利用自然启发结构设计改善熔融长丝短碳纤维增强聚酰胺复合材料的抗弯性能

IF 3.1 4区 工程技术 Q2 POLYMER SCIENCE
Kexuan Zhou, Zhaogui Wang
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引用次数: 0

摘要

类珍珠岩仿生微结构和螺旋层叠仿生结构都表现出卓越的抗损伤特性。在此基础上,创新性地将螺旋层间仿生结构的设计理念融入到仿生珍珠岩蜂窝结构的设计中。通过系统研究蜂窝层间堆叠形式的不同螺旋角,并通过四点弯曲试验深入探讨其对结构性能的影响。通过传统的熔融长丝制造(FFF)3D 打印技术,使用短碳纤维增强聚酰胺复合材料(即 PA6-CF)精心制备了机械样品,确保了所设计的生物启发样品的准确性和可靠性。实验结果表明,与均匀重叠结构相比,各种仿生珍珠质蜂窝螺旋结构的弯曲强度和弹性模量都有显著提高。与 SH-11.25 样品相比,SH-7.5 样品的抗弯强度提高了 35.47%,弹性模量提高了 65.10%。为了进一步探究碳纤维的断裂模式,还进行了基于 SEM 的微观结构分析,结果表明珍珠状蜂窝结构中采用的螺旋构造增强了 PA6-CF 复合材料的抗弯能力。亮点 一种新型的生物启发结构被应用于提高熔融长丝制造聚酰胺复合材料的机械性能,其中仿生螺旋螺旋构型被集成到高抗折性的珍珠岩类蜂窝结构中。机械测试结果表明,10°以下的螺旋角可显著改善抗弯强度的结构性能。微结构分析表明,螺旋构造增强了打印聚酰胺复合材料中增强碳纤维的承载功能。利用 FFF 三维打印技术,可以进一步将所提出的生物启发新型结构应用于具有高定制要求的轻质、耐损复合材料领域。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Improving flexural performances of fused filament fabricated short carbon fiber reinforced polyamide composites with natural‐inspired structural design
Both the nacre‐like bionic microstructure and the spiral laminated bionic configuration exhibit superior damage‐tolerance characteristics. On the basis of this observation, the design concept of the bionic helical‐interlayer configuration is innovatively integrated into the design of a bionic nacre‐like honeycomb structure. By systematically studying different spiral angles of honeycomb's interlayer stacking forms, their influence on the structural performance is deeply discussed with four‐point bending tests. Mechanical samples are carefully prepared using short carbon fiber reinforced polyamide composites (i.e., PA6‐CF) through conventional fused filament fabrication (FFF) 3D printing technology, where the accuracy and reliability of the designed bio‐inspired samples are ensured. The experimental results reveal significant improvements in bending strength and elastic modulus across various bionic nacre‐like honeycomb spiral structures compared to uniformly overlap configurations. In particular, the SH‐7.5 sample shows a remarkable 35.47% increase in bending strength and a 65.10% increase in elastic modulus over the SH‐11.25 sample. SEM‐based microstructural analyses are carried out to further explore the fracture mode of the carbon fibers, implied the helical configuration adopted in the nacre‐like honeycomb structure enhances the flexural resistant ability of the PA6‐CF composites. The findings above bear important guiding significance and reference value for the design of lightweight and high damage‐tolerance composite structures.Highlights A novel bio‐inspired structure is implemented to improve the mechanical performance of fused filament fabricated polyamide composites, where the bionic spiral helical configuration is integrated into high‐fracture‐resistance nacre‐like honeycomb structures. Mechanical testing results indicate that a helix angle under 10° results in a significant improvement in the structural performance of flexural strength. Microstructural analysis reveals that the helical configuration enhances the load‐bearing functionality of reinforcing carbon fibers in the printed polyamide composites. FFF 3D printing enables further implementation of the proposed bio‐inspired novel structure for lightweight and damage‐tolerant composite applications with high customization demands.
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来源期刊
Polymers for Advanced Technologies
Polymers for Advanced Technologies 工程技术-高分子科学
CiteScore
6.20
自引率
5.90%
发文量
337
审稿时长
2.1 months
期刊介绍: Polymers for Advanced Technologies is published in response to recent significant changes in the patterns of materials research and development. Worldwide attention has been focused on the critical importance of materials in the creation of new devices and systems. It is now recognized that materials are often the limiting factor in bringing a new technical concept to fruition and that polymers are often the materials of choice in these demanding applications. A significant portion of the polymer research ongoing in the world is directly or indirectly related to the solution of complex, interdisciplinary problems whose successful resolution is necessary for achievement of broad system objectives. Polymers for Advanced Technologies is focused to the interest of scientists and engineers from academia and industry who are participating in these new areas of polymer research and development. It is the intent of this journal to impact the polymer related advanced technologies to meet the challenge of the twenty-first century. Polymers for Advanced Technologies aims at encouraging innovation, invention, imagination and creativity by providing a broad interdisciplinary platform for the presentation of new research and development concepts, theories and results which reflect the changing image and pace of modern polymer science and technology. Polymers for Advanced Technologies aims at becoming the central organ of the new multi-disciplinary polymer oriented materials science of the highest scientific standards. It will publish original research papers on finished studies; communications limited to five typewritten pages plus three illustrations, containing experimental details; review articles of up to 40 pages; letters to the editor and book reviews. Review articles will normally be published by invitation. The Editor-in-Chief welcomes suggestions for reviews.
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