Flexural vibration of imperfect functionally graded beams based on Timoshenko beam theory: Chebyshev collocation method
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- 作者:Nuttawit Wattanasakulpong (1)
Arisara Chaikittiratana (2)
1. Department of Mechanical Engineering ; Mahanakorn University of Technology ; Nongchok ; Bangkok ; 10530 ; Thailand
2. Department of Mechanical and Aerospace Engineering ; Research Centre for Advanced Computational and Experimental Mechanics (RACE) ; King Mongkut鈥檚 University of Technology North Bangkok ; Bangkok ; 10800 ; Thailand - 关键词:Imperfect FGM beam ; Vibration ; Natural frequency ; Chebyshev collocation method
- 刊名:Meccanica
- 出版年:2015
- 出版时间:May 2015
- 年:2015
- 卷:50
- 期:5
- 页码:1331-1342
- 全文大小:575 KB
- 参考文献:1. Suresh, S, Mortensen, A (1998) Fundamental of functionally graded materials. Maney, London
2. Miyamoto, Y, Kaysser, WA, Rabin, BH, Kawasaki, A, Ford, RG (1999) Functionally graded materials: design, processing and application. Kluwer Academic Publishers, London CrossRef
3. Zhu, J, Lai, Z, Yin, Z, Jeon, J, Lee, S (2001) Fabrication of ZrO2鈥揘iCr functionally graded material by powder metallurgy. Mater Chem Phys 68: pp. 130-135 CrossRef
4. Wattanasakulpong, N, Prusty, BG, Kelly, DW, Hoffman, M (2012) Free vibration analysis of layered functionally graded beams with experimental validation. Mater Design 36: pp. 182-190 CrossRef
5. Sankar, BV (2001) An elasticity solution for functionally graded beams. Compos Sci Technol 61: pp. 689-696 CrossRef
6. Zhong, Z, Yu, T (2007) Analytical solution of a cantilever functionally graded beam. Compos Sci Technol 67: pp. 481-488 CrossRef
7. Kang, YA, Li, XF (2009) Bending of functionally graded cantilever beams with power-law non-linearity subjected to an end force. Int J Non Linear Mech 44: pp. 696-703 CrossRef
8. Kapuria, S, Bhattacharyya, M, Kumar, AN (2008) Bending and free vibration response of layered functionally graded beams: a theoretical model and its experimental validation. Compos Struct 82: pp. 390-402 CrossRef
9. Aydogdu, M, Taskin, V (2007) Free vibration analysis of functionally graded beams with simply-supported edges. Mater Design 36: pp. 182-190
10. Xiang, HJ, Yang, J (2008) Free and forced vibration of a laminated FGM Timoshenko beam of variable thickness under heat conduction. Compos Part B Eng 39: pp. 292-303 CrossRef
11. Sina, SA, Navazi, HM, Haddadpour, H (2009) An analytical method for free vibration analysis of functionally graded beams. Mater Design 30: pp. 741-747 CrossRef
12. Simsek, M (2010) Fundamental frequency analysis of functionally graded beams by using different higher-order beam theories. Nuclear Eng Design 240: pp. 697-705 CrossRef
13. Thai, HT, Vo, TP (2012) Bending and free vibration of functionally graded beams using various higher-order shear deformation theories. Int Mech Sci 62: pp. 57-66 CrossRef
14. Wattanasakulpong, N, Prusty, BG, Kelly, DW (2011) Thermal buckling and elastic vibration of third-order shear deformable functionally graded beams. Int J Mech Sci 53: pp. 734-743 CrossRef
15. Giunta, G, Crisafulli, D, Belouettar, S, Carrera, E (2011) Hierarchical theories for the free vibration analysis of functionally graded beams. Compos Struct 94: pp. 68-74 CrossRef
16. Alshorbagy, AE, Eltaher, MA, Mahmoud, FF (2011) Free vibration characteristics of a functionally graded beam by finite element method. Appl Math Model 35: pp. 412-425 CrossRef
17. Su, H, Banerjee, JR, Cheung, CW (2013) Dynamic stiffness formulation and free vibration analysis of functionally graded beams. Compos Struct 106: pp. 854-862 CrossRef
18. Pradhan, KK, Chakraverty, S (2013) Free vibration and Timoshenko functionally graded beams by Rayleigh-Ritz method. Compos Part B 51: pp. 175-184 CrossRef
