Analytical solution for bending and buckling response of laminated non-homogeneous plates using a simplified-higher order theory

Zerin, Zihni; Basoglu, Muhammed Fatih; Turan, Ferruh

doi:10.20528/cjsmec.2017.02.001

Analytical solution for bending and buckling response of laminated non-homogeneous plates using a simplified-higher order theory

Ferruh TURAN, (Ondokuz Mayıs Üniversitesi)

Muhammed Fatih BAŞOĞLU, (Ondokuz Mayıs Üniversitesi)

Zihni ZERİN (Ondokuz Mayıs Üniversitesi)

Challenge Journal of Structural Mechanics

5 0

Yıl: 2017 Cilt: 3 Sayı: 1 Sayfa Aralığı: 1 - 16 Metin Dili: İngilizce DOI: 10.20528/cjsmec.2017.02.001 İndeks Tarihi: 15-01-2020

Analytical solution for bending and buckling response of laminated non-homogeneous plates using a simplified-higher order theory

Öz:

In this study, analytical solutions for the bending and buckling analysis of simply sup-ported laminated non-homogeneous composite plates based on first and simplified-higher order theory are presented. The simplified-higher order theory assumes that the in-plane rotation tensor is constant through the thickness. The constitutive equa-tions of these theories were obtained by using principle of virtual work. Numerical results for the bending response and critical buckling loads of cross-ply laminates are presented. The effect of non-homogeneity, lamination schemes, aspect ratio, side-to-thickness ratio and in-plane orthotropy ratio on the bending and buckling response were analysed. The obtained results are compared with available elasticity and higher order solutions in the literature. The comparison studies show that simplified-higher order theory can achieve the same accuracy of the existing higher order the-ory for non-homogeneous thin plate.

Anahtar Kelime:

Konular: İnşaat Mühendisliği Malzeme Bilimleri, Özellik ve Test İnşaat ve Yapı Teknolojisi

