Fire resistance of corroded high-strength structural concrete

IF 0.9 Q4 CONSTRUCTION & BUILDING TECHNOLOGY Journal of Structural Fire Engineering Pub Date : 2020-09-17 DOI:10.1108/JSFE-10-2019-0033
K. Sobhan, D. Reddy, F. Martínez
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Abstract

Purpose The exposure of reinforced concrete structures such as high-rise residential buildings, bridges and piers to saline environments, including exposure to de-icing salts, increases their susceptibility to corrosion of the reinforcing steel. The exposure to fire can further deteriorate the structural integrity of corroded concrete structures. This combined effect of corrosion damage and fire exposure is not generally addressed in the structural concrete design codes. The synergistic combination of the effects of corrosion and fire forms the basis of this paper. Design/methodology/approach Concrete beam specimens with different strengths were prepared, moist-cured and corroded with impressed current. Later, they were “crack-scored” for corrosion evaluation, after which half were exposed to fire in a gas kiln. The fire damage was evaluated by nondestructive testing using ultrasonic pulse velocity. Next, all specimens were tested for residual flexural strength. They were then autopsied, and the level of corrosion was determined based on mass loss of the reinforcement. Findings For corroded specimens, the flexural capacity loss because of fire exposure increases as the compressive strength increases. In general, the higher the crack score, the higher the corresponding mass loss, unless some partial/segmental debonding of the reinforcement occurred. The degree of corrosion increases with decreasing compressive strength. The residual moment capacity, based on analytically determined capacities of uncorroded and nonfire-exposed beams, was significantly lower than those of uncorroded beams exposed to fire. Originality/value The combined effects of corrosion and fire on the mechanical properties of structural concrete are relatively unknown, and no guidance is available in the existing design codes to address this issue. Accordingly, the findings of the paper are expected to be valuable to both researchers and design engineers and can be regarded as the initial investigation on this topic.
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腐蚀高强结构混凝土的耐火性能
目的高层住宅、桥梁和桥墩等钢筋混凝土结构暴露在盐水环境中,包括暴露在除冰盐中,会增加其对钢筋腐蚀的敏感性。暴露在火灾中会进一步恶化腐蚀混凝土结构的结构完整性。在结构混凝土设计规范中,腐蚀损伤和火灾暴露的综合影响通常没有得到解决。腐蚀和火灾的协同作用构成了本文的基础。设计/方法/方法制备具有不同强度的混凝土梁试样,用外加电流进行湿养护和腐蚀。后来,它们被“裂纹评分”进行腐蚀评估,之后一半暴露在煤气窑中。采用超声波脉冲速度无损检测方法对火灾损伤进行了评价。接下来,对所有试样进行残余弯曲强度测试。然后对其进行尸检,并根据钢筋的质量损失确定腐蚀程度。发现对于腐蚀试样,由于暴露在火中而导致的弯曲能力损失随着抗压强度的增加而增加。一般来说,裂缝得分越高,相应的质量损失就越高,除非钢筋出现部分/节段脱胶。腐蚀程度随着抗压强度的降低而增加。基于分析确定的未受腐蚀和未受火暴露梁的承载力,剩余弯矩承载力显著低于未受腐蚀暴露在火中的梁。独创性/价值腐蚀和火灾对结构混凝土力学性能的综合影响相对未知,现有设计规范中没有解决这一问题的指南。因此,该论文的发现对研究人员和设计工程师都有价值,可以视为对该主题的初步研究。
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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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