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Analytical Approaches to Vibration Analysis of Thick Plates Subjected to Different Supports, Loadings and Boundary Conditions - A Literature Survey
Abstract:
Plates are one of the most important structural components used in many industries like aerospace, marine and various other engineering fields and thus motivate designers and engineers to study the vibrational characteristics of these structures. A lot of research work and studies have been done to study its vibration characteristics. This paper is a review of existing literature on vibration analysis of plates. Focus has been kept on prominent studies related to isotropic plates based on Mindlin plate theory; however few citations on orthotropic plates and higher order shear deformation theories have also been included. All citations are in English language. This review is aimed to provide contemporarily relevant survey of papers on vibrational characteristics of thick plates and identification of various methods and approaches that have been used to study the vibration characteristics. This paper will not only be useful for scientists, designers and researchers to locate important and relevant literature/research quickly but will also help them to identify and apply some of these methods and approaches to study the vibration characteristics of various other 2D and 3D structures.
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[1] E. F. F. CHLADNI 1802 Die Akustik. Leipzig.
[2] LORD RAYLEIGH 1877, Theory of Sound, Volume 1. London: Macmillan; reprinted 1945 by Dover, New York.
[3] W. RITZ 1909, Journal fur Reine und Angewandte Mathematik 135, 1-61. Uber eine neue methode zur losung gewisser variations probleme der mathematischen physic.
[4] S. P. TIMOSHENKO and J. M. GERE 1961, Theory of Elastic Stability. New York: McGraw-Hill.
[5] E. HINTON 1988 Numerical methods and Software for Dynamic Analysis of Plates and Shells. Swansea, U. K: Pineridge Press.
[6] C.S. KIM 1988 Ph.D. Thesis, University of Western Ontario, Canada. The vibrations of beams and plates studied using orthogonal polynomials.
[7] K. M. LIEW 1990 Ph.D. Thesis, National University of Singapore. The development of 2-D orthogonal polynomials for vibration of plates.
[8] Y. XIANG 1993 Ph.D. Thesis, The University of Queensland. The numerical developments in solving the buckling and vibration of Mindlin plates.
[9] G. K. RAMAIAH 1980 Journal of Sound and Vibration 72, 11-23. Flexural vibrations and elastic stability of annular plates under uniform in-plate tensile forces along inner edge.
[10] S. M. DICKINSON and A. DI BLASIO 1986 Journal of Sound and Vibration 108, 51-62. On the use of orthogonal polynomials in the Rayleigh-Ritz method for the study of the flexural vibration and buckling of isotropic and orthotropic rectangular plates.
[11] T. MIZUSAWA and J. W. LEONARD 1990 Engineering Structures 12, 285-290. Vibration and buckling of plates with mixed boundary conditions.
[12] A. W. LEISSA 1969 NASA SP-169 Vibration of Plates. Washington, D.C.: Office of Technology Utilization.
[13] A. W. LEISSA 1987 The Shock and Vibration Digest 19(3), 10–24. Recent research in plate vibrations, 1981–1985, Part II: complicating effects.
[14] C. W. BERT 1976 The Shock and Vibration Digest 8(11), 15–24. Dynamics of composite and sandwich panels, Parts I and II.
[15] C. W. BERT 1979 The Shock and Vibration Digest 11(10), 13–23. Recent research in composite and sandwich plate dynamics.
[16] C. W. B 1982 The Shock and Vibration Digest 14(10), 17–34. Research on dynamics of composite and sandwich plates.
[17] C. W. BERT 1985, The Shock and Vibration Digest 17(11), 3–25. Research on dynamic behavior of composite and sandwich plates, part IV.
[18] C. W. BERT 1991 The Shock and Vibration Digest 23(6), 3–14. Research on dynamic behavior of composite and sandwich plates, V: part I.
[19] C. W. BERT 1991 The Shock and Vibration Digest 23(7), 9–21. Research on dynamic behavior of composite and sandwich plates, V: part II.
[20] E. REISSNER 1945 Transactions of the American Society of Mechanical Engineers, Journal of Applied Mechanics 12, 69–77. The effect of transverse shear deformation on the bending of elastic plate.
[21] R. D. MINDLIN 1951 Transactions of the American Society of Mechanical Engineers, Journal of Applied Mechanics 18, 31–38. Influence of rotary inertia and shear in flexural motion of isotropic, elastic plates.
DOI: 10.1115/1.4010217
[22] J. NANNI 1971 Zeitschrift fur Angewandte Mathematik und Physik 22, 156–185. Das eulersche knick problem unter berucksichtigung der querkrafte.
DOI: 10.1007/bf01624060
[23] R. B. NELSON and D. R. LORCH 1974 American Society of Mechanical Engineers Journal of Applied Mechanics 41, 177–183. A refined theory for laminated orthotropic plates.
