Machine learning-based predictions for hydrogel damage induced by cyclic swelling and deswelling (C)
Hydrogels are a type of soft polymer that exhibits non-linear mechanical behaviors and are often used in various industries for their adaptability. However, the most challenging feature is their fracture phenomena which is unpredictable due to countless random crosslinked network structures. Henc...
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| 其他作者: | |
| 格式: | Final Year Project |
| 語言: | English |
| 出版: |
Nanyang Technological University
2024
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| 主題: | |
| 在線閱讀: | https://hdl.handle.net/10356/176897 |
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| 總結: | Hydrogels are a type of soft polymer that exhibits non-linear mechanical behaviors and are
often used in various industries for their adaptability. However, the most challenging feature is
their fracture phenomena which is unpredictable due to countless random crosslinked network
structures. Hence, this research looks more into this soft material.
Deep Learning (DL) is widely used in prediction by learning the underlying patterns within the
data. Convolutional Neural Networks (CNN) are known to deal with images and videos. Hence,
it is being selected as the main DL model for this project. While many studies have researched
on crack propagation in hard materials, there is limited research done using DL models on soft
materials such as hydrogels.
This report will start with an introduction to hydrogels, followed by a literature review on the
fracture mechanics of hydrogel and various CNN models proposed to predict the crack
propagation path on different materials. The data that will be used in the model are images from
the simulations using Matrix Laboratory (MATLAB) and Abaqus software with a total of 300
sets of data. The focus will be on developing and applying four modified CNN modelsto predict
the behavior of the crack propagation path. Finally, the performance of the four modified CNNs
will be compared and the output image from the Abaqus simulation will be used to validate the
accuracy of the prediction. In this project, two modified CNNs show a better performance
among the four models.
This project aims to demonstrate that the neural network model is a potential approach to
predicting a crack propagation path in the hydrogel accurately while reducing the high
computational cost when the randomized molecule density networks of simulated hydrogel
samples become more complex. |
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