Bending resistance mechanism of prestressed ultra-high performance concrete - reinforced concrete beam based on a full-scale experiment

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Xiangdong Sun, Yuquan Ma, Feng Jiang, Xueming Fan, Honglin Wu
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Abstract

Ultra-High Performance Concrete (UHPC) is a new type of engineering material with high compressive strength, high tensile strength, and high fracture toughness. Its bending failure mechanism is different from that of traditional concrete beams, which requires a new computational model to describe the bending failure phenomena of the prestressed ultra-high performance concrete - reinforced concrete (UHPC-RC) beam without web reinforcement. Therefore, this paper, through full-scale tests on a 30m prestressed UHPC-RC beam without web reinforcement, captures unique bending failure phenomena, including initial cracking, development of local cracks, and rupture of prestressed steel strands. Considering the tension-compression constitutive relationship of UHPC material, an innovative computational model for bending bearing capacity is proposed. Based on this model, a study on the minimum reinforcement ratio of full prestressed-ordinary steel bars is conducted. The results show that in the bending failure of the prestressed UHPC-RC beam without web reinforcement, excessive tensile strain of steel strands will occur at the local crack location. At this time, the structure does not satisfy the assumption of plane sections, and the introduction of the calculation model of the limit state of external prestressed tendons can effectively match this model, which is highly consistent with the experimental results. The minimum reinforcement ratio of full prestressed-ordinary steel bars is revised to the auxiliary reinforcement ratio of full prestressed-ordinary steel bars, quantifying the minimum reinforcement requirements of ordinary steel bars. The research results of this paper can provide reference for the next step of theoretical research.
基于全尺寸实验的预应力超高性能混凝土-钢筋混凝土梁的抗弯机理
超高性能混凝土(UHPC)是一种具有高抗压强度、高抗拉强度和高断裂韧性的新型工程材料。其弯曲破坏机理不同于传统混凝土梁,这就需要一个新的计算模型来描述无腹板配筋的预应力超高性能混凝土-钢筋混凝土(UHPC-RC)梁的弯曲破坏现象。因此,本文通过对无腹板配筋的 30 米预应力 UHPC-RC 梁进行全尺寸试验,捕捉到了独特的弯曲破坏现象,包括初始开裂、局部裂缝发展和预应力钢绞线断裂。考虑到 UHPC 材料的拉伸-压缩构成关系,提出了一种创新的抗弯承载力计算模型。基于该模型,对全预应力普通钢筋的最小配筋率进行了研究。结果表明,无腹板配筋的预应力 UHPC-RC 梁在弯曲破坏时,局部裂缝位置的钢绞线会出现过大的拉应变。此时,结构不满足平面截面假设,引入外预应力筋极限状态计算模型可有效匹配该模型,与实验结果高度吻合。将全预应力普通钢筋的最小配筋率修正为全预应力普通钢筋的辅助配筋率,量化了普通钢筋的最小配筋要求。本文的研究成果可为下一步的理论研究提供参考。
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
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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