Developing a visco-hyperelastic material model for 3D finite deformation of elastomers

Developing a visco-hyperelastic material model for 3D finite deformation of elastomers

In this research, using a phenomenological strain energy function, a 3D visco-hyperelastic constitutive equation for the finite deformation of elastomers is developed. For the quasi-static response, a strain energy function, composed of two exponential terms, is employed. The same energy function is...

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Bibliographic Details
Published in:Finite elements in analysis and design Vol. 140; pp. 1 - 10
Main Authors: Fahimi, Shayan, Baghani, Mostafa, Zakerzadeh, Mohammad-Reza, Eskandari, AmirHossein
Format: Journal Article
Language:English
Published: Amsterdam Elsevier B.V 15-02-2018
Elsevier BV
Subjects:
Computer simulation
Constitutive equations
Constitutive relationships
Deformation
Elastomers
Energy consumption
Finite element analysis
Finite-strain deformation
Mathematical models
Multiple objective analysis
Optimization algorithms
Parameters
Recursive methods
Relaxation time
Simulation
Strain rate
Three dimensional models
Time dependence
Time-dependent response
Visco-hyperelastic material model
Viscoelasticity
Time-dependent response
Finite-strain deformation
Finite element analysis
Visco-hyperelastic material model
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Summary:In this research, using a phenomenological strain energy function, a 3D visco-hyperelastic constitutive equation for the finite deformation of elastomers is developed. For the quasi-static response, a strain energy function, composed of two exponential terms, is employed. The same energy function is considered as the kernel in the hereditary integral approach to derive the visco-hyperelastic model for the time-dependent response. To reduce the number of material parameters, an inverse power-law function between relaxation time and strain rate is proposed. Discretization of the analytical formulation of the visco-hyperelastic model in time is performed to be used in numerical simulations. This approach provides a recursive formulation to update the stress in each time step based on the deformation history. Then, the model is used to study the behavior of elastomeric bushing in radial, torsional and axial deformations. In all these cases, the material parameters are determined by applying a multi-objective optimization algorithm, in which the objective function is the difference between experimental and numerical results. The proposed visco-hyperelastic model shows accurate results for elastomers under 3D quasi-static and time-dependent loadings. Moreover, the accuracy of the results is not dependent on the amount of strain, the strain rate, and modes of deformation. •A new strain energy function is presented for a phenomenological visco-hyperelastic material model.•The numerical formulation is developed to apply in explicit finite element analysis.•A multi-objective optimization method is employed to calibrate the material parameters.•The model is used to predict behavior of elastomeric bushing in real-world 3D tests.
ISSN:0168-874X
1872-6925
DOI:10.1016/j.finel.2017.10.009