A NEW BIO-INSPIRED WING DESIGN WITH 3D ADDITIVE MANUFACTURING SCANNING AND PRINTING METHOD: MJF TECHNOLOGY
Abstract
In this study, unlike many wing profiles currently available, a new wing design has been carried out with bio-inspiration, which has attracted the attention of many scientists. There are many traditional methods in 3d additive manufacturing technologies. There are several types of 3D printing method. The four most preferred 3d printing methods are as follows. Fused Deposition Modeling (FDM), Stereolithography (SLA), Selective Laser Sintering (SLS), Multi Jet Fusion (MJF). MJF technology, one-to-one prototype production of wings with very small dimensions and aerodynamic structure has been achieved. In contrast to FDM and other additive printing technologies, it is possible to eliminate highly sensitive and high surface quality products.
Keywords
Bio-inspired wings 3D additive manufacturing technologies Multi Jet Fusion (MJF) technology
Supporting Institution
POLİGON 3D MÜHENDİSLİK
Thanks
POLİGON YAZILIM VE MÜHENDİSLİK FİRMASINA DOKTORA TEZİM BOYUNCA DESTEKLERİNDEN VE AYRICA ARGE EKİBİNİN DA TASARIM VE TARAMA KONUSUNDA YARDIMLARINDAN DOLAYI TEŞEKKÜRÜ BORÇ BİLİRİM.
References
- [1] Celebi A, Tosun H, Oncag AÇ. Manufacturing A Damaged Skull with 3D Printer and Implant A Design, international Journal of 3d Printing Technologies And Digital Industry, 2017; 1(1): 27-35.
- [2] Karaman A, Yıldırım MN, Yaşar ŞŞ. Determination of Bending Moment Capacity on “L” Type Furniture Corner Assembly Elements Produced by 3D Printers, Gümüşhane Üniversitesi Fen Bilimleri Dergisi, 2020; 10(4): 1057-1065.
- [3] Ozgül HG, Tatlı O. 3d Printer Design, Manufacturing And Effect of Infill Patterns On Mechanical Properties. Icontech International Journal, 2020; 4(1), 13-24.
- [4] Tagliaferri V, Trovalusci F, Guarino S, Venettacci, S. Environmental and Economic Analysis of FDM, SLS and MJF Additive Manufacturing Technologies. Materials, 2019;12(24), 4161.
- [5] Rosso S, Meneghello R, Biasetto L, Grigolato L, Concheri G, Savio G. In-depth comparison of polyamide 12 parts manufactured by Multi Jet Fusion and Selective Laser Sintering. Additive Manufacturing. 2020;36. 1-13.
- [6] Mele M, Campana G, Monti GL. Modelling of The Capillarity Effect in Multi Jet Fusion Technology, Additive Manufacturing, 2019;30, 100879.
- [7] Habib FN, Iovenitti P, Masood SH, Nikzad M, Fabrication of Polymeric Lattice Structures for Optimum Energy Absorption Using Multi Jet Fusion Technology, Materials and Design, 2018;155. 86-98.
- [8] Aydın N, Caliskan ME, Sabirli MU, Karagoz I. An experimental study of the aerodynamic performance of a maple wing model at low Reynolds numbers, Mechanics Research Communications, 2023;130. 104104.
A NEW BIO-INSPIRED WING DESIGN WITH 3D ADDITIVE MANUFACTURING SCANNING AND PRINTING METHOD: MJF TECHNOLOGY
Abstract
In this study, unlike many wing profiles currently available, a new wing design has been carried out with bio-inspiration, which has attracted the attention of many scientists. There are many traditional methods in 3d additive manufacturing technologies. There are several types of 3D printing method. The four most preferred 3d printing methods are as follows. Fused Deposition Modeling (FDM), Stereolithography (SLA), Selective Laser Sintering (SLS), Multi Jet Fusion (MJF). MJF technology, one-to-one prototype production of wings with very small dimensions and aerodynamic structure has been achieved. In contrast to FDM and other additive printing technologies, it is possible to eliminate highly sensitive and high surface quality products.
Keywords
Bio-inspired wings 3D additive manufacturing technologies Multi Jet Fusion (MJF) technology
References
- [1] Celebi A, Tosun H, Oncag AÇ. Manufacturing A Damaged Skull with 3D Printer and Implant A Design, international Journal of 3d Printing Technologies And Digital Industry, 2017; 1(1): 27-35.
- [2] Karaman A, Yıldırım MN, Yaşar ŞŞ. Determination of Bending Moment Capacity on “L” Type Furniture Corner Assembly Elements Produced by 3D Printers, Gümüşhane Üniversitesi Fen Bilimleri Dergisi, 2020; 10(4): 1057-1065.
- [3] Ozgül HG, Tatlı O. 3d Printer Design, Manufacturing And Effect of Infill Patterns On Mechanical Properties. Icontech International Journal, 2020; 4(1), 13-24.
- [4] Tagliaferri V, Trovalusci F, Guarino S, Venettacci, S. Environmental and Economic Analysis of FDM, SLS and MJF Additive Manufacturing Technologies. Materials, 2019;12(24), 4161.
- [5] Rosso S, Meneghello R, Biasetto L, Grigolato L, Concheri G, Savio G. In-depth comparison of polyamide 12 parts manufactured by Multi Jet Fusion and Selective Laser Sintering. Additive Manufacturing. 2020;36. 1-13.
- [6] Mele M, Campana G, Monti GL. Modelling of The Capillarity Effect in Multi Jet Fusion Technology, Additive Manufacturing, 2019;30, 100879.
- [7] Habib FN, Iovenitti P, Masood SH, Nikzad M, Fabrication of Polymeric Lattice Structures for Optimum Energy Absorption Using Multi Jet Fusion Technology, Materials and Design, 2018;155. 86-98.
- [8] Aydın N, Caliskan ME, Sabirli MU, Karagoz I. An experimental study of the aerodynamic performance of a maple wing model at low Reynolds numbers, Mechanics Research Communications, 2023;130. 104104.
Details
| Primary Language | English |
|---|---|
| Subjects | Engineering, Mechanical Engineering (Other) |
| Journal Section | Articles |
| Authors | |
| Publication Date | December 27, 2023 |
| Published in Issue | Year 2023 Volume: 24 Issue: 4 - Eskişehir Technical University Journal of Science and Technology A - Applied Sciences and Engineering |