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Vibration Analysis of Non-Uniform Imperfect Functionally Graded Beams with Porosities in Thermal Environment

Published online by Cambridge University Press:  09 October 2017

F. Ebrahimi*
Affiliation:
Department of Mechanical EngineeringImam Khomeini International UniversityQazvin, Iran
M. Hashemi
Affiliation:
Department of Mechanical EngineeringImam Khomeini International UniversityQazvin, Iran
*
*Corresponding author (febrahimy@eng.ikiu.ac.ir)
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Abstract

In the present study, thermo-mechanical vibration behavior of non-uniform beams made of functionally graded (FG) porous material are investigated under different thermal loadings for the first time. It is observed that during the fabrication of functionally graded materials (FGMs) porosities and micro-voids can be occured inside the material, thus in this study vibration analysis of FG beams by considering the effect of these imperfections is performed. Material properties of the FG beam are assumed to be temperature-dependent and vary continuously through thickness direction according to a power-law scheme which is modified to approximate material properties for both even and uneven distributions of the porosities. Different thermal environmental conditions, including uniform, linear and non-linear temperature changes through the thickness direction are considered. The motion equations are derived based on the Euler-Bernoulli beam theory through Hamilton's principle and they are solved applying the differential transformation method (DTM). In order to show the accuracy of the present analysis, comparisons are made with previous researches and an excellent agreement is observed. The obtained results are presented for the thermo-mechanical vibration characteristics of the FG beams such as the influences of various temperature rises, gradient index, porosity volume fraction, taper ratio and the boundary conditions in detail.

Type
Research Article
Copyright
Copyright © The Society of Theoretical and Applied Mechanics 2017 

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References

1. Koizumi, M. and Niino, M., “Overview of FGM Research in Japan,” Mrs Bulletin, 20, pp. 1921 (1995).CrossRefGoogle Scholar
2. Zhao, N., Qiu, P. Y. and Cao, L. L., “Development and Application of Functionally Graded Material,” Advanced Materials Research, 562, pp. 371375 (2012).Google Scholar
3. Leiser, D. B., Rasky, D. and Arnold, J. O., Thermal Protection Systems for Future NASA Space Vehicles (2000).Google Scholar
4. Wang, Y. Q. and Zu, J. W., “Nonlinear Steady-State Responses of Longitudinally Traveling Functionally Graded Material Plates in Contact with Liquid,” Composite Structures, 164, pp. 130144 (2017).CrossRefGoogle Scholar
5. Pradhan, K. K. and Chakraverty, S., “Free Vibration of Euler and Timoshenko Functionally Graded Beams by Rayleigh–Ritz Method,” Composites Part B: Engineering, 51, pp. 175184 (2013).CrossRefGoogle Scholar
6. Pradhan, K. K. and Chakraverty, S., “Effects of Different Shear Deformation Theories on Free Vibration of Functionally Graded Beams,” International Journal of Mechanical Sciences, 82, pp 149160 (2014).CrossRefGoogle Scholar
7. Jin, C. and Wang, X., “Accurate Free Vibration Analysis of Euler Functionally Graded Beams by the Weak Form Quadrature Element Method,” Composite Structures, 125, pp. 4150 (2015).CrossRefGoogle Scholar
8. Şimşek, M., “Fundamental Frequency Analysis of Functionally Graded Beams by Using Different Higher-Order Beam Theories,” Nuclear Engineering and Design, 240, pp. 697705 (2010).CrossRefGoogle Scholar
