Improving the forming quality of fused filament fabrication parts by applied vibration

Purpose The purpose of this study is to investigate the efficiency of applied vibration in improving the forming quality (mechanical property and dynamics characteristics) of fused filament fabrication (FFF) parts. Design/methodology/approach A vibrating FFF three-dimensional printer was set up, wit...

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Bibliographic Details
Published in:Rapid prototyping journal 2020-01, Vol.26 (1), p.202-212
Main Authors: Jiang, Shijie, Siyajeu, Yannick, Shi, Yinfang, Zhu, Shengbo, Li, He
Format: Article
Language:English
Subjects:
3-D printers
Additive manufacturing
Anisotropy
Biodegradable materials
Bond strength
CAD
Component reliability
Computer aided design
Damping ratio
Fused deposition modeling
Mechanical properties
Modal damping
Quality
Rapid prototyping
Raw materials
Resonant frequencies
Scanning electron microscopy
Tensile strength
Tensile tests
Three dimensional printing
Vibration analysis
Viscosity
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Summary:Purpose The purpose of this study is to investigate the efficiency of applied vibration in improving the forming quality (mechanical property and dynamics characteristics) of fused filament fabrication (FFF) parts. Design/methodology/approach A vibrating FFF three-dimensional printer was set up, with which the samples fabricated in different directions were manufactured separately without and with vibration applied. A series of experimental tests, including tensile tests, dynamics tests and scanning electron microscopy (SEM) tests, were performed on these samples to experimentally quantify the effect of applied vibration on their forming quality. Findings It has been found that the applied vibration can significantly increase the tensile strength and plasticity of the samples built in Z-direction, and obviously decrease the orthogonal anisotropy. It can also significantly change the sample’s natural frequency, decrease the resonant response and increase the modal damping ratio, thus improve the anti-vibration capability of FFF samples. In addition, the SEM analysis confirmed that applying vibration into FFF process could improve the forming quality of the fabricated part. Research limitations/implications Future research may be focused on investigating the efficiency of applied vibration in improving the forming quality of parts fabricated by the other additive manufacturing techniques. Practical implications This study helps to improve the reliability of FFF parts and extend the application range of FFF technology. Originality/value A novel method to improve the forming quality of FFF parts is provided and the available information about the performance of dynamics characteristics.
ISSN:1355-2546
1758-7670
DOI:10.1108/RPJ-12-2018-0314