PHENOMENOLOGICAL KINETIC EQUATION OF THE CONVERSION FOR A BINDER OF COMPOSITE MATERIALS BASED ON ISOTHERMAL TESTS

Q3 Materials Science

PNRPU Mechanics Bulletin Pub Date : 2023-01-01 DOI:10.15593/perm.mech/2023.1.07

A. V. Kondyurin, V. Pestrenin, I. Pestrenina, L. V. Landik

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Abstract

In the problems of technological mechanics: the manufacture of structures from composites, packaging and deployment of products from prepreg for space purposes, and others, it becomes necessary to calculate the current mechanical properties of a composite material with an incompletely cured binder. Such properties are determined primarily by the binder state, which may be described by the conversion kinetic equation. The parameters of the kinetic equation depend on many factors: temperature, diffusion, the presence of a catalytic system, modifiers, reagents, the formation of by-products of kinetic reactions, the evaporation of reagents, the effect of radiation, etc. Reliable consideration of the influence of each factor in the kinetic equation turns out to be practically impossible. Therefore, most authors use the phenomenological conversion equation based on experimental data, since these data reflect all the features of the kinetic process. We consider the first order conversion equation, which takes into account auto-acceleration and auto-deceleration. The equation parameters are determined on the basis of isothermal experimental data by the following method. The equation for the conversion rate is integrated, the integral is used to construct a system of equations containing experimental data and the desired approximation parameters, which are determined by standard mathematical methods. The dependence of the kinetic equation parameters on temperature is also constructed by approximation. Examples of constructing conversion equations for a two-component and industrial multicomponent Barnes mixture are given. It is shown that the parameters of the kinetic equation in both cases significantly depend on temperature, and for a multicomponent mixture this dependence is more complicated due to the simultaneous implementation of several reactions. Examples of using the obtained kinetic equation to calculate the curing degree of samples under a given temperature loading are given.

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基于等温试验的复合材料粘结剂转化现象动力学方程

在技术力学问题中:从复合材料制造结构，包装和部署用于空间目的的预浸料产品，以及其他，有必要计算具有未完全固化粘合剂的复合材料的当前机械性能。这些性质主要由粘合剂状态决定，而粘合剂状态可以用转化动力学方程来描述。动力学方程的参数取决于许多因素:温度、扩散、催化体系的存在、改性剂、试剂、动力学反应副产物的形成、试剂的蒸发、辐射的作用等。可靠地考虑动力学方程中每个因素的影响实际上是不可能的。因此，大多数作者使用基于实验数据的现象学转换方程，因为这些数据反映了动力学过程的所有特征。我们考虑了一阶转换方程，其中考虑了自加速和自减速。根据等温实验数据，用以下方法确定了方程参数。对转换率方程进行积分，用积分建立一个包含实验数据和所需近似参数的方程组，用标准数学方法确定。通过近似建立了动力学方程参数对温度的依赖关系。给出了双组分和工业多组分巴恩斯混合物转换方程的构造实例。结果表明，在这两种情况下，动力学方程的参数明显依赖于温度，而对于多组分混合物，由于同时进行几个反应，这种依赖关系更为复杂。给出了在给定温度载荷下，用所得到的动力学方程计算试样固化度的实例。

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

PNRPU Mechanics Bulletin Materials Science-Materials Science (miscellaneous)

CiteScore

1.10

自引率

0.00%

发文量