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Acta Mechanica

Erschienen in:

02.07.2020 | Original Paper

Inflation, extension and torsion analysis of compressible functionally graded hyperelastic tubes

verfasst von: Maedeh Hajhashemkhani, Mohammad Rahim Hematiyan

Erschienen in: Acta Mechanica | Ausgabe 9/2020

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Abstract

Problems of inflation, extension and torsion of hyperelastic rods and tubes are of great interest for modelling and characterizing rubber-like materials and soft biological tissues. For incompressible and compressible hyperelastic tubes, analytical solutions for the problem of inflation, extension and torsion have not been proposed. In this research, the problem of inflation, extension and torsion of a functionally graded compressible hyperelastic tube is formulated as a one-dimensional problem and is solved using the finite difference method. First, the proposed method is verified against existing analytical and three-dimensional finite element method solutions. After that, by analyzing a number of problems over a wide range of variables, the interactions of inflation, extension and torsion are investigated.

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Tauheed, F., Sarangi, S.: Modelling of damage in finite torsion, extension and inflation of an arterial tissue. In: 6th World Congress of Biomechanics (WCB), pp. 879–882. Springer, Berlin, Heidelberg, Singapore (2010)

Horgan, C.O., Murphy, J.G.: On the modeling of extension–torsion experimental data for transversely isotropic biological soft tissues. J. Elast. 108(2), 179–191 (2012a)MathSciNetMATHCrossRef

Lectez, A.S., Verron, E., Huneau, B., Beranger, A.S., Le Brazidec, F.: Characterization of elastomers under simultaneous tension and torsion for application to engine mounts. In: Proceedings of the 8th European Conference on Constitutive Models for Rubber (ECCMR), Vol. 8, pp. 585-590 (2013)

Lectez, A.S., Verron, E., Huneau, B.: How to identify a hyperelastic constitutive equation for rubber-like materials with multiaxial tension–torsion experiments. Int. J. Non-Linear Mech. 65, 260–270 (2014)CrossRef

Rodríguez, J., Merodio, J.: Helical buckling and postbuckling of pre-stressed cylindrical tubes under finite torsion. Finite Elem. Anal. Des. 112, 1–10 (2016)MathSciNetCrossRef

Polignone, D.A., Horgan, C.O.: Pure torsion of compressible non-linearly elastic circular cylinders. Q. Appl. Math. 49(3), 591–607 (1991)MathSciNetMATHCrossRef

Horgan, C.O., Polignone, D.A.: A note on the pure torsion of a circular cylinder for a compressible nonlinearly elastic material with nonconvex strain-energy. J. Elast. 37(2), 167–178 (1995)MathSciNetMATHCrossRef

Zidi, M.: Combined torsion, circular and axial shearing of a compressible hyperelastic and prestressed tube. J. Appl. Mech. 67(1), 33–40 (1999)MATHCrossRef

Zidi, M.: Finite torsion and anti-plane shear of a compressible hyperelastic and transversely isotropic tube. Int. J. Eng. Sci. 38(13), 1487–1496 (2000)CrossRef

10.

Kirkinis, E., Ogden, R.W.: On extension and torsion of a compressible elastic circular cylinder. Math. Mech. Solids 7(4), 373–392 (2002)MathSciNetMATHCrossRef

11.

Kanner, L.M., Horgan, C.O.: On extension and torsion of strain-stiffening rubber-like elastic circular cylinders. J. Elast. 93(1), 39 (2008)MathSciNetMATHCrossRef

12.

Horgan, C.O., Murphy, J.G.: Torsion of incompressible fiber-reinforced nonlinearly elastic circular cylinders. J. Elast. 103(2), 235–246 (2011)MathSciNetMATHCrossRef

13.

Horgan, C.O., Murphy, J.G.: Finite extension and torsion of fiber-reinforced non-linearly elastic circular cylinders. Int. J. Non-Linear Mech. 47(2), 97–104 (2012)CrossRef

14.

Merodio, J., Ogden, R.W.: Extension, inflation and torsion of a residually stressed circular cylindrical tube. Contin. Mech. Thermodyn. 28(1–2), 157–174 (2016)MathSciNetMATHCrossRef

15.

Valiollahi, A., Shojaeifard, M., Baghani, M.: Closed form solutions for large deformation of cylinders under combined extension–torsion. Int. J. Mech. Sci. 157, 336–347 (2019a)CrossRef

16.

El Hamdaoui, M., Merodio, J., Ogden, R.W., Rodríguez, J.: Finite elastic deformations of transversely isotropic circular cylindrical tubes. Int. J. Solids Struct. 51(5), 1188–1196 (2014)CrossRef

17.

