On the accuracy and fitting of transversely isotropic material models

Y Feng, RJ Okamoto, GM Genin, PV Bayly - journal of the mechanical …, 2016 - Elsevier
journal of the mechanical behavior of biomedical materials, 2016Elsevier
Fiber reinforced structures are central to the form and function of biological tissues.
Hyperelastic, transversely isotropic material models are used widely in the modeling and
simulation of such tissues. Many of the most widely used models involve strain energy
functions that include one or both pseudo-invariants (I 4 or I 5) to incorporate energy stored
in the fibers. In a previous study we showed that both of these invariants must be included in
the strain energy function if the material model is to reduce correctly to the well-known …
Fiber reinforced structures are central to the form and function of biological tissues. Hyperelastic, transversely isotropic material models are used widely in the modeling and simulation of such tissues. Many of the most widely used models involve strain energy functions that include one or both pseudo-invariants (I 4 or I 5) to incorporate energy stored in the fibers. In a previous study we showed that both of these invariants must be included in the strain energy function if the material model is to reduce correctly to the well-known framework of transversely isotropic linear elasticity in the limit of small deformations. Even with such a model, fitting of parameters is a challenge. Here, by evaluating the relative roles of I 4 and I 5 in the responses to simple loadings, we identify loading scenarios in which previous models accounting for only one of these invariants can be expected to provide accurate estimation of material response, and identify mechanical tests that have special utility for fitting of transversely isotropic constitutive models. Results provide guidance for fitting of transversely isotropic constitutive models and for interpretation of the predictions of these models.
Elsevier
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