Capturing Dynamic Behaviors of a Rate Sensitive, Elastomer with Strain Energy Absorptions and Dissipation Effects

Ali, Shahzad Fateh; Fan, Jihui

doi:10.1142/s1758825121501040

Cited by 9 publications

(2 citation statements)

References 37 publications

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“…When the glass transition temperature is higher than room temperature, the polymers are flexible, like rubber, elastomers, etc. Such polymers have a large deformation capability and improved strength at a high strain rate [ 63 , 64 , 65 , 66 ]. Thus, these polymers are a promising candidate for energy absorption in impact engineering.…”

Section: Discussionmentioning

confidence: 99%

Interpretable Machine Learning Framework to Predict the Glass Transition Temperature of Polymers

Uddin,

Fan

2024

Polymers

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The glass transition temperature of polymers is a key parameter in meeting the application requirements for energy absorption. Previous studies have provided some data from slow, expensive trial-and-error procedures. By recognizing these data, machine learning algorithms are able to extract valuable knowledge and disclose essential insights. In this study, a dataset of 7174 samples was utilized. The polymers were numerically represented using two methods: Morgan fingerprint and molecular descriptor. During preprocessing, the dataset was scaled using a standard scaler technique. We removed the features with small variance from the dataset and used the Pearson correlation technique to exclude the features that were highly connected. Then, the most significant features were selected using the recursive feature elimination method. Nine machine learning techniques were employed to predict the glass transition temperature and tune their hyperparameters. The models were compared using the performance metrics of mean absolute error (MAE), root mean square error (RMSE), and coefficient of determination (R2). We observed that the extra tree regressor provided the best results. Significant features were also identified using statistical machine learning methods. The SHAP method was also employed to demonstrate the influence of each feature on the model’s output. This framework can be adaptable to other properties at a low computational expense.

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Section: Discussionmentioning

confidence: 99%

Interpretable Machine Learning Framework to Predict the Glass Transition Temperature of Polymers

Uddin,

Fan

2024

Polymers

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“…The geometrical parameters of the flexible probabilistic mechanical fastener of the baseline group are detailed in Table 1. The experimental obtained constitutive relationship of novel modified polyurethane [13,14] adopted in the research is plotted in Fig. 4.…”

Section: Design and Modelingmentioning

confidence: 99%

Mechanical property analysis of a novel peel-speed sensitive flexible fastener

Zhang¹,

Xie²,

Fang³

et al. 2022

Vib. proced.

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A design of peel-speed sensitive flexible fastener was proposed based on a novel modified polyurethane. Taking the microtrichia of the head-arrester system of lestes barbarous as the bionic prototype, the structure of the micro protuberance was designed as self-mating type with hemispherical caps. Considering the nonlinearities of contact behavior and of the material property, a micromechanical model of typical interlocking element is established. Adopting the explicit dynamics finite element method, the mechanical responses of fastener in peeling are analyzed. The detachment of interlocking element is predicated by taking the total strain energy as an indicator. The influences of peel speed and friction coefficient on the mechanical performances are parametrically studied. The results show that the maximum peel force and the strength increased with respect to the enhancing peel speed because of the intrinsic nonlinearity in the constitutive relation of novel modified polyurethane the investigation adopted. With larger friction coefficient, the maximum peel force, the total strain energy and the corresponding de-adhesion displacements are respectively enhanced.

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Numerical model for penetration process of a deformable projectile into ductile metallic target plate considering the interaction of projectile and target

Cao,

Fan

2025

International Journal of Impact Engineering

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Capturing Dynamic Behaviors of a Rate Sensitive, Elastomer with Strain Energy Absorptions and Dissipation Effects

Cited by 9 publications

References 37 publications

Interpretable Machine Learning Framework to Predict the Glass Transition Temperature of Polymers

Interpretable Machine Learning Framework to Predict the Glass Transition Temperature of Polymers

Mechanical property analysis of a novel peel-speed sensitive flexible fastener

Numerical model for penetration process of a deformable projectile into ductile metallic target plate considering the interaction of projectile and target

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