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Prediction of surface profile in CFRP machining
Citation Link: https://doi.org/10.15480/882.14554
Publikationstyp
Conference Presentation
Date Issued
2024-05
Sprache
English
TORE-DOI
Journal
Volume
123
Start Page
143
End Page
148
Citation
Procedia CIRP 123: 143-148 (2024)
Contribution to Conference
Publisher
Elsevier
Peer Reviewed
true
Carbon fibre-reinforced polymer (CFRP) is favored for its high strength to weight ratio, outstanding direction dependent mechanical properties and the high potential for load adapted design. However, machining unidirectional CFRP is challenging due to its anisotropic behavior, resulting in variable surface quality under identical machining parameters with different fibre orientations.
Recently, a universal, process-independent model describing the engagement conditions in oblique cutting of unidirectional CFRPs has been developed, introducing the spatial fibre cutting angle 𝜃₀ and the spatial engagement angle 𝜙₀. Milling and drilling are mostly used for machining CFRP. Since the engagement conditions are rather complex, first analogy experiments are conducted in turning with variation of the setting and inclination angles. In this study, continuous surface profiles were recorded as a function of the spatial fibre cutting angle. Phenomenological and continuous wavelet analyses can be used to describe the surface profiles as a function of the spatial engagement conditions and to accurately predict them and the surface roughness using an inverse wavelet transformation. Experimental investigations with a side milling process of CFRP validate the prediction approach and show a good agreement between the experimental and predicted surface profiles.
Recently, a universal, process-independent model describing the engagement conditions in oblique cutting of unidirectional CFRPs has been developed, introducing the spatial fibre cutting angle 𝜃₀ and the spatial engagement angle 𝜙₀. Milling and drilling are mostly used for machining CFRP. Since the engagement conditions are rather complex, first analogy experiments are conducted in turning with variation of the setting and inclination angles. In this study, continuous surface profiles were recorded as a function of the spatial fibre cutting angle. Phenomenological and continuous wavelet analyses can be used to describe the surface profiles as a function of the spatial engagement conditions and to accurately predict them and the surface roughness using an inverse wavelet transformation. Experimental investigations with a side milling process of CFRP validate the prediction approach and show a good agreement between the experimental and predicted surface profiles.
Subjects
carbon fibre reinforced polymers ,cutting; turning; sawing; spatial engagement conditions; surface roughness
DDC Class
620.1: Engineering Mechanics and Materials Science
621: Applied Physics
519: Applied Mathematics, Probabilities
Funding Organisations
More Funding Information
HI 843/13-1; 457264004
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Name
CIRPCSI2024_TUHH_IMPT.pdf
Size
2.68 MB
Format
Adobe PDF