具有机械防护和抗雨蚀性能的聚硫化物双功能环氧纳米复合涂料

IF 7.3 2区材料科学 Q1 CHEMISTRY, APPLIED

Progress in Organic Coatings Pub Date : 2025-08-16 DOI:10.1016/j.porgcoat.2025.109598

I.M. Hegazy , W. Weaver , A. Elmarakbi

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引用次数: 0

摘要

本研究提出了一种新型的环氧基纳米复合涂层，该涂层结合了石墨烯纳米片（GNP）和环氧端聚硫化物（EPS35），以提高机械耐久性和抗雨蚀性。开发了一系列具有不同GNP负载（0-0.1 wt%）和EPS35含量（0-20 wt%）的配方，并评估了所选组合物在高速水冲击下的机械性能、粘弹性行为和抗侵蚀性。EPS35提高了灵活性和抗冲击性，由于控制相分离，在15% wt%时性能最佳。GNP的加入表现出浓度依赖效应：在纯环氧树脂中团聚会降低韧性，而在eps35改性的基体中分散会在低浓度下显著提高性能。优化后的配方P-28 （5% EPS35, 0.025% GNP）在芯轴弯曲或冲击测试中没有出现开裂，交联密度增加了223.6%，证实了基体增强的改善。在100巴和150巴的模拟雨水侵蚀下，P-28涂层的性能明显优于商用聚氨酯涂层（CP），材料损耗减少38.9%，抗裂性能提高95.9%。EPS35和GNP的协同作用可以提高材料的变形能力和抗裂能力，而GNP通过阻止裂纹扩展、偏转裂纹路径和衰减应力波来提高结构的完整性。由此产生的双相形态提供了刚度和韧性的最佳平衡。与含有对环境有害的异氰酸酯的CP不同，开发的系统提供了一种更安全、更可持续的替代品。这些发现突出了EPS35/ gnp改性环氧涂层在风力涡轮机叶片保护和其他需要增强抗侵蚀性和长期机械可靠性的应用中的潜力。

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Dual-function epoxy nanocomposite coatings with GNP and polysulphide for mechanical protection and rain erosion resistance

This study presents a novel epoxy-based nanocomposite coating incorporating graphene nanoplatelets (GNP) and epoxy-terminated polysulphide (EPS35) to enhance mechanical durability and rain erosion resistance. A range of formulations with varying GNP loadings (0–0.1 wt%) and EPS35 contents (0–20 wt%) were developed, and selected compositions were assessed for mechanical performance, viscoelastic behaviour and erosion resistance under high-speed water impact. EPS35 improved flexibility and impact resistance, with optimal performance at 15 wt% due to controlled phase separation. GNP addition showed a concentration-dependent effect: while agglomeration in neat epoxy reduced toughness, its dispersion within the EPS35-modified matrix significantly enhanced performance at low concentrations. The optimised formulation, P-28 (5 % EPS35, 0.025 % GNP), exhibited no cracking under mandrel bending or impact testing and showed a 223.6 % increase in crosslink density, confirming improved matrix reinforcement. Under simulated rain erosion at 100 and 150 bar, P-28 significantly outperformed a commercial polyurethane-based coating (CP), with a 38.9 % reduction in material loss and up to 95.9 % improvement in crack resistance. These improvements are attributed to the synergistic roles of EPS35 and GNP: EPS35 enhanced deformation capacity and crack resistance, while GNP improved structural integrity by impeding crack propagation, deflecting crack paths, and attenuating stress waves. The resulting biphasic morphology offered an optimal balance of stiffness and toughness. Unlike CP, which contains environmentally hazardous isocyanates, the developed system provides a safer, more sustainable alternative. These findings highlight the potential of EPS35/GNP-modified epoxy coatings for wind turbine blade protection and other applications requiring enhanced erosion resistance and long-term mechanical reliability.

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来源期刊

Progress in Organic Coatings 工程技术-材料科学：膜

CiteScore

11.40

自引率

15.20%

发文量

577

审稿时长

48 days

期刊介绍： The aim of this international journal is to analyse and publicise the progress and current state of knowledge in the field of organic coatings and related materials. The Editors and the Editorial Board members will solicit both review and research papers from academic and industrial scientists who are actively engaged in research and development or, in the case of review papers, have extensive experience in the subject to be reviewed. Unsolicited manuscripts will be accepted if they meet the journal''s requirements. The journal publishes papers dealing with such subjects as: • Chemical, physical and technological properties of organic coatings and related materials • Problems and methods of preparation, manufacture and application of these materials • Performance, testing and analysis.