Modeling of Elasticity and Damping for Filled Elastomers
(1997) In TVSM-1000- Abstract
- Elasticity and damping are significant properties of rubber, taken advantage of in engineering applications. It is therefore important that the constitutive model accurately captures these aspects of the mechanical behavior.
In the first part of the thesis a description of theory and experiments for determination of hyperelastic parameters required for finite element analysis is provided. Test specimens and corresponding stress-strain relations for calibration of the hyperelastic models are discussed. Mechanical conditioning procedures are compared and fitting of the models are discussed, with special emphasis on a ``cubic I1'' model proposed by O.H. Yeoh. A strain energy plot to check the quality of the fitted model is... (More) - Elasticity and damping are significant properties of rubber, taken advantage of in engineering applications. It is therefore important that the constitutive model accurately captures these aspects of the mechanical behavior.
In the first part of the thesis a description of theory and experiments for determination of hyperelastic parameters required for finite element analysis is provided. Test specimens and corresponding stress-strain relations for calibration of the hyperelastic models are discussed. Mechanical conditioning procedures are compared and fitting of the models are discussed, with special emphasis on a ``cubic I1'' model proposed by O.H. Yeoh. A strain energy plot to check the quality of the fitted model is presented, which reveals whether the model is valid for use in finite element analysis. The accuracy of existing test specimens, and a new axisymmetric combined compression and tension specimen proposed here, are investigated by finite element analysis. A modified hardness test for evaluation of hyperelastic constants is presented and evaluated by finite element analysis. Moreover, a method for contact-free strain measurement for evaluation of surface strain fields is presented. Experimental deformation gradients can also be obtained by this method.
The second part of the thesis concerns modeling of dynamic material properties of filled rubbers. Experiments show that constitutive models available in commercial finite element codes are not able to model the behavior of filled rubber vulcanizates in dynamic applications. One-dimensional models are used to examine the mechanisms of damping in these rubbers. The ability of the models to capture the frequency and amplitude dependence of the dynamic modulus and equivalent phase angle is investigated. The microstructure and the experimental results support a model with nonlinear elastic, viscous (rate-dependent) and frictional (rate-independent) elements connected in parallel. A generalization of this one-dimensional viscoplastic model to multiaxial and large strains is proposed and evaluated in simple shear and uniaxial stress. (Less)
Please use this url to cite or link to this publication:
https://lup.lub.lu.se/record/18414
- author
- Austrell, Per Erik LU
- supervisor
- opponent
-
- Professor Hibbitt, David, HKS Inc., 1080 Main Street, Pawtucket, RI 02860
- organization
- publishing date
- 1997
- type
- Thesis
- publication status
- published
- subject
- keywords
- rheological models, contact-free strain measurement, modified hardness test, solid dumbbell test specimen, mechanical conditioning, strain energy plot, hyperelasticity, carbon-black-filled rubbers, amplitude dependence, multiaxial viscoplastic model, Building construction, Byggnadsteknik
- in
- TVSM-1000
- issue
- TVSM-1009
- pages
- 222 pages
- publisher
- Structural Mechanics, Lund University
- defense location
- John Ericssons vag 1, V:C
- defense date
- 1997-04-10 10:15:00
- external identifiers
-
- other:LUTVDG/(TVSM-1009)/1-222/(1997)
- language
- English
- LU publication?
- yes
- id
- 9d8a1621-f34f-4e19-91a0-978c1e533e21 (old id 18414)
- date added to LUP
- 2016-04-04 11:25:05
- date last changed
- 2023-10-16 09:53:47
@phdthesis{9d8a1621-f34f-4e19-91a0-978c1e533e21, abstract = {{Elasticity and damping are significant properties of rubber, taken advantage of in engineering applications. It is therefore important that the constitutive model accurately captures these aspects of the mechanical behavior.<br/><br> <br/><br> In the first part of the thesis a description of theory and experiments for determination of hyperelastic parameters required for finite element analysis is provided. Test specimens and corresponding stress-strain relations for calibration of the hyperelastic models are discussed. Mechanical conditioning procedures are compared and fitting of the models are discussed, with special emphasis on a ``cubic I1'' model proposed by O.H. Yeoh. A strain energy plot to check the quality of the fitted model is presented, which reveals whether the model is valid for use in finite element analysis. The accuracy of existing test specimens, and a new axisymmetric combined compression and tension specimen proposed here, are investigated by finite element analysis. A modified hardness test for evaluation of hyperelastic constants is presented and evaluated by finite element analysis. Moreover, a method for contact-free strain measurement for evaluation of surface strain fields is presented. Experimental deformation gradients can also be obtained by this method.<br/><br> <br/><br> The second part of the thesis concerns modeling of dynamic material properties of filled rubbers. Experiments show that constitutive models available in commercial finite element codes are not able to model the behavior of filled rubber vulcanizates in dynamic applications. One-dimensional models are used to examine the mechanisms of damping in these rubbers. The ability of the models to capture the frequency and amplitude dependence of the dynamic modulus and equivalent phase angle is investigated. The microstructure and the experimental results support a model with nonlinear elastic, viscous (rate-dependent) and frictional (rate-independent) elements connected in parallel. A generalization of this one-dimensional viscoplastic model to multiaxial and large strains is proposed and evaluated in simple shear and uniaxial stress.}}, author = {{Austrell, Per Erik}}, keywords = {{rheological models; contact-free strain measurement; modified hardness test; solid dumbbell test specimen; mechanical conditioning; strain energy plot; hyperelasticity; carbon-black-filled rubbers; amplitude dependence; multiaxial viscoplastic model; Building construction; Byggnadsteknik}}, language = {{eng}}, number = {{TVSM-1009}}, publisher = {{Structural Mechanics, Lund University}}, school = {{Lund University}}, series = {{TVSM-1000}}, title = {{Modeling of Elasticity and Damping for Filled Elastomers}}, url = {{https://lup.lub.lu.se/search/files/160169822/web1009.pdf}}, year = {{1997}}, }