Application of Indentation Size Effect in Finite Element Analysis for Friction Simulation

Taureza, Muhammad; Castagne, Sylvie; Lim, Samuel Chao Voon

doi:10.4028/www.scientific.net/kem.535-536.227

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“…In a previous study with conical asperity [10], it was shown that the measured friction during the simulation is lower when the depth-dependent flow stress is introduced. More importantly, the influence of indentation size effect model is stronger in smoother surface.…”

Section: Introductionmentioning

confidence: 93%

Depth-dependent stress–strain relation for friction prediction

Taureza

Song

Castagne

2014

International Journal of Mechanical Sciences

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The effect of strain gradient on mechanical property of material is implemented through depth-dependent stress strain relation model in conventional finite element simulations for use in friction prediction. For the incorporation of strain gradient effect, contact simulation involving asperities was developed with the assumption that the deformation pattern created by asperities from tool surface in microforming is comparable to the deformation created by the indenter in a hardness test. Consequently, depth-dependent stress-strain relation was derived from the indentation size effect model and this stress-strain relation was used in a simulation to show the effect of strain gradient to friction behaviour in microforming at different surface roughness levels. Experiment was conducted alongside the simulation and the results showed that with asperity ploughing considered as major contributor to friction in microforming at room temperature, the simulation involving depth-dependent material properties is able to predict the better predict the friction behaviour as compared to its continuum simulation counterpart.

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Section: Introductionmentioning

confidence: 93%