Statistically equivalent surrogate material models: Impact of random imperfections on the elasto-plastic response

Manufactured materials usually contain random imperfections due to the fabrication process, e.g., the 3D-printing, casting, etc. These imperfections affect significantly the effective material properties and result in uncertainties in the mechanical response. Numerical analysis of the effects of the...

Full description

Saved in:
Bibliographic Details
Published in:Computer methods in applied mechanics and engineering 2022-12, Vol.402, p.115278, Article 115278
Main Authors: Khristenko, Ustim, Constantinescu, Andrei, Le Tallec, Patrick, Wohlmuth, Barbara
Format: Article
Language:English
Subjects:
Additive manufacturing
Algorithms
Calibration
Casting defects
Deformation effects
Design parameters
Elasto-plastic material
Elastoplasticity
Material properties
Materials and structures in mechanics
Mathematical models
Mechanical analysis
Mechanics
Modulus of elasticity
Numerical analysis
Perturbation
Physics
Random fields
Sampling
Stochastic optimization
Surrogate model
Three dimensional printing
Two phase materials
Uncertainty
Uncertainty quantification
Unit cell
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Manufactured materials usually contain random imperfections due to the fabrication process, e.g., the 3D-printing, casting, etc. These imperfections affect significantly the effective material properties and result in uncertainties in the mechanical response. Numerical analysis of the effects of the imperfections and the uncertainty quantification (UQ) can be often done by use of digital stochastic surrogate material models. In this work, we present a new flexible class of surrogate models depending on a small number of parameters and a calibration strategy ensuring that the constructed model fits to the available observation data, with special focus on two-phase materials. The surrogate models are constructed as the level-set of a linear combination of an intensity field representing the topological shape and a Gaussian perturbation representing the imperfections, allowing for fast sampling strategies. The mathematical design parameters of the model are related to physical ones and thus easy to interpret. The calibration of the model parameters is performed using progressive batching sub-sampled quasi-Newton minimization, using a designed distance measure between the synthetic samples and the data. Then, employing a fast sampling algorithm, an arbitrary number of synthetic samples can be generated to use in Monte Carlo type methods for prediction of effective material properties. In particular, we illustrate the method in application to UQ of the elasto-plastic response of an imperfect octet-truss lattice which plays an important role in additive manufacturing. To this end, we study the effective material properties of the lattice unit cell under elasto-plastic deformations and investigate the sensitivity of the effective Young’s modulus to the imperfections.
ISSN:0045-7825
1879-2138
DOI:10.1016/j.cma.2022.115278