Alhayani, A.A., Rodríguez, J., Merodio, J.: Numerical analysis of neck and bulge propagation in anisotropic tubes subject to axial loading and internal pressure. Finite Elem. Anal. Des. 90, 11–19 (2014)CrossRef

18.

El Hamdaoui, M., Merodio, J., Ogden, R.W.: Loss of ellipticity in the combined helical, axial and radial elastic deformations of a fibre-reinforced circular cylindrical tube. Int. J. Solids Struct. 63, 99–108 (2015)CrossRef

19.

El Hamdaoui, M., Merodio, J., Ogden, R.W.: Deformation induced loss of ellipticity in an anisotropic circular cylindrical tube. J. Eng. Math. 109(1), 31–45 (2018)MathSciNetMATHCrossRef

20.

Anani, Y., Rahimi, G.H.: Stress analysis of thick pressure vessel composed of functionally graded incompressible hyperelastic materials. Int. J. Mech. Sci. 104, 1–7 (2015)CrossRef

21.

Anani, Y., Rahimi, G.H.: Stress analysis of rotating cylindrical shell composed of functionally graded incompressible hyperelastic materials. Int. J. Mech. Sci. 108, 122–128 (2016)CrossRef

22.

Wu, B., Su, Y., Liu, D., Chen, W., Zhang, C.: On propagation of axisymmetric waves in pressurized functionally graded elastomeric hollow cylinders. J. Sound Vib. 421, 17–47 (2018)CrossRef

23.

Pascon, J.P.: Finite element analysis of functionally graded hyperelastic beams under plane stress. Eng. Comput. (2019). https://doi.org/10.1007/s00366-019-00761-wCrossRef

24.

Mohammadi, M., Mohseni, E., Moeinfar, M.: Bending, buckling and free vibration analysis of incompressible functionally graded plates using higher order shear and normal deformable plate theory. Appl. Math. Model. 69, 47–62 (2019)MathSciNetMATHCrossRef

25.

Valiollahi, A., Shojaeifard, M., Baghani, M.: Implementing stretch-based strain energy functions in large coupled axial and torsional deformations of functionally graded cylinder. Int. J. Appl. Mech. 11(04), 1950039 (2019b)CrossRef

26.

Bower, A.F.: Applied Mechanics of Solids. CRC Press, Boca Raton (2009)CrossRef

27.

Tran, H.V., Charleux, F., Rachik, M., Ehrlacher, A., Ho Ba Tho, M.C.: In vivo characterization of the mechanical properties of human skin derived from MRI and indentation techniques. Comput. Methods Biomech. Biomed. Eng. 10(6), 401–407 (2007)CrossRef

28.

Chen, Z., Scheffer, T., Seibert, H., Diebels, S.: Macroindentation of a soft polymer: identification of hyperelasticity and validation by uni/biaxial tensile tests. Mech. Mater. 64, 111–127 (2013)CrossRef

29.

Zisis, T., Zafiropoulou, V.I., Giannakopoulos, A.E.: Evaluation of material properties of incompressible hyperelastic materials based on instrumented indentation of an equal-biaxial prestretched substrate. Int. J. Solids Struct. 64, 132–144 (2015)MATHCrossRef

30.

Hajhashemkhani, M., Hematiyan, M.R.: Determination of material parameters of isotropic and anisotropic hyper-elastic materials using boundary measured data. J. Theor. Appl. Mech. 53(4), 895–910 (2015)CrossRef

31.

Methia, M., Bechir, H., Frachon, A., Hocine, N.A.: An asymptotic finite plane deformation analysis of the elastostatic fields at a crack tip in the framework of hyperelastic, isotropic, and nearly incompressible neo-Hookean materials under mode-I loading. Acta Mech. 231, 929–946 (2020)MathSciNetMATHCrossRef

32.

Hajhashemkhani, M., Hematiyan, M.R., Goenezen, S.: Identification of hyper-viscoelastic material parameters of a soft member connected to another unidentified member by applying a dynamic load. Int. J. Solids Struct. 165, 50–62 (2019)CrossRef

33.

Landauer, A.K., Li, X., Franck, C., Henann, D.L.: Experimental characterization and hyperelastic constitutive modeling of open-cell elastomeric foams. J. Mech. Phys. Solids 133, 103701 (2019)MathSciNetCrossRef

Titel: Inflation, extension and torsion analysis of compressible functionally graded hyperelastic tubes
verfasst von: Maedeh Hajhashemkhani
Mohammad Rahim Hematiyan
Publikationsdatum: 02.07.2020
Verlag: Springer Vienna
Erschienen in: Acta Mechanica / Ausgabe 9/2020
Print ISSN: 0001-5970
Elektronische ISSN: 1619-6937
DOI: https://doi.org/10.1007/s00707-020-02742-3

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