Analytical description of adjustment of rolls for manufacturing parts from elastic sheet material

Q3 Mathematics

Eastern-European Journal of Enterprise Technologies Pub Date : 2024-02-28 DOI:10.15587/1729-4061.2024.298427

S. Pylypaka, Vyacheslav Hropost, T. Volina, T. Kresan, Serhii Borodai

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引用次数: 0

Abstract

The object of research is the process of bending sheet material, taking into account its springiness. When manufacturing sheet parts by bending from a completely elastic sheet, its shape is completely restored after the deformation stops, unlike an elastic sheet. Thus, when producing cylindrical parts by drawing between three rolls, the resulting radius of the cylindrical part will be larger than the calculated one. This phenomenon is evaluated by the coefficient of springing – the ratio of the calculated radius to the one obtained after partial expansion. When manufacturing conical parts, this approach cannot be applied, because the value of the radius is variable. The article applies the theory of surface bending from differential geometry. The curvature of the line on the surface has two components - normal and geodesic. When the surface is bent, the normal component changes, while the geodesic component remains unchanged. The magnitude of the normal component depends on the angle between the origin of the cone and its axis. So, for a cone with a base of radius R and an angle of 20°, the normal curvature is 0.94/R, and the geodesic curvature is 0.34/R. For cylindrical parts, the geodesic curvature of the cross-section (circle) is zero, so it is not necessary to take it into account. Usually, adjustment of rolls for the production of conical parts is carried out experimentally. The difference of the proposed approach lies in the elimination of this problem thanks to the decomposition of the curvature of the base of the cone into two components. This allows to calculate the settings of the rolls and thereby reduce their adjustment time. The parameters of the rolls and their mutual placement are calculated for the production of conical parts of the required size, taking into account their springiness. The field of application of the obtained results is the production of parts by bending flat metal sheet blanks

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用弹性板材制造零件时轧辊调整的分析说明

研究对象是考虑到板材弹性的板材弯曲工艺。与弹性板材不同，用完全弹性板材弯曲制造板材零件时，变形停止后其形状会完全恢复。因此，通过在三个轧辊之间拉伸来生产圆柱形零件时，所得到的圆柱形零件半径会大于计算结果。这种现象用弹力系数来评估，即计算半径与部分膨胀后所得半径的比值。在生产圆锥形零件时，不能使用这种方法，因为半径值是可变的。文章应用了微分几何中的表面弯曲理论。曲面上直线的曲率有两个分量--法线和测地线。曲面弯曲时，法线分量发生变化，而测地线分量保持不变。法线分量的大小取决于圆锥的原点与其轴线之间的夹角。因此，对于底面半径为 R、夹角为 20°的圆锥，法线曲率为 0.94/R，大地曲率为 0.34/R。对于圆柱形零件，横截面（圆）的测地曲率为零，因此无需将其考虑在内。所提议方法的不同之处在于，由于将锥体底部的曲率分解为两个部分，从而消除了这一问题。这样就可以计算轧辊的设置，从而减少调整时间。轧辊参数及其相互位置的计算是为了生产出所需尺寸的锥形零件，同时考虑到其弹性。所获成果的应用领域是通过弯曲金属平板坯料生产零件

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

Eastern-European Journal of Enterprise Technologies Mathematics-Applied Mathematics

CiteScore

2.00

自引率

0.00%

发文量

369

审稿时长

6 weeks

期刊介绍： Terminology used in the title of the "East European Journal of Enterprise Technologies" - "enterprise technologies" should be read as "industrial technologies". "Eastern-European Journal of Enterprise Technologies" publishes all those best ideas from the science, which can be introduced in the industry. Since, obtaining the high-quality, competitive industrial products is based on introducing high technologies from various independent spheres of scientific researches, but united by a common end result - a finished high-technology product. Among these scientific spheres, there are engineering, power engineering and energy saving, technologies of inorganic and organic substances and materials science, information technologies and control systems. Publishing scientific papers in these directions are the main development "vectors" of the "Eastern-European Journal of Enterprise Technologies". Since, these are those directions of scientific researches, the results of which can be directly used in modern industrial production: space and aircraft industry, instrument-making industry, mechanical engineering, power engineering, chemical industry and metallurgy.