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Mechanical Behavior Modeling of Hyperelastic Transversely Isotropic Materials Based on a New Polyconvex Strain Energy Function

D. M. Taghizadeh

Mechanical Engineering Department, Shahid Bahonar University of Kerman, Kerman, Iran

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H. Darijani

Mechanical Engineering Department, Shahid Bahonar University of Kerman, Kerman, Iran

E-mail Address: darijani@uk.ac.ir

E-mail Address: hdarijani@gmail.com

Corresponding author.

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https://doi.org/10.1142/S1758825118501041Cited by:15 (Source: Crossref)

Abstract

In this paper, the mechanical behavior of incompressible transversely isotropic materials is modeled using a strain energy density in the framework of Ball’s theory. Based on this profound theory and with respect to physical and mathematical aspects of deformation invariants, a new polyconvex constitutive model is proposed for the mechanical behavior of these materials. From the physical viewpoint, it is assumed that the proposed model is additively decomposed into three parts nominally representing the energy contributions from the matrix, fiber and fiber–matrix interaction where each of the parts should be presented in terms of the invariants consistent with the physics of the deformation. From the mathematical viewpoint, the proposed model satisfies the fundamental postulates on the form of strain energy density, specially polyconvexity and coercivity constraints. Indeed, polyconvexity ensures ellipticity condition, which in turn provides material stability and in combination with coercivity condition, guarantees the existence of the global minimizer of the total energy. In order to evaluate the performance of the proposed strain energy density function, some test data of incompressible transverse materials with pure homogeneous deformations are used. It is shown that there is a good agreement between the test data and the obtained results from the proposed model. At the end, the performance of the proposed model in the prediction of the material behavior is evaluated rather than other models for two representative problems.

Keywords:

