Bond in a reinforced concrete (RC) structure is the interaction force that transfers force between the steel and concrete. It influences the structural performance and serviceability of a structure under both static and cyclic loading. Corrosion of reinforcing steel in RC structures is the primary reason behind bond loss in RC elements. A loss of bond in concrete results in a decrease in the serviceability strength and eventually causes a brittle and sudden failure. Structures, such as bridges, are vulnerable to corrosion and at the same time are subjected to repeated loading rather than static loading. Nevertheless, little experimental or analytical studies that address the problem of corroded steelconcrete bond under repeated loading exist.; This study was aimed at increasing the understanding of the behaviour of bond between corroded reinforcing steel bars and concrete for structures subjected to repeated loading. In addition, the effect of fibre reinforced polymers (FRP) as a rehabilitation method was assessed. Fibre reinforced polymers is considered to be a state-of-the art rehabilitation material due to its advantages, such as high strength, light weight and ease of handling and application.; Forty-seven anchorage-beam specimens were cast and tested. The specimens' dimensions were 152 x 254 x 2000 mm reinforced with two 20M bars. The steel reinforcement in a specimen was unbonded except for 250 mm from each end. This bonded length was selected to ensure a bond failure. The corrosion was induced using an accelerated corrosion process. The parameters investigated were the corrosion level (0, 5 and 9% measured mass loss), whether the specimen was wrapped in the anchorage zone with a U-shaped carbon fibre reinforced polymer (CFRP) sheets or not, and the load range applied. The minimum load applied was 10% of the static bond capacity of the specimen. The maximum load was varied to give the desired range of fatigue lives (103 to 106 cycles). The test frequency for all repeated tests was 1.5 Hz.; Results showed that the repeated loading either pushed the bottom concrete cover away from the steel bar by wedge action for unwrapped beams or cracked and crushed the CFRP confined bottom concrete cover for wrapped beams. The concrete damage caused the bond stress to undergo a gradual redistribution, moving the peak bond stress from the loaded end towards the free end, resulting in failure of the specimens by fatigue of bond. Corrosion levels of 5% and 9% decreased the fatigue bond strength on average by 19%. The rate of slip of the steel bar increased as the corrosion level increased. CFRP sheets changed the mechanism by which the concrete resist the bond forces by engaging the bottom cover. This in turn increased the fatigue bond strength at all corrosion levels on average by 31% compared to unwrapped specimens.; Based on the test results and observations, a hypothesis of the mechanics of bond under repeated loading was postulated and a fatigue slip-growth analysis (similar to the fracture mechanics crack growth approach) was proposed to calculate the fatigue life of a specimen that fail in bond. The proposed analysis was in reasonable agreement with the experimental results.
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机译:钢筋混凝土(RC)结构中的粘结是在钢和混凝土之间传递力的相互作用力。它会影响静态和循环荷载下结构的结构性能和可维修性。钢筋混凝土结构中钢筋的腐蚀是造成钢筋混凝土单元粘结损失的主要原因。混凝土中粘结的丧失导致使用强度的降低,并最终导致脆性和突然破坏。诸如桥梁之类的结构易受腐蚀,并且同时承受反复荷载而不是静态荷载。然而,很少有实验或分析研究解决重复荷载下锈蚀的混凝土钢筋粘结问题。这项研究的目的是增进人们对反复加载结构的锈蚀钢筋和混凝土之间粘结性能的了解。此外,评估了纤维增强聚合物(FRP)作为康复方法的效果。纤维增强聚合物由于其优点,例如高强度,重量轻以及易于处理和应用而被认为是最先进的康复材料。铸造和测试了47个锚定梁样品。样品的尺寸为152 x 254 x 2000 mm,并用两个20M钢筋加固。样品中的钢筋未粘结,但两端各不超过250 mm。选择该粘结长度以确保粘结失败。使用加速腐蚀过程诱发腐蚀。研究的参数包括腐蚀程度(测得的质量损失为0、5%和9%),是否用U形碳纤维增强聚合物(CFRP)板将试样包裹在锚固区中以及施加的载荷范围。施加的最小载荷为样品静态粘结能力的10%。改变最大载荷以给出期望的疲劳寿命范围(103至106个循环)。所有重复测试的测试频率为1.5 Hz。结果表明,反复的荷载要么通过楔形作用将底部混凝土盖推离钢筋,以解决未包裹的梁,要么将CFRP约束的底部混凝土盖破裂并压碎,用于包裹梁。混凝土的损坏使粘结应力逐渐重新分布,使峰值粘结应力从受力端向自由端移动,导致粘结疲劳导致试样破坏。 5%和9%的腐蚀水平平均会使疲劳粘结强度降低19%。钢筋的滑移率随着腐蚀程度的增加而增加。 CFRP板材改变了通过接合底盖来抵抗粘结力的机制。与未包裹的试样相比,这反过来使所有腐蚀水平下的疲劳粘结强度平均提高了31%。根据测试结果和观察结果,提出了反复加载下粘结力学的假设,并提出了疲劳滑移增长分析(类似于断裂力学的裂纹扩展方法)来计算失效时的疲劳寿命。键。所提出的分析与实验结果合理吻合。
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