Creep of a closed cylindrical tank at hydrostatic pressure

Herald of Dagestan State Technical University. Technical Sciences Pub Date : 2024-01-21 DOI:10.21822/2073-6185-2023-50-4-184-190

M. S. Gatiev, B. M. Yazyev, Yu. P. Ivanova, S. Klyuev

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Abstract

Objective. When constructing the resolving relations of the theory of shells, the validity of the basic assumptions about the material of the structure under consideration is assumed, which is considered homogeneous, isotropic and viscoelastic, i.e. obeying the Maxwell-Gurevich law. The subject to study is a polymer cylindrical shell, rigidly clamped at the base and subject to internal hydrostatic pressure. Method. The problem is reduced to an inhomogeneous differential equation of the fourth degree with respect to the displacement of the middle surface w along the z axis. Since the closed form representation of the solution to this equation is extremely difficult, the search for it is presented numerically, in particular, using the grid method. The creep strain components ε*x, ε*θ, γ*xθ were determined as a linear approximation of the velocity by the Runge-Kutta method. Result. In the process of calculating the shell using moment theory, it was found that as a result of shell creep, tangential stresses increased by more than 12 percent. Conclusion. The proposed technique makes it possible to simulate changes in the mechanical properties of the shell (for example, indirect heterogeneity) caused by the influence of physical fields.

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静水压力下封闭式圆柱形储罐的蠕变

目的。在构建壳理论的解析关系时，假定对所考虑的结构材料的基本假设是有效的，这种材料被认为是均质、各向同性和粘弹性的，即服从麦克斯韦-古列维奇定律。研究对象是一个聚合物圆柱形壳体，底部刚性夹紧，受内部静水压力作用。方法。将问题简化为关于中间表面 w 沿 z 轴位移的四阶不均匀微分方程。由于该方程解的闭式表示极为困难，因此采用数值方法，特别是网格法来寻找。蠕变应变分量 ε*x、ε*θ、γ*xθ 是通过 Runge-Kutta 方法确定的速度线性近似值。计算结果在使用力矩理论计算壳体的过程中发现，由于壳体蠕变，切向应力增加了 12%以上。结论。所提出的技术可以模拟物理场影响导致的壳体机械性能变化（例如间接异质性）。

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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Herald of Dagestan State Technical University. Technical Sciences

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