SIMULATION OF WORK OF A REINFORCED PRE-STRESSED WOODEN ELEMENT

Petro Homon
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Abstract

An undeniable disadvantage of wood when using it in construction is its excessive flexibility. One of the ways to increase the stiffness of wooden elements is to use prestressing and reinforcement with stiffer elements. The manufacturing process of pre-stressed bending elements proposed by us is simple. However, determining the necessary effort, the necessary bending of the beam to ensure reliable operation, preventing the destruction of the element is quite difficult. One of the methods of prestressing is described, namely, the method by which the beam receives internal stresses due to the release of the bending element after the action of the external load by gluing reinforced elements. The principle of such tension can be described in the following sequence: 1. We create a bend in the bending element by applying an external load to the element. 2. We reinforce the lower zone of the bending element. At the same time, we need to know under which stress-strained state the reinforced element was installed, so that its operation can be predicted. 3. We remove the applied force with which we created the bend in the flexible wooden element, while the element wants to acquire its original shape, but this will be prevented by the armature, which will absorb part of the load and leave a small bend. It was established that the level of prestressing, namely the curvature acquired by the bending element after prestressing, depends on the initial curvature of the wooden element, as well as on the area and physical and mechanical characteristics of the materials reinforcing the beam zones. To determine the prestress, it is necessary to establish the stress-deformed states of the bending element, which occur after gluing and release of the external force. At the same time, 3 levels of the stress-strain state can be distinguished. 1. At the first stage, the compressed zone is more than the stretched zone. The relative deformations of the compressed lower zone, where the material is to be attached, is the initial start for the work of the reinforced element. 2. At the second stage, the external bending moment decreases, the internal redistribution of forces takes place, in addition to the moment perceived by the compressed and stretched zone, a moment also occurs in the stretched reinforced element. 3. The third stage is characterized by the absence of an external load, and this causes a balance between the internal forces of the bending prestressed element. The equilibrium equation for three stages was obtained. When using the element as a load-bearing structure, the cross-section in the element can be with both positive and negative curvature. The peculiarities of these two stress-strain states are manifested in the change in the position of the compressed and stretched zones. In the first case, the compressed zone is located in the lower part of the element and the upper part is occupied by the stretched zone. After the curvature changes its sign from negative to positive, the upper part becomes compressed, and the lower part becomes stretched. As a result of the simulation, it is possible to conclude that the cross-section of a bending wooden element undergoes 3 main stress-deformed states during prestressing and two during its operation
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钢筋预应力木构件的工作模拟
在建筑中使用木材时,不可否认的缺点是其过度的灵活性。增加木构件刚度的方法之一是采用预应力和加劲构件加固。我们提出的预应力弯曲元件的制作工艺简单。然而,确定必要的努力,必要的弯曲梁,以确保可靠的运行,防止破坏的元素是相当困难的。本文描述了预应力的一种方法,即,在外部荷载作用后,通过粘合增强元件,使梁受到由于弯曲元件释放而产生的内应力的方法。这种张力的原理可以用以下顺序来描述:我们通过向弯曲元件施加外部负载来在该元件中创建弯曲。2. 我们加固了弯曲单元的下部区域。同时,我们需要知道加固单元是在何种应力-应变状态下安装的,以便预测其运行情况。3.。我们消除了在柔性木制元件中产生弯曲的作用力,而元件想要获得其原始形状,但这将被电枢阻止,电枢将吸收部分负载并留下一个小弯曲。确定了预应力水平,即弯曲单元在预应力后获得的曲率,取决于木制单元的初始曲率,以及加强梁区的材料的面积和物理力学特性。为了确定预应力,需要建立弯曲单元在粘接和外力释放后的应力变形状态。同时,可以区分出应力-应变状态的3个等级。1. 在第一阶段,压缩区大于拉伸区。被压缩的下部区域的相对变形,也就是材料被附着的地方,是加固单元工作的初始开始。2. 在第二阶段,外部弯矩减小,内部发生力的重新分配,除了压缩和拉伸区感知到的弯矩外,被拉伸的加筋单元也出现了弯矩。3.。第三阶段的特点是没有外部载荷,这导致弯曲预应力元件的内力之间的平衡。得到了三个阶段的平衡方程。当单元用作承重结构时,单元内的截面既可以具有正曲率,也可以具有负曲率。这两种应力-应变状态的特殊性表现在压缩区和拉伸区位置的变化上。在第一种情况下,压缩区位于单元的下部,上部被拉伸区占据。曲率由负变为正后,上半部分被压缩,下半部分被拉伸。仿真结果表明,弯曲木构件的截面在预应力过程中经历了3种主要的应力变形状态,在运行过程中经历了2种主要的应力变形状态
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