The high velocity oxy-fuel (HVOF) combustion spray process has been demonstrated as a viable approach for producing nano-reinforced semi-crystalline polymer composite coatings by controlling both the particle dwell time and substrate temperature. HVOF sprayed polymer matrix composites incorporating ceramic reinforcements ranging from 7 nm to 100 urn are being studied to bridge between the nano and conventional size scale regimes. Microstructural characterization is being used to analyze the dispersion and distribution of the ceramic reinforcements. The effect of particle size on dispersion and distribution, and the influence of substrate temperature on coating adhesion, have been investigated. Changes in crystallinity, as determined by Thermal Gravimetric Analysis (TGA), are being correlated to nano/multi scale coating microstructures, reinforcement loadings and processing parameter variations. Results of optical and scanning electron microscopy, scratch testing and TGA characterization of the feedstock materials and sprayed coatings will be presented. Coatings of nominal 60 um Nylon-11 with 10 vol. % of nano and micron sized hydrophilic silica reinforcements exhibited ~22 % improvement in scratch resistance compared to pure Nylon-11 coatings. A 15 % improvement in scratch resistance was obtained for coatings containing 10 vol. % of nano scale hydrophilic silica reinforcement.
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机译:高速氧-燃料(HVOF)燃烧喷涂工艺已被证明是通过控制颗粒的停留时间和基材温度来生产纳米增强的半结晶聚合物复合涂层的可行方法。 HVOF喷涂的聚合物基复合材料结合了7纳米至100微米的陶瓷增强材料,正在研究中,以在纳米尺寸和常规尺寸尺寸方案之间架起桥梁。微观结构表征被用于分析陶瓷增强材料的分散和分布。已经研究了粒径对分散和分布的影响,以及基材温度对涂料附着力的影响。通过热重分析(TGA)确定的结晶度变化与纳米/多尺度涂层微结构,增强载荷和加工参数变化相关。将介绍原料和喷涂层的光学和扫描电子显微镜,划痕测试和TGA表征的结果。标称60 um Nylon-11和10 vol。与纯尼龙11涂层相比,纳米级和微米级亲水性二氧化硅增强材料的%表现出约22%的耐刮擦性改善。对于包含10vol。%的涂料,抗划伤性提高了15%。 %的纳米级亲水性二氧化硅增强剂。
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