Top

Mechanics of Composite Materials

Published in:

06-07-2023

Investigation Method of the Static Strength of Structurally-Anisotropic Composite Panels According to a Refined Theory

Authors: L. M. Gavva, V. V. Firsanov

Published in: Mechanics of Composite Materials | Issue 3/2023

Activate our intelligent search to find suitable subject content or patents.

search-config

AI-assisted search

Off

Abstract

The stress-strain state of structurally-anisotropic composite panels was investigated analytically by a refined theory within the framework of a multidisciplinary approach. New mathematical models for examining the stress-strain state of flat rectangular multilayered composite panels with an eccentric assembly of longitudinal and transverse stiffening ribs were proposed. It was refined the work of the stiffener under one-sided contact with the skin. The novelty of the theory of thin-walled elastic panels developed consists in considering the contact problem for the skin and stiffening rib. The flat skins from high-modulus composites anisotropic due to nonsymmetric layup across the thickness were also considered. In addition, the influence of residual thermal stresses was taken into account. Resolving equations of eighth- and eighteenth-order linear differential operators and natural boundary conditions were obtained using the energy approach. The solution of boundary-value problems in a closed form was performed in single trigonometric series for a particular case of consistent boundary conditions along two opposite edges. The boundary conditions at the ends correspond to a fairly general interpretation of the physical boundary conditions of the structural elements. Package of computer codes was developed is the MATLAB software. The new mathematical models and fast procedures for numerical solutions can be useful for designing the panels from advanced composites for the prospective aviation products.

previous article Experimental Investigation of Foam-Filled Composite Double-Arrow Auxetic Structures in Impulse Loadings

next article Behavior of the Dynamic Fracture of a Hybrid Nanocomposite: an Optical Study of Synergistic Toughening Effects

Dont have a licence yet? Then find out more about our products and how to get one now:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

über 102.000 Bücher
über 537 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Finance + Banking
Management + Führung
Marketing + Vertrieb
Maschinenbau + Werkstoffe
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

inform now

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 390 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Maschinenbau + Werkstoffe

Jetzt Wissensvorsprung sichern!

inform now

L. M. Gavva and V. V. Firsanov, “Mathematical models and methods for calculating the stress-strain state of aircraft panels from composite materials taking into account the production technology,” Mech. Solids (Springer), No. 3, 603-612 (2020).

P. Cerracchio, M. Gherlone, and A. Tessler, “Real-time displacement monitoring of a composite stiffened panel subjected to mechanical and thermal loads,” Mechanics, 50, 2487-2496 (2015).

N. S. K. Deb, “Effects of fiber orientation and material isotropy on the analytical elastic solution of a stiffened orthotropic panel subjected to a combined loading,” Advances in Mater. Sci. and Eng., 710143 (2013).

D. A. Edwards, F. W. Williams, and D. Kennedy, “Cost optimization of stiffened panels using VICONOPT,” AIAA J., 36, No. 2, 267-272 (1998).CrossRef

M. Shahravi, S. Fallahzade, and M. Mokhtari, “An analytical approach to thermoelastic bending of simply supported advanced ribbed composite plates,” Mech. Adv. Compos. Struct., 5, No. 2, 173-186 (2018).

H. Altenbach, “Main directions of the theory of multilayer thin-walled structures. Review,” Mech. Composite Mater., 34, No. 3, 333-348 (1998).

A. N. Andreev and Yu. V. Nemirovskii, Multilayer Anisotropic Shells and Plates [in Russian], Novosibirsk, Nauka (2001).

A. B. Akhmedov, “Qualitative algorithm of the theory of plates from composite materials,” Probl. Prochn., 81-84 (2011).

S. K. Golushko and Yu. V. Nemirovskii, Direct and Inverse Problems of Mechanics of Elastic Composite Plates and Shells of Revolution [in Russian], M., Fizmatlit (2008).

10.

E. I. Grigolyuk and G. M. Kulikov, “Ways of development of the theory of elastic multilayer plates and shells,” Vestn. TSTU, 11, No. 2, 439-448 (2005).

11.

S. Candiotti and J. L. Mantari, “Evaluation of the best new cross-ply laminated plate theories through the axiomatic/asymptotic approach,” J. Appl. Comput. Mech., 4, No. 4, 331-351 (2015).

