, the results of a parametric study that has been completed as part of the current study to investigate the effects of the applied load ratios show that the application of axial load up to 80% of the compressive resistance of the column did not considerably influence the residual compressive strength of the shorter columns (i.e. 1,500 and 2,000-mm high). However, increasing the height of the column to 2,500 or 3,000 mm considerably reduced the residual compressive strength when the load ratio applied on the columns exceeded 60 and 40%, respectively. Also, when the different columns were simulated under two-hour standard fire exposure, the dominant failure was buckling rather than concrete crushing which was the typical failure mode in most columns.Originality/valueThe outcomes of the numerical study presented in this paper reflect the residual compressive strength of RC columns subjected to various applied load ratios and standard fire durations. Also, the parametric study conducted as part of this research on the effects of higher load ratios and greater column heights on the residual compressive strength of the fire-damaged columns is practical and efficient. The developed computer models can be beneficial to assist engineers in assessing the validity of rehabilitating concrete structures after being exposed to fire.
不同标准火灾持续时间和荷载比下钢筋混凝土柱残余抗压强度的参数研究
目的由于立柱是关键的结构元件,它们应能承受危险,不会造成任何严重损坏。在火灾的情况下,尽管与其他建筑材料相比,混凝土的导热系数较低,但其性能在高温下会发生变化。最关键的是,火灾暴露后,钢筋混凝土柱的残余抗压强度显著降低。火灾暴露后恢复混凝土结构的价值的验证在很大程度上取决于准确确定火灾损坏的基本结构元件(如立柱)的残余强度。设计/方法/方法在本研究中,在先前的相关研究中,对8根钢筋混凝土柱(200×200×1500 mm)进行了实验检验,并使用ABAQUS软件对其进行了数值模拟,以研究其在暴露于不同标准火灾持续时间(即1小时和2小时)后,在不同的荷载比下的残余抗压强度(即柱抗压强度的20%和40%)。数值模拟的结果与先前研究的实验结果进行了验证。发现在随后的阶段,作为当前研究的一部分,已完成的一项参数研究的结果表明,施加高达柱抗压强度80%的轴向载荷不会显著影响较短柱(即1500和2000 mm高)的残余抗压强度。然而,当施加在柱上的载荷比分别超过60%和40%时,将柱的高度增加到2500或3000mm会显著降低残余抗压强度。此外,当在两小时标准火灾暴露下模拟不同的柱时,主要的破坏是屈曲,而不是混凝土压碎,这是大多数柱的典型破坏模式。原创性/价值本文中的数值研究结果反映了RC柱在不同荷载比和标准火灾持续时间下的残余抗压强度。此外,作为本研究的一部分,对更高的荷载比和更高的柱高度对火灾受损柱的残余抗压强度的影响进行的参数研究是实用和有效的。所开发的计算机模型有助于帮助工程师评估暴露在火灾中后修复混凝土结构的有效性。
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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