基于蜻蜓翅脉结构的连续碳纤维增强树脂基复合材料仿生设计与增材制造

doi:10.16085/j.issn.1000-6613.2022-0211

摘要/Abstract

摘要：

以具有轻质高强优异性能的蜻蜓翅脉结构为设计灵感，在分析翅脉网格结构抗冲击原理的基础上，设计了传统和仿生两类对比结构。采用熔融挤出3D打印机成功制备了具有不同结构的连续碳纤维增强聚乳酸复合材料试样，并对不同结构复合材料试样的拉伸性能和抗冲击性能进行了测试和对比分析。研究分析结果表明：由于拉伸力方向上的连续碳纤维含量相对较少，限制了仿生结构复合材料抗拉强度的提高，但仿生结构的平均抗拉强度为传统结构的1.18倍；当仿生结构复合材料试样受到冲击力时，其内部六边形结构的连接角度会发生变化，从而极大消耗冲击能量，同时具有六边形网格结构的连续碳纤维可以有效阻碍裂纹的扩展，因此仿生结构的平均冲击韧性可以达到传统结构的2.46倍；仿生蜻蜓翅脉结构可以显著提高增材制造复合材料的综合力学性能，且对于抗冲击性能的提高具体突出效果。连续碳纤维增强树脂基复合材料的有效可行的仿生蜻蜓翅脉结构设计和增材制造，可极大扩展其在高冲击载荷领域中的相应应用。

关键词: 增材制造, 连续碳纤维增强, 树脂基复合材料, 仿生蜻蜓翅脉结构, 力学性能

Abstract:

The dragonfly wing structure with excellent lightweight and high strength performance was taken as the design inspiration. On the basis of analyzing the impact resistance principle of the wing vein grid structure, the traditional and bionic structures were designed. Continuous carbon fiber reinforced polylactic acid (PLA) composites with different structures were successfully prepared by melt extrusion 3D printer, and the tensile and impact properties of the composites with different structures were tested and analyzed. The results showed that the improvement of the tensile strength of the biomimetic composite was limited by the relatively small content of continuous carbon fiber in the direction of tensile force, but the average tensile strength of the biomimetic composite was 1.18 times that of the traditional structure. When the biomimetic structure composite sample was subjected to impact force, the connection angle of hexagons inside it would change, which would greatly consume impact energy. Meanwhile, the continuous carbon fiber with hexagonal grid structure can effectively hinder the crack propagation, and thus the average impact toughness of biomimetic structure can reach 2.46 times that of traditional structure. Biomimetic dragonfly wing structure can significantly enhance the comprehensive mechanical properties of additive manufacturing composites, and improve the impact resistance of concrete outstanding effect. The effective and feasible structure design and additive manufacturing of continuous carbon fiber reinforced resin matrix composites can greatly expand their corresponding applications in the field of high impact loads.

Key words: additive manufacturing, continuous carbon fiber reinforced, resin matrix composites, bionic dragonfly wing vein structure, mechanical property

中图分类号:

TH164

杨立宁, 郑东昊, 王立新, 杨光. 基于蜻蜓翅脉结构的连续碳纤维增强树脂基复合材料仿生设计与增材制造[J]. 化工进展, 2022, 41(11): 5961-5967.

YANG Lining, ZHENG Donghao, WANG Lixin, YANG Guang. Bionic design and additive manufacturing of continuous carbon fiber reinforced resin matrix composites with dragonfly wing venation structure[J]. Chemical Industry and Engineering Progress, 2022, 41(11): 5961-5967.

