Nonlinear analysis of unreinforced beam-column joints

IF 0.3 Q4 ENGINEERING, MULTIDISCIPLINARY
Daniel Ricardo Salinas Guayacundo, Roberto Tomas Leon Saenz
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引用次数: 0

Abstract

Introduction- Reinforced Concrete Frames (RCF) constitute a significant portion of the building stock in areas with seismic hazard. Many older buildings of this type were designed and constructed with little or no consideration of lateral load effects. When not properly designed, the Beam-Column Joints (BCJ) can be the weak links in the RCF. Unreinforced BCJ are still quite prevalent in older-type construction especially in Asia and Latin America. The unreinforced BCJ are key components that have a significant impact on the structure’s behavior of RCF. Regarding the analytical approaches applicable to BCJ, the approaches range from simplified to more elaborate and phenomenological-oriented. Unfortunately, most of them lack of simplicity, numerical stability and practicality to robustly evaluate the performance of unreinforced BCJ. This paper presents an analytical approach to modeling unreinforced BCJ. Objective- The aim of this paper is to present a modified modeling approach to simulate the nonlinear behavior of unreinforced BCJ in RCF structures. Method- The approach presented is based on the model presented in [1]. The model was modified to follow the same nomenclature of the [2]. In the proposed approach, the BCJ subassembly is represented by (1) a set of rigid links placed in cross-shape are used to represent the joint geometry, (2) a zero-length element with an empirical quad-backbone curve, placed at the middle point of the rigid links, to represent the joint shear behavior, and (3) columns and beams elements modeled with fiber formulation and five integration points to capture the material nonlinearity of the elements that frame into the joint. The approach was implemented in the OpenSEES platform, and this was validated with 13 test results of unreinforced BCJ documented in the literature. Results- The proposed modelling approach can satisfactorily predict the joint shear capacity. A 2% difference and a standard deviation of about 11% were obtained when compared to 13 test results of unreinforced BCJ documented in the literature. In terms of cyclic behavior, the proposed modelling approach shown to adequately capture the initial stiffness, strength degradation, reloading stiffness, pre-capping, and post-capping capacity. Conclusions- The method proposed presents satisfactory agreement with the test results analyzed. Taking into account the minor modifications applied to the proposed method and the uncertainties associated with the materials, test measurements, test setup, and the tolerances, the proposed method can satisfactorily predict the unreinforced BCJ shear capacity in RCF structures. It is assumed that the procedures presented here will contribute in the incorporation of the unreinforced BCJ flexibility when modeling older-type RCF construction in a pragmatic manner.
无配筋梁柱节点非线性分析
导言-钢筋混凝土框架(RCF)构成了地震危险地区建筑存量的重要组成部分。许多这种类型的老建筑在设计和建造时很少或根本没有考虑侧向荷载的影响。如果设计不当,梁柱节点(BCJ)可能是RCF中的薄弱环节。未加固的BCJ在老式建筑中仍然相当普遍,特别是在亚洲和拉丁美洲。未加筋的BCJ是影响RCF结构性能的关键部件。关于BCJ的分析方法,从简化到更详细和现象学导向的方法不等。遗憾的是,这些方法大多缺乏简便性、数值稳定性和实用性,难以对未加筋BCJ的性能进行稳健评价。本文提出了一种非增强BCJ模型的解析方法。目的-本文的目的是提出一种改进的建模方法来模拟RCF结构中未加筋BCJ的非线性行为。方法:本文提出的方法基于文献[1]中的模型。该模型被修改为遵循与[2]相同的命名法。在提出的方法中,BCJ组件由(1)一组十字形的刚性链接来表示节点几何形状,(2)一个具有经验四骨干曲线的零长度单元,放置在刚性链接的中点,来表示节点的剪切行为,以及(3)用纤维配方建模的柱和梁单元和五个积分点来捕捉连接到节点的单元的材料非线性。该方法在OpenSEES平台上实现,并通过文献中记录的13个未强化BCJ测试结果进行了验证。结果:所提出的模型方法能较好地预测节理抗剪能力。与文献记载的13例未加筋BCJ试验结果相比,差异为2%,标准差约为11%。就循环行为而言,所提出的建模方法表明可以充分捕捉初始刚度、强度退化、再加载刚度、封顶前和封顶后的能力。结论:所提出的方法与分析的试验结果一致。考虑到所提出方法的微小修改以及与材料、试验测量、试验设置和公差相关的不确定性,所提出的方法可以令人满意地预测RCF结构中未加筋的BCJ抗剪能力。假设这里提出的程序将有助于在以实用的方式建模旧类型RCF构建时纳入未增强的BCJ灵活性。
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
INGE CUC
INGE CUC ENGINEERING, MULTIDISCIPLINARY-
自引率
50.00%
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0
审稿时长
8 weeks
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