DOI: 10.1115/1.3423219
[24] K. H. LO, R. M. CHRISTENSEN and E. M. WU 1977 Transactions of the American Society of Mechanical Engineers, Journal of Applied Mechanics 44, 663–676. A higher-order theory of plate deformation, part 1: homogeneous plates/part 2: laminated plates.
DOI: 10.1115/1.3424155
[25] M. LEVINSON 1980 Mechanics Research Communications 7, 343–350. An accurate simple theory of the statics and dynamics of elastic plates.
[26] M. V. V. MURTHY November 1981 NASA Technical Paper 1903. An improved transverse shear deformation theory for laminated anisotropic plate.
[27] J. N. REDDY 1984 Transactions of the American Society of Mechanical Engineers, Journal of Applied Mechanics 51, 745–752. A simple higher-order theory for laminated composite plates.
DOI: 10.1115/1.3167719
[28] N. R. SENTHILNATHAN 1989 Ph.D. Thesis, National University of Singapore. A simple higher-order shear deformation plate theory.
[29] J. L. DOONG, C. LEE and C. P. FUNG 1991 Journal of Sound and Vibration 151, 193–201. Vibration and stability of laminated plates based on a modified plate theory.
[30] K. M. LIEW, Y. XIANG and S. KITIPORNCHAI 1993, Dynamics and Vibration Centre, Nanyang Technological University Singapore. Research on thick plate vibrations-A literature survey.
[31] K. M. LIEW, Y. XIANG and S. KITIPORNCHAI 1993 Computers and Structure 49, 1-29, Transverse vibration of thick rectangular plates, I: comprehensive sets of boundary conditions.
[32] K. M. LIEW, Y. XIANG and S. KITIPORNCHAI 1993 Computers and Structure 49, 31-58, Transverse vibration of thick rectangular plates, II: Inclusion of oblique internal line supports.
[33] K. M. LIEW, Y. XIANG and S. KITIPORNCHAI 1993 Computers and Structure 49, 59-67, Transverse vibration of thick rectangular plates, III: effects of multiple internal eccentric ring supports.
[34] K. M. LIEW, Y. XIANG and S. KITIPORNCHAI 1993 Computers and Structure 49, 69-78, Transverse vibration of thick rectangular plates, IV: influence of isotropic in-plane pressure.
[35] K. M. LIEW, Y. XIANG and S. KITIPORNCHAI and M.K. LIM 1994, American Society of Mechanical Engineers, Journal of Vibration and Acoustics in press, Vibration of rectangular Mindlin plates with intermediate stiffeners.
DOI: 10.1115/1.2930459
[36] C.M. WANG 1994 American Society of Mechanical Engineers Journal of Vibration and Acoustics in press, Natural frequencies formula for simply supported Mindlin plates.
DOI: 10.1115/1.2930460
[37] Y. XIANG, C. M. WANG and S. KITIPORNCHAI 1994 International Journal of Mechanical Sciences 36, 311-316. Exact vibration solution for initially stressed Mindlin plates on Pasternak foundation.
[38] D. J. GORMAN, World Scientific, (1999), Vibration analysis of plates by the superposition method.
[39] M. H. HUANG, D. P. THAMBIRATNAM., Computers and Structures, 79 (2001) 2547-2557, Analysis of plate resting on elastic supports and elastic foundation by finite strip method.
[40] D. ZHOU, 2001 International Journal of Solids and Structures 38 (2001) 5565-5580. Vibrations of Mindlin Rectangular plates with elastically restrained edges using Static Timoshenko beam functions with the Rayleigh-Ritz method.
[41] Y.B. ZHAO and G.W. WEI, Journal of sound and vibration 2002, 255(2), 203-228, DSC analysis of rectangular plates with non-uniform boundary conditions.
[42] W. L. LI 2000 Journal of Sound and vibration 237, 709-725. Free vibrations of beams with general boundary conditions.
[43] W. L. LI and M. DANIELS, 2002, Journal of Sound and vibration 252(4), 768-781. A Fourier series method for the vibrations of elastically restrained plates arbitrarily loaded with springs and Masses.
[44] J. P. ARENAS, Journal of Sound and Vibration, 266 (2003) 912-918, On the vibration analysis of rectangular clamped plates using the virtual work principle.
[45] W. L. LI, Journal of Sound and Vibration 273 (2004) 619–635, Vibration analysis of rectangular plates with general elastic boundary supports.
[46] M. AMABILI, Journal of Sound and Vibration 291 (2006) 539–565, Theory and experiments for large-amplitude vibrations of rectangular plates with geometric imperfections.
[47] D. J. GORMAN, Journal of Sound and Vibration, 285 (2005) 941-966. Free in-plane vibration analysis of rectangular plates with elastic support normal to the boundaries.
