Rapid inverse calibration of a multiscale model for the viscoplastic and creep behavior of short fiber-reinforced thermoplastics based on Deep Material Networks

In this work, we propose to use deep material networks (DMNs) as a surrogate model for full-field computational homogenization to inversely identify material parameters of constitutive inelastic models for short fiber-reinforced thermoplastics (SFRTs). Micromechanics offers an elegant way to obtain...

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Bibliographic Details
Published in:International journal of plasticity 2023-01, Vol.160, p.103484, Article 103484
Main Authors: Dey, Argha Protim, Welschinger, Fabian, Schneider, Matti, Gajek, Sebastian, Böhlke, Thomas
Format: Article
Language:English
Subjects:
Creep
Deep material networks
Inverse parameter identification
Multiscale model
Short fiber reinforced thermoplastics
Viscoplasticity
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Summary:In this work, we propose to use deep material networks (DMNs) as a surrogate model for full-field computational homogenization to inversely identify material parameters of constitutive inelastic models for short fiber-reinforced thermoplastics (SFRTs). Micromechanics offers an elegant way to obtain constitutive models of materials with complex microstructure, as these emerge naturally once an accurate geometrical representation of the microstructure and expressive material models of the constituents forming the material are known. Unfortunately, obtaining the latter is non-trivial, essentially for two reasons. For a start, experiments on pure samples may not accurately represent the conditions present in the composite. Moreover, the manufacturing process may alter the material behavior, and a subsequent modification is necessary. To avoid modeling the physics of the manufacturing process, one may identify the material models of the individual phases of the composite based on experiments on the composite. Unfortunately, this procedure requires conducting time-consuming simulations. In the work at hand, we use Deep Material Networks to replace full-field simulations, and to carry out an inverse parameter optimization of the matrix model in a SFRT. We are specifically concerned with the long-term creep response of SFRTs, which is particularly challenging to both experimental and simulation-based approaches due to the strong anisotropy and the long time scales involved. We propose a dedicated fully coupled plasticity and creep model for the polymer matrix and provide details on the experimental procedures. •We propose an inverse calibration method for the matrix model in a fiber reinforced thermoplastic.•A novel creep plasticity model is introduced.•Deep Material Networks are used to replace full-field micromechanical simulations.•Potential error sourced in the microstructure characteristics are investigated.•The approach is validated with creep tests in complimentary directions.
ISSN:0749-6419
1879-2154
DOI:10.1016/j.ijplas.2022.103484