References

Ball, J. M. [1977] “ Convexity conditions and existence theorems in non-linear elasticity,” Archive of Rational Mechanics and Analysis 63, 337–403. Web of Science, Google Scholar
Balzani, D., Neff, P., Schröder, J. and Holzapfel, G. A. [2006] “ A polyconvex framework for soft biological tissues. Adjustment to experimental data,” International Journal of Solides and Structures 43(20), 6052–6070. Web of Science, Google Scholar
Balzani, D., Schröder, J. and Neff, P. [2010] “ Applications of anisotropic polyconvex energies: Thin shells and biomechanics of arterial walls,” Poly-, Quasi- and Rank-One Convexity in Applied Mechanics, CISM Lecture Notes, Springer, Vol. 516, pp. 131–157. Google Scholar
Beju, I. [1971] “ Theorems on existence, uniqueness and stability of the solution of the place boundary-value problem, in statics, for hyperelastic materials,” Archive for Rational Mechanics and Analysis 42, 1–23. Web of Science, Google Scholar
Boehler, J. P. [1979] “ A simple derivation of representations for nonpolynomial constitutive equations in some cases of anisotropy” ZAMM 59, 157–167. Web of Science, Google Scholar
Boehler, J. P. [1987] “ Introduction to the invariant formulation of anisotropic constitutive equations,” Applications of Tensor Functions in Solid Mechanics, CISM Course and Lectures, ed. J. P. Boehler , Springer, Vol. 292, pp. 13–30. Google Scholar
Chagnon, G., Rebouah, M. and Favier, D. [2015] “ Hyperelastic energy densities for soft biological tissues: A review,” Journal of Elasticity 120(2), 129–160. Web of Science, Google Scholar
Ciarlet, P. G. [1988] “ Three dimensional elasticity,” Mathematical Elasticity, Vol. 1 (Elsevier Science Publishers, BV, North-Holland). Google Scholar
Ciarlet, P. G. and Nečas, J. [1987] “ Injectivity and self-contact in nonlinear elasticity,” Archive for Rational Mechanics and Analysis 97, 171–188. Web of Science, Google Scholar
Criscione, J. C., Douglas, A. S. and Hunter, W. C. [2001] “ Physically based strain invariant set for materials exhibiting transversely isotropic behavior,” Journal of the Mechanics and Physics of Solids 49(4), 871–897. Web of Science, Google Scholar
Dacorogna, B. [1989] “ Direct methods in the calculus of variations,” Applied Mathematical Science, Vol. 78 (Springer-Verlag). Google Scholar
Destrade, M., Mac Donald, B., Murphy, J. G. and Saccomandi, G. [2013] “ At least three invariants are necessary to model the mechanical response of incompressible, transversely isotropic materials,” Computational Mechanics 52, 959–969. Web of Science, Google Scholar
Dokos, S., Smaill, B. H., Young, A. A. and LeGrice, I. J. [2002] “ Shear properties of passiveventricular myocardium,” American Journal of Physiology Heart and Circulatory Physiology 283, H2650–H2659. Web of Science, Google Scholar
Epstein, M. [2012] The Elements of Continuum Biomechanics (John Wiley & Sons). Google Scholar
Feng, Y., Okamoto, R. J., Namani, R., Genin, G. M. and Bayly, P. V. [2013] “ Measurements of mechanical anisotropy in brain tissue and implications for transversely isotropic material models of white matter,” Journal of the Mechanical Behaviour of Biomedical Meterials 23, 117–132. Web of Science, Google Scholar
Fujita, Y., Wagner, D. R., Biviji, A. A., Duncan, N. A. and Lotz, J. C. [2000] “ Anisotropic shear behavior of the annulus fibrosus: Effect of harvest site and tissue prestrain,” Medical Engineering and Physics 22, 349–357. Web of Science, Google Scholar
Gardiner, J. C. and Weiss, J. A. [2001] “ Simple shear testing of parallel fibered planar soft tissue,” ASME Journal of Biomechanical Engineering 123, 170–175. Web of Science, Google Scholar
Glodež, S., Dervaric, S., Kramberger, J. and Šraml, M. [2016] “ Fatigue crack initiation and propagation in lotus-type porous material,” Frattura ed Integrità Strutturale 35, 152–160. Google Scholar
Guo, Z. and Caner, F. C. [2010] “ Mechanical behaviour of transversely isotropic porous neo-hookean solids,” International Journal of Applied Mechanics 2(1), 11–39. Link, Web of Science, Google Scholar
