On calculation of stress-strain state of steel closed ropes in extension and twisting. Part 1. Determination of generalized stiffness and deformation coefficients

IF 0.6 Q4 METALLURGY & METALLURGICAL ENGINEERING

CIS Iron and Steel Review Pub Date : 2021-12-29 DOI:10.17580/cisisr.2021.02.04

V. Danenko, L. Gurevich

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引用次数: 1

Abstract

Closed hoisting ropes are related to multi-layer ropes with single laying and they are used as a motive component in lifting and transportation machines and mechanisms. It is known that closed hoisting ropes are used as a rod core for transmission of reciprocating and rotating motion from a surface drive to an operating body of well pump in oil production from wells [1, 2]. Closed ropes are often failing to operate owing to structure violation, such as buckling, lamination, unlocking and destruction of external Z-shape wires etc. [2–6]. To provide reliable and safe rope operation, it is necessary to have trustworthy methods for determination of stress-strain state (SSS) of role elements (wires and layers). The main approaches to theoretical SSS investigation for rope elements were discussed in the works [3, 4, 7–10]. The paper [7] attract attention to the techniques providing higher calculation precision and maximal approximation to construction of the real rope. These techniques are based on the following ideas: a) discrete model where rope is presented as a complicated and statically undefined rod system that can be subjected to calculation by the methods of building mechanics [3]; b) the theory of fiber composites and solution of the SaintVenant problem for a cylinder with screw anisotropy [8]. The mathematical model, where each rope layer is considered from the point of view of energetic approach as anisotropic cylinder shell equivalent with its elastic properties, while a rope in general is considered as the system of cylinder shells inserted inside each other and mutually contacting due to contact pressure and friction, is suggested in the works [11, 12]. Independently of the used techniques, the expressions for determination of force parameters in cross section of rope elements during joint extension and rotation are described as the system including two equations [3]:

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钢闭绳拉伸和扭转时应力-应变状态的计算。第1部分。广义刚度和变形系数的确定

闭式起重绳索是一种单层多层绳索，在起重运输机械和机构中用作动力部件。众所周知，在油井采油过程中，封闭式提升绳作为抽油杆芯，用于将地面驱动器的往复和旋转运动传递到油井泵的操作体中[1,2]。封闭绳索经常由于结构破坏而无法运行，如外部z形钢丝的屈曲、层压、解锁和破坏等[2-6]。为了保证钢丝绳的安全可靠运行，需要有可靠的作用元件(钢丝绳和层)应力-应变状态(SSS)测定方法。文献[3,4,7 - 10]讨论了绳件SSS理论研究的主要方法。本文关注的是能够提供更高的计算精度和最大程度地逼近实绳构造的技术。这些技术基于以下思想:a)离散模型，其中绳子被呈现为一个复杂的、静态未定义的杆系统，可以通过建筑力学[3]方法进行计算;b)纤维复合材料理论及螺旋各向异性圆柱体的sainvenant问题的求解。文献[11,12]提出了一种数学模型，从能量方法的角度将每一层绳视为具有弹性的各向异性筒壳，而将一根绳一般视为由于接触压力和摩擦而相互插入并相互接触的筒壳系统。与所采用的技术无关，确定关节伸展和旋转过程中绳单元横截面受力参数的表达式描述为包含两个方程[3]的系统:

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来源期刊

CIS Iron and Steel Review METALLURGY & METALLURGICAL ENGINEERING-

CiteScore

2.50

自引率

12.50%

发文量

期刊介绍： “CIS Iron and Steel Review” is the only Russian metallurgical scientific-technical journal in English, publishing materials about whole spectrum of the problems, innovations and news of foreign iron and steel industry. The mission of this edition is to make foreign specialists aware about scientific and technical researches and development in iron and steel industry in the former USSR countries.