TY - JOUR

T1 - A kinetic two-scale damage model for high-cycle fatigue simulation using multi-temporal Latin framework

AU - Bhattacharyya, Mainak

AU - Fau, Amélie

AU - Desmorat, Rodrigue

AU - Alameddin, Shadi

AU - Néron, David

AU - Ladevèze, Pierre

AU - Nackenhorst, Udo

N1 - Funding Information: The support by the German Research Foundation (DFG) via IRTG 1627 is highly appreciated.

PY - 2019/9

Y1 - 2019/9

N2 - The goal of this paper is to introduce a model order reduction method for high-cycle fatigue simulations using a kinetic damage model, i.e. a constitutive model in which the damage evolution law is defined as a rate form [Formula presented] for the damage variable D. In the framework of continuum mechanics, high-cycle fatigue simulation involves a two-scale damage model, which includes macroscopic elastic and microscopic plastic behaviours, for a very large number of cycles. Unlike the classical usage of the two-scale damage model by Lemaitre and co-workers, where damage is calculated as a post-process of an elastic or elasto-plastic macroscopic analysis, in this work, a fully coupled analysis is conducted assuming a macroscopic damage feedback from its microscopic counterpart. Damage is considered to be isotropic with micro-defect closure effect on both macroscopic and microscopic scales. To overcome the numerical expense, the large time increment (LATIN) method is used as a linearisation framework, where the constitutive behaviour is separated from the global admissibility which in turn is solved through separation of variables using a proper generalised decomposition (PGD)-based model reduction method. A multi-temporal discretisation approach is henceforth used based on finite element like description in time for the quantities of interest, providing a sophisticated numerical approach suitable for high-cycle fatigue simulation under complex loading.

AB - The goal of this paper is to introduce a model order reduction method for high-cycle fatigue simulations using a kinetic damage model, i.e. a constitutive model in which the damage evolution law is defined as a rate form [Formula presented] for the damage variable D. In the framework of continuum mechanics, high-cycle fatigue simulation involves a two-scale damage model, which includes macroscopic elastic and microscopic plastic behaviours, for a very large number of cycles. Unlike the classical usage of the two-scale damage model by Lemaitre and co-workers, where damage is calculated as a post-process of an elastic or elasto-plastic macroscopic analysis, in this work, a fully coupled analysis is conducted assuming a macroscopic damage feedback from its microscopic counterpart. Damage is considered to be isotropic with micro-defect closure effect on both macroscopic and microscopic scales. To overcome the numerical expense, the large time increment (LATIN) method is used as a linearisation framework, where the constitutive behaviour is separated from the global admissibility which in turn is solved through separation of variables using a proper generalised decomposition (PGD)-based model reduction method. A multi-temporal discretisation approach is henceforth used based on finite element like description in time for the quantities of interest, providing a sophisticated numerical approach suitable for high-cycle fatigue simulation under complex loading.

KW - Damage mechanics

KW - High-cycle fatigue

KW - LATIN-PGD method

KW - Model order reduction

KW - Two-scale model

KW - Two-temporal scales

UR - http://www.scopus.com/inward/record.url?scp=85069575761&partnerID=8YFLogxK

U2 - 10.1016/j.euromechsol.2019.103808

DO - 10.1016/j.euromechsol.2019.103808

M3 - Article

AN - SCOPUS:85069575761

VL - 77

JO - European Journal of Mechanics, A/Solids

JF - European Journal of Mechanics, A/Solids

SN - 0997-7538

M1 - 103808

ER -