Guo, Z. Y., Peng, X. Q. and Moran, B. [2006] “ A composites-based hyperelastic constitutive model for soft tissue with application to the human annulus fibrosus,” Journal of Mechanics and Physics of Solids 54(9), 1952–1971. Web of Science, Google Scholar
Hartmann, S. and Neff, P. [2003] “ Polyconvexity of generalized polynomial-type hyperelastic strain energy functions for near-incompressibility,” International Journal of Solids and Structures 40, 2767–2791. Web of Science, Google Scholar
Hill, R. [1957] “ On uniqueness and stability in the theory of finite elastic strain,” Journal of Mechnics and Physics Solids 5, 229–241. Web of Science, Google Scholar
Holzapfel, G. A. , [2000] Nonlinear Solid Mechanics: A Continuum Approach for Engineering, John Wiley & Sons, Chichester. Google Scholar
Holzapfel, G. A., Schulze-Bauer, C. A. J., Feigl, G. and Regitnig, P. [2005] “ Single lamellar mechanics of the human lumbar anulus fibrosus,” Biomechanics and Modeling Mechanobiology 3, 125–140. Web of Science, Google Scholar
Holzapfel, G. A., Gasser, Th. C. and Ogden, R. W. [2000] “ A new constitutive framework for arterial wall mechanics and a comparative study of material models,” Journal of Elasticity 61, 1–48. Web of Science, Google Scholar
Horgan, C. O. and Saccomandi, G. [2005] “ A new constitutive theory for fiber reinforced incompressible nonlinearly elastic solids,” Journal of Mechanics and Physics of Solids 53, 1985–2015. Web of Science, Google Scholar
Itskov, M. and Aksel, A. [2004] “ A class of orthotropic and transversely isotropic hyperelastic constitutive models based on a polyconvex strain energy function,” International Journal of Solids and Structures 41, 3833–3848. Web of Science, Google Scholar
Itskov, M., Ehret, A. E. and Mavrilas, D. [2006] “ A polyconvex anisotropic. strain-energy function for soft collagenous tissues,” Biomechanics of Modeling Mechanbiology 5, 17–26. Web of Science, Google Scholar
Kulkarni, S. G., Gao, X-L., Horner, S. E., Mortlock, R. F. and Zheng, J. Q. [2014] “ A transversely isotropic visco-hyperelastic constitutive model for soft tissues,” Mathematics and Mechanics of Solids, 1–24. Web of Science, Google Scholar
Lai, W. M., Rubin, D. and Krempl, E. [2010] Introduction to Continuum Mechanics, 4th edition (Butterworth Hermann). Google Scholar
Markert, B., Ehlers, W. and Karajan, N. [2005] “ general polyconvex strain energy function for fiber-reinforced materials,” Proceeding in Applied Mathematics and Mechanics 5, 245–246. Google Scholar
Marsden, J. E. and Hughes, J. R. [1983] Mathematical Foundations of Elasticity (Prentice-Hall). Google Scholar
Merodio, J. and Ogden, R. W. [2002] “ Material instabilities in fiber-reinforced nonlinearly elastic solids under plane deformation,” Archives of Mechanics 54, 525–552. Google Scholar
Merodio, J. and Ogden, R. W. [2005] “ Mechanical response of fiber-reinforced incompressible non-linearly elastic solids,” International Journal of Non-linear Mechanics 40(2–3), 213–227. Web of Science, Google Scholar
Morrey, [1952] “ Quasi-convexity and the lower semicontinuity of multiple integrals,” Pacific Journal of Mathematics 2, 25–53. Google Scholar
Murphy, J. G. [2013] “ Transversely isotropic biological soft tissue must be modelled using both anisotropic invariants,” European Journal of Mechanics A/Solids 42, 90–96. Web of Science, Google Scholar
Nakajima, H. [2013] Porous Metals with Directional Pores (Springer, Japan). Google Scholar
Oden, J. T. [1973] “ Approximations and numerical analysis of finite deformations of elastic solids,” Nonlinear Elasticity, ed. R. W. DICKEY (Academic Press, New York). Google Scholar
Ogden, R. W. [1997] Non-Linear Elastic Deformations (Dover Publications, Mineola, New York). Google Scholar
Ogden, R. W., Saccomandi, G. and Sgura, I. [2004] “ Fitting hyperelastic models to experimental data,” Computational Mechanics 34(6), 484–502. Web of Science, Google Scholar
Panoskaltsis, V. P. and Soldatos, D. [2013] “ A phenomenological constitutive model of non-conventional elastic response,” International Journal of Applied Mechanics 5(4), 1350036. Link, Web of Science, Google Scholar
Pedregal, P. [2000] Variational Methods in Nonlinear Elasticity (SIAM, Philadelphia, PA). Google Scholar
