Time-domain simulation of milling processes including process damping

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Autoren

  • B. Denkena
  • R. Grabowski
  • A. Krödel
  • L. Ellersiek

Organisationseinheiten

Externe Organisationen

  • IAV GmbH
Forschungs-netzwerk anzeigen

Details

OriginalspracheEnglisch
Seiten (von - bis)149-156
Seitenumfang8
FachzeitschriftCIRP Journal of Manufacturing Science and Technology
Jahrgang30
Frühes Online-Datum4 Juni 2020
PublikationsstatusVeröffentlicht - Aug. 2020

Abstract

Process damping is an important effect in preventing chatter vibrations. However, common modelling approaches, e.g. semi-discretization and zero order solution, can not consider the non-linear behaviour of process damping. A further approach is the time-domain simulation, which simulates an entire cutting process in time-discrete steps. In this paper, a time-domain simulation is developed, which considers the process damping effect of flank face chanmfers. Process damping is considered by calculating the volume of the workpiece material which is indented by the flank face. Moreover, a stability criterion based on the force signal in frequency-domain is established. The simulation is used to create stability charts for unchamfered and chamfered tools. The calculated stability limits are compared with experimental data and stability limits calculated with the semi-discretization method. The results show a good agreement between calculated and experimental stability charts for an unchamfered tool. However, significant deviations exist between calculated and experimental stability charts for the chamfered tools. Possible causes, e.g. the neglection of plastic deformations and thermal loads, are discussed at the end of the paper.

ASJC Scopus Sachgebiete

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Time-domain simulation of milling processes including process damping. / Denkena, B.; Grabowski, R.; Krödel, A. et al.
in: CIRP Journal of Manufacturing Science and Technology, Jahrgang 30, 08.2020, S. 149-156.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Denkena, B, Grabowski, R, Krödel, A & Ellersiek, L 2020, 'Time-domain simulation of milling processes including process damping', CIRP Journal of Manufacturing Science and Technology, Jg. 30, S. 149-156. https://doi.org/10.1016/j.cirpj.2020.05.003
Denkena, B., Grabowski, R., Krödel, A., & Ellersiek, L. (2020). Time-domain simulation of milling processes including process damping. CIRP Journal of Manufacturing Science and Technology, 30, 149-156. https://doi.org/10.1016/j.cirpj.2020.05.003
Denkena B, Grabowski R, Krödel A, Ellersiek L. Time-domain simulation of milling processes including process damping. CIRP Journal of Manufacturing Science and Technology. 2020 Aug;30:149-156. Epub 2020 Jun 4. doi: 10.1016/j.cirpj.2020.05.003
Denkena, B. ; Grabowski, R. ; Krödel, A. et al. / Time-domain simulation of milling processes including process damping. in: CIRP Journal of Manufacturing Science and Technology. 2020 ; Jahrgang 30. S. 149-156.
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title = "Time-domain simulation of milling processes including process damping",
abstract = "Process damping is an important effect in preventing chatter vibrations. However, common modelling approaches, e.g. semi-discretization and zero order solution, can not consider the non-linear behaviour of process damping. A further approach is the time-domain simulation, which simulates an entire cutting process in time-discrete steps. In this paper, a time-domain simulation is developed, which considers the process damping effect of flank face chanmfers. Process damping is considered by calculating the volume of the workpiece material which is indented by the flank face. Moreover, a stability criterion based on the force signal in frequency-domain is established. The simulation is used to create stability charts for unchamfered and chamfered tools. The calculated stability limits are compared with experimental data and stability limits calculated with the semi-discretization method. The results show a good agreement between calculated and experimental stability charts for an unchamfered tool. However, significant deviations exist between calculated and experimental stability charts for the chamfered tools. Possible causes, e.g. the neglection of plastic deformations and thermal loads, are discussed at the end of the paper.",
keywords = "Chatter, Finishing, Milling, Process damping, Roughing, Time-domain simulation",
author = "B. Denkena and R. Grabowski and A. Kr{\"o}del and L. Ellersiek",
note = "Funding information: The authors thank the German Research Foundation ( DFG ) for the financial support within the project “ DE 447/139-1 ”.",
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AU - Denkena, B.

AU - Grabowski, R.

AU - Krödel, A.

AU - Ellersiek, L.

N1 - Funding information: The authors thank the German Research Foundation ( DFG ) for the financial support within the project “ DE 447/139-1 ”.

PY - 2020/8

Y1 - 2020/8

N2 - Process damping is an important effect in preventing chatter vibrations. However, common modelling approaches, e.g. semi-discretization and zero order solution, can not consider the non-linear behaviour of process damping. A further approach is the time-domain simulation, which simulates an entire cutting process in time-discrete steps. In this paper, a time-domain simulation is developed, which considers the process damping effect of flank face chanmfers. Process damping is considered by calculating the volume of the workpiece material which is indented by the flank face. Moreover, a stability criterion based on the force signal in frequency-domain is established. The simulation is used to create stability charts for unchamfered and chamfered tools. The calculated stability limits are compared with experimental data and stability limits calculated with the semi-discretization method. The results show a good agreement between calculated and experimental stability charts for an unchamfered tool. However, significant deviations exist between calculated and experimental stability charts for the chamfered tools. Possible causes, e.g. the neglection of plastic deformations and thermal loads, are discussed at the end of the paper.

AB - Process damping is an important effect in preventing chatter vibrations. However, common modelling approaches, e.g. semi-discretization and zero order solution, can not consider the non-linear behaviour of process damping. A further approach is the time-domain simulation, which simulates an entire cutting process in time-discrete steps. In this paper, a time-domain simulation is developed, which considers the process damping effect of flank face chanmfers. Process damping is considered by calculating the volume of the workpiece material which is indented by the flank face. Moreover, a stability criterion based on the force signal in frequency-domain is established. The simulation is used to create stability charts for unchamfered and chamfered tools. The calculated stability limits are compared with experimental data and stability limits calculated with the semi-discretization method. The results show a good agreement between calculated and experimental stability charts for an unchamfered tool. However, significant deviations exist between calculated and experimental stability charts for the chamfered tools. Possible causes, e.g. the neglection of plastic deformations and thermal loads, are discussed at the end of the paper.

KW - Chatter

KW - Finishing

KW - Milling

KW - Process damping

KW - Roughing

KW - Time-domain simulation

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U2 - 10.1016/j.cirpj.2020.05.003

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