采用增材技术制备的复合材料的物理力学性能研究

V. Solovei, V Vitalii Oleksyshen
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引用次数: 0

摘要

聚合物在人类生活各个领域的广泛应用,要求以聚合物基体和增强填料为基础,创造新的更有效的复合材料,以其特性满足社会日益增长的需求。在现代工业中,生产速度不断提高,因此增材制造技术正在成为传统单一和小规模生产的有力替代方案。在现有的增材技术类型中,熔融沉积建模(FDM)方法值得特别关注,它提供了在有限的材料、时间和人力资源条件下组织生产的机会。与传统的生产技术(如注塑成型)相反,FDM允许您使用聚合物基质和增强填料的不同组合来创建更复杂几何形状的产品,从而创建具有所需物理机械,流变学和其他性能的复合材料。同时,FDM的主要优点也引起了一些严重的缺点,如成品性能的各向异性,印刷缺陷导致次品产量增加,物理和机械性能不均匀等。特别是,fdm打印产品性能的各向异性导致零件在3D打印方向(股叠加方向)的横向强度明显低于纵向强度,高分子材料股中增强纤维的不连续导致强度降低。使用FDM方法在3D打印机上实现产品制造过程现代化的主要研究领域是:3D打印机组件和结构的现代化,以改进熔化过程和材料分层,旨在提高打印质量和速度,并减少次品产量;改善原材料的性能,创造复合材料,以提高成品的质量及其特性,如电气、化学、机械、热学、环境等;新生物聚合物的开发,其生产技术和3d打印的使用,未来计划用于创造人体的仿生部分等。为了克服FDM技术的主要缺点,建议对3D打印方法和3D打印机的挤出机单元进行现代化改造,使其能够直接(直接在挤出机中)使用聚合物基质和固体增强纤维的不同组合来创建复合材料。
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Investigation of the physical and mechanical properties of composite materials obtained using additive technologies
The prevalence of polymers in all spheres of human life necessitates the creation of new more effective composite materials based on polymer matrices and reinforcing fillers, which by their characteristics meet the growing needs of society. In modern industry, production speeds are constantly increasing, so additive technologies are becoming a powerful alternative to traditional single and small-scale production. Among the existing types of additive technologies, the method of fused deposition modeling (FDM) deserves special attention, which provides an opportunity to organize production in conditions of limited material, time and human resources. As opposite to traditional production technologies, such as injection molding, FDM allows you to create products of more complex geometric shapes, using different combinations of polymer matrices and reinforcing fillers and thus create composite materials with the required physico-mechanical, rheological and other properties. At the same time, the main advantages of FDM also cause a number of serious disadvantages, such as anisotropy of the properties of finished products, printing defects that lead to increased yields of defective products, uneven physical and mechanical properties etc. In particular, the anisotropy of the properties of FDM-printed products results in significantly lower strength of the parts in the transverse direction to the 3D printing direction (strand overlay direction) compared to the longitudinal one, and the discontinuity of the reinforcing fibers in the strands of polymeric material leads to reduced strength. The main areas of research to modernize the process of manufacturing products on a 3D printer using the FDM method are: modernization of components and structures of 3D printers to improve the melting process and layering of materials, aimed at improving print quality and speed, as well as reducing defective yield products; improving the properties of raw materials and creating composite materials to improve the quality of finished products and their characteristics, such as electrical, chemical, mechanical, thermal, environmental, etc .; development of new biopolymers, technologies of their production and use for 3D-printing, which in the future are planned to be used in the creation of bionic parts of human bodies, etc. To overcome the main shortcomings of FDM technology, it is proposed to modernize the method of 3D printing and the extruder unit of the 3D printer, which allows to create composite materials directly (directly in the extruder), using different combinations of polymer matrices and solid reinforcing fibers.
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