Mechanical performance of FRP-RC flexural members subjected to fire conditions

Budownictwo i Architektura Pub Date : 2020-11-02 DOI:10.35784/bud-arch.2119

K. Protchenko, Szmigiera Elżbieta, M. Urbański, A. Garbacz

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Abstract

One of the main concerns that limit the widespread use of Fibre-Reinforced Polymers (FRP) bars as internal reinforcement for reinforced concrete (RC) structures is their relatively unexplored response to elevated temperatures. The behaviour of FRP reinforcement at elevated temperature as well as their post-fire behaviour can be different from conventional reinforcement and depends on the properties of the constituents of the bars. Therefore, the fire resistance of FRP-RC structures is an important issue that needs careful investigation before FRP reinforcement can be implemented in RC structures. The experimental results for full-scale FRP-RC beams subjected to specific fire action were presented and discussed in this paper. The specimens were exposed to heat in the mid-section from below (tension zone) and from the sides. As one of the main aims was to examine the influence of different reinforcement configurations, the testing was made for concrete beams reinforced with three different types of FRP bars: (i) basalt-FRP (BFRP), (ii) hybrid FRP with carbon and basalt fibres (HFRP) and (iii) nano-hybrid FRP (nHFRP), with modification of the epoxy matrix of the rebars. The present work describes the behaviour of FRP-RC beams exposed to fire conditions and simultaneous loading (50 % of their ultimate strength capacity at normal temperature) and unloaded beams were tested after the cooling phase in order to evaluate their residual resistance. Present work shows that the type of FRP bars used has a direct influence on the outcomes and the way of destruction. The maximum ductility, the longest heating time of approximately 100 minutes, was obtained for beams reinforced with BFRP bars and attained deflections were corresponded to the value of 162 mm.

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火灾条件下FRP-RC受弯构件的力学性能

限制纤维增强聚合物(FRP)棒作为钢筋混凝土(RC)结构内部钢筋广泛使用的主要问题之一是它们对高温的相对未开发的响应。FRP钢筋在高温下的性能以及火灾后的性能可能与传统钢筋不同，这取决于钢筋成分的性能。因此，FRP-RC结构的耐火性能是FRP加固在RC结构中实施前需要认真研究的一个重要问题。本文介绍并讨论了全尺寸FRP-RC梁在特定火灾作用下的试验结果。试样在中部从下方(张力区)和侧面受热。由于主要目的之一是检查不同的加固结构的影响，测试是对混凝土梁进行了三种不同类型的FRP筋加固:(i)玄武岩-FRP (BFRP)， (ii)复合FRP与碳和玄武岩纤维(HFRP)和(iii)纳米复合FRP (nHFRP)，改性环氧基的钢筋。本工作描述了FRP-RC梁在火灾条件下的行为和同时加载(常温下其极限强度容量的50%)，并在冷却阶段后对卸载梁进行了测试，以评估其剩余阻力。目前的研究表明，使用FRP筋的类型对结果和破坏方式有直接影响。BFRP筋加固梁的最大延性，最长的加热时间约为100分钟，获得的挠度对应于162 mm的值。

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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