Peng, X. Q., Guo, Z. Y. and Moran, B. [2006] “ An anisotropic hyperelastic constitutive model with fiber–matrix shear interaction for the human annulus fibrosus,” Journal of Applied Mechanics 73(5), 815–824. Web of Science, Google Scholar
Pioletti, D. P., Rakotomanana, L. R., Benvenuti, J. and Leyvraz, P. [1998] “ Viscoelastic constitutive law in large deformations: Applications to human knee ligaments and tendons,” Journal of Biomechanics 31, 753–757. Web of Science, Google Scholar
Pucci, E. and Saccomandi, G. [2014] “ On the use of universal relations in the modeling of transversely isotropic materials,” International Journal of Solids and Structures 51, 377–380. Web of Science, Google Scholar
Qiu, G. Y. and Pence, T. J. [1997] “ Remarks on the behavior of simple directionally reinforced incompressible nonlinearly elastic spheres,” Journal of Elasticity 49, 1–30. Web of Science, Google Scholar
Quapp, K. M. and Weiss, J. A. [1998] “ Material characterization of human medial collateral ligament,” ASME Journal of Biomechanical Engineering 120, 757–763. Web of Science, Google Scholar
Raoult, A. [2010] “ Quasiconvex envelopes in nonlinear elasticity,” Poly-, Quasi- and Rank-one Convexity in Applied Mechanics, eds. J. Schröder and P. Neff , CISM Lecture Notes, Springer, Vol. 516, pp. 17–51. Google Scholar
Sacks, M. S. [2000] “ Biaxial mechanical evaluation of planar biological materials,” Journal of Elasticity 61, 199–246. Web of Science, Google Scholar
Schröder, J. [2010] “ Anisotropic polyconvex energies,” Poly-, Quasi- and Rank-one Convexity in Applied Mechanics, eds. J. Schröder and P. Neff , CISM Lecture Notes, Springer, Vol. 516, pp. 53–105. Google Scholar
Schröder, J. and Neff, P. [2001] “ On the construction of polyconvex anisotropic free energy functions,” Proceedings of the IUTAM Symposium on Computational Mechanics of Solid Materials at Large Strains, ed. C. Miehe (Kluwer Academic Publishers, Dordrecht), pp. 171–180. Google Scholar
Schröder, J. and Neff, P. [2003] “ Invariant formulation of hyperelastic transverse isotropy based on polyconvex free energy functions,” International Journal of Solids and Structures 40, 401–445. Web of Science, Google Scholar
Schröder, J., Neff, P. and Balzani, D. [2004] “ A variational approach for materially stable anisotropic hyperelasticity,” International Journal of Solids and Structures 42(15), 4352–4371. Web of Science, Google Scholar
Schröder, J., Neff, P. and Ebbing, V. [2008] “ Anisotropic polyconvex energies on the basis of crystallographic motivated structural tensors,” Journal of the Mechanics and Physics of Solids 56, 3486–3506. Web of Science, Google Scholar
Spencer, A. J. M. [1982] “ The formulation of constitutive equation for anisotropic solids,” Mechanical Behavior of Anisotropic Solids, Vol. 295, eds. J. P. Boehler , Martinus Nijhoff Publishers, pp. 3–26. Google Scholar
Spencer, A. J. M. [1992] Continuum Theory of the Mechanics of Fibre-Reinforced Composites (Springer-Verlag, New York). Google Scholar
Steigmann, D. J. [2003] “ Frame-invariant polyconvex strain-energy functions for some anisotropic solids,” Mathematics and Mechanics of Solids 8, 497–506. Web of Science, Google Scholar
Taghizadeh, D. M., Bagheri, A. and Darijani, H. [2015] “ On the hyperelastic pressurized thick-walled spherical shells and cylindrical tubes using the analytical closed-form solutions,” International Journal of Applied Mechanics 7(2), 1550027. Link, Web of Science, Google Scholar
Toh, W., Liu, Z., Ng, T. and Hong, W. [2013] “ Inhomogeneous large deformation kinetics of polymeric gels,” International Journal of Applied Mechanics 5(1), 1350001. Link, Web of Science, Google Scholar
Truesdell, C. and Noll, W. [1965] The Nonlinear Field Theories of Mechanics (Springer-Verlag). Google Scholar
Wang, C. C. and Truesdell, C. [1973] Introduction to Rational Elasticity (Springer-Verlag). Google Scholar
Zheng, Q. S. [1994] “ Theory of representations for tensor functions — A unified invariant approach to constitutive equations,” Applied Mechanics Reviews 47(11), 545–587. Google Scholar