Characterisation of Sticky Debris Generated During Smear Wear

IF 1.2 4区工程技术 Q4 POLYMER SCIENCE

Rubber Chemistry and Technology Pub Date : 2023-11-07 DOI:10.5254/rct-23.236012

Guangchang Wu, Paul Sotta, Menglong Huang, Lewis B Tunnicliffe, James JC Busfield

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引用次数: 0

Abstract

ABSTRACT Smear wear behavior has often been observed during rubber abrasion, especially under mild test severities. It generates degraded sticky rubber debris that often produces erratic measurements of abrasion weight loss. Various practical methods to avoid or remove the debris from the abrasion test surface have been reported, such as applying a drying powder lubricant. However, the detailed mechanism of smear wear behavior is still not clear. Various characterization techniques are applied to investigate the smear wear of both an unfilled NR model compound and a commercial carbon black (CB)–filled SBR tire tread compound obtained during blade abrasion testing. The debris showed lower molecular weight and higher oxygen content than the virgin materials. In addition, 75% of the smear wear was found to be de-crosslinked during smear wear, as detected by the double quantum-NMR technique. For the first time, it is demonstrated that both the polymer itself and crosslinking points are broken down during smear wear. The effect of the smear layer on friction and abrasion is also discussed.

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涂抹磨损过程中产生的粘性碎屑的特征

在橡胶磨损过程中经常观察到涂抹磨损行为，特别是在轻度试验严重程度下。它会产生降解的粘性橡胶碎片，通常会产生不稳定的磨损重量损失测量。已经报道了各种避免或去除磨损试验表面碎屑的实用方法，例如应用干粉润滑剂。然而，涂层磨损行为的具体机理尚不清楚。采用各种表征技术来研究在叶片磨损测试中获得的未填充NR模型化合物和商用炭黑(CB)填充SBR轮胎胎面化合物的涂抹磨损。与原始材料相比，碎屑的分子量更低，氧含量更高。此外，通过双量子核磁共振技术检测，发现在涂抹磨损过程中，75%的涂抹磨损是去交联的。这是第一次证明聚合物本身和交联点在涂抹磨损过程中都被破坏。讨论了涂抹层对摩擦磨损的影响。

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.