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Prediction of Short Fiber Composite Properties by an Artificial Neural Network Trained on an RVE Database

Kevin Breuer, Markus Stommel

2021Fibers60 citationsDOIOpen Access PDF

Abstract

In this study, an artificial neural network is designed and trained to predict the elastic properties of short fiber reinforced plastics. The results of finite element simulations of three-dimensional representative volume elements are used as a data basis for the neural network. The fiber volume fraction, fiber length, matrix-phase properties, and fiber orientation are varied so that the neural network can be used within a very wide range of parameters. A comparison of the predictions of the neural network with additional finite element simulations shows that the stiffnesses of short fiber reinforced plastics can be predicted very well by the neural network. The average prediction accuracy is equal or better than by a two-step homogenization using the classical method of Mori and Tanaka. Moreover, it is shown that the training of the neural network on an extended data set works well and that particularly calculation-intensive data points can be avoided without loss of prediction quality.

Topics & Concepts

Artificial neural networkFinite element methodHomogenization (climate)FiberMaterials scienceVolume fractionRepresentative elementary volumeComputer scienceBiological systemArtificial intelligenceStructural engineeringComposite materialEngineeringEcologyBiodiversityBiologyComposite Material MechanicsMechanical Behavior of CompositesInnovative concrete reinforcement materials
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