评估硫化胶硅橡胶相互作用的新实验方法

IF 3.2 4区 工程技术 Q2 ENGINEERING, CHEMICAL
Weijie Jia, Feifei Lin, Zhibo Li, Hao Zhang, Feng Liu, Yan Yang
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引用次数: 0

摘要

二氧化硅与聚合物之间的相互作用在提高绿色轮胎性能方面的重要性已得到广泛认可。然而,一直以来都缺乏一种标准化的方法来准确表征硫化胶中的这种相互作用。本文介绍了一种表征聚合物与二氧化硅之间相互作用的新方法,重点关注填料负载、偶联剂和硫的含量对这种相互作用的影响。该方法以平衡溶胀实验为基础。在氨气环境中进行溶胀试验有助于消除物理相互作用。因此,得出的交联密度主要包括橡胶基体的交联密度和二氧化硅与聚合物的化学相互作用。用氢氟酸处理硫化胶可消除二氧化硅与橡胶之间的化学作用。在此过程之后,平衡溶胀试验可确定橡胶基体的交联密度。因此,氨处理后和氢氟酸处理后获得的交联密度之间的差异表明聚合物和二氧化硅之间存在化学作用。研究结果表明,与偶联剂双[3-(三乙氧基硅基)丙基]二硫化物相比,偶联剂双[3-(三乙氧基硅基)丙基]四硫化物(TESPT)所促进的聚合物-二氧化硅相互作用的程度明显更高。此外,二氧化硅与聚合物的相互作用还与二氧化硅/TESPT 的负载量和硫含量呈正相关。值得注意的是,本文为通过溶解填料计算交联复合材料中聚合物-填料相互作用提供了一种解决方案和理论依据。该方法也可用于交联聚合物/纳米填料复合材料。TESPT 是一种比 TESPD 更有效的硅烷,甚至可以补偿硫。聚合物与填料的相互作用深受多硫化物-聚合物反应的影响。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Novel experimental approach to evaluate silica–elastomer interactions of vulcanizates
The importance of the silica–polymer interaction in enhancing the performance of green tires is well recognized. However, there has been a lack of a standardized method to accurately characterize this interaction in vulcanizates. This paper introduces a new methodology for characterizing the interaction between polymer and silica, focusing on the impact of filler loading, coupling agents, and amount of sulfur on this interaction. The methodology is based on equilibrium swelling experiments. Conducting the swelling test in an ammonia atmosphere facilitates the elimination of physical interactions. Consequently, the resulting crosslink density predominantly encompasses that of the rubber matrix and the chemical silica–polymer interaction. Treatment of vulcanizates with hydrofluoric acid serves to nullify the chemical interaction between silica and rubber. Following this process, the equilibrium swelling test enables the determination of the crosslink density of the rubber matrix. As such, the disparity between the crosslink densities obtained after ammonia and after the hydrofluoric acid treatment signifies the chemical interaction between the polymer and silica. The findings revealed that the polymer–silica interaction facilitated by the coupling agent bis[3‐(triethoxysilyl)propyl]tetrasulfide (TESPT) exhibited a notably higher magnitude compared to that enabled by the coupling agent bis[3‐(triethoxysilyl)propyl]disulfide. Moreover, the silica–polymer interaction demonstrated a positive correlation with both silica/TESPT loading and sulfur content. It is worth noting that this paper provides one solution and theoretical basis for calculating polymer–filler interactions in crosslinked composites by dissolving fillers.Highlights Experimental method for quantitative evaluation of silica–polymer interaction. The method can also be applied to crosslinked polymer/nanofiller composites. TESPT is a more potent silane than TESPD, even sulfur is compensated. Polymer–filler interaction is deeply affected by polysulfide‐polymer reaction.
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来源期刊
Polymer Engineering and Science
Polymer Engineering and Science 工程技术-高分子科学
CiteScore
5.40
自引率
18.80%
发文量
329
审稿时长
3.7 months
期刊介绍: For more than 30 years, Polymer Engineering & Science has been one of the most highly regarded journals in the field, serving as a forum for authors of treatises on the cutting edge of polymer science and technology. The importance of PE&S is underscored by the frequent rate at which its articles are cited, especially by other publications - literally thousand of times a year. Engineers, researchers, technicians, and academicians worldwide are looking to PE&S for the valuable information they need. There are special issues compiled by distinguished guest editors. These contain proceedings of symposia on such diverse topics as polyblends, mechanics of plastics and polymer welding.
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