The current study aims the comprehensive comparative analysis of linear, geometric and coupled geometric–material nonlinear bending responses of three-dimensional (3D) functionally graded (FG) panels, including uniform and non-uniform porosity distribution. In contrast to conventional FG models, the current work employs continuous material gradations in all three spatial directions simultaneously. The modified rule-of -mixture is utilised to evaluate the elastic properties of the FG-panel. At the same time, the plastic behaviour of the FG-panel is defined using the von Mises yield criterion, bilinear isotropic strain hardening, and the Prandtl-Reuss constitutive equations in combination with the Tamura-Tomota-Ozawa (TTO) model. The von Karman nonlinear strain-based kinematics and the incremental theory of plasticity are employed to capture geometric and material nonlinearity. The fundamental equation is obtained by using the principle of minimum potential energy and is further solved by the Newton-Raphson iterative technique. The accuracy and robustness of the existing model are validated against established benchmark solutions. Lastly, a detailed parametric study is performed to examine the effect of material gradient index, porosity index, aspect ratio and support condition on the nonlinear bending responses of the three-dimensional FG-panel. In addition, the development of von Mises stresses and plastic zones on the 3D FG-panels is also studied and discussed.
HeidariFTaheriKJanghorbanM. On the experimental results of functionally graded materials with computational mechanics approach. Proc Inst Mech Eng G J Aerosp Eng2024: 09544100241259904.
2.
NaebeMShirvanimoghaddamK. Functionally graded materials: a review of fabrication and properties. Appl Mater Today2016; 5: 223–245.
3.
ShenHS. Functionally graded materials: nonlinear analysis of plates and shells. CRC Press, 2016.
4.
SolaABellucciDCannilloV. Functionally graded materials for orthopedic Applications–An update on design and manufacturing. Biotechnol Adv2016; 34: 504–531.
5.
XuFZhangXZhangH. A review on functionally graded structures and materials for energy absorption. Eng Struct2018; 171: 309–325.
6.
GuptaATalhaM. Recent development in modeling and analysis of functionally graded materials and structures. Prog Aero Sci2015; 79: 1–4.
7.
AshooriARVaniniSSSalariE. Size-dependent axisymmetric vibration of functionally graded circular plates in bifurcation/limit point instability. Appl Phys A2017; 123: 226.
8.
MaLSLeeDW. Exact solutions for nonlinear static responses of a shear deformable FGM beam under an in-plane thermal loading. Eur J Mech Solid2012; 31: 13–20.
9.
NguyenVCTranHQPhamVV. Nonlinear static analysis of bi-directional functionally graded sandwich plates in thermal environments by a higher-order finite element model. Thin-Walled Struct2023; 188: 110819.
10.
HongNT. Nonlinear static bending and free vibration analysis of bidirectional functionally graded material plates. International Journal of Aerospace Engineering2020; 2020: 8831366.
11.
SalariESadough VaniniSA. Nonlocal nonlinear static/dynamic snap-through buckling and vibration of thermally post-buckled imperfect functionally graded circular nanoplates. Waves Random Complex Media2025; 35: 3805–3851.
12.
ChenXZhangXLuY, et al.Static and dynamic analysis of the postbuckling of bi-directional functionally graded material microbeams. Int J Mech Sci2019; 151: 424–443.
13.
Lezgy-NazargahM. Fully coupled thermo-mechanical analysis of bi-directional FGM beams using NURBS isogeometric finite element approach. Aero Sci Technol2015; 45: 154–164.
14.
SahSKGhoshA. Effect of bi-directional material gradation on thermo-mechanical bending response of metal-ceramic FGM sandwich plates using inverse trigonometric shear deformation theory. Int J Struct Integr2024; 15: 561–593.
15.
MehrabadiSJAraghBS. On the thermal analysis of 2-D temperature-dependent functionally graded open cylindrical shells. Compos Struct2013; 96: 773–785.
16.
SahSKGhoshA. Influence of porosity distribution on free vibration and buckling analysis of multi-directional functionally graded sandwich plates. Compos Struct2022; 279: 114795.
17.
GhatagePSKarVRSudhagarPE. On the numerical modelling and analysis of multi-directional functionally graded composite structures: a review. Compos Struct2020; 236: 111837.
18.
BurzyńskiSChróścielewskiJDaszkiewiczK, et al.Elastoplastic nonlinear FEM analysis of FGM shells of cosserat type. Compos B Eng2018; 154: 478–491.
19.
BocciarelliMBolzonGMaierG. A constitutive model of metal–ceramic functionally graded material behavior: formulation and parameter identification. Comput Mater Sci2008; 43: 16–26.
20.
MedjahedRMokhtariMGouasmiS, et al.Elastoplastic limit analysis of functionally graded materials pipe elbows to predict the damage under in-plane bending moment using XFEM-technic. Mech Base Des Struct Mach2024; 53: 1–28.
21.
JinZHPaulinoGHDoddsJRH. Cohesive fracture modeling of elastic–plastic crack growth in functionally graded materials. Eng Fract Mech2003; 70: 1885–1912.
22.
XuGHuangHChenB, et al.Buckling and postbuckling of elastoplastic FGM plates under inplane loads. Compos Struct2017; 176: 225–233.
23.
PitakthapanaphongSBussoEP. Self-consistent elastoplastic stress solutions for functionally graded material systems subjected to thermal transients. J Mech Phys Solid2002; 50(4): 695–716.
24.
AkisT. Elastoplastic analysis of functionally graded spherical pressure vessels. Comput Mater Sci2009; 46: 545–554.
