On the Application of a Fractional-Power Rheological Model in the Study of Creep and Long-Term Failure of a Composite Rod Taking into Account the Non-Classical Diffusion Effect of the Active Medium

IF 0.6 4区工程技术 Q4 MECHANICS

Mechanics of Solids Pub Date : 2025-03-18 DOI:10.1134/S0025654424606414

L. V. Fomin

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Abstract

The article considers the application of a singular fractional-power rheological model in modeling creep and long-term failure of a composite tensile rod in an active medium. The singular fractional-power model contains a natural mechanical characteristic – the short-term strength limit at the corresponding temperature. A rod of rectangular cross-section consists of three parts symmetrically located along the width and connected to each other with ideal adhesion without slipping. An additional factor affecting the studied rod system is the influence of the active medium, and a non-classical diffusion process is considered, taking into account the presence of the medium in the material in both free and bound states. Based on the kinetic theory of Yu.N. Rabotnov with two structural parameters, the resulting system of equations for determining the dependences of stresses and damage on time during creep is obtained. A criterial assessment is proposed for determining the time to failure of both individual parts and the entire considered rod system as a whole.

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考虑活性介质非经典扩散效应的分数次流变模型在复合棒蠕变和长期失效研究中的应用

本文考虑了单一分数次流变模型在模拟复合材料拉伸杆在活性介质中的蠕变和长期破坏中的应用。奇异分数幂模型包含了一个自然的力学特征——相应温度下的短期强度极限。一根横截面为矩形的棒材由沿宽度对称分布的三部分组成，三部分相互连接，具有理想的附着力而不打滑。影响研究棒系的另一个因素是活性介质的影响，考虑到介质在材料中的自由态和束缚态的存在，考虑了非经典扩散过程。基于un的动力学理论。用两个结构参数，得到了蠕变过程中应力和损伤随时间变化关系的方程组。提出了一种确定单个部件和整个考虑杆系统作为一个整体的失效时间的标准评估方法。

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来源期刊

Mechanics of Solids 医学-力学

CiteScore

1.20

自引率

42.90%

发文量

112

审稿时长

6-12 weeks

期刊介绍： Mechanics of Solids publishes articles in the general areas of dynamics of particles and rigid bodies and the mechanics of deformable solids. The journal has a goal of being a comprehensive record of up-to-the-minute research results. The journal coverage is vibration of discrete and continuous systems; stability and optimization of mechanical systems; automatic control theory; dynamics of multiple body systems; elasticity, viscoelasticity and plasticity; mechanics of composite materials; theory of structures and structural stability; wave propagation and impact of solids; fracture mechanics; micromechanics of solids; mechanics of granular and geological materials; structure-fluid interaction; mechanical behavior of materials; gyroscopes and navigation systems; and nanomechanics. Most of the articles in the journal are theoretical and analytical. They present a blend of basic mechanics theory with analysis of contemporary technological problems.