Belge Türü: Makale Makale Türü: Araştırma Makalesi Erişim Türü: Erişime Açık

Beena K, Parvathy U (2014). Linear static analysis of functionally graded plate using spline finite strip method. Composite Structures, 117, 309-315.
Fares M (1999). Non-linear bending analysis of composite laminated plates using a refined first-order theory. Composite Structures, 46(3), 257-266.
Fares M, Zenkour A (1999). Buckling and free vibration of non-homo-geneous composite cross-ply laminated plates with various plate theories. Composite Structures, 44(4), 279-287.
Gosling P, Polit O (2014). A high-fidelity first-order reliability analysis for shear deformable laminated composite plates. Composite Struc-tures, 115, 12-28.
Gupta A, Johri T, Vats R (2007). Thermal effect on vibration of non-ho-mogeneous orthotropic rectangular plate having bi-directional par-abolically varying thickness. Proceeding of International Conference in World Congress on Engineering and Computer Science.
Gupta U, Lal R, Sharma S (2006). Vibration analysis of non-homogene-ous circular plate of nonlinear thickness variation by differential quadrature method. Journal of Sound and Vibration, 298(4), 892-906.
He WM, Chen WQ, Qiao H (2013). In-plane vibration of rectangular plates with periodic inhomogeneity: Natural frequencies and their adjustment. Composite Structures, 105, 134-140.
Kim S-E, Thai H-T, Lee J (2009). A two variable refined plate theory for laminated composite plates. Composite Structures, 89(2), 197-205.
Kolpakov A (1999). Variational principles for stiffnesses of a non-ho-mogeneous plate. Journal of the Mechanics and Physics of Solids, 47(10), 2075-2092.
Komur MA, Sonmez M (2015). Elastic buckling behavior of rectangular plates with holes subjected to partial edge loading. Journal of Con-structional Steel Research, 112, 54-60.
Kulkarni K, Singh B, Maiti D (2015). Analytical solution for bending and buckling analysis of functionally graded plates using inverse trigo-nometric shear deformation theory. Composite Structures, 134, 147-157.
Lal R (2007). Transverse vibrations of non-homogeneous orthotropic rectangular plates of variable thickness: A spline technique. Journal of Sound and Vibration, 306(1), 203-214.
Leknitskii SG, Fern P (1963). Theory of elasticity of an anisotropic elas-tic body. Holden-Day.
Librescu L, Khdeir A (1988). Analysis of symmetric cross-ply laminated elastic plates using a higher-order theory: Part I—Stress and dis-placement. Composite Structures, 9(3), 189-213.
Mojahedin A, Jabbari M, Khorshidvand A, Eslami M (2016). Buckling analysis of functionally graded circular plates made of saturated porous materials based on higher order shear deformation theory. Thin-Walled Structures, 99, 83-90.
Neves A, Ferreira A (2016). Free vibrations and buckling analysis of laminated plates by oscillatory radial basis functions. Curved and Layered Structures, 3(1), 17-21.
Noor AK (1973). Free vibrations of multilayered composite plates. AIAA Journal, 11(7), 1038-1039.
Pagano N (1970). Exact solutions for rectangular bidirectional compo-sites and sandwich plates. Journal of Composite Materials, 4(1), 20-34.
Pagano N, Hatfield HJ (1972). Elastic behavior of multilayered bidirec-tional composites. AIAA Journal, 10(7), 931-933.
Papkov S, Banerjee J (2015). A new method for free vibration and buck-ling analysis of rectangular orthotropic plates. Journal of Sound and Vibration, 339, 342-358.
Patel SN (2014). Nonlinear bending analysis of laminated composite stiffened plates. Steel and Composite Structures, 17(6), 867-890.
Phan N, Reddy J (1985). Analysis of laminated composite plates using a higher-order shear deformation theory. International Journal for Numerical Methods in Engineering, 21(12), 2201-2219.
Putcha N, Reddy J (1986). Stability and natural vibration analysis of laminated plates by using a mixed element based on a refined plate theory. Journal of Sound and Vibration, 104(2), 285-300.
Reddy BS, Kumar JS, Reddy C, Reddy KVK (2015). Buckling analysis of functionally graded plates using higher order shear deformation theory with thickness stretching effect. International Journal of Ap-plied Science and Engineering 13 (1), 19-36.
Reddy JN (1984). A simple higher-order theory for laminated compo-site plates. Journal of Applied Mechanics, 51(4), 745-752.
Reddy JN (2004). Mechanics of laminated composite plates and shells: theory and analysis. CRC press.
Reissner E (1975). On transverse bending of plates, including the effect of transverse shear deformation. International Journal of Solids and Structures, 11(5), 569-573.
Sadoune M, Tounsi A, Houari MSA, Bedia ELAA (2014). A novel first-order shear deformation theory for laminated composite plates. Steel and Composite Structures, 17(3), 321-338.
Saheb KM, Aruna K (2015). Buckling analysis of moderately thick rec-tangular plates using coupled displacement field method. Journal of Physics: Conference Series.
Schmitz A, Horst P (2014). A finite element unit-cell method for homog-enised mechanical properties of heterogeneous plates. Composites Part A: Applied Science and Manufacturing, 61, 23-32.
Senthilnathan N, Lim S, Lee K, Chow S (1988). Vibration of laminated orthotropic plates using a simplified higher-order deformation the-ory. Composite Structures, 10(3), 211-229.
Shahbaztabar A, Ranji AR (2016). Effects of in-plane loads on free vi-bration of symmetrically cross-ply laminated plates resting on Pas-ternak foundation and coupled with fluid. Ocean Engineering, 115, 196-209.
Sofiyev A (2016). Buckling of heterogeneous orthotropic composite conical shells under external pressures within the shear defor-mation theory. Composites Part B: Engineering, 84, 175-187.
Sofiyev A, Kuruoglu N (2014). Combined influences of shear defor-mation, rotary inertia and heterogeneity on the frequencies of cross-ply laminated orthotropic cylindrical shells. Composites Part B: Engineering, 66, 500-510.
Sofiyev A, Kuruoğlu N (2016). The stability of FGM truncated conical shells under combined axial and external mechanical loads in the framework of the shear deformation theory. Composites Part B: En-gineering, 92, 463-476.
Sofiyev A, Zerin Z, Korkmaz A (2008). The stability of a thin three-lay-ered composite truncated conical shell containing an FGM layer subjected to non-uniform lateral pressure. Composite Structures, 85(2), 105-115.
Sreehari V, Maiti D (2015). Buckling and post buckling analysis of lam-inated composite plates in hygrothermal environment using an In-verse Hyperbolic Shear Deformation Theory. Composite Structures, 129, 250-255.
Stürzenbecher R, Hofstetter K (2011). Bending of cross-ply laminated composites: An accurate and efficient plate theory based upon models of Lekhnitskii and Ren. Composite Structures, 93(3), 1078-1088.
Thai HT, Choi DH (2013a). A simple first-order shear deformation theory for laminated composite plates. Composite Structures, 106, 754-763.
Thai HT, Choi DH (2013b). A simple first-order shear deformation the-ory for the bending and free vibration analysis of functionally graded plates. Composite Structures, 101, 332-340.
Vescovini R, Dozio L (2016). A variable-kinematic model for variable stiffness plates: Vibration and buckling analysis. Composite Struc-tures, 142, 15-26.
Yin S, Hale JS, Yu T, Bui TQ, Bordas SP (2014). Isogeometric locking-free plate element: a simple first order shear deformation theory for functionally graded plates. Composite Structures, 118, 121-138.
Yu T, Bui TQ, Yin S, Doan DH, Wu C, Van Do T, Tanaka S (2016). On the thermal buckling analysis of functionally graded plates with inter-nal defects using extended isogeometric analysis. Composite Struc-tures, 136, 684-695.
Zenkour A (2011). Bending responses of an exponentially graded simply-supported elastic/viscoelastic/elastic sandwich plate. Acta Mechanica Solida Sinica, 24(3), 250-261.
Zenkour A, Fares M (1999). Non-homogeneous response of cross-ply laminated elastic plates using a higher-order theory. Composite Structures, 44(4), 297-305.
Zenkour AM, Allam M, Mashat D (2007). Linear bending analysis of in-homogeneous variable-thickness orthotropic plates under various boundary conditions. International Journal of Computational Meth-ods, 4(03), 417-438.
Zerin Z, Turan F, Basoglu MF (2016). Examination of non-homogeneity and lamination scheme effects on deflections and stresses of lami-nated composite plates. Structural Engineering and Mechanics, 57(4), 603-616.
Zhen W, Lo S (2015). Hygrothermomechanical effects on laminated composite plates in terms of a higher-order global-local model. Journal of Thermal Stresses, 38(5), 543-568.

