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Engineering with Computers
Erschienen in: Engineering with Computers 1/2023

04.09.2021 | Original Article

A nonlocal strain gradient analysis of laminated composites and sandwich nanoplates using meshfree approach

verfasst von: Chien H. Thai, A. J. M. Ferreira, H. Nguyen-Xuan, Lieu B. Nguyen, P. Phung-Van

Erschienen in: Engineering with Computers | Ausgabe 1/2023

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Abstract

This paper aims to develop a nonlocal strain gradient meshfree plate approach which combines the nonlocal strain gradient theory (NSGT), higher order shear deformation theory (HSDT) and meshfree method, for the bending and free vibration analyses of laminated composite and sandwich nanoplates. Mechanical characteristics of small-scale structures can be described by using two scale parameters related to the nonlocal and strain gradient effects. The weak form of governing equations is extracted from the virtual work principle. Exploiting the higher order derivatives of moving Kriging (MK) shape functions, the present approach satisfies the requirement of the third-order derivatives of weak approximations. The displacements and natural frequencies of laminated composite and sandwich nanoplates are then determined by utilizing the MK meshfree method. Numerical results show that the deflections and natural frequencies of laminated composite and sandwich nanoplates are significantly influenced by the boundary conditions, nonlocal parameter and strain gradient parameter, geometry, length-to-thickness ratios. As observed, a large difference between NSGT and classical HSDT results is reported and discussed. It is clear that the results of both models coincide when the nonlocal and strain gradient parameters are taken as zero.
Vorheriger Artikel Editorial: Computational modeling based on nonlocal theory
Nächster Artikel Nonlocal strong forms of thin plate, gradient elasticity, magneto-electro-elasticity and phase-field fracture by nonlocal operator method