9. Şimşek, M., “Bi-Directional Functionally Graded Materials (BDFGMs) for Free and Forced Vibration of Timoshenko Beams with Various Boundary Conditions,” Composite Structures, 133, pp. 968978 (2015).CrossRefGoogle Scholar
10. Kumar, S., Mitra, A. and Roy, H., “Geometrically Nonlinear Free Vibration Analysis of Axially Functionally Graded Taper Beams,” Engineering Science and Technology, an International Journal, 18, pp. 579593 (2015).CrossRefGoogle Scholar
11. Huang, Y., Yang, L. E. and Luo, Q. Z., “Free Vibration of Axially Functionally Graded Timoshenko Beams with Non-Uniform Cross-Section,” Composites Part B: Engineering, 45, pp. 14931498 (2013).CrossRefGoogle Scholar
12. Ozgumus, O. O. and Kaya, M. O., “Vibration Analysis of a Rotating Tapered Timoshenko Beam Using DTM,” Meccanica, 45, pp. 3342 (2010).CrossRefGoogle Scholar
13. Zhou, J. K., “Differential Transformation and Its Applications for Electrical Circuits,” Huazhong University Press, Wuhan, pp. 12791289 (1986).Google Scholar
14. Wattanasakulpong, N. and Ungbhakorn, V., “Free Vibration Analysis of Functionally Graded Beams with General Elastically End Constraints by DTM,” World Journal of Mechanics, 2, p. 297 (2012).CrossRefGoogle Scholar
15. Rajasekaran, S., “Differential Transformation and Differential Quadrature Methods for Centrifugally Stiffened Axially Functionally Graded Tapered Beams,” International Journal of Mechanical Sciences, 74, pp. 1531 (2013).CrossRefGoogle Scholar
16. Mahi, A., Bedia, E. A., Tounsi, A. and Mechab, I., “An Analytical Method for Temperature-Dependent Free Vibration Analysis of Functionally Graded Beams with General Boundary Conditions,” Composite Structures, 92, pp. 18771887 (2010).CrossRefGoogle Scholar
17. Fallah, A. and Aghdam, M. M., “Thermo- Mechanical Buckling and Nonlinear Free Vibration Analysis of Functionally Graded Beams on Nonlinear Elastic Foundation,” Composites Part B: Engineering, 43, pp. 15231530 (2012).CrossRefGoogle Scholar
18. Nateghi, A. and Salamat-talab, M., “Thermal Effect on Size Dependent Behavior of Functionally Graded Microbeams Based on Modified Couple Stress Theory,” Composite Structures, 96, pp. 97110 (2013).CrossRefGoogle Scholar
19. Niknam, H., Fallah, A. and Aghdam, M. M., “Nonlinear Bending of Functionally Graded Tapered Beams Subjected to Thermal and Mechanical Loading,” International Journal of Non-Linear Mechanics, 65, pp. 141147 (2014).CrossRefGoogle Scholar
20. Shen, H. S. and Wang, Z. X., “Nonlinear Analysis of Shear Deformable FGM Beams Eesting on Elastic Foundations in Thermal Environments,” International Journal of Mechanical Sciences, 81, pp. 195206 (2014).CrossRefGoogle Scholar
21. Zahedinejad, P., “Free Vibration Analysis of Functionally Graded Beams Resting on Elastic Foundation in Thermal Environment,” International Journal of Structural Stability and Dynamics, 16, 1550029 (2015).CrossRefGoogle Scholar
22. Zhu, J., Lai, Z., Yin, Z., Jeon, J. and Lee, S., “Fabrication of ZrO 2–NiCr Functionally Graded Material by Powder metallurgy,” Materials Chemistry and Physics, 68, pp. 130135 (2001).CrossRefGoogle Scholar
23. Wattanasakulpong, N., Prusty, B. G., Kelly, D. W. and Hoffman, M., “Free Vibration Analysis of Layered Functionally Graded Beams with Experimental Validation,” Materials & Design, 36, pp. 182190 (2012).CrossRefGoogle Scholar
24. Wattanasakulpong, N. and Ungbhakorn, V., “Linear and Nonlinear Vibration Analysis of Elastically Restrained Ends FGM Beams with Porosities,” Aerospace Science and Technology, 32, pp. 111120 (2014).CrossRefGoogle Scholar
