Metal Part Production with Additive Manufacturing for Aerospace and Defense Industry
In the aerospace and defense industry, the production of parts using existing technologies is difficult. The production problem of these difficult parts is solved by the Additive Manufacturing (AM) method. It is possible to produce parts with complex geometry which cannot be manufactured by traditional manufacturing method. In addition, more functional, lighter and more economical parts are produced by AM method. In our country, the most innovative and value-added applications of additive manufacturing technologies are used in the aviation, aerospace and defense industries. The main uses of additive manufacturing technology in the field of aviation and defense to accelerate the time of product launch to market by shortening the design and manufacturing process, to increase productivity, to reduce costs and to provide cost advantage in low number production. In the light of this information, instead of the existing technology in the aeronautics and defense industry sector, metal parts manufacturing comes to the fore with AM method. In the study, the current state of additive manufacturing technology in the aerospace sector is examined. In addition, advantages and disadvantages of AM method for aerospace and defense sector are presented. In our country, companies such as TEI, TAI, KALEGRUP, ASELSAN and FNSS are among the international suppliers in the aerospace and defense industry. These companies have, instead of themselves, their sub-suppliers manufacture parts by AM method. The objective is to increase the number of sub-suppliers as fan expansion and floor expansion in the aerospace sector. In the light of this information, instead of the existing technology in the aeronautics and defense industry sector, metal parts manufacturing comes to the fore with AM method. In the study, the current state of additive manufacturing technology in the aerospace sector is examined. In addition, advantages and disadvantages of AM method for aerospace and defense sector are presented.
Anahtar Kelimeler:
Additive Manufacturing, Aerospace, Defense Industry, Metal Parts
Metal Part Production with Additive Manufacturing for Aerospace and Defense Industry
In the aerospace and defense industry, the production of parts using existing technologies is difficult. The production problem of these difficult parts is solved by the Additive Manufacturing (AM) method. It is possible to produce parts with complex geometry which cannot be manufactured by traditional manufacturing method. In addition, more functional, lighter and more economical parts are produced by AM method. In our country, the most innovative and value-added applications of additive manufacturing technologies are used in the aviation, aerospace and defense industries. The main uses of additive manufacturing technology in the field of aviation and defense to accelerate the time of product launch to market by shortening the design and manufacturing process, to increase productivity, to reduce costs and to provide cost advantage in low number production. In the light of this information, instead of the existing technology in the aeronautics and defense industry sector, metal parts manufacturing comes to the fore with AM method. In the study, the current state of additive manufacturing technology in the aerospace sector is examined. In addition, advantages and disadvantages of AM method for aerospace and defense sector are presented.
Keywords:
Additive Manufacturing, Aerospace, Defense Industry, Metal Parts,
___
- ASTM (2010). F2792-10, Standard Terminology for Additive Manufacturing Technologies, ASTM International, West Conshohocken, PA, www.astm.org (09.08.2019)
- Balc, N. O., Berce, P., & Pacurar, R. (2010). Comparison between SLM and SLS in producing complex metal parts. Annals of DAAAM & Proceedings, 7-9.
- Bamberg, J., Dusel, K. H., & Satzger, W. (2015, March). Overview of additive manufacturing activities at MTU aero engines. In AIP Conference Proceedings 1650 (1), 156-163.
- Custompartnet (2010). Fused Deposition Modeling (FDM), http://www.custompartnet.com/wu/fused-deposition-modeling (24.02.2018)
- DefenceIQ, (2016). https://defencesummits.files.wordpress.com/2016/02/additive-manufacturing-in-defence-and-aerospace-analysis-and-trends-20161.pdf (09.08.2019)
- EADS (2015). Study Demonstrates Savings Potential for DMLS in the Aerospace Industry
- Ektam, (2019). http://ektam.gazi.edu.tr/posts/view/title/aselsan-197915?siteUri=ektam (09.08.2019)
- EOS GmbH (1989). http://www.eos.info (10.09.2014).
- Espace.net, (2014). http://worldwide.espacenet.com/publicationDetails/biblio?DB=EPODOC&II=20&ND=3&adjacent=true&locale=en_EP&FT=D&date=19940429&CC=FI&NR=91725B&KC=B (16.09.2014).
- GE Aviation Signs Additive Manufacturing Cooperative Agreement with Sigma Labs – www.geaviation.com
- Giannatsis, J., Dedoussis, V., (2009). Additive fabrication technologies applied to medicine and health care: a review, Int. J. Adv. Manuf. Technol., 40, 116-127.