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Literatur
1.
Wu W (2017) Inorganic nanomaterials for printed electronics: a review. Nanoscale 9(22):7342–7372
2.
Gohardani O, Elola MC, Elizetxea C (2014) Potential and prospective implementation of carbon nanotubes on next generation aircraft and space vehicles: a review of current and expected applications in aerospace sciences. Prog Aerosp Sci 70:42–68
3.
Bonanni A, del Valle M (2010) Use of nanomaterials for impedimetric DNA sensors: a review. Anal Chim Acta 678(1):7–17
4.
5.
6.
Mindlin RD (1965) Second gradient of strain and surface-tension in linear elasticity. Int J Solids Struct 1(4):417–438
7.
Aifantis EC (1999) Strain gradient interpretation of size effects. Int J Fract 95(1):299
8.
Yang F, Chong ACM, Lam DCC, Tong P (2002) Couple stress based strain gradient theory for elasticity. Int J Solids Struct 39(10):2731–2743MATH
9.
Lam DCC, Yang F, Chong ACM, Wang J, Tong P (2003) Experiments and theory in strain gradient elasticity. J Mech Phys Solids 51(8):1477–1508MATH
10.
Thai H-T, Vo TP, Nguyen T-K, Kim S-E (2017) A review of continuum mechanics models for size-dependent analysis of beams and plates. Compos Struct 177:196–219
11.
Aifantis EC (2016) Chapter one—internal length gradient (ILG) material mechanics across scales and disciplines. In: Bordas SPA, Balint DS (eds) Advances in applied mechanics. Elsevier, Amsterdam, pp 1–110
12.
Askes H, Aifantis EC (2011) Gradient elasticity in statics and dynamics: an overview of formulations, length scale identification procedures, finite element implementations and new results. Int J Solids Struct 48(13):1962–1990
13.
Phung-Van P, Lieu QX, Nguyen-Xuan H, Abdel WM (2017) Size-dependent isogeometric analysis of functionally graded carbon nanotube-reinforced composite nanoplates. Compos Struct 166:120–135
14.
Phung-Van P, Thai CH, Nguyen-Xuan H, Abdel WM (2019) Porosity-dependent nonlinear transient responses of functionally graded nanoplates using isogeometric analysis. Compos B Eng 164:215–225
15.
Phung-Van P, Thai CH, Nguyen-Xuan H, Abdel-Wahab M (2019) An isogeometric approach of static and free vibration analyses for porous FG nanoplates. Eur J Mech A Solids 78:103851MathSciNetMATH
16.
Thai CH, Ferreira AJM, Nguyen-Xuan H (2018) Isogeometric analysis of size-dependent isotropic and sandwich functionally graded microplates based on modified strain gradient elasticity theory. Compos Struct 192:274–288
17.
Thai CH, Ferreira AJM, Phung-Van P (2020) Free vibration analysis of functionally graded anisotropic microplates using modified strain gradient theory. Eng Anal Bound Elem 117:284–298MathSciNetMATH
18.
Thai CH, Ferreira AJM, Rabczuk T, Nguyen-Xuan H (2018) Size-dependent analysis of FG-CNTRC microplates based on modified strain gradient elasticity theory. Eur J Mech A Solids 72:521–538MathSciNetMATH
19.
Thai CH, Ferreira AJM, Tran TD, Phung-Van P (2019) A size-dependent quasi-3D isogeometric model for functionally graded graphene platelet-reinforced composite microplates based on the modified couple stress theory. Compos Struct 234:111695
20.
Arefi M, Mohammad-Rezaei Bidgoli E, Rabczuk T (2019) Thermo-mechanical buckling behavior of FG GNP reinforced micro plate based on MSGT. Thin Walled Struct 142:444–459
21.
Arefi M, Mohammad-Rezaei Bidgoli E, Rabczuk T (2019) Effect of various characteristics of graphene nanoplatelets on thermal buckling behavior of FGRC micro plate based on MCST. Eur J Mech A Solids 77:103802MathSciNetMATH
22.
Mohammad-Rezaei Bidgoli E, Arefi M (2019) Free vibration analysis of micro plate reinforced with functionally graded graphene nanoplatelets based on modified strain-gradient formulation. J Sandwich Struct Mater 23(2):436–472
23.
Nguyen HX, Nguyen TN, Abdel-Wahab M, Bordas SPA, Nguyen-Xuan H, Vo TP (2017) A refined quasi-3D isogeometric analysis for functionally graded microplates based on the modified couple stress theory. Comput Methods Appl Mech Eng 313:904–940MathSciNetMATH
24.
Lim CW, Zhang G, Reddy JN (2015) A higher-order nonlocal elasticity and strain gradient theory and its applications in wave propagation. J Mech Phys Solids 78:298–313MathSciNetMATH
25.
Mehralian F, Tadi Beni Y, Karimi ZM (2017) Nonlocal strain gradient theory calibration using molecular dynamics simulation based on small scale vibration of nanotubes. Phys B 514:61–69
26.
Barretta R, Feo L, Luciano R, Marotti de Sciarra F, Penna R (2016) Functionally graded Timoshenko nanobeams: a novel nonlocal gradient formulation. Compos Part B Eng 100:208–219