25. Wattanasakulpong, N. and Chaikittiratana, A., “Flexural Vibration of Imperfect Functionally Graded Beams Based on Timoshenko Beam Theory: Chebyshev Collocation Method,” Meccanica, 50, pp. 13311342 (2015).CrossRefGoogle Scholar
26. Ebrahimi, F. and Rastgoo, A., “Free Vibration Analysis of Smart Annular FGM Plates Integrated with Piezoelectric Layers,” Smart Materials and Structures, 17, 015044 (2008).CrossRefGoogle Scholar
27. Ebrahimi, F. and Rastgoo, A., “An Analytical Study on the Free Vibration of Smart Circular Thin FGM Plate Based on Classical Plate Theory,” Thin-Walled Structures, 46, pp. 14021408 (2008).CrossRefGoogle Scholar
28. Ebrahimi, F. and Rastgoo, A., “Free Vibration Analysis of Smart FGM Plates,” International Journal of Mechanical Systems Science and Engineering, 2, pp. 9499 (2008).Google Scholar
29. Ebrahimi, F., Rastgoo, A. and Kargarnovin, M. H., “Analytical Investigation on Axisymmetric Free Vibrations of Moderately Thick Circular Functionally Graded Plate Integrated with Piezoelectric Layers,” Journal of Mechanical Science and Technology, 22, pp. 10581072 (2008).CrossRefGoogle Scholar
30. Ebrahimi, F., Rastgoo, A. and Atai, A. A., “Theoretical Analysis of Smart Moderately Thick Shear Deformable Annular Functionally Graded Plate,” European Journal of Mechanics - A/Solids, 28, pp. 962997 (2009).CrossRefGoogle Scholar
31. Ebrahimi, F., Naei, M. H. and Rastgoo, A., “Geometrically Nonlinear Vibration Analysis of Piezoelectrically Actuated FGM Plate with An Initial Large Deformation,” Journal of Mechanical Science and Technology, 23, pp. 21072124 (2009).CrossRefGoogle Scholar
32. Ebrahimi, F., “Analytical Investigation on Vibrations and Dynamic Response of Functionally Graded Plate Integrated with Piezoelectric Layers in Thermal Environment,” Mechanics of Advanced Materials and Structures, 20, pp. 854870 (2013).CrossRefGoogle Scholar
33. Ebrahimi, F., Ghasemi, F. and Salari, E., “Investigating Thermal Effects on Vibration Behavior of Temperature-Dependent Compositionally Graded Euler Beams with Porosities,” Meccanica, 51, pp. 223249 (2016).CrossRefGoogle Scholar
34. Ebrahimi, F. and Zia, M., “Large Amplitude Nonlinear Vibration Analysis of Functionally Graded Timoshenko Beams with Porosities,” Acta Astronautica, 116, pp. 117125 (2015).CrossRefGoogle Scholar
35. Ebrahimi, F. and Jafari, A., “Buckling Behavior of Smart MEE-FG Porous Plate with Various Boundary Conditions Based on Refined Theory,” Advances in Materials Research, 5, pp. 261276 (2016).CrossRefGoogle Scholar
36. Ebrahimi, F. and Mokhtari, M., “Transverse Vibration Analysis of Rotating Porous Beam with Functionally Graded Microstructure Using the Differential Transform Method,” Journal of the Brazilian Society of Mechanical Sciences and Engineering, 37, pp. 110 (2015).CrossRefGoogle Scholar
37. Ebrahimi, F. and Barati, M. R., “Vibration Analysis of Smart Piezoelectrically Actuated Nanobeams Subjected to Magneto-Electrical Field in Thermal Environment,” Journal of Vibration and Control, DOI: 10.1177/1077546316646239 (2016).Google Scholar
38. Ebrahimi, F. and Barati, M. R, “Buckling Analysis of Nonlocal Third-Order Shear Deformable Functionally Graded Piezoelectric Nanobeams Embedded in Elastic Medium,” Journal of the Brazilian Society of Mechanical Sciences and Engineering, pp. 116 (2016).Google Scholar
39. Ebrahimi, F. and Barati, M. R., “Small Scale Effects on Hygro-Thermo-Mechanical Vibration of Temperature Dependent Nonhomogeneous Nanoscale Beams,” Mechanics of Advanced Materials and Structures, 24, pp. 924936 (2017).CrossRefGoogle Scholar
