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Analytical Solutions for Axisymmetric Normal Loadings Acting on a Particulate Composite Modeled as a Mixture of Two Linear Elastic Solids

Published online by Cambridge University Press:  15 May 2017

E. Kurt
Affiliation:
Faculty of Mechanical Engineeringİstanbul Technical Universityİstanbul, Turkey
M. S. Dokuz*
Affiliation:
Faculty of Mechanical Engineeringİstanbul Technical Universityİstanbul, Turkey
*
*Corresponding author (dokuzme@itu.edu.tr)
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Abstract

Constitutive equations, based on continuum mechanics and representing behavior of a mixture of two elastic solids, can be used for modeling of materials such as particulate composites. In this study, the behavior of continuum of a mixture occupying half-space under axisymmetric loads is calculated using Fourier and Hankel transform methods. For this purpose, Love's strain functions are used and the general solution of problem under proper boundary conditions is presented. By applying the results obtained to the sinusoidal distributed vertical load and Boussinesq problems that require the use of Cartesian and cylindrical coordinate systems, displacement vectors, diffusive force vector and components of stress tensors are calculated. At the end of the study, the experimental results of a special particulate composite are used to check the accuracy of the solutions obtained.

Type
Research Article
Copyright
Copyright © The Society of Theoretical and Applied Mechanics 2018 

