通过反应性或互穿性分子刷改善弹性硅酮密封胶与难粘合聚合物基材的粘合机理

W. Gutowski, G. Toikka, Sheng Li
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引用次数: 2

摘要

弹性体粘合剂对金属,陶瓷和有机基材的高质量和耐用粘合对于广泛的行业至关重要,例如建筑和建筑,汽车,电子,航空航天,生物医学等。本文讨论了接枝接枝分子在工程基板表面的原理。特别是,两种重要的相互作用模式的表面接枝“分子刷”进行了研究和实验验证。研究表明,在聚合物界面处包含硅烷和/或胺端接枝分子,如硅烷或聚乙烯亚胺,可以在一系列有机衬底和弹性体密封胶之间形成强分子桥,从而显著改善键合。该技术已被全球汽车工业成功采用,用于改善各种粘合剂和涂料对聚烯烃基材的附着力。
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The Mechanism of Adhesion Improvement of Elastomeric Silicone Sealants to Difficult-to-Bond Polymeric Substrates through Reactive or Interpenetrating Molecular Brushes
High-quality and durable adhesion of elastomeric adhesives to metallic, ceramic, and organic substrates is essential to a broad range of industries, e.g., building and construction, automotive, electronic, aerospace, biomedical, and others. The principles of engineering substrate surfaces through grafted connector molecules are discussed in this paper. In particular, two important modes of interaction for surface-grafted “molecular brushes” are investigated and experimentally verified. It is demonstrated that the inclusion of silicone- and/or amine-terminated graft molecules, such as silanes or polyethyleneimines, at polymer interfaces, results in the formation of strong molecular bridges between a range of organic substrates and elastomeric sealants leading to significantly improved bonding. The technology has been successfully adopted by global automotive industry for improving adhesion of a variety of adhesives and coatings to polyolefinic substrates.
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