Cutting force based surface integrity soft-sensor when hard machining AISI 4140

Meurer, Markus; Tekkaya, Berk; Augspurger, Thorsten; Pullen, Thomas; Schraknepper, Daniel; Bergs, Thomas; Münstermann, Sebastian

doi:10.1515/teme-2020-0050

Cited by 14 publications

(1 citation statement)

References 24 publications

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“…Stampfer et al [56] considered cutting force measurement insufficient for the development of a soft sensor and propose further process measurands such as acoustic emission. Meurer et al [57] proposed a surface integrity sensor based on cutting force to predict white layer thickness. The predicted white layer thickness values showed deviations of more than 100% to experimental data.…”

Section: Introductionmentioning

confidence: 99%

Machine Learning of Surface Layer Property Prediction for Milling Operations

Uhlmann

Holznagel

Schehl

et al. 2021

JMMP

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Tool wear and cutting parameters have a significant effect on the surface layer properties in milling. Since the relation between tool wear, cutting parameters, and surface layer properties is mostly unknown, the latter cannot be controlled during production and may vary from part to part as tool wear progresses. To account for this uncertainty and to prevent premature failure, components often need to be oversized or surface layer properties need to be adjusted in subsequent manufacturing processes. Several approaches have been made to obtain models that predict the surface layer properties induced by manufacturing processes. However, those approaches need to be calibrated with a considerable number of experimental trials. As trials are time-consuming and surface layer measurements are laborious, no industrial applications have been realized. Complex models have one major drawback. They have to be re-parameterized as soon as process characteristics change. Therefore, manual experimental parameterization does not appear to be a feasible approach for industrial application. A highly automated approach for the machine learning of the relation between tool wear, cutting parameters and surface layer properties is presented in this paper. The amount of obtained measurement data allows a fundamental analysis of the approach, which paves the way for further developments.

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Section: Introductionmentioning

confidence: 99%

Machine Learning of Surface Layer Property Prediction for Milling Operations

Uhlmann

Holznagel

Schehl

et al. 2021

JMMP

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Control concept for the regulation of the surface layer properties using consecutive cuts in cryogenic hard turning of AISI 52100

Grossmann,

Follmann,

Zhu

et al. 2024

Prod. Eng. Res. Devel.

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In this study, a control concept for the simultaneous adjustment of the workpiece residual stresses and the surface roughness when cryogenic hard turning AISI 52100 is presented. The turning process is comprised by two consecutive cuts in which the process parameters vary, focusing on roughing and finishing; i.e. first a high, then a low depth of cut. On the first cut, the surface residual stress is adjusted via the cutting speed. On the second cut, the surface roughness is minimized by adjusting the feed rate while maintaining high compressive residual stresses. The surface residual stresses are determined by XRD and hole drilling measurements. For the estimation of the residual stresses the passive force is used. Based on these results, a control concept is presented which makes several assumptions that are partly validated by experiments.

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