Popescua, D., Zapciua, A., Amzab, C., Baciuc, F., & Marinescu, R. Comparison of osteointegration property between PEKK and PEEK: Effects of surface structure and chemistry. Yuan, B., Cheng, Q., Zhao, R., Zhu, X., Yang, X., Yang, X., Zhang, K., Song, Y., & Zhang, X. Thermal localization improves the interlayer adhesion and structural integrity of 3D printed PEEK lumbar spinal cages. 3D printing PLA waste to produce ceramic based particulate reinforced composite using abundant silica-sand: Mechanical properties characterization. Composites Part B: Engineering, 172, 671–678.Īhmed, W., Siraj, S., & Al-Marzouqi, A. 3D printed antibacterial silver nanowire/polylactide nanocomposites. Polymer Testing, 63, 251–262.īayraktar, I., Doganay, D., Coskun, S., Kaynak, C., Akca, G., & Unalan, H. Fused deposition modelling of high temperature polymers: Exploring CNT PEEK composites. Electrically conductive polyetheretherketone nanocomposite filaments: from production to fused deposition modeling. Gonçalves, J., Lima, P., Krause, B., Pötschke, P., Lafont, U., Gomes, J. Evaluation of carbon fiber-embedded 3D printed structures for strengthening and structural-health monitoring. Yao, X., Luan, C., Zhang, D., Lan, L., & Fu, J. Composites Part B: Engineering, 148, 93–103. Impact damage resistance of 3D printed continuous fibre reinforced thermoplastic composites using fused deposition modelling. Composites Part B: Engineering, 175, 107147.Ĭaminero, M. Mechanical characterization of FDM 3D printing of continuous carbon fiber reinforced PLA composites. Heidari-Rarani, M., Rafiee-Afarani, M., & Zahedi, A. Effect of thermal processing and heat treatment condition on 3D printing PPS properties. 3D printing of thermoplastic PI and interlayer bonding evaluation. Effects of nozzle temperature and building orientation on mechanical properties and microstructure of PEEK and PEI printed by 3D-FDM. BioMed Research International, 2018, 7.ĭing, S., Zou, B., Wang, P., & Ding, H. Adhesion and proliferation of osteoblast-like cells on porous polyetherimide scaffolds. Effect of ultrasonic vibration on mechanical properties of 3D printing non-crystalline and semi-crystalline polymers. Li, G., Zhao, J., Wu, W., Jiang, J., Wang, B., Jiang, H., & Fuh, J. Influence of layer thickness and raster angle on the mechanical properties of 3D-printed PEEK and a comparative mechanical study between PEEK and ABS. Wu, W., Geng, P., Li, G., Zhao, D., Zhang, H., & Zhao, J. Thermal processing was another critical factor in achieving higher performance of 3D printing PEEK components. Mechanical and thermal properties had been significantly improved when appropriate substrate temperature parameters were used during the printing process, demonstrating the enormous potential in printing PEEK material. Concurrently, the crystallinity increased by 6.67% to 31.56%. The results indicated that the maximum relative interlayer bonding force was 989.91 N, while comparing to the lowest initial ambient and substrate temperature 60 ☌ and 90 ☌, the optimal tensile and bending strengths both increased by 28.46% and 13.86% to 86.62 MPa and 113.21 MPa under ambient and substrate temperature 90 ☌ and 160 ☌, respectively. Numerous critical properties such as interlayer bonding force, tensile and bending properties, dynamic mechanical properties, and crystallization had been investigated in this work. This study aimed to investigate the thermodynamic properties of thin-structure PEEK samples by printing them under various conditions, including varying substrate and ambient temperature parameters, under a control- method. The design of various 3D printing (3DP) parameters had a significant impact on its mechanical and thermal properties. Poly-ether-ether-ketone (PEEK) was one of the most promising engineering plastics, which had been widely employed in the aerospace, biomedical and automotive industry and manufacturing.
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