Modulus of Natural Rubber Cross-Linked by Dicumyl Peroxide. I. Experimental Observations.

Journal of research of the National Bureau of Standards. Section A, Physics and chemistry Pub Date : 1972-09-01 DOI:10.5254/1.3544746

L. Wood, G. W. Bullman, G. Decker

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引用次数: 6

Abstract

Natural rubber mixed with varying amounts of dicumyl peroxide was cross-linked by heating 120 min at 149 °C. The quantitative measure of cross-linking was taken as the amount fp of decomposed dicumyl peroxide, the product of p, the number of parts added per hundred of rubber and f the fraction decomposed during the time of cure. The shear creep modulus G was calculated from measurements of the indentation of a flat rubber sheet by a rigid sphere. The glass transition temperature T g , was raised about 1.2 °C for each part of decomposed dicumyl peroxide. Above (T g + 12) the modulus-temperature relations were linear with a slope that increased with increasing cross-linking. The creep rate was negligible except near the glass transition and at low values of fp. Values of G, read from these plots at seven temperatures, were plotted as a function of fp. The linearity of the two plots permits the derivation of the general relation: G = S(fp + B)T + H(fp + B) + A where A, B, H, and S are constants. The lines representing G as a function of fp at each temperature all intersected near the point, fp = 0.45 phr, G = 2.70 Mdyn cm-2 (0.270 MN m-2). The constants were evaluated as A = 2.70 Mdyn cm-2, B = -0.45 phr, S = 5.925 × 10-3 Mdyn cm-2(phr)-1K-1 and H = 0.0684 (Mdyn cm-2) (phr)-1. This equation represented satisfactorily all the data obtained at temperatures from -50 to +100 °C for values of fp from about 1 to 24 phr.

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过氧化二氨基交联天然橡胶的模量。1 .实验观察。

将天然橡胶与不同量的过氧化二氨基混合，在149℃下加热120 min交联。交联的定量指标为过氧化二氨基的分解量fp、产物p、每百橡胶加入的份数和固化过程中分解的分数f。用刚性球测量橡胶板的压痕，计算了剪切蠕变模量G。过氧化二氨基每部分的玻璃化转变温度提高1.2℃左右。在(T g + 12)以上，模量与温度呈线性关系，斜率随交联的增加而增大。除了在玻璃化转变附近和fp值较低时，蠕变速率可以忽略不计。在7种温度下从这些图中读取的G值被绘制为fp的函数。两个图的线性关系允许推导一般关系:G = S(fp + B)T + H(fp + B) + A，其中A, B, H和S是常数。在每个温度下，代表G作为fp函数的线都在点附近相交，fp = 0.45 phr, G = 2.70 Mdyn cm-2 (0.270 MN m-2)。测定常数为A = 2.70 Mdyn cm-2, B = -0.45 phr, S = 5.925 × 10-3 Mdyn cm-2(phr)-1K-1, H = 0.0684 (Mdyn cm-2) (phr)-1。该方程令人满意地表示了在-50至+100°C温度下fp值约为1至24 phr时获得的所有数据。

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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Journal of research of the National Bureau of Standards. Section A, Physics and chemistry

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