40. Ebrahimi, F. and Barati, M. R., “Dynamic Modeling of a Thermo–Piezo-Electrically Actuated Nanosize Beam Subjected to a Magnetic Field,” Applied Physics A, 122, pp. 118 (2016).Google Scholar
41. Ebrahimi, F. and Barati, M. R., “Magnetic Field Effects on Buckling Behavior of Smart Size-Dependent Graded Nanoscale Beams,” The European Physical Journal Plus, 131, pp. 114 (2016).CrossRefGoogle Scholar
42. Ebrahimi, F. and Barati, M. R., “Vibration Analysis of Nonlocal Beams Made of Functionally Graded Material in Thermal Environment,” The European Physical Journal Plus, 131, 279 (2016).CrossRefGoogle Scholar
43. Ebrahimi, F. and Barati, M. R., “A Nonlocal Higher-Order Refined Magneto-Electro-Viscoelastic Beam Model for Dynamic Analysis of Smart Nanostructures,” International Journal of Engineering Science, 107, pp. 183196 (2016).CrossRefGoogle Scholar
44. Ebrahimi, F. and Barati, M. R., “Small-Scale Effects on Hygro-Thermo-Mechanical Vibration of Temperature-Dependent Nonhomogeneous Nanoscale Beams,” Mechanics of Advanced Materials and Structures, pp. 113 (2016).Google Scholar
45. Ebrahimi, F. and Barati, M. R., “A Unified Formulation for Dynamic Analysis of Nonlocal Heterogeneous Nanobeams in Hygro-Thermal Environment,” Applied Physics A, 122, 792 (2016).CrossRefGoogle Scholar
46. Ebrahimi, F. and Barati, M. R., “Electromechanical Buckling Behavior of Smart Piezoelectrically Actuated Higher-Order Size-Dependent Graded Nanoscale Beams in Thermal Environment,” International Journal of Smart and Nano Materials, 7, pp. 6990 (2016).CrossRefGoogle Scholar
47. Ebrahimi, F. and Barati, M. R., “Wave Propagation Analysis of Quasi-3D FG Nanobeams in Thermal Environment Based on Nonlocal Strain Gradient Theory,” Applied Physics A, 122, 843 (2016).CrossRefGoogle Scholar
48. Touloukian, Y. S., Thermophysical Properties of High Temperature Solid Materials: Elements, Macmillan, 1 (1967).Google Scholar
49. Ebrahimi, F. and Barati, M. R., “Flexural Wave Propagation Analysis of Embedded S-FGM Nanobeams under Longitudinal Magnetic Field Based on Nonlocal Strain Gradient Theory,” Arabian Journal for Science and Engineering, pp. 112 (2016).Google Scholar
50. Wang, Y. Q., Huang, X. B. and Li, J., “Hydroelastic Dynamic Analysis of Axially Moving Plates in Continuous Hot-Dip Galvanizing Process,” International Journal of Mechanical Sciences, 110, pp. 201216 (2016).CrossRefGoogle Scholar
51. Wang, Y. Q., Xue, S. W., Huang, X. B. and Du, W., “Vibrations of Axially Moving Vertical Rectangular Plates in Contact with Fluid,” International Journal of Structural Stability and Dynamics, 16, 1450092 (2016).CrossRefGoogle Scholar
52. Hassan, I. A. H., “On Solving Some Eigenvalue Problems by Using a Differential Transformation,” Applied Mathematics and Computation, 127, pp. 122 (2002).CrossRefGoogle Scholar
53. Wang, Y., Du, W., Huang, X. and Xue, S., “Study on the Dynamic Behavior of Axially Moving Rectangular Plates Partially Submersed in Fluid,” Acta Mechanica Solida Sinica, 28, pp. 706721 (2015).CrossRefGoogle Scholar
54. Ebrahimi, F. and Hashemi, M., “On Vibration Behavior of Rotating Functionally Graded Double- Tapered Beam with the Effect of Porosities,” Proceedings of the Institution of Mechanical Engineers, Part G: Journal of Aerospace Engineering, 230, pp. 19031916 (2016).CrossRefGoogle Scholar
55. Kiani, Y. and Eslami, M. R., “An Exact Solution for Thermal Buckling of Annular FGM Plates on an Elastic Medium,” Composites Part B: Engineering, 45, pp. 101110 (2013).CrossRefGoogle Scholar