- Geekwire, (2018) http://geekwire.com (17.11.2018)
- IDTechEx, (2018) http://IDTechEx.com (17.11.2018)
- IECETECH, (2016) https://iecetech.org/issue/2014-06/Aerospace-3D-printing-takes-off (25.12.2019)
- Jacobs P F. (1992). Rapid Prototyping & Manufacturing: Fundamentals of Stereolithography. Dearborn: SME publication.
- Kalender M., Kılıç S. E., Ersoy S., Bozkurt Y. and Salman S., (2019). Additive Manufacturing and 3D Printer Technology in Aerospace Industry," 9th International Conference on Recent Advances in Space Technologies (RAST), Istanbul, Turkey, pp. 689-694.
- Kayacan, M.Y., Yilmaz, N. (2019). DMLS eklemeli imalatta süreç ve maliyet modeli geliştirilmesi. Politeknik Dergisi, 22(3), 763-770.
- Kellner T., (2015). The FAA cleared the first 3D printed part to fly in a commercial jet engine from GE https://www.ge.com/reports/post/116402870270/the-faa-cleared-the-first-3d-printed-part-to-fly-2/>
- Keller T. (2017). Mind melt: how GE and a 3D-printing visionary joined forces, in GE Reporta https://www.ge.com/reports/mind-me-ge-3d-printing-visionary-joined-forces/
- LENS Teknolojisi, Mudge ve Wald, (2007). http://www.rpmandassociates.com/uploads/lens_advances_manufacturing_and_repair_.pdf (22.11.2018)
- Levy, G.N., Schindel, R., Kruth, J.P., (2003). Rapid Manufacturing And Rapid Tooling With Layer Manufacturing (LM) Technologies, State Of The Art And Future Perspectives. CIRP Annals - Manufacturing Technology, 52(2), 589-609.
- Marketsandmarkets, (2013). Report Code: SE 2154; Report Code: SE 2936 https://www.marketsandmarkets.com/Market-Reports/3d-printing-market-1276.html (17.11.2018).
- Meiners, W., Wissenbach, K., Gasser, A., (2001). Selective Laser Sintering At Melting Temperature. Patent no: US6215093.
- Müller, A., and Karevska, S. (2016). EY’s Global 3D printing Report. EY.
- Nichita, G.G., (2007). An Review About Rapid Manufacturing, Annals of the Oradea Universıty. Fascicle of Management and Technological Engineering, VI (XVI), 1417-1422.
- Pratt-whitney, (2015). http://www.pratt-whitney.com/Press/Story/20150401-1500/2015/All%20Categories (09.08.2019) Rolls-Royce, (2019). Trent XWB-97 completes first test flight, www.rolls-royce.com (04.03.2019)
- Stelia (2018), manufactures fuselage panel through 3D printing.” [Online]. Available: https://www.flightglobal.com/news/articles/stelia-manufactures-fuselage-panelthrough-3d-printi-446028/ (17.12.2018).
- Strateji ve Bütçe Başkanlığı (SBB). (2019). Üretimde Paradigma Değişikliği, Artırımsal Üretim, Üç Boyutlu Yazıcılar (Yayın No:0007). Ankara, TC Cumhurbaşkanlığı.
- Technavio (2016). Global Aerospace 3D Printing Market 2016-2020. https://www.technavio.com/report/global-aerospace-components-global-aerospace-3d-printing-market-2016-2020 (25.12.2019)
- Turkcadcam, (2018). http://www.turkcadcam.net/rapor/autofab/tech-powder_binding-fusing.html#eosint (10.09.2018)
- 5nplus, (2014). http://www.5nplus.com/index.php/en/about-us/history/-MCP (09.09.2014)
- Başlangıç: 2009
- Yayıncı: Isparta Uygulamalı Bilimler Üniversitesi
Sayıdaki Diğer Makaleler
Termoplastik Malzemelerin Ultrasonik Kaynağı ve Kaynak Parametrelerinin Çekme Dayanımına Etkisi
Bekir YALÇIN, Berkay ERGENE, Serdar NAR
Metal Part Production with Additive Manufacturing for Aerospace and Defense Industry
Koray ÖZSOY, Burhan DUMAN, Diyar İÇKALE GÜLTEKİN
Gültekin BASMACI, Levent SAYIN
Control and Monitoring of Greenhouse System with Matlab GUI
Rulet Tekerleği Yöntemi Kullanılarak Simbiyotik Organizmalar Arama Algoritmasının Geliştirilmesi