The purpose of this research was to experimentally determine if any relationship exists between the concrete strength and the post-cracking behaviour of a reinforced concrete member. A total of nine large-scale reinforced concrete tension specimens, using either high or normal-strength concrete, were constructed and tested in addition to a series of six small-scale reinforced high strength concrete specimens (pilot specimens). High strength concrete refers to a material meeting the requirements of the Canadian specification CSA A23.1-94 ({dollar}fsb{lcub}c{rcub}' > 70{dollar} MPa).; The extension response with respect to increasing tensile load of all specimens was measured, adjusted to account for shrinkage, and subsequently presented as bond performance ({dollar}betasb{lcub}c{rcub}{dollar}) factor values. Shrinkage corrected response curves more appropriately evaluate the post-cracking behaviour, which would otherwise underestimate the tension stiffening potential. In addition to concrete strength, other variables were tested for influence on post-cracking behaviour and included: the steel reinforcing ratio, grade of reinforcement (deformed bar or prestressing strand), and concrete section and bar layout (effective area). A series of comparative based results regarding specimen variables were then produced from the accumulated research data. Observation of crack width and spacing developments were also made for the large scale specimens during testing.; It was found that, although the high strength specimens were indeed stronger (ie. larger cracking load) and stiffer than the normal strength members, concrete strength had little or no effect on the relative post-cracking behaviour (ie. {dollar}betasb{lcub}c{rcub}{dollar} was largely unaffected by concrete compressive strength). Perhaps the only variable influencing the {dollar}betasb{lcub}c{rcub}{dollar} values obtained was the steel reinforcing ratio. A {dollar}betasb{lcub}c{rcub}{dollar} function (for reinforced concrete in tension) is suggested which better fits the experimental data than other published models do. The effective area of concrete in tension given in the CEB-FIP code is found to reasonably agree with the information collected under this programme.
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机译:这项研究的目的是通过实验确定混凝土强度与钢筋混凝土构件的开裂后性能之间是否存在任何关系。除了一系列六个小规模的高强度混凝土高强度混凝土样本(试点)之外,总共构造并测试了使用高强度或正常强度混凝土的九个大型钢筋混凝土拉伸样本。高强度混凝土是指符合加拿大规范CSA A23.1-94要求的材料({fsb {lcub} c {rcub}'> 70 {dollar MPa)”。测量相对于所有样品增加的拉伸载荷的延伸响应,调节以解决收缩,然后以粘结性能(美元)β(sbsb {lcub} c {rcub} {美元))表示。收缩率校正后的响应曲线可以更恰当地评估开裂后的行为,否则会低估拉伸强度。除混凝土强度外,还测试了其他变量对开裂后行为的影响,其中包括:钢筋配比,钢筋等级(变形的钢筋或预应力钢绞线)以及混凝土的截面和钢筋布局(有效面积)。然后,从累积的研究数据中得出了一系列有关样本变量的比较结果。在测试过程中,还观察了大型试样的裂缝宽度和间距发展。结果发现,尽管高强度试样确实比普通强度构件更坚固(即更大的开裂荷载)和坚硬度,但混凝土强度对开裂后的相对行为(即{dollar} betasb { lcub} c {rcub} {dollar}在很大程度上不受混凝土抗压强度的影响。影响获得的{beta} b {lcub} c {rcub} {dollar}值的唯一变量可能是钢的增强比。建议使用{dollar} betasb {lcub} c {rcub} {dollar}函数(用于受拉钢筋混凝土),比其他已发表的模型更适合实验数据。 CEB-FIP规范中给出的受拉混凝土有效面积与该计划下收集的信息合理地吻合。
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