Advances in Pure Mathematics

Volume 6, Issue 9 (August 2016)

ISSN Print: 2160-0368   ISSN Online: 2160-0384

Google-based Impact Factor: 0.48  Citations  

Continuum Constitutive Modeling for Isotropic Hyperelastic Materials

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DOI: 10.4236/apm.2016.69046    3,093 Downloads   5,292 Views  Citations
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ABSTRACT

The partial differential equation for isotropic hyperelastic constitutive models has been postulated and derived from the balance between stored energy and stress work done. The partial differential equation as a function of three invariants has then been solved by Lie group methods. With geometric meanings of deformations, the general solution boils down to a particular three-term solution. The particular solution has been applied for several isotropic hyperelastic materials. For incompressible materials, vulcanized rubber containing 8% sulfur and Entec Enflex S4035A thermoplastic elastomer, three coefficients have been determined from uniaxial tension data and applied to predict the pure shear and equibiaxial tension modes. For a slightly compressible rubber material, the coefficients have also been extracted from the confined volumetric test data.

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Zhao, F. (2016) Continuum Constitutive Modeling for Isotropic Hyperelastic Materials. Advances in Pure Mathematics, 6, 571-582. doi: 10.4236/apm.2016.69046.

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