[48] SH. HOSSEINI-HASHEMI and M. ARSANJANI, International Journal of Solids and Structures, Volume 42, Issues 3–4, February 2005, Pages 819–85, Exact characteristic equations for some of classical boundary conditions of vibrating moderately thick rectangular plates.
[49] W.L. LI, 2006 Acoustical Society of America, Vibroacoustic analysis of rectangular plates with elastic rotational edge restraints.
DOI: 10.1121/1.2211567
[50] D. ZHOU, T. J. JI. International Journal of Solids and Structures, 43 (2006) 6502-6520. Free vibration of rectangular plates with continuously distributed spring mass.
[51] JINGTAO DU, W. L. LI, GUOYONG JIN, TIEJUN YANG and ZHIGANG LIU, Journal of Sound and Vibration 306 (2007) 908–927, An analytical method for the in-plane vibration analysis of rectangular plates with elastically restrained edges.
[52] S. W. KANG, S. H. KIM. Journal of Sound and Vibration, 312 (2008) 551-562 Vibration analysis of simply supported rectangular plates with unidirectionally, arbitrarily varying thickness.
[53] HENRY KHOV, WEN L. LI and RONALD F. GIBSON, Composite Structures 90 (2009) 474–481, An accurate solution method for the static and dynamic deflections of orthotropic plates with general boundary conditions.
[54] W.L. LI, XUEFENG ZHANG, JINGTAO DU and ZHIGANG LIU, Journal of Sound and Vibration 321(2009)254–269, An exact series solution for the transverse vibrations of rectangular plates with general elastic boundary supports.
[55] SH. HOSSEINI-HASHEMI, K. KHORSHIDI and H. PAYANDEH. Mechanical Engineering Vol. 16, No. 1, p.22.
[56] YUFENG XING and BO LIU, Acta Mechanica Solida Sinica, Vol. 22, No. 2, April, 2009. Characteristic equations and Closed-form solutions for free vibrations of rectangular Mindlin plates.
[57] X. ZHANG and W.L. LI, Journal of Sound and Vibration 326 (2009) 221–234, Vibrations of rectangular plates with arbitrary non-uniform elastic edge restraints.
[58] CHEN YUEHUA, JIN GUOYONG, DU JINGTAO and LIU ZHIGANG, Proceedings of 20th International Congress on Acoustics, ICA 2010 Austrailia Power transmission analysis of coupled rectangular plates with elastically restrained coupling edge including in-plane vibration.
[59] JINGTAO DU, ZHIGANG LIU and WEN.L. LI. Journal of Vibration and Acoustics JUNE 2010, Vol. 132 / 031002-1. Free In-Plane Vibration Analysis of Rectangular Plates With Elastically Point-Supported Edges.
DOI: 10.1115/1.4000777
[60] HONGAN XU, JINGTAO DU and WEN L. LI, Journal of Sound and Vibration 329 (2010) 3759–3779, Vibrations of rectangular plates reinforced by any number of beams of arbitrary lengths and placement angles.
[61] SH. HOSSEINI-HASHEMI, MOHAMMAD FADAEE and HOSSEIN RD TAHIR, Journal of Applied Mathematical Modeling 35 (2011).
[62] SH. HOSSEINI-HASHEMI, MOHAMMAD FADAEE and S. R ATASHIPOUR, International Journal of Mechanical Sciences, 53 (2011)11-22, A new exact analytical approach for free vibration of Reissner-Mindlin functionally graded rectangular plates.
[63] L.H. WU and Y. LU, International Journal of Mechanical Sciences 53 (2011) 494–504, Free vibration analysis of rectangular plates with internal columns and uniform elastic edge supports by pb-2 Ritz method.
[64] L. DOZIO. Thin-Walled Structures, 49 (2011) 129-144, use of the Trigonometric Ritz method for general vibration analysis of rectangular Kirchhoff plates.
[65] JINGTAO DU, WEN L. LI and ZHIGANG LIU, Journal of Sound and vibration 330 (2011) 788–804. Free vibration of two elastically coupled rectangular plates with uniform elastic boundary restraints.
[66] JINGTAO DU, WEN L. LI, HONGAN XU and ZHIGANG LIU, Journal of Acoustical society of America 130 (2), August 2011, Acoustic analysis of a rectangular cavity with general impedance boundary conditions.
DOI: 10.1121/1.3605534
[67] H.A. XU and WEN L. LI, Science China technological Sciences, May 2011 Vol. 54 No. 5: 1141–1153, Vibration and power flow analysis of periodically reinforced plates.
[68] CHEN YUEHUA, JIN GUOYONG, DU JINGTAO, and LIU ZHIGANG, Chinese Journal of Mechanical Engineering, Vol. 24, No 6, 2011. Vibration Characteristics and Power Transmission of Coupled Rectangular Plates with Elastic Coupling Edge and Boundary Restraints.