12.

E. Carrera, “Historical review of Zig-Zag theories for multilayered plates and shells,” Appl. Math. Rev., 56, No. 3, 287-308 (2003).

13.

E. Carrere, “Developments, ideas, and evaluations based upon Reissner’s mixed variational theorem in the modeling of multilayered plates and shells,” Appl. Mech. Rev., 54, No. 4, 301-329 (2001).CrossRef

14.

I. F. Obraztsov, O. S. Sirotkin, and V. B. Litvinov, “Integral constructions from composite materials and prospects for their application,” Konstr. Kompoz. Mater., No. 2, 78-84 (2000).

15.

Kobayashi Harutoshi. A survey of books and monographs on plates,” Mem. Fac. Eng., 38, 73-98 (1997).

16.

Yu. V. Nemirovskii and G. L. Gorynin, “Method of stiffness functions in problems of calculation of multilayer rods and plates,” Vestn. Nizhegorsk N. I. Lobachevsky Univ., 1654-1656 (2011).

17.

E. Carrera and L. Demasi, “Two benchmarks to assess 2D theories of sandwich, composite plates,” AIAA J., 41, No. 7, 1356-1362 (2003).CrossRef

18.

D. D. Zakharov, “Nonclassical models of the mechanics of thin composite packages,” Vestn. MIIT, No. 3, 117-122 (2000).

19.

O. V. Motygin and S. A. Nazarov, “Justification of the Kichhoff hypotheses and error estimation for 2D models of anisotropic and inhomogeneous plates, including laminated plates,” IMA J. Appl., 65, No. 1, 1-28 (2000).CrossRef

20.

K. P. Soldatos and P. Watson, “Accurate stress analysis of laminated plates combining a two-dimensional theory with exact three-dimensional solution for simply supported edges,” Math. Mech. Solids, 2, No. 4, 459-489 (1997).CrossRef

21.

T. N. Nguyen, C. H. Thai, and H. Nguyen-Xuan, “On the general framework of high order shear deformation theories for laminated composite plate structures: A novel unified approach,” Int. J. Mech. Sci., 110, 242-255 (2016).CrossRef

22.

L. V. Tran and S. E. Kim, “Static and free vibration analyzes of multilayered plates by a higher-order shear and normal deformation theory and isogeometric analysis,” Thin-Walled Struct., 130, 622-640 (2018).CrossRef

23.

V. I. Gorbachev, “Engineering theory of deformation of inhomogeneous plates from composite materials,” Mekh. Kompoz. Mater. Konstrukt., 22, 585-601 (2017).

24.

F. Gruttmann and W. Wagner, “Shear correction factors for layered plates and shells,” Comput. Mech., 59, No. 1, 129-146 (2017).CrossRef

25.

N. M. L. Hug and A. M. Afsar, “A mathematical model for the analysis of elastic field in a stiffened cantilever of laminated composite,” Advances in Mech. Eng., 170704 (2012).

26.

S. Javed, K. K. Viswanathan, Z. A. Aziz, K. Karthik, and J. H. Lee, “Vibration of anti-symmetric angle-ply laminated plates under higher order shear theory,” Steel and Compos. Struct., 22, No. 6, 1281-1299 (2016).CrossRef

27.

M. Petrolo, M. Cinefra, A. Lamberti, and E. Carrera, “Evaluation of mixed theories for laminated plates through the axiomatic/asymptotic method,” Compos., Part B, 76, 260-272 (2015).CrossRef

28.

M. Petrolo and A. Lamberti, “Axiomatic/asymptotic analysis of refined layer-wise theories for composite and sandwich plates,” Mech. Adv. Mater. Struct., 23, 28-42 (2016).CrossRef

29.

S. Ramaswamy, J. S. Rajadurai, and A. A. M. Moshi, “Comparative analysis on classical laminated plate theory and higher order lamination plate theory for cross-ply FRP composite structures,” J. Computat. Theoretical Nanoscience, 14, No. 11, 5444-5449 (2017).CrossRef

30.

J. Yarasca, J. L. Mantari, M. Petrolo, and E. Carrera, “Multiobjective best theory diagrams cross-ply composite plates employing polynomial, zig-zag, trigonometric and exponential thickness expansions,” Compos. Struct., 176, 860-876 (2017).CrossRef

31.

