Stress-strain state during the formation of normal cracks in three-layer bendable reinforced concrete elements under the action of longitudinal and transverse forces

O.A. Korol, Т.А. Barabanova, E.U. Abdullazianov, L. Sabitov, M.M. Ayzatullin
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Abstract

Most wall panels in operating multi-storey residential buildings are in a complex stress-strain state under the influence of vertical and horizontal loads, such as their own weight, wind, etc. These features must be taken into account in the calculation in order to ensure operational safety. The combination of vertical and horizontal forces acting simultaneously for three-layer bending elements leads to the fact that the boundary between the compressed and tensile zones not only moves from one layer to another, but also has a different geometric shape depending on the ratio between the vertical and horizontal load. The stress-strain state during the formation of normal cracks in three-layer bendable reinforced concrete elements is caused by the impact on layers of different concretes. The formation of normal cracks occurs due to the achievement of ultimate tensile strength by the most stretched concrete under the influence of external loads. Since three-layer reinforced concrete elements consist of two outer layers (reinforced concrete) and a middle layer (lightweight concrete), when such an element bends, the outer layers are subject to compression, and the middle layer is subject to tension. The boundary of the compressed zone can be located either in one of the outer layers or intersect the middle layer, which falls into both the compressed and stretched zones. To analyze the stress-strain state during the formation of normal cracks, it is necessary to take into account the fol-lowing parameters: geometric characteristics of the element (dimensions and shape of the section, layer thickness, etc.), physical and mechanical properties of concrete (compressive and tensile strength, elastic modulus, Poisson's ratio, crack resistance coefficient, etc.), characteristics of reinforcement (class, diameter, pitch of bars, etc.) and its location in the section.
纵向和横向力作用下三层可弯曲钢筋混凝土构件法向裂缝形成过程中的应力-应变状态
在垂直和水平荷载(如自重、风力等)的影响下,运行中的多层住宅楼中的大多数墙板都处于复杂的应力-应变状态。计算时必须考虑到这些特点,以确保运行安全。对三层弯曲元件而言,同时作用的垂直力和水平力的组合导致压缩区和拉伸区之间的边界不仅从一层移动到另一层,而且根据垂直荷载和水平荷载之间的比率而具有不同的几何形状。三层可弯曲钢筋混凝土构件法向裂缝形成过程中的应力-应变状态是由不同混凝土层受到的冲击造成的。正常裂缝的形成是由于在外部荷载的影响下,拉伸最大的混凝土达到了极限抗拉强度。由于三层钢筋混凝土构件由两个外层(钢筋混凝土)和一个中间层(轻质混凝土)组成,当这种构件弯曲时,外层受压,中间层受拉。压缩区的边界可以位于其中一个外层,也可以与中间层相交,中间层既属于压缩区,也属于拉伸区。要分析法向裂缝形成过程中的应力应变状态,必须考虑以下参数:构件的几何特征(截面的尺寸和形状、层厚等)、混凝土的物理和机械性能(抗压和抗拉强度、弹性模量、泊松比、抗裂系数等)、钢筋的特征(等级、直径、钢筋间距等)及其在截面中的位置。
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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