Abstract
Currently, carbon fiber composite has been applied in the field of three-dimensional printing to produce the high-performance parts with complex geometric features. This technique comprise both the advantages of three-dimensional printing and the material, which are light weight, high strength, integrated molding, and without mold, and the limitation of model complexity. In order to improve the performance of three-dimensional printing process using carbon fiber composite, in this article, a novel molding process of three-dimensional printing for continuous carbon fiber composites is developed, including the construction of printing material, the design of printer nozzle, and the modification of printing process. A suitable structure of nozzle on the printer is adjusted for the continuous carbon fiber composites. For the sake of ensuring the continuity of composited material during the processing, a cutting algorithm for jumping point is proposed to improve the printing path during process. On this basis, the experiment of continuous carbon fiber composite is performed and the mechanical properties of the printed test samples are analyzed. The results show that the tensile strength and bending strength of the sample printed by polylactic acid–continuous carbon fiber composites increased by 204.7% and 116.3%, respectively compared with pure polylactic acid materials, and those of the sample printed by nylon–continuous carbon fiber composites increased by 301.1% and 17.4% compared with pure nylon materials, and those of test sample by nylon–continuous carbon fiber composites under the heated and pressurized treatment increased by 383.6% and 233.2% compared with pure nylon material.
Highlights
Nowadays, three-dimensional (3D) printing with carbon fiber (CF) attracts more and more attentions in both academic and industrial applications
continuous carbon fiber composites (CCFCs) can make up this shortcoming, but many questions exist to be solved for 3D printing with CCFC, such as the continuity of feeding, the jumping of nozzle, the cutting of composites, and the control of multi-process parameters
The results show that the tensile strength and bending strength of 3D-printed test sample by polylactic acid (PLA)-CCFC increased by 204.7% and 116.3%, respectively, compared with pure PLA materials and that of the sample printed by Nylon-CCFC increased by 301.1% and 17.4%, respectively, compared with pure nylon materials, and that of the sample printed by Nylon-CCFC under the heated and pressurized treatment increased by 383.6% and 233.2%, respectively, compared with pure Nylon material
Summary
Three-dimensional (3D) printing with carbon fiber (CF) attracts more and more attentions in both academic and industrial applications. It is found that the short carbon fiber (SCF) enhances the acrylonitrile butadiene styrene (ABS)/PLA material in a certain degree, the effect is not evident enough to reflect sufficiently the excellent performance of CF.[19,20] CCFC can make up this shortcoming, but many questions exist to be solved for 3D printing with CCFC, such as the continuity of feeding, the jumping of nozzle, the cutting of composites, and the control of multi-process parameters. From the respects of technology and performance, Chuncheng Yang et al introduced the process of ABS-CCFC in detail and tested the performance of printing model This increased the in-plane mechanical properties by a factor of 2–5, but a limiting factor was the interlaminar shear properties of the printed part.[24] within this method, CCF and thermoplastic resin are mixed at the melt area of the nozzle, which aids the non-uniform distribution of CF in the resin and eliminates the need of mixing due to the small melting area. This article contributes a new reference and data support to the applications of molding process of continuous CF 3D printing
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