Comparison of linear and trochoidal milling for wear and vibration reduced machining
Gross D, Friedl F, Meier T, Hanenkamp N (2020)
Publication Type: Journal article, Original article
Publication year: 2020
Journal
Publisher: Elsevier B.V.
Book Volume: 90
Pages Range: 563-567
Conference Proceedings Title: Procedia CIRP
Event location: Grenoble
DOI: 10.1016/j.procir.2020.01.069
Abstract
Vibrations during milling lead to frequent tool replacements. This results in an unsteady load on the machine, which leads to increased tool wear, poor surface quality and therefore strong economic and ecological burden. Self-excited vibrations are influenced by the machining conditions, such as the workpiece geometry or the tool path generated by the used computer-aided manufacturing (CAM) software. This article compares linear and trochoidal milling in terms of vibration behavior and resulting wear phenomena by machining different component geometries. The results show, that trochoidal milling is not a suitable strategy to reduce vibrations and tool wear compared to linear milling.
Authors with CRIS profile
Daniel Gross
Lehrstuhl für Ressourcen- und Energieeffiziente Produktionsmaschinen
Trixi Meier
Lehrstuhl für Ressourcen- und Energieeffiziente Produktionsmaschinen
Nico Hanenkamp
Lehrstuhl für Ressourcen- und Energieeffiziente Produktionsmaschinen
How to cite
APA:
Gross, D., Friedl, F., Meier, T., & Hanenkamp, N. (2020). Comparison of linear and trochoidal milling for wear and vibration reduced machining. Procedia CIRP, 90, 563-567. https://dx.doi.org/10.1016/j.procir.2020.01.069
MLA:
Gross, Daniel, et al. "Comparison of linear and trochoidal milling for wear and vibration reduced machining." Procedia CIRP 90 (2020): 563-567.
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