Synergistic interlaminar strengthening of high-content continuous fiber reinforced composites via ultrasound and plasma-assisted 3D printing

IF 8.3 1区材料科学 Q1 MATERIALS SCIENCE, COMPOSITES

Composites Science and Technology Pub Date : 2025-01-28 DOI:10.1016/j.compscitech.2025.111079

Weijun Zhu, Long Fu, Quan Zhi, Zhikun Zhang, Ning Wang, Yingying Zhang, Dongsheng Li

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Abstract

Poor interlaminar performance is still the major problem for 3D printing of continuous fiber-reinforced thermoplastic composites, especially when the fiber content is over 50 %. In this work, an ultrasound and plasma-assisted 3D printing method was proposed towards the synergistic interlaminar strengthening. Fiber-matrix interface defects at the interlaminar zone were identified by a comparison study, which are the causes behind the poor interlaminar properties for high fiber content composites. Experimental and modeling approaches were used to study the effects of printing and strengthening parameters on interlaminar properties. The physical and chemical effects of ultrasound and plasma on material microstructure was investigated and a synergistic effect model was presented. The proposed synergistic strengthening method can greatly reduce the porosity, from 14 % to 3 %, enhance interlayer bonding strength, and result in a 54.17 % increase in interlaminar shear strength. Better interlaminar properties have positive implications for other mechanical properties, e.g. the tensile strength and modulus can reach approximately 1254 MPa and 89 GPa, respectively.

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利用超声和等离子体辅助3D打印技术对高含量连续纤维增强复合材料进行层间协同强化

层间性能差仍然是连续纤维增强热塑性复合材料3D打印的主要问题，特别是当纤维含量超过50%时。在这项工作中，提出了一种超声和等离子体辅助的3D打印方法来协同强化层间。通过对比研究，确定了高纤维含量复合材料层间性能差的主要原因是层间区纤维-基体界面缺陷。采用实验和建模方法研究了打印和强化参数对层间性能的影响。研究了超声和等离子体对材料微观结构的物理和化学影响，并建立了协同效应模型。提出的协同强化方法可使孔隙率从14%大幅降低至3%，层间结合强度提高，层间抗剪强度提高54.17%。较好的层间性能对其他力学性能有积极的影响，例如抗拉强度和模量分别可达到约1254 MPa和89 GPa。

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来源期刊

Composites Science and Technology 工程技术-材料科学：复合

CiteScore

16.20

自引率

9.90%

发文量

611

审稿时长

33 days

期刊介绍： Composites Science and Technology publishes refereed original articles on the fundamental and applied science of engineering composites. The focus of this journal is on polymeric matrix composites with reinforcements/fillers ranging from nano- to macro-scale. CSTE encourages manuscripts reporting unique, innovative contributions to the physics, chemistry, materials science and applied mechanics aspects of advanced composites. Besides traditional fiber reinforced composites, novel composites with significant potential for engineering applications are encouraged.