EXAMINATION OF THE INFLUENCE OF PRINTING PARAMETERS FOR THE CONTINUOUS CARBON FIBER-REINFORCED THERMOPLASTICS BASED ON FUSED DEPOSITION MODELING

Altuğ Uşun; Recep Gümrük; Nuri Yıldız; Bahri Barış Vatandaş

EN

EXAMINATION OF THE INFLUENCE OF PRINTING PARAMETERS FOR THE CONTINUOUS CARBON FIBER-REINFORCED THERMOPLASTICS BASED ON FUSED DEPOSITION MODELING

Abstract

The continuous carbon fiber-reinforced thermoplastic (CFRTP) printing process has been used more widely in recent years and is an alternative production method, especially in sectors such as aviation, automotive, prototyping, medical applications, and aerospace. Although additive manufacturing reduces the design limitations and makes it easier to manufacture, it is one of the disadvantages of this method: it has relatively low thermal and mechanical properties compared to standard production techniques. Therefore, in this study, printing parameters such as nozzle temperature, printing speed, layer thickness and heated bed temperature was investigated for fused deposition modelling. In this regard, a polymer impregnation line based on the melt impregnation technique was utilized to obtain CFRTP filaments using polylactic acid (PLA) and 3K carbon fiber. Obtained filaments then were used to print three-point bending test samples in order to investigate mechanical performance. The test result showed flexural stress between 108 and 224 MPa and flexural modulus between 9.67 and 17.69 GPa with a 23% fiber ratio. Results from this study proclaim that CFRTP's manufactured with this method and optimized printing parameters have great potential for implementing future production methods.

Keywords

Additive Manufacturing, Polymer-matrix Composites, Continuous Fiber-reinforced Thermoplastic, Mechanical Properties

Supporting Institution

The Scientific and Technical Research Council of Turkey (TÜBİTAK), Office of Scientific Research Projects of Karadeniz Technical University

Project Number

120M717, FBA-2020-8974

Thanks

This work was supported by The Scientific and Technical Research Council of Turkey (TÜBİTAK) with grant number 120M717 and the Office of Scientific Research Projects of Karadeniz Technical University, Turkey, with the grant number FBA-2020-8974.

References

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Details

Primary Language

English

Subjects

Mechanical Engineering, Mechanical Engineering (Other), Composite and Hybrid Materials

Journal Section

Research Article

Authors

Altuğ Uşun ^*
0000-0003-0773-9548
Türkiye

Recep Gümrük
Türkiye

Nuri Yıldız
Türkiye

Bahri Barış Vatandaş
Türkiye

Publication Date

December 31, 2022

Submission Date

November 20, 2021

Acceptance Date

August 1, 2022

Published in Issue

Year 2022 Volume: 5 Number: 2

IZ

https://izlik.org/JA35DR98FP

APA

Uşun, A., Gümrük, R., Yıldız, N., & Vatandaş, B. B. (2022). EXAMINATION OF THE INFLUENCE OF PRINTING PARAMETERS FOR THE CONTINUOUS CARBON FIBER-REINFORCED THERMOPLASTICS BASED ON FUSED DEPOSITION MODELING. The International Journal of Materials and Engineering Technology, 5(2), 65-70. https://izlik.org/JA35DR98FP

AMA

1.Uşun A, Gümrük R, Yıldız N, Vatandaş BB. EXAMINATION OF THE INFLUENCE OF PRINTING PARAMETERS FOR THE CONTINUOUS CARBON FIBER-REINFORCED THERMOPLASTICS BASED ON FUSED DEPOSITION MODELING. TIJMET. 2022;5(2):65-70. https://izlik.org/JA35DR98FP

Chicago

Uşun, Altuğ, Recep Gümrük, Nuri Yıldız, and Bahri Barış Vatandaş. 2022. “EXAMINATION OF THE INFLUENCE OF PRINTING PARAMETERS FOR THE CONTINUOUS CARBON FIBER-REINFORCED THERMOPLASTICS BASED ON FUSED DEPOSITION MODELING”. The International Journal of Materials and Engineering Technology 5 (2): 65-70. https://izlik.org/JA35DR98FP.

EndNote

Uşun A, Gümrük R, Yıldız N, Vatandaş BB (December 1, 2022) EXAMINATION OF THE INFLUENCE OF PRINTING PARAMETERS FOR THE CONTINUOUS CARBON FIBER-REINFORCED THERMOPLASTICS BASED ON FUSED DEPOSITION MODELING. The International Journal of Materials and Engineering Technology 5 2 65–70.

IEEE

[1]A. Uşun, R. Gümrük, N. Yıldız, and B. B. Vatandaş, “EXAMINATION OF THE INFLUENCE OF PRINTING PARAMETERS FOR THE CONTINUOUS CARBON FIBER-REINFORCED THERMOPLASTICS BASED ON FUSED DEPOSITION MODELING”, TIJMET, vol. 5, no. 2, pp. 65–70, Dec. 2022, [Online]. Available: https://izlik.org/JA35DR98FP

ISNAD

Uşun, Altuğ - Gümrük, Recep - Yıldız, Nuri - Vatandaş, Bahri Barış. “EXAMINATION OF THE INFLUENCE OF PRINTING PARAMETERS FOR THE CONTINUOUS CARBON FIBER-REINFORCED THERMOPLASTICS BASED ON FUSED DEPOSITION MODELING”. The International Journal of Materials and Engineering Technology 5/2 (December 1, 2022): 65-70. https://izlik.org/JA35DR98FP.

JAMA

1.Uşun A, Gümrük R, Yıldız N, Vatandaş BB. EXAMINATION OF THE INFLUENCE OF PRINTING PARAMETERS FOR THE CONTINUOUS CARBON FIBER-REINFORCED THERMOPLASTICS BASED ON FUSED DEPOSITION MODELING. TIJMET. 2022;5:65–70.

MLA

Uşun, Altuğ, et al. “EXAMINATION OF THE INFLUENCE OF PRINTING PARAMETERS FOR THE CONTINUOUS CARBON FIBER-REINFORCED THERMOPLASTICS BASED ON FUSED DEPOSITION MODELING”. The International Journal of Materials and Engineering Technology, vol. 5, no. 2, Dec. 2022, pp. 65-70, https://izlik.org/JA35DR98FP.

Vancouver

1.Altuğ Uşun, Recep Gümrük, Nuri Yıldız, Bahri Barış Vatandaş. EXAMINATION OF THE INFLUENCE OF PRINTING PARAMETERS FOR THE CONTINUOUS CARBON FIBER-REINFORCED THERMOPLASTICS BASED ON FUSED DEPOSITION MODELING. TIJMET [Internet]. 2022 Dec. 1;5(2):65-70. Available from: https://izlik.org/JA35DR98FP

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EXAMINATION OF THE INFLUENCE OF PRINTING PARAMETERS FOR THE CONTINUOUS CARBON FIBER-REINFORCED THERMOPLASTICS BASED ON FUSED DEPOSITION MODELING

Abstract

Keywords

Abstract

Supporting Institution

Project Number

Thanks

References

Details

Primary Language

Subjects

Journal Section

Authors

Publication Date

Submission Date

Acceptance Date

Published in Issue

IZ

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