Numerical Study of Hand Disc Grinding of Ni-Base Alloy 690

Sawsen Youssef; O. Calonne; E. Feulvarch; P. Gilles; Hédi Hamdi

doi:10.4028/www.scientific.net/AMR.445.102

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HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 445Numerical Study of Hand Disc Grinding of Ni-Base...

Numerical Study of Hand Disc Grinding of Ni-Base Alloy 690

Abstract:

The state of the surface, whatever the metal or alloy used is of paramount importance. Hand disc grinding operation is difficult to master in terms of results on the surface due to its manual nature. From this, comes the great importance to the mastery of the consequences induced by this abrasive process. A previous experimental study on hand disc grinding revealed several consequences on the surface integrity in terms of residual stresses, micro-hardness, hardening of the material etc. Numerical simulation can be a good way to prevent manufacturers of very time consuming experiments for the prediction of residual stresses due to grinding. The purpose of this study is to predict the consequences in terms of induced temperature fields and the state of residual stresses. The action of the disk-grinding wheel on the Workpiece is modeled by a moving heat flux on top of the part surface. All the difficulties lie in the quantification of the heat flux and more precisely in the heat flux density that gives the way the thermal load is distributed in the contact disk grinding/workpiece area. In this paper, an original analytical model for the determination of the heat flux density has been developed. For each step, the thermo-mechanical calculation is performed. Finally, the distribution of temperature and residual stresses will be carried out with the FE software SYSWELD 2010®.

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Periodical:

Advanced Materials Research (Volume 445)

Pages:

102-107

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.445.102

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Online since:

January 2012

Authors:

Sawsen Youssef, O. Calonne, E. Feulvarch, P. Gilles, Hédi Hamdi

Keywords:

Analytical Model, Disk Grinding, Hand Grinding, Heat Flux, Residual Stress, Surface Integrity

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