27.
Apuzzo A, Barretta R, Faghidian SA, Luciano R, Marotti de Sciarra F (2018) Free vibrations of elastic beams by modified nonlocal strain gradient theory. Int J Eng Sci 133:99–108MathSciNetMATH
28.
Li L, Li X, Hu Y (2016) Free vibration analysis of nonlocal strain gradient beams made of functionally graded material. Int J Eng Sci 102:77–92MATH
29.
Lu L, Guo X, Zhao J (2017) A unified nonlocal strain gradient model for nanobeams and the importance of higher order terms. Int J Eng Sci 119:265–277
30.
Ebrahimi F, Barati MR (2017) A nonlocal strain gradient refined beam model for buckling analysis of size-dependent shear-deformable curved FG nanobeams. Compos Struct 159:174–182
31.
Farajpour A, Yazdi MRH, Rastgoo A, Mohammadi M (2016) A higher-order nonlocal strain gradient plate model for buckling of orthotropic nanoplates in thermal environment. Acta Mech 227(7):1849–1867MathSciNetMATH
32.
Nematollahi MS, Mohammadi H (2019) Geometrically nonlinear vibration analysis of sandwich nanoplates based on higher-order nonlocal strain gradient theory. Int J Mech Sci 156:31–45
33.
Arefi M, Kiani M, Rabczuk T (2019) Application of nonlocal strain gradient theory to size dependent bending analysis of a sandwich porous nanoplate integrated with piezomagnetic face-sheets. Compos B Eng 168:320–333
34.
Arefi M, Kiani M, Zamani MH (2018) Nonlocal strain gradient theory for the magneto-electro-elastic vibration response of a porous FG-core sandwich nanoplate with piezomagnetic face sheets resting on an elastic foundation. J Sandwich Struct Mater 22(7):2157–2185
35.
Arefi M, Mohammad-Rezaei Bidgoli E, Dimitri R, Tornabene F (2018) Free vibrations of functionally graded polymer composite nanoplates reinforced with graphene nanoplatelets. Aerosp Sci Technol 81:108–117
36.
Mirjavadi SS, Afshari BM, Barati MR, Hamouda AMS (2019) Transient response of porous FG nanoplates subjected to various pulse loads based on nonlocal stress-strain gradient theory. Eur J Mech A Solids 74:210–220MathSciNetMATH
37.
Arefi M, Zenkour A (2017) Thermo-electro-mechanical bending behavior of sandwich nanoplate integrated with piezoelectric face-sheets based on trigonometric plate theory. Compos Struct 162:108–122
38.
Żur KK, Arefi M, Kim J, Reddy JN (2020) Free vibration and buckling analyses of magneto-electro-elastic FGM nanoplates based on nonlocal modified higher-order sinusoidal shear deformation theory. Compos Part B Eng 182:7601
39.
Phung-Van P, Tran LV, Ferreira AJM, Nguyen-Xuan H, Abdel-Wahab M (2017) Nonlinear transient isogeometric analysis of smart piezoelectric functionally graded material plates based on generalized shear deformation theory under thermo-electro-mechanical loads. Nonlinear Dyn 87(2):879–894MATH
40.
41.
Phung-Van P, Abdel-Wahab M, Liew KM, Bordas SPA, Nguyen-Xuan H (2015) Isogeometric analysis of functionally graded carbon nanotube-reinforced composite plates using higher-order shear deformation theory. Compos Struct 123:137–149
42.
Thanh C-L, Phung-Van P, Thai CH, Nguyen-Xuan H, Abdel WM (2018) Isogeometric analysis of functionally graded carbon nanotube reinforced composite nanoplates using modified couple stress theory. Compos Struct 184:633–649
43.
Phung-Van P, Ferreira AJM, Nguyen-Xuan H, Thai CH (2021) Scale-dependent nonlocal strain gradient isogeometric analysis of metal foam nanoscale plates with various porosity distributions. Compos Struct 268:113949
44.
45.
Fan F, Safaei B, Sahmani S (2020) Buckling and postbuckling response of nonlocal strain gradient porous functionally graded micro/nano-plates via NURBS-based isogeometric analysis. Thin-Walled Struct 159:107231
46.
Fan F, Sahmani S, Safaei B (2021) Isogeometric nonlinear oscillations of nonlocal strain gradient PFGM micro/nano-plates via NURBS-based formulation. Compos Struct 255:112969
47.
Jalaei MH, Thai H-T (2019) Dynamic stability of viscoelastic porous FG nanoplate under longitudinal magnetic field via a nonlocal strain gradient quasi-3D theory. Compos Part B Eng 175:107164
48.
Sahmani S, Fattahi AM (2018) Small scale effects on buckling and postbuckling behaviors of axially loaded FGM nanoshells based on nonlocal strain gradient elasticity theory. Appl Math Mech 39(4):561–580MathSciNetMATH
49.
Ghorbani K, Mohammadi K, Rajabpour A, Ghadiri M (2019) Surface and size-dependent effects on the free vibration analysis of cylindrical shell based on Gurtin-Murdoch and nonlocal strain gradient theories. J Phys Chem Solids 129:140–150