[69] CHEN YUEHUA, GUOYONG JIN, MINGGANG ZHU and WEN L. LI, Journal of Sound and vibrations, 331 (2012) 849–867, Vibration behaviors of a box-type structure built up by plates and energy transmission through the structure.
[70] SH. HOSSENI. HASHEMI, S. R. ATASHIPOUR and M. FADAEE, Arch Appl Mech (2012) 82: 677–698, An exact analytical approach for in-plane and out-of-plane free vibration analysis of thick laminated transversely isotropic plates.
[71] S. A EFTEKHARI and A. A JAFARI, Applied Mathematical Modeling 36 (2012) 2814–2831, A mixed method for free and forced vibration of rectangular plates.
[72] S. A EFTEKHARI and A. A JAFARI, International Journal of Mechanical Sciences (2013), Accurate variational approach for free vibration of variable thickness thin and thick plates with edges elastically restrained against translation and rotation.
[73] S. MOTAGHIAN, M. MOFID and J.E. AKIN, Applied Mathematical Modeling 36 (2012) 4473–4482, Free vibration response of rectangular plates, partially supported on elastic foundation.
[74] M. DEHGHANY and A. FARAJPOUR, Engineering Solid Mechanics 2 (2013) 29-42, Free vibration of simply supported rectangular plates on Pasternak foundation: An exact and three-dimensional solution.
[75] H.N. JAHROMI, M.M. AGHDAM and A. FALLAH, International Journal of Mechanical Sciences 75(2013)1–7, Free vibration analysis of Mindlin plates partially resting on Pasternak foundation.
[76] S.J. SEMNANI, R. ATTARNEJAD and R. K. FIROUZJAEI, Acta Mech 224, 1643–1658 (2013), Free vibration analysis of variable thickness thin plates by two-dimensional differential transform method.
[77] IVO SENJANOVIC, NIKOLA VILADIMIR and M. TOMIC, Journal of Sound and Vibration 332 (2013) 1868–1880, An advanced theory of moderately thick plate vibrations.
[78] HUU-TAI-THAI, MINWO PARK and DONG-HO-CHOI, International Journal of Mechanical Sciences 73(2013)40–52, A simple refined theory for bending, buckling and vibration of thick plates resting on elastic foundation.
[79] EBIRIM, STANLEY I, EZEH, J. C, IBEARUGBULEM and OWUS M, International Journal of Engineering & Technology, 3(1) (2014) 30-36, Free vibration analysis of isotopic rectangular plate with one edge free of support (CSCF and SCFC plate).
[80] EZEH, J. C, IBEARUGBULEM, OWUS M, EBIRIM and STANLEY I, International Journal of Engineering and Technology Volume 4 No. 1, January, 2014, Vibration Analysis of Plates with One Free edge using Energy method.
[81] M. NEFOVSKA-DANILOVIC and M. PETRONIJEVIC, Proceedings of the 9th International Conference on Structural Dynamics, EURODYN 2014, Free in-plane vibration of rectangular plates using spectral element method.
[82] IVO SENJANOVIC, NIKOLA VILADIMIR, DAE-SEUNG CHO and TAI-MUK CHOI, Proceedings of the ASME 2014 33rd International Conference on Ocean, Offshore and Arctic Engineering OMAE2014, Vibrational Analysis of Thick Plates- Analytical and Numerical Approaches.
[83] DONGYAN SHI, QINGSHAN WANG, XIANJIE SHI and FUZHEN PANG, Hindawi Publishing Corporation Shock and Vibration Volume 2014, Article ID 572395, 25 pages, Free vibration analysis of moderately thick rectangular plates with variable thickness and Arbitrary boundary conditions.
DOI: 10.1155/2014/572395
[84] M. NEFOVSKA-DANILOVIC and M. PETRONIJEVIC, Computers and Structures 152 (2015) 82–95, In-plane free vibrations and response analysis of isotropic rectangular plates using the dynamic stiffness method.
[85] KARAN KUMAR PRADHAN and SNEHASHISH CHAKRAVERTY, International Journal of Mechanical Sciences 94-95(2015)211–231, Transverse vibration of isotropic thick rectangular plates based on new inverse trigonometric shear deformation theories.
[86] I. I. SAYYAD, S. M. HON, K. K. JOSHI, P. N. KOLASE and OMKAR BABASAHEB KALE, International Journal of Advanced Engineering and Nano Technology (IJAENT), Volume-2, Issue-5, April 2015, Vibration Analysis of Thick Plate by Using Refined Plate Theory and ANSYS.
[87] IVO SENJANOVIC, NIKOLA VILADIMIR and DAE SEUNG CHO, International Journal of Naval Architecture and Ocean Engg. (2015) 7: 324-345, A new finite element formulation for vibration analysis of thick plates.