基于纳米粒子改性聚丙烯纤维的功能材料

Q3 Engineering
O. Tchaikovskaya, E. Bocharnikova, I. Lysak, T. Malinovskaya, G. Lysak, I. Plotnikova, S. Sakipova
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引用次数: 0

摘要

聚丙烯纤维表面的形成和改性为各种应用提供了一种通用材料。本研究考察了通过聚丙烯熔体射流的气动喷涂生产新材料的情况,在聚丙烯熔体射流表面使用溶胶-凝胶技术和光还原,然后进行超高频处理制备金属和金属氧化物纳米颗粒。我们使用所获得的材料来去除光反应器中的双酚A。在分析所获得的喷射区数值特征值和所考虑标准的物理本质的基础上,提出了纤维成型系统形成时熔体射流破坏的机制。用电子光谱法和荧光光谱法对双酚A的降解进行了分析。聚丙烯纤维表面的复合活性层“聚合物-无机纳米颗粒”已被证明可以创造新的光催化材料。水中的双酚A被检测为有毒物质。在分析所获得的喷雾区数值特性值和所考虑标准的物理本质的基础上,熔体的流变性能是影响气动喷涂超细纤维形态和尺寸的主要因素。经测定,基于最大直径为6.71μm的聚丙烯载体的材料对双酚a具有最佳的吸附能力。在聚丙烯存在下,在30分钟的紫外线照射下,水中双酚a的浓度降低了两倍以上,而无需额外注入氧化剂。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Functional Materials based on Nanoparticle Modified Polypropylene Fibers
The formation and modification of the surface of polypropylene fibers provides a versatile material for a variety of applications. This research examines the production of new materials by pneumatic spraying of a polypropylene melt jet, on the surface of which metal and metal oxide nanoparticles are prepared using the sol-gel technique and photoreduction followed by ultra-high frequency processing. We used the obtained materials to remove Bisphenol A in the photoreactor. Based on an analysis of the obtained values of the numerical characteristics in the spray zone and the physical essence of the criteria under consideration, a mechanism for the destruction of the melt jet from the formation of a fiber-forming system is proposed. Analysis of the degradation of Bisphenol A was carried out by electron spectroscopy and fluorescence. A composite active layer, “polymer – inorganic nanoparticles”, on the surface of polypropylene fibers has been demonstrated to create new photocatalytic materials. Bisphenol A in water was examined as a toxicant. Based on the analysis of the obtained values of the numerical characteristics in the spray zone and the physical essence of the considered criteria, it was found that the pressure drop in the nozzle, the nozzle critical section area, and the rheological properties of the melt are dominating factors in the influence on the morphology and size of the ultra-fine fibers obtained by pneumatic spraying. It was determined that materials based on a polypropylene carrier with the largest diameter of 6.71 μm have the best sorption capacity for Bisphenol A. A decrease in the concentration of bisphenol A in water by more than two times in 30 minutes of UV irradiation in the presence of polypropylene was achieved without additional injection of oxidants.
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来源期刊
Micro and Nanosystems
Micro and Nanosystems Engineering-Building and Construction
CiteScore
1.60
自引率
0.00%
发文量
50
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