Maximizing Performance and Efficiency in 3D Printing of Polylactic Acid Biomaterials: Unveiling of Microstructural Morphology, and Implications of Process Parameters and Modeling of the Mechanical Strength, Surface Roughness, Print Time, and Print Energy for Fused Filament Fabricated (FFF) Bioparts.

Ray Tahir Mushtaq,Yanen Wang,Chengwei Bao,Mudassar Rehman,Shubham Sharma,Aqib Mashood Khan,Elsayed M-Tag Eldin,Mohamed Abbas

International Journal of Biological Macromolecules（2024）

Northwestern Polytech Univ | Chitkara Univ | Univ Chakwal | Future Univ Egypt | King Khalid Univ

Cited 18|Views21

Abstract

Medical stents, artificial teeth, and grafts are just some of the many applications for additive manufacturing techniques like bio-degradable polylactic acid 3D printing. However, there are drawbacks associated with fused filament fabrication-fabricated objects, including poor surface quality, insufficient mechanical strength, and a lengthy construction time for even a relatively small object. Thus, this study aims to identify the finest polylactic acid 3D printing parameters to maximize print quality while minimizing energy use, print time, flexural and tensile strengths, average surface roughness, and print time, respectively. Specifically, the infill density, printing speed, and layer thickness are all variables that were selected. A full-central-composite design generated 20 samples to test the prediction models' experimental procedures. Validation trial tests were used to show that the experimental findings agreed with the predictions, and analysis of variance was used to verify the importance of the performance characteristics (ANOVA). At layer thickness = 0.26 mm, infill density = 84 %, and print speed = 68.87 mm/s, the following optimized values were measured for PLA: flexural strength = 70.1 MPa, tensile strength = 39.2 MPa, minimum surface roughness = 7.8 μm, print time = 47 min, and print energy = 0.18 kwh. Firms and clinicians may benefit from utilizing the developed, model to better predict the required surface characteristic for various aspects afore trials.

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Key words

Bio-degradable material,Optimization,Fused filament fabrication,Mechanical strength,Energy

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Pretraining has recently greatly promoted the development of natural language processing (NLP)
We show that M6 outperforms the baselines in multimodal downstream tasks, and the large M6 with 10 parameters can reach a better performance
We propose a method called M6 that is able to process information of multiple modalities and perform both single-modal and cross-modal understanding and generation
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