Finite element simulation of rate-dependent damage in elastomers Finite element simulation of rate-dependent damage in elastomers

Predicting the mechanical response and damage evolution of elastomers under large deformation is of great significance in engineering applications. In this work, a finite element (FE) scheme is formulated and used to simulate rate-dependent damage in elastomers. While based on the theoretical model...

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Published inInternational journal of fracture Vol. 249; no. 1; p. 10
Main Authors Wang, Pinyi, Lavoie, Shawn R., Tang, Tian
Format Journal Article
LanguageEnglish
Published Dordrecht Springer Netherlands 01.02.2025
Springer Nature B.V
Subjects
Algorithms
Automotive Engineering
Chain scission
Characterization and Evaluation of Materials
Civil Engineering
Classical Mechanics
Compressibility
Crack tips
Damage
Defects
Deformation
Elastomers
Engineering
Finite element method
Mechanical analysis
Mechanical Engineering
Polydispersity
Damage model
Rate dependent scission
Finite element analysis
Finite strain
Polydispersity
Elastomer
Online AccessGet full text
ISSN0376-9429
1573-2673
DOI10.1007/s10704-024-00818-y

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Abstract Predicting the mechanical response and damage evolution of elastomers under large deformation is of great significance in engineering applications. In this work, a finite element (FE) scheme is formulated and used to simulate rate-dependent damage in elastomers. While based on the theoretical model of Lavoie et al. (Extrem Mech Lett 8:114–124, 2016) and maintaining the key features such as kinetics of chain scission and polydispersity, the FE scheme presented here includes the consideration of finite compressibility. Both implicit and explicit algorithms are derived and implemented as user subroutines in ABAQUS. Validated against existing numerical results as well as experimental data on homogeneous deformation, the capability of the FE scheme to solve problems involving inhomogeneous deformation is further explored by simulating samples with pre-existing defects. The numerical results can successfully capture several interesting phenomena, such as crack blunting, stress reduction near defect caused by damage, and rate-dependent damage evolution. Good agreement is also found with experimental data on the strain field near a crack tip.
AbstractList Predicting the mechanical response and damage evolution of elastomers under large deformation is of great significance in engineering applications. In this work, a finite element (FE) scheme is formulated and used to simulate rate-dependent damage in elastomers. While based on the theoretical model of Lavoie et al. (Extrem Mech Lett 8:114–124, 2016) and maintaining the key features such as kinetics of chain scission and polydispersity, the FE scheme presented here includes the consideration of finite compressibility. Both implicit and explicit algorithms are derived and implemented as user subroutines in ABAQUS. Validated against existing numerical results as well as experimental data on homogeneous deformation, the capability of the FE scheme to solve problems involving inhomogeneous deformation is further explored by simulating samples with pre-existing defects. The numerical results can successfully capture several interesting phenomena, such as crack blunting, stress reduction near defect caused by damage, and rate-dependent damage evolution. Good agreement is also found with experimental data on the strain field near a crack tip.
ArticleNumber 10
Author Lavoie, Shawn R.
Wang, Pinyi
Tang, Tian
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  surname: Lavoie
  fullname: Lavoie, Shawn R.
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  givenname: Tian
  surname: Tang
  fullname: Tang, Tian
  email: ttang1@ualberta.ca, tian.tang@ualberta.ca
  organization: Department of Mechanical Engineering, University of Alberta
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Issue 1
Keywords Damage model
Rate dependent scission
Finite element analysis
Finite strain
Polydispersity
Elastomer
Language English
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Snippet Predicting the mechanical response and damage evolution of elastomers under large deformation is of great significance in engineering applications. In this...
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SubjectTerms Algorithms
Automotive Engineering
Chain scission
Characterization and Evaluation of Materials
Civil Engineering
Classical Mechanics
Compressibility
Crack tips
Damage
Defects
Deformation
Elastomers
Engineering
Finite element method
Mechanical analysis
Mechanical Engineering
Polydispersity
Subtitle Finite element simulation of rate-dependent damage in elastomers
Title Finite element simulation of rate-dependent damage in elastomers
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