Regenerative machine tool chatter is investigated for a single-degree-of-freedom model of turning processes. The cutting force is modeled as the resultant of a force system distributed along the rake face of the tool, whose magnitude is a nonlinear function of the chip thickness. Thus, the process is described by a nonlinear delay-differential equation, where a short distributed delay is superimposed on the regenerative point delay. The corresponding stability lobe diagrams are computed and are shown numerically that a subcritical Hopf bifurcation occurs along the stability boundaries for realistic cutting-force distributions. Therefore, a bistable region exists near the stability boundaries, where large-amplitude vibrations (chatter) may arise for large perturbations. Analytical formulas are obtained to estimate the size of the bistable region based on center manifold reduction and normal form calculations for the governing distributed-delay equation. The locally and globally stable parameter regions are computed numerically as well using the continuation algorithm implemented in dde-biftool. The results can be considered as an extension of the bifurcation analysis of machining operations with point delay.
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September 2016
Research-Article
Estimation of the Bistable Zone for Machining Operations for the Case of a Distributed Cutting-Force Model
Tamás G. Molnár,
Tamás G. Molnár
Department of Applied Mechanics,
Budapest University of
Technology and Economics,
Budapest 1111, Hungary
e-mail: molnar@mm.bme.hu
Budapest University of
Technology and Economics,
Budapest 1111, Hungary
e-mail: molnar@mm.bme.hu
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Tamás Insperger,
Tamás Insperger
Department of Applied Mechanics,
Budapest University of
Technology and Economics,
Budapest 1111, Hungary
e-mail: insperger@mm.bme.hu
Budapest University of
Technology and Economics,
Budapest 1111, Hungary
e-mail: insperger@mm.bme.hu
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S. John Hogan,
S. John Hogan
Department of Engineering Mathematics,
University of Bristol,
Bristol BS8 1TH, UK
e-mail: s.j.hogan@bristol.ac.uk
University of Bristol,
Bristol BS8 1TH, UK
e-mail: s.j.hogan@bristol.ac.uk
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Gábor Stépán
Gábor Stépán
Department of Applied Mechanics,
Budapest University of
Technology and Economics,
Budapest 1111, Hungary
e-mail: stepan@mm.bme.hu
Budapest University of
Technology and Economics,
Budapest 1111, Hungary
e-mail: stepan@mm.bme.hu
Search for other works by this author on:
Tamás G. Molnár
Department of Applied Mechanics,
Budapest University of
Technology and Economics,
Budapest 1111, Hungary
e-mail: molnar@mm.bme.hu
Budapest University of
Technology and Economics,
Budapest 1111, Hungary
e-mail: molnar@mm.bme.hu
Tamás Insperger
Department of Applied Mechanics,
Budapest University of
Technology and Economics,
Budapest 1111, Hungary
e-mail: insperger@mm.bme.hu
Budapest University of
Technology and Economics,
Budapest 1111, Hungary
e-mail: insperger@mm.bme.hu
S. John Hogan
Department of Engineering Mathematics,
University of Bristol,
Bristol BS8 1TH, UK
e-mail: s.j.hogan@bristol.ac.uk
University of Bristol,
Bristol BS8 1TH, UK
e-mail: s.j.hogan@bristol.ac.uk
Gábor Stépán
Department of Applied Mechanics,
Budapest University of
Technology and Economics,
Budapest 1111, Hungary
e-mail: stepan@mm.bme.hu
Budapest University of
Technology and Economics,
Budapest 1111, Hungary
e-mail: stepan@mm.bme.hu
Contributed by the Design Engineering Division of ASME for publication in the JOURNAL OF COMPUTATIONAL AND NONLINEAR DYNAMICS. Manuscript received July 19, 2015; final manuscript received December 30, 2015; published online February 3, 2016. Assoc. Editor: Stefano Lenci.
J. Comput. Nonlinear Dynam. Sep 2016, 11(5): 051008 (10 pages)
Published Online: February 3, 2016
Article history
Received:
July 19, 2015
Revised:
December 30, 2015
Citation
Molnár, T. G., Insperger, T., John Hogan, S., and Stépán, G. (February 3, 2016). "Estimation of the Bistable Zone for Machining Operations for the Case of a Distributed Cutting-Force Model." ASME. J. Comput. Nonlinear Dynam. September 2016; 11(5): 051008. https://doi.org/10.1115/1.4032443
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