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An FE-DMN method for the multiscale analysis of thermomechanical composites

Sebastian Gajek, Matti Schneider, Thomas Böhlke

2022Computational Mechanics43 citationsDOIOpen Access PDF

Abstract

Abstract We extend the FE-DMN method to fully coupled thermomechanical two-scale simulations of composite materials. In particular, every Gauss point of the macroscopic finite element model is equipped with a deep material network (DMN). Such a DMN serves as a high-fidelity surrogate model for full-field solutions on the microscopic scale of inelastic, non-isothermal constituents. Building on the homogenization framework of Chatzigeorgiou et al. (Int J Plast 81:18–39, 2016), we extend the framework of DMNs to thermomechanical composites by incorporating the two-way thermomechanical coupling, i.e., the coupling from the macroscopic onto the microscopic scale and vice versa, into the framework. We provide details on the efficient implementation of our approach as a user-material subroutine (UMAT). We validate our approach on the microscopic scale and show that DMNs predict the effective stress, the effective dissipation and the change of the macroscopic absolute temperature with high accuracy. After validation, we demonstrate the capabilities of our approach on a concurrent thermomechanical two-scale simulation on the macroscopic component scale.

Topics & Concepts

Homogenization (climate)Materials scienceFinite element methodSubroutineScale (ratio)Macroscopic scaleIsothermal processCoupling (piping)Composite materialMicroscopic scaleComputer scienceStructural engineeringPhysicsEngineeringThermodynamicsBiologyEcologyBiodiversityOpticsOperating systemQuantum mechanicsComposite Material MechanicsAdvanced Mathematical Modeling in EngineeringNumerical methods in engineering
An FE-DMN method for the multiscale analysis of thermomechanical composites | Litcius