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Markforged 3D打印碳/凯夫拉混合连续纤维复合蜂窝结构耐撞性的实验与仿真研究

Experiment and Simulation Study on the Crashworthiness of Markforged 3D-Printed Carbon/Kevlar Hybrid Continuous Fiber Composite Honeycomb Structures.

作者信息

Ju Jinlong, Yang Nana, Yu Lei, Zhang Zhe, Jiang Hongyong, Wu Wenhua, Ma Guolu

机构信息

College of Shipbuilding Engineering, Harbin Engineering University, Harbin 150001, China.

China Aerodynamics Research and Development Center, Mianyang 621000, China.

出版信息

Materials (Basel). 2025 Jan 5;18(1):192. doi: 10.3390/ma18010192.

DOI:10.3390/ma18010192
PMID:39795837
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11721899/
Abstract

Fiber hybridization can effectively solve the localized brittle fracture problem of composite honeycomb, but the interaction between different fibers leads to a very complex failure mechanism. Hence, 3D-printed hybrid continuous fiber composite honeycombs with a combination of carbon and Kevlar fibers are designed to study the structural failure behaviors by the experiment and simulation method. The experimental samples, including Onyx, carbon, Kevlar, carbon/Kevlar, and Kevlar/carbon composites, are fabricated based on Markforged 3D printing technology, and the crushing tests are conducted to evaluate the failure behaviors. An equivalence finite element modeling method to replace the heterogeneous microstructure of hybrid composites is proposed to analyze the failure behaviors. Results indicate that carbon/Kevlar honeycomb exhibits the highest energy absorption and cost effectiveness, while CFRP honeycomb demonstrates the highest load-carrying capacity. It is found that carbon/Kevlar and Kevlar/carbon honeycombs have significant hybrid effects compared to single-fiber honeycombs, which also reveals the hybrid mechanisms between carbon and Kevlar fibers. Furthermore, the Onyx honeycomb, lacking long fibers, exhibits brittle collapse, whereas other honeycombs show ductile collapse due to the presence of Kevlar fibers. Combining the simulation studies, the damage evolution mechanisms of honeycombs, including fiber/matrix tension and compression, shear damage, interface damage, etc., are further revealed. This work provides valuable insights into the design and failure analysis of 3D-printed hybrid fiber composite honeycombs.

摘要

纤维混杂能够有效解决复合蜂窝材料的局部脆性断裂问题,但不同纤维之间的相互作用会导致非常复杂的失效机制。因此,设计了一种由碳纤和芳纶纤维组合而成的3D打印混杂连续纤维复合蜂窝材料,通过实验和模拟方法研究其结构失效行为。基于Markforged 3D打印技术制备了包括尼龙、碳纤维、芳纶纤维、碳/芳纶以及芳纶/碳复合材料的实验样品,并进行了压缩试验以评估其失效行为。提出了一种等效有限元建模方法来替代混杂复合材料的非均匀微观结构,以分析其失效行为。结果表明,碳/芳纶蜂窝材料具有最高的能量吸收能力和性价比,而碳纤维增强塑料蜂窝材料则具有最高的承载能力。研究发现,与单纤维蜂窝材料相比,碳/芳纶和芳纶/碳蜂窝材料具有显著的混杂效应,这也揭示了碳纤和芳纶纤维之间的混杂机制。此外,缺乏长纤维的尼龙蜂窝材料表现出脆性坍塌,而其他蜂窝材料由于芳纶纤维的存在则表现出韧性坍塌。结合模拟研究,进一步揭示了蜂窝材料的损伤演化机制,包括纤维/基体的拉伸和压缩、剪切损伤、界面损伤等。这项工作为3D打印混杂纤维复合蜂窝材料的设计和失效分析提供了有价值的见解。

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