SHEAR TRANSFER BEHAVIOR OF FIBROUS CONCRETE

Journal of Engineering and Sustainable Development Pub Date : 2023-01-01 DOI:10.31272/jeasd.27.1.9

Eman Jwad, W. A. Waryosh

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Abstract

Fibrous concrete's shear strength behavior is important in structural design. Brackets, corbels, and ledger beams are examples of concrete members that might collapse in shear. Such a failure might be brittle and sudden. Fibers improve concrete's behavior by increasing residual shear transfer and reducing crack development and extension. In an experimental study, nine push-off specimens were divided into three groups and examined as part of the experiment. Conventional concrete, conventional concrete with 1% glass fiber, and conventional concrete with 1% steel fiber were the groups. There were three push-off specimens with various shear reinforcement ratios in each of the groups that were examined (0.0, 0.45, and 0.68%). The specimens utilized had dimensions of 500mm x 250mm x 125mm. The vertical slip and horizontal separation at the shear plane were measured using two-stroke linear variable displacement transducers (LVDT). The effect of fiber type and the ratio of transverse reinforcement across the shear plane were the parameters evaluated. The presence of fibers enhances final shear strength, which is more obvious in specimens without stirrups in the shear plane. Where the addition of 1% of glass fiber to normal strength concrete increased ultimate shear strength by 32.26%, 12.38%, and 12.5%, while adding 1% of steel fiber to normal strength concrete increased ultimate shear strength by up to 53.22%, 19%, and 25%, respectively, for the specimens without stirrups, two stirrups, and three stirrups. The fibrous specimens were stiffer and ductile failure was seen. Steel fibers improved overall concrete shear behavior better than glass fibers.

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纤维混凝土的剪切传递特性

纤维混凝土的抗剪性能在结构设计中具有重要意义。托架、支撑梁和横梁都是可能在剪切作用下倒塌的混凝土构件。这种失败可能是脆弱而突然的。纤维通过增加残余剪切传递和减少裂缝的发展和扩展来改善混凝土的性能。在一项实验研究中，将9个推脱标本分为三组，并作为实验的一部分进行检查。分为常规混凝土、1%玻璃纤维常规混凝土和1%钢纤维常规混凝土三组。每组各有3个抗剪配筋率不同的推脱试件(0.0、0.45和0.68%)。所使用的试件尺寸为500mm x 250mm x 125mm。采用二行程线性可变位移传感器(LVDT)测量了剪切面上的垂直滑移和水平分离。考察了纤维类型和横向配筋比对剪切面的影响。纤维的存在提高了最终抗剪强度，这在剪切面不加箍筋的试件中表现得更为明显。其中，普通强度混凝土中添加1%的玻璃纤维可使抗剪强度分别提高32.26%、12.38%和12.5%，而普通强度混凝土中添加1%的钢纤维可使无箍筋、双箍筋和三箍筋试件的抗剪强度分别提高53.22%、19%和25%。纤维试样较硬，出现延性破坏。钢纤维对混凝土整体抗剪性能的改善优于玻璃纤维。

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