Probabilistic sequential prediction of cutting forces is performed applying Bayesian inference to Kienzle force model. The model uncertainties are quantified using the Metropolis algorithm of the Markov chain Monte Carlo (MCMC) approach. Prior probabilities are established and posteriors of the models parameters and force predictions are completed using the results of orthogonal turning experiments. Two types of tools with chamfer (rake) angles of 0 deg and −10 deg are tested under various cutting speed and feed per revolution values. First, Bayesian inference is applied to two force models, Merchant and Kienzle, to investigate the cutting force prediction at the low feed values for the 0 deg rake angle tool. Second, the results of the posteriors of the Kienzle model parameters are used as prior probabilities of the −10 deg rake angle tool. The simulation results of the 0 deg and −10 deg tool rake angle are compared with the experiments which are obtained under other cutting conditions for model verification. Maximum prediction errors of 7% and 9% are reported for the tangential and feed forces, respectively. This indicates a good capability of the Bayesian inference for model parameter identification and cutting force prediction considering the inherent uncertainty and minimum input experimental data.
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January 2019
Research-Article
Probabilistic Sequential Prediction of Cutting Force Using Kienzle Model in Orthogonal Turning Process
M. Salehi,
M. Salehi
Department of Mechanical Engineering,
Institute for Information Management
in Engineering,
Karlsruhe Institute of Technology,
Kaiserstr. 12,
Karlsruhe 76131, Germany;
Department of Mechanical Engineering
and Mechatronic,
Institute of Materials and Processes,
Karlsruhe University of Applied Science,
Moltkestr.30,
Karlsruhe 76133, Germany
e-mail: mehdi.salehi@hs-karlsruhe.de
Institute for Information Management
in Engineering,
Karlsruhe Institute of Technology,
Kaiserstr. 12,
Karlsruhe 76131, Germany;
Department of Mechanical Engineering
and Mechatronic,
Institute of Materials and Processes,
Karlsruhe University of Applied Science,
Moltkestr.30,
Karlsruhe 76133, Germany
e-mail: mehdi.salehi@hs-karlsruhe.de
Search for other works by this author on:
T. L. Schmitz,
T. L. Schmitz
Department of Mechanical Engineering and
Engineering Science,
University of North Carolina at Charlotte,
Charlotte, NC 28223
Engineering Science,
University of North Carolina at Charlotte,
Charlotte, NC 28223
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R. Copenhaver,
R. Copenhaver
Department of Mechanical Engineering and
Engineering Science,
University of North Carolina at Charlotte,
Charlotte, NC 28223
Engineering Science,
University of North Carolina at Charlotte,
Charlotte, NC 28223
Search for other works by this author on:
R. Haas,
R. Haas
Department of Mechanical Engineering
and Mechatronic,
Institute of Materials and Processes,
Karlsruhe University of Applied Science,
Karlsruhe 76133, Germany
and Mechatronic,
Institute of Materials and Processes,
Karlsruhe University of Applied Science,
Moltkestr.30
,Karlsruhe 76133, Germany
Search for other works by this author on:
J. Ovtcharova
J. Ovtcharova
Department of Mechanical Engineering,
Institute for Information Management in
Engineering,
Karlsruhe Institute of Technology,
Karlsruhe 76131, Germany
Institute for Information Management in
Engineering,
Karlsruhe Institute of Technology,
Kaiserstr. 12
,Karlsruhe 76131, Germany
Search for other works by this author on:
M. Salehi
Department of Mechanical Engineering,
Institute for Information Management
in Engineering,
Karlsruhe Institute of Technology,
Kaiserstr. 12,
Karlsruhe 76131, Germany;
Department of Mechanical Engineering
and Mechatronic,
Institute of Materials and Processes,
Karlsruhe University of Applied Science,
Moltkestr.30,
Karlsruhe 76133, Germany
e-mail: mehdi.salehi@hs-karlsruhe.de
Institute for Information Management
in Engineering,
Karlsruhe Institute of Technology,
Kaiserstr. 12,
Karlsruhe 76131, Germany;
Department of Mechanical Engineering
and Mechatronic,
Institute of Materials and Processes,
Karlsruhe University of Applied Science,
Moltkestr.30,
Karlsruhe 76133, Germany
e-mail: mehdi.salehi@hs-karlsruhe.de
T. L. Schmitz
Department of Mechanical Engineering and
Engineering Science,
University of North Carolina at Charlotte,
Charlotte, NC 28223
Engineering Science,
University of North Carolina at Charlotte,
Charlotte, NC 28223
R. Copenhaver
Department of Mechanical Engineering and
Engineering Science,
University of North Carolina at Charlotte,
Charlotte, NC 28223
Engineering Science,
University of North Carolina at Charlotte,
Charlotte, NC 28223
R. Haas
Department of Mechanical Engineering
and Mechatronic,
Institute of Materials and Processes,
Karlsruhe University of Applied Science,
Karlsruhe 76133, Germany
and Mechatronic,
Institute of Materials and Processes,
Karlsruhe University of Applied Science,
Moltkestr.30
,Karlsruhe 76133, Germany
J. Ovtcharova
Department of Mechanical Engineering,
Institute for Information Management in
Engineering,
Karlsruhe Institute of Technology,
Karlsruhe 76131, Germany
Institute for Information Management in
Engineering,
Karlsruhe Institute of Technology,
Kaiserstr. 12
,Karlsruhe 76131, Germany
1Corresponding author.
Manuscript received June 4, 2018; final manuscript received October 4, 2018; published online November 8, 2018. Assoc. Editor: Laine Mears.
J. Manuf. Sci. Eng. Jan 2019, 141(1): 011009 (12 pages)
Published Online: November 8, 2018
Article history
Received:
June 4, 2018
Revised:
October 4, 2018
Citation
Salehi, M., Schmitz, T. L., Copenhaver, R., Haas, R., and Ovtcharova, J. (November 8, 2018). "Probabilistic Sequential Prediction of Cutting Force Using Kienzle Model in Orthogonal Turning Process." ASME. J. Manuf. Sci. Eng. January 2019; 141(1): 011009. https://doi.org/10.1115/1.4041710
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