SULFUR VULCANIZATION OF LOW- VERSUS HIGH-UNSATURATED RUBBERS (IIR AND EPDM VERSUS NR AND BR): PART II—NETWORK STRUCTURE AND TENSILE PROPERTIES

IF 1.2 4区工程技术 Q4 POLYMER SCIENCE

Rubber Chemistry and Technology Pub Date : 2023-08-28 DOI:10.5254/rct.23.76991

C. Gögelein, M. van Duin

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引用次数: 0

Abstract

Sulfur vulcanization is the most common crosslinking technology for unsaturated rubbers. To enhance our generic understanding of the structure–property relationships for sulfur-vulcanized rubber networks, we have studied two low-unsaturated rubbers, IIR and EPDM, and two high-unsaturated rubbers, NR and BR, at varying levels of sulfur curatives. In the first part of this series, the rheometer torque maximum and the compression set as a function of the temperature were discussed. In this second part, the effects of the level of the rubber unsaturation, the density of the trapped entanglements, and the chemical crosslink density on the network structure and tensile properties are discussed quantitatively. Our results reveal that the networks of the vulcanized BR and EPDM consist mainly of trapped entanglements. For EPDM and IIR, all unsaturation can be fully converted to sulfur crosslinks. The tensile strength at break (TS) of vulcanized EPDM and BR is independent of the permanent network density, which is the sum of the chemical crosslink density and the trapped entanglements. The TS shows a pronounced maximum versus the permanent crosslink density for vulcanized IIR and NR, due to the absence of the reinforcing effect of strain-induced crystallization (SIC) at low crosslink densities and the suppression of SIC at high crosslink densities. The elongation at break decreases with increasing network density, following a power-law relation. Mooney–Rivlin analysis of the stress–strain curves confirms our findings of the network structure as obtained from rheometry. However, an unexpected, curved course of the second Mooney–Rivlin parameter as a function of the varying sulfur content is observed for the EPDM samples, indicating that vulcanized EPDM has a different, entanglement-dominated network structure in contrast to IIR, NR, and BR.

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低不饱和橡胶与高不饱和橡胶(iir和epdm与nr和br)的硫硫化:第二部分-网络结构和拉伸性能

硫硫化是不饱和橡胶最常用的交联工艺。为了加强我们对硫硫化橡胶网络结构-性能关系的一般理解，我们研究了两种低不饱和橡胶(IIR和EPDM)和两种高不饱和橡胶(NR和BR)在不同硫硫化剂水平下的结构-性能关系。在本系列的第一部分中，讨论了流变仪的最大扭矩和压缩集作为温度的函数。在第二部分中，定量地讨论了橡胶不饱和水平、被困缠结密度和化学交联密度对网络结构和拉伸性能的影响。结果表明，硫化橡胶和三元乙丙橡胶的网状结构主要由被困缠结组成。对于EPDM和IIR，所有的不饱和都可以完全转化为硫交联。硫化EPDM和BR的断裂拉伸强度与永久网络密度无关，永久网络密度是化学交联密度和被困缠结之和。由于在低交联密度下没有应变诱导结晶(SIC)的增强作用，而在高交联密度下对SIC的抑制作用，硫化IIR和NR的TS对永久交联密度有显著的最大值。断裂伸长率随网络密度的增加呈幂律关系降低。应力-应变曲线的Mooney-Rivlin分析证实了我们从流变学中得到的网络结构的发现。然而，在EPDM样品中，第二个Mooney-Rivlin参数作为硫含量变化的函数出现了一个意想不到的曲线过程，这表明与IIR、NR和BR相比，硫化EPDM具有不同的、以缠结为主的网络结构。

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

Rubber Chemistry and Technology 工程技术-高分子科学

CiteScore

3.50

自引率

20.00%

发文量

审稿时长

3.6 months

期刊介绍： The scope of RC&T covers: -Chemistry and Properties- Mechanics- Materials Science- Nanocomposites- Biotechnology- Rubber Recycling- Green Technology- Characterization and Simulation. Published continuously since 1928, the journal provides the deepest archive of published research in the field. Rubber Chemistry & Technology is read by scientists and engineers in academia, industry and government.