Lifetime evaluation of two different hot work tool steels in aluminium extrusion

During aluminium extrusion, the die experience cyclic thermo-mechanical loads that can lead to materials degradation and failure. For a process optimization and a comparison of different hot work tool steels, the finite element method is an appropriate means. Local inelastic strains result from the...

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Published in:Computational materials science 2008-07, Vol.43 (1), p.82-91
Main Authors: Sommitsch, C., Sievert, R., Wlanis, T., Redl, C.
Format: Article
Language:English
Subjects:
Aging
Applied sciences
Creep
Exact sciences and technology
Extrusion
Failure
Fatigue
Forging and extrusion
Forming
Metals. Metallurgy
Production techniques
Viscoplasticity
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description During aluminium extrusion, the die experience cyclic thermo-mechanical loads that can lead to materials degradation and failure. For a process optimization and a comparison of different hot work tool steels, the finite element method is an appropriate means. Local inelastic strains result from the interaction of the applied temperature and stress loading and can be computed by suitable inelastic constitutive equations. Stress amplitudes and dwell times during extrusion result in creep-fatigue damage. A lifetime consumption model sums increments of a damage variable over time and defines materials failure as the accumulation of the resulting damage variable to a critical value. The procedure for the identification of the material parameters for both the constitutive and the damage model is described in detail, including the material parameters for the description of time-effects, and applied to the hot work tool steel Böhler W300 ISOBLOC (EN 1.2343). The lifetime consumption for two different hot work tool steels is compared on the basis of an example in aluminium extrusion.
doi_str_mv 10.1016/j.commatsci.2007.07.054
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source ScienceDirect Journals
subjects Aging
Applied sciences
Creep
Exact sciences and technology
Extrusion
Failure
Fatigue
Forging and extrusion
Forming
Metals. Metallurgy
Production techniques
Viscoplasticity
title Lifetime evaluation of two different hot work tool steels in aluminium extrusion
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