APA	Turan F, Basoglu M, Zerin Z (2017). Analytical solution for bending and buckling response of laminated non-homogeneous plates using a simplified-higher order theory. , 1 - 16. 10.20528/cjsmec.2017.02.001
Chicago	Turan Ferruh,Basoglu Muhammed Fatih,Zerin Zihni Analytical solution for bending and buckling response of laminated non-homogeneous plates using a simplified-higher order theory. (2017): 1 - 16. 10.20528/cjsmec.2017.02.001
MLA	Turan Ferruh,Basoglu Muhammed Fatih,Zerin Zihni Analytical solution for bending and buckling response of laminated non-homogeneous plates using a simplified-higher order theory. , 2017, ss.1 - 16. 10.20528/cjsmec.2017.02.001
AMA	Turan F,Basoglu M,Zerin Z Analytical solution for bending and buckling response of laminated non-homogeneous plates using a simplified-higher order theory. . 2017; 1 - 16. 10.20528/cjsmec.2017.02.001
Vancouver	Turan F,Basoglu M,Zerin Z Analytical solution for bending and buckling response of laminated non-homogeneous plates using a simplified-higher order theory. . 2017; 1 - 16. 10.20528/cjsmec.2017.02.001
IEEE	Turan F,Basoglu M,Zerin Z "Analytical solution for bending and buckling response of laminated non-homogeneous plates using a simplified-higher order theory." , ss.1 - 16, 2017. 10.20528/cjsmec.2017.02.001
ISNAD	Turan, Ferruh vd. "Analytical solution for bending and buckling response of laminated non-homogeneous plates using a simplified-higher order theory". (2017), 1-16. https://doi.org/10.20528/cjsmec.2017.02.001

APA	Turan F, Basoglu M, Zerin Z (2017). Analytical solution for bending and buckling response of laminated non-homogeneous plates using a simplified-higher order theory. Challenge Journal of Structural Mechanics, 3(1), 1 - 16. 10.20528/cjsmec.2017.02.001
Chicago	Turan Ferruh,Basoglu Muhammed Fatih,Zerin Zihni Analytical solution for bending and buckling response of laminated non-homogeneous plates using a simplified-higher order theory. Challenge Journal of Structural Mechanics 3, no.1 (2017): 1 - 16. 10.20528/cjsmec.2017.02.001
MLA	Turan Ferruh,Basoglu Muhammed Fatih,Zerin Zihni Analytical solution for bending and buckling response of laminated non-homogeneous plates using a simplified-higher order theory. Challenge Journal of Structural Mechanics, vol.3, no.1, 2017, ss.1 - 16. 10.20528/cjsmec.2017.02.001
AMA	Turan F,Basoglu M,Zerin Z Analytical solution for bending and buckling response of laminated non-homogeneous plates using a simplified-higher order theory. Challenge Journal of Structural Mechanics. 2017; 3(1): 1 - 16. 10.20528/cjsmec.2017.02.001
Vancouver	Turan F,Basoglu M,Zerin Z Analytical solution for bending and buckling response of laminated non-homogeneous plates using a simplified-higher order theory. Challenge Journal of Structural Mechanics. 2017; 3(1): 1 - 16. 10.20528/cjsmec.2017.02.001
IEEE	Turan F,Basoglu M,Zerin Z "Analytical solution for bending and buckling response of laminated non-homogeneous plates using a simplified-higher order theory." Challenge Journal of Structural Mechanics, 3, ss.1 - 16, 2017. 10.20528/cjsmec.2017.02.001
ISNAD	Turan, Ferruh vd. "Analytical solution for bending and buckling response of laminated non-homogeneous plates using a simplified-higher order theory". Challenge Journal of Structural Mechanics 3/1 (2017), 1-16. https://doi.org/10.20528/cjsmec.2017.02.001