19. Suddoung, K, Charoensuk, J, Wattanasakulpong, N (2014) Vibration response of stepped. Appl Acoust 77: pp. 20-28 CrossRef
20. Rajasekaran, S (2013) Buckling and vibration of axially functionally graded nonuniform beams using differential transformation based dynamic stiffness approach. Meccanica 48: pp. 1053-1070 CrossRef
21. Vo, TP, Thai, HT, Nguyen, TK, Inam, F (2014) Static and vibration analysis of functionally graded beams using refined shear deformation theory. Meccanica 49: pp. 155-168 CrossRef
22. Rajasekaran, S, Tochaei, EN (2014) Free vibration analysis of axially functionally graded tapered Timoshenko beams using differential transformation element method and differential quadrature element method of lowest-order. Meccanica 49: pp. 995-1009 CrossRef
23. Wattanasakulpong, N, Ungbhakorn, V (2014) Linear and nonlinear vibration analysis of elastically restrained ends FGM beams with porosities. Aerosp Sci Technol 32: pp. 111-120 CrossRef
24. Fox, L, Parker, IB (1968) Chebyshev polynomials in numerical analysis. Oxford University Press, London
25. Elbarbary, EME (2005) Chebyshev finite difference method for the solution of boundary-layer equations. Appl Math Comput 160: pp. 487-498 CrossRef
26. Celik, I (2005) Approximate computation of eigenvalues with Chebyshev collocation method. Appl Math Comput 160: pp. 401-410 CrossRef
27. Biazar, J, Ebrahimi, H (2012) Chebyshev wavelets approach for nonlinear systems of Volterra integral equations. Comput Math Appl 63: pp. 608-616 CrossRef
28. Doha, EH, Abd-Elhameed, WM, Bassuony, MA (2013) New algorithms for solving high even-order differential equations using third and fourth Chebyshev-Galerkin method. J Comput Phys 236: pp. 563-579 CrossRef
29. Lin, CH, Jen, MHR (2005) Analysis of a laminated anisotropic plate by Chebyshev collocation method. Compos B 36: pp. 155-169 CrossRef
30. Lee, J, Schultz, WW (2004) Eigenvalue analysis of Timoshenko beams and axisymmetric Mindlin plates by the pseudospectral method. J Sound Vib 269: pp. 609-621 CrossRef
31. Sari, MS, Butcher, EA (2010) Natural frequencies and critical loads of beams and columns with damaged boundaries using Chebyshev polynomials. Int J Eng Sci 48: pp. 862-873 CrossRef
32. Sari, MS, Butcher, EA (2012) Free vibration analysis of non-rotating and rotating Timoshenko beams with damaged boundaries using the Chebyshev collocation method. Int J Mech Sci 60: pp. 1-11 CrossRef
33. Delale, F, Erdogan, F (1983) The crack problem for a nonhomogeneous plane. ASME J Appl Mech 50: pp. 609-614 CrossRef - 刊物类别:Physics and Astronomy
- 刊物主题:Physics
Mechanics
Civil Engineering
Automotive and Aerospace Engineering and Traffic
Mechanical Engineering - 出版者:Springer Netherlands
- ISSN:1572-9648
文摘
Flexural vibration analysis of beams made of functionally graded materials (FGMs) with various boundary conditions is considered in this paper. Due to technical problems during FGM fabrication, porosities and micro-voids can be created inside FGM samples which may lead to the reduction in density and strength of materials. In this investigation, the FGM beams are assumed to have even and uneven distributions of porosities over the beam cross-section. The modified rule of mixture is used to approximate material properties of the FGM beams including the porosity volume fraction. In order to cover the effects of shear deformation, axial and rotary inertia, the Timoshenko beam theory is used to form the coupled equations of motion for describing dynamic behavior of the beams. To solve such a problem, Chebyshev collocation method is employed to find natural frequencies of the beams supported by different end conditions. Based on numerical results, it is revealed that FGM beams with even distribution of porosities have more significant impact on natural frequencies than FGM beams with uneven porosity distribution.