Mathematical model of running-in of tribosystems under conditions of boundary lubrication. Part 1. Development of a mathematical model

Problemi tribologii Pub Date : 2023-03-17 DOI:10.31891/2079-1372-2022-107-1-25-33

A. Voitov

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引用次数: 1

Abstract

The paper further developed the methodological approach in obtaining mathematical models that describe the running-in of tribosystems under boundary lubrication conditions.The structural and parametric identification of the tribosystem as an object of simulation of running-in under conditions of extreme lubrication was carried out. It has been established that the processes of running-in of tribosystems are described by a second-order differential equation and, unlike the known ones, take into account the limit of loss of stability (robustness reserve) of tribosystems. It is shown that the nature of tribosystems running-in conditions of extreme lubrication depends on the gain coefficients and time constants, which are included in the right-hand side of the differential equation. It is shown that the processes of running-in of tribosystems depend on the type of the magnitude of the input influence on the tribosystem, the first and second derivatives. The input influence is represented as a product of coefficients and a time constant К0·К2·Т3. This allows us to state that the processes of the tribosystem running-in will effectively take place when the input action (load and sliding speed), will change in time and have fluctuations with positive and negative acceleration of these values from the set (program) value. This requirement corresponds to the running-in program "at the border of seizing".The left part of the equation is the response of the tribosystem to the input signal. Tribosystem time constants Т2 and Т3 have the dimension of time and characterize the inertia of the processes occurring in the tribosystem during running-in. Increasing the time constants makes the process less sensitive to changes in the input signal, the warm-up process increases in time, and the tribosystem becomes insensitive to small changes in load and sliding speed. Conversely, the reduction of time constants makes the tribosystem sensitive to any external changes

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边界润滑条件下摩擦系统磨合的数学模型。第1部分。数学模型的发展

本文进一步发展了获得描述边界润滑条件下摩擦系统磨合的数学模型的方法。以摩擦系统为对象，进行了摩擦系统的结构和参数辨识，并进行了极端润滑条件下的磨合仿真。建立了用二阶微分方程描述摩擦系统磨合过程的方法，与已知的方法不同，该方法考虑了摩擦系统的稳定性损失极限(鲁棒性储备)。结果表明，摩擦系统极端润滑磨合条件的性质取决于微分方程右侧的增益系数和时间常数。结果表明，摩擦系统的磨合过程取决于输入对摩擦系统影响的大小、一阶导数和二阶导数的类型。输入影响表示为系数与时间常数К0·К2·Т3的乘积。这允许我们声明，当输入动作(负载和滑动速度)随时间变化并且随着这些值与设定(程序)值的正加速度和负加速度的波动时，摩擦系统的磨合过程将有效地发生。这一要求对应于“处于捕获边缘”的磨合程序。方程的左边是摩擦系统对输入信号的响应。摩擦系统时间常数Т2和Т3具有时间维度，表征磨合过程中摩擦系统中发生的过程的惯性。增加时间常数使过程对输入信号的变化不敏感，预热过程的时间增加，摩擦系统对载荷和滑动速度的微小变化不敏感。相反，时间常数的减小使摩擦系统对任何外部变化都敏感

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

Problemi tribologii

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审稿时长

10 weeks