D
D. Dudzinski
Researcher at University of Lorraine
Publications - 44
Citations - 2871
D. Dudzinski is an academic researcher from University of Lorraine. The author has contributed to research in topics: Machining & Chip formation. The author has an hindex of 23, co-authored 43 publications receiving 2506 citations. Previous affiliations of D. Dudzinski include Metz & Arts et Métiers ParisTech.
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Measuring temperature of rotating cutting tools: Application to MQL drilling and dry milling of aerospace alloys
TL;DR: In this article, the authors proposed a new temperature measuring system for rotating cutting tools, which is composed of a thermocouple integrated into the drill or into the mill and positioned as close as possible to the cutting face and near the cutting edge.
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Modelling of cutting forces in ball-end milling with tool–surface inclination: Part I: Predictive force model and experimental validation
TL;DR: In this paper, the effect of tool-surface inclination on cutting forces in ball-end milling was investigated. But the results were limited to a three-axis CNC equipped with a Kistler dynamometer.
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A modelling of cutting for viscoplastic materials
D. Dudzinski,Alain Molinari +1 more
TL;DR: In this paper, a model of stationary shearing produced during the chip formation in orthogonal cutting is presented, where the work material is supposed to be a thermal sensitive viscoplastic rigid material.
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Perturbation analysis of thermoviscoplastic instabilities in biaxial loading
D. Dudzinski,Alain Molinari +1 more
TL;DR: In this paper, the sheet metal ductility for a thermoviscoplastic material is analyzed by using a perturbation method and a significant rate of growth of the instability is characterized in terms of an effective instability analysis.
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Predictive force model for ball-end milling and experimental validation with a wavelike form machining test
TL;DR: In this article, a predictive force model for ball-end milling based on thermomechanical modeling of oblique cutting is presented, where the tool geometry is decomposed into a series of axial elementary cutting edges.