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Production Engineering

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01-12-2011 | Production Process

Advanced friction modeling for bulk metal forming processes

Authors: Bernd-Arno Behrens, Anas Bouguecha, Tarik Hadifi, Jens Mielke

Published in: Production Engineering | Issue 6/2011

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Abstract

The finite element method is a powerful tool for the design and optimization of hot forming processes. In order to obtain high accuracy in simulation results, exact knowledge of the process conditions is required. Due to the fact that friction in the contact area has a significant impact on the material flow during the forming process, a realistic description of this boundary condition in the FE simulation is important for the usability of the simulation results. The most important influencing factors are the contact pressure, the roughness of the contact surfaces, the sliding velocity and the flow behavior of the material. Currently, only constant friction coefficients are considered in commercial finite element systems for the simulation of bulk metal forming processes. However, this description does not represent the state of the art in tribology. A new friction model is developed, taking into account the sliding velocity between tools and workpiece. This is confirmed by experimental and numerical investigations on model experiments and industrial process.

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Altan T, Vazquez V (1996) Numerical process simulation for tool and process design in bulk metal forming. Ann CIRP 45(2):599–615CrossRef

Becker P, Jeon HJ, Chang CC et al (2003) Modelling the Friction interface in bulk forming processes. In: Neugebauer R (ed) 10. Sächsische Fachtagung Umformtechnik in Chemnitz 14.-15.10.2003, Wissenschaftliche Skripten, Zwickau, S. 179–191

Finnie I, Shaw MC (1956) The friction process in metal cutting. Trans Am Soc Mech Eng 78:1649–1657

Neumaier T (2003) Zur Optimierung der Verfahrensauswahl von Kalt-, Halbwarm- und Warmmassivumformverfahren. Ph.D. Thesis, Universität Hannover

Schey J (1979) Metal deformation processes: friction and lubrication. Dekker/Pergamon, New York

Doege E, Bederna C (1996) Analysis of boundary stresses and temperatures in hot massive forming. Prod Eng 3(2)

Shaw MC (1963) The role of friction in deformation processing. Wear 6:140–158CrossRef

Bernhardt R (1998) Ein Beitrag zur experimentellen und numerischen Analyse lokaler Kontaktspannungen und Kontakttemperaturen in der Wirkfuge von Gesenkgravuren unter besonderer Beachtung des Randreibungsproblems. Ph.D. Thesis, Bergakademie Freiberg

Bay N, Wanheim T (1976) Real area of contact and friction stress at high pressure sliding contact. Wear 38:201–209CrossRef

10.

Chen CC, Kobayashi S (1978) Rigid-plastic finite element analysis for ring compression. Appl Num Methods Form Proc ASME AMD 28:163

11.

Mikic BB (1972) Thermal contact conductance theoretical consideration. Int J Heat Mass Transf 17:205–214CrossRef

12.

Alasti M (2008) Modellierung von Reibung und Wärmeübergang in der FEM-Simulation von Warmmassivumformprozessen. Ph.D. Thesis, Leibniz Universität Hannover

13.

Behrens B-A, Alasti M, Bouguecha A, Hadifi T, Mielke J, Schäfer F (2009) Numerical and experimental investigations an extension of friction and heat transfer models for an improved simulation of hot forging processes. 12th ESAFORM2009 conference on material forming, Twente, Netherlands

14.

Behrens B-A, Bouguecha A, Mielke J, Hirt G, Bambach M, Demant A (2010) Investigation and extension of existing approaches to the improved description of friction and heat transfer in the FEM simulation of hot forming processes. Forschung für die Praxis P 772, Forschungsvereinigung Stahlanwendung e. V., FOSTA

Title: Advanced friction modeling for bulk metal forming processes
Authors: Bernd-Arno Behrens
Anas Bouguecha
Tarik Hadifi
Jens Mielke
Publication date: 01-12-2011
Publisher: Springer-Verlag
Published in: Production Engineering / Issue 6/2011
Print ISSN: 0944-6524
Electronic ISSN: 1863-7353
DOI: https://doi.org/10.1007/s11740-011-0344-8

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