Structure Control in Fiber Reinforced Polymer Composites in Additive Manufacturing Technologies

• Autorzy: Prusinowski A. , Kaczyński R.
• Języki publikacji: EN

Abstrakty

EN

The main reason for the authors to discuss the subject is the need to fill the gaps in the knowledge regarding the abrasive wear of polymer composites with reinforcement in the form of short carbon fibers that can be used in additive manufacturing technologies. The illustrated design of the extrusion head makes it possible to obtain a composite with a matrix in the form of a thermoplastic and reinforcement as carbon fibers evenly spaced along the extrusion axis. The results of the simulation of heat propagation in the extrusion head and the flow of the matrix material in the nozzle are shown. This paper presents the research on the mixing process of the matrix material in the designed system and describes further planned tests. The output materials were obtained at various amounts of the PLA matrix material fed in at both entrances to the extrusion head. Mixing of materials has been shown by obtaining different colors of the outgoing material using two different colors of one type of input material.

Słowa kluczowe

EN

FRCP; fused deposition modelling; additive manufacturing

• Wydawca: Oficyna Wydawnicza Politechniki Warszawskiej
• Czasopismo: Machine Dynamics Research
• Rocznik: 2018
• Tom: Vol. 42, No. 3
• Strony: 17--25
• Opis fizyczny: Bibliogr. 9 poz., fot., rys.

Twórcy

autor

Prusinowski A.

• Bialystok Univesity of Technology, Mechanical Faculty

autor

Kaczyński R.

• Bialystok Univesity of Technology, Mechanical Faculty

Bibliografia

• 1. Gardner, J. M., Sauti, G., Kim, J.-W., Cano, R. J., Wincheski, R. A., Stelter, C. J., Grimsley, B. W., Working, D. C., and Siochi, E. J. (2016). 3-d printing of multifunctional carbon nanotube yarn reinforced components. Additive Manufacturing, 12:38–44.
• 2. Lee, J. and Huang, A. (2013). Fatigue analysis of fdm materials. Rapid prototyping journal, 19(4):291–299.
• 3. Mohamed, O. A., Masood, S. H., and Bhowmik, J. L. (2018). Analysis of wear behavior of additively manufactured pc-abs parts. MaterialsLetters,230:261–265.
• 4. Prusinowski, A. and Kaczyński, R. (2017). Simulation of processes occurring in the extrusion head used in additive manufacturing technology. Acta Mechanica et Automatica, 11(4):317–321.
• 5. Singh Boparai, K., Singh, R., and Singh, H. (2016). Wear behavior of fdm parts fabricated by composite material feed stock filament. Rapid Prototyping Journal, 22(2):350–357.
• 6. Sood, A.K., Equbal, A., Toppo, V., Ohdar, R., and Mahapatra, S. (2012). An investigation on sliding wear of fdm built parts. CIRP Journal of Manufacturing Science and Technology, 5(1):48–54.
• 7. Suresha, B., Kumar, K. S., Seetharamu, S., and Kumaran, P. S. (2010). Friction and dry sliding wear behavior of carbon and glass fabric reinforced vinyl ester composites. Tribology International, 43(3):602–609.
• 8. Wilczewska, I. and Kaczyński, R. (2009). Identification of friction and wear parameters of carbon fiber polymers in diferent working environments - in polish. Acta Mechanica et Automatica, 3(2):106–110.
• 9. Zhao, G., Hussainova, I., Antonov, M., Wang, Q., Wang, T., and Yung, D.-L. (2015). Effect of temperature on sliding and erosive wear of fiber reinforced polyimide hybrids. Tribology International, 82:525–533.