Analysis of The Basic Parameters in Additive Manufacturing of The Elastomeric Materials
Year 2018,
Volume: 2 Issue: 1, 69 - 75, 13.03.2018
Savaş Dilibal
,
Haydar Sahin
,
Ömer Elbaba
Samet Sezer
Abstract
The
development in additive manufacturing technology facilitates the production of
the final product for varied applications; such as mechatronics, robotics,
aerospace and biomedical devices. The soft mechanical property is one of the
desired parameters for these applications. The final product can be easily
manufactured through the additive manufacturing process compared to the
conventional casting technique. In this study, the prerequisite for material
selection and manufacturing parameters in additive manufacturing investigated for
the soft products. Taking into consideration the mechanical properties such as
tensile strength, hardness and modulus of elasticity, it has been determined
that polymeric materials should be selected according to the application
requirements to be used. Manufacturing parameters were determined with a
flexible polymeric filament using fused deposition modeling (FDM) technique.
References
- [1] Saari, M., Galla, M., Cox, B., Krueger, P., Cohen, A. and Richer, E., 2015. Additive Manufacturing of Soft and Composite Parts from Thermoplastic Elastomers. In Solid Freeform Fabrication Symposium. Austin, TX: University of Texas at Austin (pp. 949-958)
- [2] Mutlu, R., Yildiz, S.K., Alici, G., in het Panhuis, M. and Spinks, G.M., 2016, July. Mechanical stiffness augmentation of a 3D printed soft prosthetic finger. In Advanced Intelligent Mechatronics (AIM), 2016 IEEE International Conference on (pp. 7-12). IEEE.
- [3] Mutlu, R., Alici, G., in het Panhuis, M. and Spinks, G., 2015, July. Effect of flexure hinge type on a 3D printed fully compliant prosthetic finger. In Advanced Intelligent Mechatronics (AIM), 2015 IEEE International Conference on (pp. 790-795)
- [4] Moscato, S., Bahr, R., Le, T., Pasian, M., Bozzi, M., Perregrini, L. and Tentzeris, M.M., 2016. Infill-Dependent 3-D-Printed Material Based on NinjaFlex Filament for Antenna Applications. IEEE Antennas and Wireless Propagation Letters, 15, pp.1506-1509.
- [5] Przybytek, A., Kucińska-Lipka, J. and Janik, H., 2016. Thermoplastic elastomer filaments and their application in 3D printing. Elastomery, 20.
- [6] Gebhardt, A., 2007. Rapid Prototyping–Rapid Tooling–Rapid Manufacturing. Carl Hanser, München.
- [7] http://www.gyrobot.co.uk/blog/how-to-3d-print-with-flexible-filaments, erişim tarihi 06.03.2017
ELASTOMETRİK MALZEMELERİN KATMANLI İMALATINDA TEMEL PARAMETRELERİN ANALİZİ
Year 2018,
Volume: 2 Issue: 1, 69 - 75, 13.03.2018
Savaş Dilibal
,
Haydar Sahin
,
Ömer Elbaba
Samet Sezer
Abstract
Katmanlı
imalat teknolojisindeki gelişmeler mekatronik, robotik, havacılık ve
biyomedikal ürünler gibi birçok farklı uygulamanın üretim yapılmasına olanak
sağlamaktadır. Bu uygulamalardaki istenen parametrelerden biri de esnek mekanik
özelliklere sahip olunmasıdır. Geleneksel döküm teknolojisi kullanılarak
yapılan üretimle karşılaştırıldığında katmanlı imalat tekniği birçok açıdan
daha kolay son ürüne erişilebilen bir tekniktir. Bu çalışmada, esnek ürün elde
edilmesi için katmanlı imalat teknolojisinde malzeme seçimi ve imalat parametreleri
ile ilgili gerekli ön şartlar araştırılmıştır.
References
- [1] Saari, M., Galla, M., Cox, B., Krueger, P., Cohen, A. and Richer, E., 2015. Additive Manufacturing of Soft and Composite Parts from Thermoplastic Elastomers. In Solid Freeform Fabrication Symposium. Austin, TX: University of Texas at Austin (pp. 949-958)
- [2] Mutlu, R., Yildiz, S.K., Alici, G., in het Panhuis, M. and Spinks, G.M., 2016, July. Mechanical stiffness augmentation of a 3D printed soft prosthetic finger. In Advanced Intelligent Mechatronics (AIM), 2016 IEEE International Conference on (pp. 7-12). IEEE.
- [3] Mutlu, R., Alici, G., in het Panhuis, M. and Spinks, G., 2015, July. Effect of flexure hinge type on a 3D printed fully compliant prosthetic finger. In Advanced Intelligent Mechatronics (AIM), 2015 IEEE International Conference on (pp. 790-795)
- [4] Moscato, S., Bahr, R., Le, T., Pasian, M., Bozzi, M., Perregrini, L. and Tentzeris, M.M., 2016. Infill-Dependent 3-D-Printed Material Based on NinjaFlex Filament for Antenna Applications. IEEE Antennas and Wireless Propagation Letters, 15, pp.1506-1509.
- [5] Przybytek, A., Kucińska-Lipka, J. and Janik, H., 2016. Thermoplastic elastomer filaments and their application in 3D printing. Elastomery, 20.
- [6] Gebhardt, A., 2007. Rapid Prototyping–Rapid Tooling–Rapid Manufacturing. Carl Hanser, München.
- [7] http://www.gyrobot.co.uk/blog/how-to-3d-print-with-flexible-filaments, erişim tarihi 06.03.2017