EFFECT OF DIFFERENT AMOUNTS OF CARBON FIBER ADDITIVE ABS ON THERMAL DISTORTION AND COOLING TIME
Year 2022,
Volume: 5 Issue: 1, 13 - 17, 30.06.2022
Ömer Eyercioğlu
,
Engin Tek
,
Mehmet Aladağ
,
Gülağa Taş
Abstract
This study presents an analysis of the distortions of ABS composites with different amounts of carbon fiber produced by large-scale additive manufacturing (LSAM). Part failures often occur in extrusion-based large-scale additive manufacturing due to thermal contraction. These are called thermal distortions. Undesirable distortions are caused by differential thermal expansion and contraction and corresponding residual stresses. Residual stress and strain analysis require accurate thermo-mechanical material properties. These can be controlled by changing the amount of additives in polymer material. In this study, fiber orientations in Acrylonitrile Butadiene Styrene (ABS) reinforced with 10%, 5%, 0% carbon fiber by weight were modeled using a homogenization technique. The amount of distortion of the parts modeled according to these carbon fiber ratios was examined and, the cooling durations were compared.
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Year 2022,
Volume: 5 Issue: 1, 13 - 17, 30.06.2022
Ömer Eyercioğlu
,
Engin Tek
,
Mehmet Aladağ
,
Gülağa Taş
References
- 1. Mellor, S., Hao, L., and Zhang, D. Additive manufacturing: A framework for implementation. Int. J. Prod. Econ., (2014), 149, 194–201.
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- 13. Polyzos, E., Katalagarianakis, A., Van Hemelrijck, D., and Pyl, L. Delamination analysis of 3D-printed nylon reinforced with continuous carbon fibers. Addit. Manuf., (2021), 46, 102144.
- 14. Eyercioglu, O., Aladag, M., and Sever, S. Temperature Evaluation and Bounding Quality of Large Scale Additive Manufacturing Thin Wall Parts. Sigma J Eng Nat Sci, (2018), 36 (3), 645–654.