图/表 11

图1 连续碳纤维增强聚乳酸复合材料丝材

表1 复合材料丝材制备用原材料

原材料	型号/规格	生产厂家
连续碳纤维	T300/1K	日本东丽
聚乳酸（PLA）	4032D	美国Natureworks

图2 连续碳纤维增强树脂基复合材料增材制造工艺过程及复合材料丝材熔融挤出喷头

图3 蜻蜓翅脉结构及其消耗冲击能量的原理模型

图4 对比试验结构设计与增材制造试样

表2 复合材料增材制造工艺参数

参数	数值
喷头孔径	0.8mm
喷头温度	240℃
基本温度	60℃
送丝速度	5mm/s
打印速度	5mm/s
路径搭接率	40%
打印层厚	0.7mm

图5 不同结构试样拉伸性能测试的应力-应变曲线

图6 不同结构试样的拉伸性能测试结果

图7 不同结构试样的拉伸断裂过程示意图以及结构1和结构3试样拉伸断口处微观形貌

图8 不同结构试样的抗冲击性能测试结果

图9 结构1和结构3试样冲击断裂过程示意图及其冲击断口处微观形貌

参考文献 24

1	YU T Y, ZHANG Z Y, SONG S T, et al. Tensile and flexural behaviors of additively manufactured continuous carbon fiber-reinforced polymer composites[J]. Composite Structures, 2019, 225: 111147.
2	WANG J H, GE X H, LIU Y J, et al. A review on theoretical modelling for shearing viscosities of continuous fibre-reinforced polymer composites[J]. Rheologica Acta, 2019, 58(6/7): 321-331.
3	何亚飞, 矫维成, 杨帆, 等. 树脂基复合材料成型工艺的发展[J]. 纤维复合材料, 2011, 28(2): 7-13.
	HE Yafei, JIAO Weicheng, YANG Fan, et al. The development of polymer composites forming process[J]. Fiber Composites, 2011, 28(2): 7-13.
4	VAIDYA U K, CHAWLA K K. Processing of fibre reinforced thermoplastic composites[J]. International Materials Reviews, 2008, 53(4): 185-218.
5	KANG H R, SHAN Z D, ZANG Y, et al. Effect of yarn distortion on the mechanical properties of fiber-bar composites reinforced by three-dimensional weaving[J]. Applied Composite Materials, 2016, 23(2): 119-138.
6	SHAN Z D, CHEN S S, ZHANG Q, et al. Three-dimensional woven forming technology and equipment[J]. Journal of Composite Materials, 2016, 50(12): 1587-1594.
7	马青松, 陈朝辉, 郑文伟, 等. 树脂传递模塑-复合材料成型新工艺[J]. 材料科学与工程, 2000, 18(4): 92-97.
	MA Qingsong, CHEN Zhaohui, ZHENG Wenwei, et al. Resin transfer molding: a novel shaping process for composite materials[J]. Materials Science and Engineering, 2000, 18(4): 92-97.
8	卢秉恒, 李涤尘. 增材制造(3D打印)技术发展[J]. 机械制造与自动化, 2013, 42(4): 1-4.
	LU Bingheng, LI Dichen. Development of the additive manufacturing(3D printing) technology[J]. Machine Building & Automation, 2013, 42(4): 1-4.
9	VAN DER KLIFT F, KOGA Y, TODOROKI A, et al. 3D printing of continuous carbon fibre reinforced thermo-plastic (CFRTP) tensile test specimens[J]. Open Journal of Composite Materials, 2016, 6(1): 18-27.
10	LI N Y, LI Y G, LIU S T. Rapid prototyping of continuous carbon fiber reinforced polylactic acid composites by 3D printing[J]. Journal of Materials Processing Technology, 2016, 238: 218-225.
11	TIAN X Y, LIU T F, YANG C C, et al. Interface and performance of 3D printed continuous carbon fiber reinforced PLA composites[J]. Composites A: Applied Science and Manufacturing, 2016, 88: 198-205.
12	毕向军, 田小永, 张帅, 等. 连续纤维增强热塑性复合材料3D打印的研究进展[J]. 工程塑料应用, 2019, 47(2): 138-142.
	BI Xiangjun, TIAN Xiaoyong, ZHANG Shuai, et al. Research progress in 3D printing technology of continuous fiber reinforced thermoplastic composites[J]. Engineering Plastics Application, 2019, 47(2): 138-142.
13	BRENKEN B, BAROCIO E, FAVALORO A, et al. Fused filament fabrication of fiber-reinforced polymers: a review[J]. Additive Manufacturing, 2018, 21: 1-16.
14	CHACÓN J M, CAMINERO M A, NÚÑEZ P J, et al. Additive manufacturing of continuous fibre reinforced thermoplastic composites using fused deposition modelling: effect of process parameters on mechanical properties[J]. Composites Science and Technology, 2019, 181: 107688.
15	CAMINERO M A, CHACÓN J M, GARCÍA-MORENO I, et al. Interlaminar bonding performance of 3D printed continuous fibre reinforced thermoplastic composites using fused deposition modelling[J]. Polymer Testing, 2018, 68: 415-423.
16	YANG C C, TIAN X Y, LIU T F, et al. 3D printing for continuous fiber reinforced thermoplastic composites: mechanism and performance[J]. Rapid Prototyping Journal, 2017, 23(1): 209-215.
17	NING F D, CONG W L, HU Y B, et al. Additive manufacturing of carbon fiber-reinforced plastic composites using fused deposition modeling: effects of process parameters on tensile properties[J]. Journal of Composite Materials, 2017, 51(4): 451-462.
18	LUO M, TIAN X Y, SHANG J F, et al. Impregnation and interlayer bonding behaviours of 3D-printed continuous carbon-fiber-reinforced poly-ether-ketone composites[J]. Composites: Applied Science and Manufacturing, 2019, 121: 130-138.
19	WANG F J, ZHENG J Q, WANG G S, et al. A novel printing strategy in additive manufacturing of continuous carbon fiber reinforced plastic composites[J]. Manufacturing Letters, 2021, 27: 72-77.
20	WANG F J, WANG G S, NING F D, et al. Fiber-matrix impregnation behavior during additive manufacturing of continuous carbon fiber reinforced polylactic acid composites[J]. Additive Manufacturing, 2021, 37: 101661.
21	REN L Q, LIANG Y H. Biological couplings: function, characteristics and implementation mode[J]. Science China Technological Sciences, 2010, 53(2): 379-387.
22	LIANG Y H, LIU C, ZHAO Q, et al. Bionic design and 3D printing of continuous carbon fiber-reinforced polylactic acid composite with barbicel structure of eagle-owl feather[J]. Materials, 2021, 14(13): 3618.
23	CHEN R, LIU J F, YANG C J, et al. Transparent impact-resistant composite films with bioinspired hierarchical structure[J]. ACS Applied Materials & Interfaces, 2019, 11(26): 23616-23622.
24	REN L Q, LI X J. Functional characteristics of dragonfly wings and its bionic investigation progress[J]. Science China Technological Sciences, 2013, 56(4): 884-897.

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