25.
HuangHHanQ. Stability of pressure-loaded functionally graded cylindrical shells with inelastic material properties. Thin-Walled Struct2015; 92: 21–28.
26.
NguyenDKNguyenKVGanBS, et al.Nonlinear bending of elastoplastic functionally graded ceramic-metal beams subjected to nonuniform distributed loads. Appl Math Comput2018; 333: 443–459.
27.
MoitaJSSoaresCMSoaresCA, et al.Elastoplastic and nonlinear analysis of functionally graded axisymmetric shell structures under thermal environment, using a conical frustum finite element model. Compos Struct2019; 226: 111186.
28.
ZafarmandHKadkhodayanM. Nonlinear material and geometric analysis of thick functionally graded plates with nonlinear strain hardening using nonlinear finite element method. Aero Sci Technol2019; 92: 930–944.
29.
ArslanKGunesRApalakMK, et al.Evaluation of geometrically nonlinear and elastoplastic behavior of functionally graded plates under mechanical loading–unloading. Mech Adv Mater Struct2022; 29: 1587–1600.
30.
JradHMarsJWaliM, et al.Geometrically nonlinear analysis of elastoplastic behavior of functionally graded shells. Eng Comput2019; 35: 833–847.
31.
RahmaniMMohammadiYKakavandF. Vibration analysis of different types of porous FG circular sandwich plates. Int J Adv Manuf Technol2019; 12: 63–75.
32.
LongVTTungHV. Postbuckling responses of porous FGM spherical caps and circular plates including edge constraints and nonlinear three-parameter elastic foundations. Mech Base Des Struct Mach2023; 51: 4214–4236.
33.
TahirSITounsiAChikhA, et al.An integral four-variable hyperbolic HSDT for the wave propagation investigation of a ceramic-metal FGM plate with various porosity distributions resting on a viscoelastic foundation. Waves Random Complex Media2024; 34: 1616.
34.
WangWXueGLeiF, et al.Free vibration and buckling behavior of porous P-type FGM and S-type FGM circular plates on elastic foundation under non-uniform thermal field. J Strain Anal Eng Des2024: 03093247241257064.
35.
HadjiLMadanRBernardF. Thermal buckling in multi-directional porous plates: the effects of material grading and aspect ratio. Proc Inst Mech Eng G J Aerosp Eng2024; 238: 412–426.
36.
SalariESadough VaniniSA. Small/Large amplitude vibration, snap-through and nonlinear thermo-mechanical instability of temperature-dependent FG porous circular nanoplates. Eng Comput2023; 39: 2295–2326.
37.
DemirhanPATaskinV. Bending and free vibration analysis of Levy-type porous functionally graded plate using state space approach. Compos B Eng2019; 160: 661–676.
38.
BelarbiMOKaramanliABenounasS, et al.Bending, free vibration and buckling finite element analysis of porous functionally graded plates with various porosity distributions using an improved FSDT. Mech Base Des Struct Mach2025; 53(1): 401–445.
39.
ZghalSDammakF. Buckling responses of porous structural components with gradient power-based and sigmoid material variations under different types of compression loads. Compos Struct2021; 273: 114313.
40.
JoshiKKKarVRKumarS. Nonlinear bending characteristics of multidirectional functionally graded porous panels using higher-order finite element solution with parametric optimization. Mech Adv Mater Struct2025; 32: 169–193.
41.
ShariyatMAlipourMM. A power series solution for vibration and complex modal stress analyses of variable thickness viscoelastic two-directional FGM circular plates on elastic foundations. Appl Math Model2013; 37: 3063–3076.
42.
WangXYuanZJinC. 3D free vibration analysis of multi-directional FGM parallelepipeds using the quadrature element method. Appl Math Model2019; 68: 383–404.
43.
AkgünGKurtaranHKalbaranÖ. Non-linear transient response of porous functionally graded truncated conical panels using GDQ method. Thin-Walled Struct2021; 159: 107276.
44.
ReddyJN. Mechanics of laminated composite plates and shells: theory and analysis. CRC Press, 2003.
45.
ReddyJN. An introduction to nonlinear finite element analysis second edition: with applications to heat transfer, fluid mechanics, and solid mechanics. OUP Oxford, 2014.
46.
EfraimEEisenbergerM. Exact vibration analysis of variable thickness thick annular isotropic and FGM plates. J Sound Vib2007; 299: 720–738.
47.
JoshiKKKarVR. Elastoplastic behaviour of multidirectional porous functionally graded panels: a nonlinear FEM approach. Iranian Journal of Science and Technology, Transactions of Mechanical Engineering2024; 48(1): 307–329.
48.
VaghefiR. Assessing the effect of porosity on elastoplastic buckling behavior of functionally graded plates using meshfree Tchebychev-RPIM. Acta Mech2024; 235: 5621–5642.
49.
CookRD. Concepts and applications of finite element analysis. John Wiley & Sons, 2007.
50.
KimNH. Introduction to nonlinear finite element analysis. Springer Science & Business Media, 2014.
51.
HuangHHanQ. Elastoplastic buckling of axially loaded functionally graded material cylindrical shells. Compos Struct2014; 117: 135–142.
52.
Van DoTNguyenDKDucND, et al.Analysis of bi-directional functionally graded plates by FEM and a new third-order shear deformation plate theory. Thin-Walled Struct2017; 119: 687–699.
53.
Belinha BelinhaJDinisLM. Elasto‐plastic analysis of plates by the element free galerkin method. Eng Comput2006; 23: 525–551.