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References

1. Truesdell, C. and Toupin, R., “The Classical Field Theories,” Handbuch der Physik, III/1, Flügge, S (ed), Springer-Verlag, Berlin (1960).Google Scholar
2. Green, A. E. and Naghdi, P. M., “A Dynamical Theory of Interacting Continua,” International Journal of Engineering Science, 3, pp. 231241 (1965).Google Scholar
3. Bowen, R. M., “Theory of Mixtures,” Continuum Physics, III/1, Eringen, A. C. (ed), Academic Press, New York (1976).Google Scholar
4. Atkin, R. J. and Craine, R. E., “Continuum Theories of Mixtures: Basic Theory and Historical Development,” The Quarterly Journal of Mechanics and Applied Mathematics, 29, pp. 209245 (1976).Google Scholar
5. Bedford, A. and Drumheller, D. S., “Theory of Immiscible and Structured Mixtures,” International Journal of Engineering Science, 21, pp. 863960 (1983).Google Scholar
6. Rajagopal, K. R. and Tao, L., Mechanics of Mixtures, World Scientific, Singapore (1995).Google Scholar
7. Green, A. E. and Steel, T. R., “Constitutive Equations for Interacting Continua,” International Journal of Engineering Science, 4, pp. 483500 (1966).Google Scholar
8. Bowen, R. M. and Wiese, J. C., “Diffusion in Mixtures of Elastic Materials,” International Journal of Engineering Science, 7, pp. 689722 (1969).Google Scholar
9. Rushchitskii, Y. Y., “On Simple Waves in Solid Mixtures,” Prikladnaia Mekhanika, 32, pp. 4045 (1996).Google Scholar
10. Rushchitsky, J. J., “On Structural Mixture Theory Applied to Elastic Isotropic Materials with Internal Three-Component Nanoscale Structure,” International Applied Mechanics, 44, pp. 12331243 (2008).Google Scholar
11. Ieşan, D., “On the Theory of Mixtures of Elastic Solids,” Journal of Elasticity, 35, pp. 251268 (1994).Google Scholar
12. Ieşan, D., “A Theory of Mixtures with Different Constituent Temperatures,” Journal of Thermal Stresses, 20, pp. 147167 (1997).Google Scholar
13. Ieşan, D., “Prestressed Composite Modelled as Interacting Solid Continua,” Nonlinear Analysis: Real World Applications, 12, pp. 513524 (2011).Google Scholar
14. Ciarletta, M., “On Mixtures of Nonsimple Elastic Solids,” International Journal of Engineering Science, 36, pp. 655668 (1998).Google Scholar
15. Burchuladze, T. and Svanadze, M., “Potential Method in the Linear Theory of Binary Mixtures of Thermoelastic Solids,” Journal of Thermal Stresses, 23, pp. 601626 (2000).Google Scholar
16. Passarella, F. and Zampoli, V., “Some Results on the Spatial Behavior of Elastic Mixtures,” European Journal of Mechanics-A/Solids, 25, pp. 10311040 (2006).Google Scholar
17. Leseduarte, M. C. and Quintanilla, R., “Saint-Venant Decay Rates for an Anisotropic and Non-Homogeneous Mixture of Elastic Solids in Anti-Plane Shear,” International Journal of Solids and Structures, 45, pp. 16971712 (2008).Google Scholar
18. Simchuk, Y. V. and Priz, S. N., “A Linear Structural Theory of Isotropic Three-Component Mixture,” International Applied Mechanics, 46, pp. 763770 (2010).Google Scholar
19. Muti, S. and Dokuz, M. S., “Two-Dimensional Beltrami–Michell Equations for a Mixture of Two Linear Elastic Solids and Some Applications Using the Airy Stress Function,” International Journal of Solids and Structures, 59, pp. 140146 (2015).Google Scholar
20. Steel, T. R., “Applications of a Theory of Interacting Continua,” The Quarterly Journal of Mechanics and Applied Mathematics, 20, pp. 5772 (1967).Google Scholar
21. Steel, T. R., “Determination of the Constitutive Coefficients for a Mixture of Two Solids,” International Journal of Solids and Structures, 4, pp. 11491160 (1968).Google Scholar
22. Dokuz, M. S. and Gürgöze, İ. T., “The Galerkin Vector Solution for a Mixture of Two Elastic Solids and Boussinesq Problem,” International Journal of Engineering Science, 40, pp. 211222 (2002).Google Scholar
23. Gürgöze, İ. T. and Dokuz, M. S., “Papkovich-Neuber Solution for a Mixture of Two Elastic Solids and Kelvin Problem,” International Journal of Engineering Science, 37, pp. 497507 (1999).Google Scholar
24. Dokuz, M. S., “An Analytical Procedure to Determine Constitutive Coefficients of a Mixture of Two Linear Elastic Ssolids,” International Journal of Solids and Structures, 42, pp. 805817 (2005).Google Scholar
25. Steel, T. R., “Linearised Theory of Plane Strain of a Mixture of Two Solids,” International Journal of Engineering Science, 5, pp. 775789 (1967).Google Scholar
26. Ghiba, I. D. and Galeş, C., “On the Fundamental Solutions for Micropolar Fluid-Fluid under Steady State Vibrations,” Applied Mathematics and Computation, 219, pp. 27492759 (2012).Google Scholar
27. Ciarletta, M., “General Theorems and Fundamental Solutions in the Dynamical Theory of Mixtures,” Journal of Elasticity, 39, 229246 (1995).Google Scholar
28. Ghiba, I. D., “Representation Theorems and Fundamental Solutions for Micropolar Solid-Fuid Mixtures under Steady State Vibrations,” European Journal of Mechanics A/Solids, 29, pp. 10341041 (2010).Google Scholar
29. Svanadze, M., “Representation of the General Solution of the Equation of Steady Oscillations of Two-Component Elastic Mixtures,” International Applied Mechanics, 29, pp. 2229 (1993).Google Scholar
30. Binark, N. K. and Dokuz, M. S., “Analytical Relations for the Undetermined Constitutive Coefficients of a Binary Mixture of Elastic Solids with No Relative Component Motion and an Application for Semi-Infinite Mixture Continuum,” International Journal of Engineering Science, 111, pp. 111 (2017).Google Scholar
31. Hsieh, C. L., Tuan, W. H. and Wu, T. T., “Elastic Behaviour of a Model Two-Phase Material,” Journal of the European Ceramic Society, 24, pp. 37893793 (2004).Google Scholar