50.
Cornacchia F, Fantuzzi N, Luciano R, Penna R (2019) Solution for cross- and angle-ply laminated Kirchhoff nano plates in bending using strain gradient theory. Compos Part B Eng 173:7006
51.
Bacciocchi M, Fantuzzi N, Ferreira AJM (2020) Conforming and nonconforming laminated finite element Kirchhoff nanoplates in bending using strain gradient theory. Comput Struct 239:6322
52.
Raghu P, Rajagopal A, Reddy JN (2018) Nonlocal nonlinear finite element analysis of composite plates using TSDT. Compos Struct 185:38–50
53.
Gu L (2003) Moving kriging interpolation and element-free Galerkin method. Int J Numer Methods Eng 56(1):1–11MATH
54.
Thai CH, Do VNV, Nguyen-Xuan H (2016) An improved Moving Kriging-based meshfree method for static, dynamic and buckling analyses of functionally graded isotropic and sandwich plates. Eng Anal Bound Elem 64:122–136MathSciNetMATH
55.
Nguyen TN, Thai CH, Nguyen-Xuan H (2016) A novel computational approach for functionally graded isotropic and sandwich plate structures based on a rotation-free meshfree method. Thin Walled Struct 107:473–488
56.
Thai CH, Nguyen TN, Rabczuk T, Nguyen-Xuan H (2016) An improved moving Kriging meshfree method for plate analysis using a refined plate theory. Comput Struct 176:34–49
57.
Thai CH, Tran TD, Phung-van P (2020) A size-dependent moving Kriging meshfree model for deformation and free vibration analysis of functionally graded carbon nanotube-reinforced composite nanoplates. Eng Anal Bound Elem 115:52–63MathSciNetMATH
58.
Thai CH, Ferreira A, Lee J, Nguyen-Xuan H (2018) An efficient size-dependent computational approach for functionally graded isotropic and sandwich microplates based on modified couple stress theory and moving Kriging-based meshfree method. Int J Mech Sci 142:322–338
59.
Thai CH, Ferreira AJM, Nguyen-Xuan H (2017) Naturally stabilized nodal integration meshfree formulations for analysis of laminated composite and sandwich plates. Compos Struct 178:260–276
60.
Thai CH, Ferreira AJM, Rabczuk T, Nguyen-Xuan H (2018) A naturally stabilized nodal integration meshfree formulation for carbon nanotube-reinforced composite plate analysis. Eng Anal Bound Elem 92:136–155MathSciNetMATH
61.
Thai CH, Ferreira AJM, Wahab MA, Nguyen-Xuan H (2018) A moving Kriging meshfree method with naturally stabilized nodal integration for analysis of functionally graded material sandwich plates. Acta Mech 229(7):2997–3023MathSciNetMATH
62.
Thai CH, Phung-Van P (2020) A meshfree approach using naturally stabilized nodal integration for multilayer FG GPLRC complicated plate structures. Eng Anal Bound Elem 117:346–358MathSciNetMATH
63.
Thai CH, Ferreira AJM, Phung-Van P (2020) A nonlocal strain gradient isogeometric model for free vibration and bending analyses of functionally graded plates. Compos Struct 251:112634
64.
Thai CH, Ferreira AJM, Nguyen-Xuan H, Phung-Van P (2021) A size dependent meshfree model for functionally graded plates based on the nonlocal strain gradient theory. Compos Struct 272:114169
65.
Reddy JN (1984) A simple higher-order theory for laminated composite plates. J Appl Mech 51(4):745–752MATH
66.
Pagano NJ (1970) Exact solutions for rectangular bidirectional composites and sandwich plates. J Compos Mater 4(1):20–34
67.
Srinivas S (1973) A refined analysis of composite laminates. J Sound Vib 30(4):495–507MATH
68.
Ferreira AJM, Fasshauer GE, Batra RC, Rodrigues JD (2008) Static deformations and vibration analysis of composite and sandwich plates using a layerwise theory and RBF-PS discretizations with optimal shape parameter. Compos Struct 86(4):328–343
69.
Liew KM, Huang YQ, Reddy JN (2003) Vibration analysis of symmetrically laminated plates based on FSDT using the moving least squares differential quadrature method. Comput Methods Appl Mech Eng 192(19):2203–2222MATH
70.
Ferreira AJM, Castro LMS, Bertoluzza S (2009) A high order collocation method for the static and vibration analysis of composite plates using a first-order theory. Compos Struct 89(3):424–432
Metadaten
Titel
A nonlocal strain gradient analysis of laminated composites and sandwich nanoplates using meshfree approach
verfasst von
Chien H. Thai
A. J. M. Ferreira
H. Nguyen-Xuan
Lieu B. Nguyen
P. Phung-Van
Publikationsdatum
04.09.2021
Verlag
Springer London
Erschienen in
Engineering with Computers / Ausgabe 1/2023
Print ISSN: 0177-0667
Elektronische ISSN: 1435-5663
DOI
https://doi.org/10.1007/s00366-021-01501-9

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