C. B. York and S. F. M. de Almeida, “On extension shearing bending torsion coupled laminates,” Compos. Struct., 164, 10-22 (2017).CrossRef

32.

E. Carrera, M. Cinefra, A. Lamberti, and A. M. Zenkour, “Axiomatic/asymptotic evaluation of refined plate models for thermo-mechanical analysis,” J. Thermal Stresses, 38, No. 6, 165-187 (2015).CrossRef

33.

Y. S. Joshan, N. Grover, and B. N. Singh, “Assessment of non-polynomial shear deformation theories for thermomechanical analysis of laminated composite plates,” Steel and Compos. Struct., 27, No. 6, 761-775 (2018).

34.

A. S. Sayyad, Y. M. Ghugal, and B. A. Mhaske, “A four-variable plate theory for thermoelastic bending analysis of laminated composite plates,” J. Thermal Stresses, 38, No. 8, 904-925 (2015).CrossRef

35.

N. S. Naik and A. S. Sayyad, “An accurate computational model for thermal analysis of laminated composite and sandwich plates,” J. Thermal Stresses, 42, No. 5, 559-579 (2019).CrossRef

36.

W. Zhen and T. Li, “C0-type global-local higher-order theory including transverse normal thermal strain for laminated composite plates under thermal loading,” Compos. Struct., 101, 157-167 (20130.

37.

C. Cater and X. Xiao, “Multiscale investigation of free edge effects in laminated composites,” Proc. of the American Society for Composites, 29th Technical Conference, ASC 2014, 16th US-Japan Conference on Composite Materials, ASTM-D30 Meeting (2014).

38.

T. Chau-Dinh, T. Truong-Duc, K. Nguyen-Trung, and H. Nguyen-Van, “A node-based MITC3 element for analyzes of laminated composite plates using the higher-order shear deformation theory,” Lecture Notes in Mech. Eng., Part F3, 409-429 (2018).

39.

A. Kefal, A. Tessler, and E. Oterkus, “An enhanced inverse finite element method for displacement and stress monitoring of multilayered composite and sandwich structures,” Compos. Struct., 179, 514-540 (2017).CrossRef

40.

A. Pagani, S. Valvano, and E. Carrera, “Analysis of laminated composites and sandwich structures by variable-kinematic MITC9 plate elements,” J. Sandwich Struct. Mater., 20, No. 1, 4-41 (2018).CrossRef

41.

L. V. Tran, M. A. Wahab, and S. E. Kim, “An isogeometric finite element approach for thermal bending and buckling analyzes of laminated composite plates,” Compos. Struct., 179, 35-39 (2017).CrossRef

42.

A. Zarei and A. Khosravifard, “A meshfree method for static and buckling analysis of shear deformable composite laminates considering continuity of interlaminar transverse shearing stresses,” Compos. Struct., 206-218 (2019).

43.

O. V. Mitrofanov, “Topical problems of calculation and design of anisotropic panels ensuring stability and strength in a supercritical state,” Estestv. Tekhn. Nauk., 162, No. 11, 221-223 (2021).

44.

O. Mitrofanov, I. Lebedev, and M. Urbaha, “Design of thin composite sheathings of anisotropic structure of load-carrying panels of aircraft structures in post-buckling state under combined loading,” Engineering for Rural Development, 20. Ser. “20th Int. Sci. Conf. Engineering for Rural Development, ERD 2021 – Proceedings.” 1145-1153 (2021).

45.

B. V. Boitsov, L. M. Gavva, A. I. Endogur, and V. V. Firsanov, “Stress-strain state and buckling problem of structurallyanisotropic aircraft panels made of composite materials in view of production technology,” Russian Aeronautics., 61, No. 4, 524-532 (2018).CrossRef

46.

V. V. Firsanov and L. M. Gavva, “Analysis of edge effects and the main stress-strain state of structurally-anisotropic aircraft panels using composite materials according to a refined theory,” Konstr. Kompoz. Mater., No. 1, 3-9 (2021).

47.

L. M. Gavva, “Experimental studies of the stability of structurally-anisotropic panels using composite materials for verification of refined mathematical models,” Konstr. Kompoz. Mater., No. 1, 10-15 (2021).

Title: Investigation Method of the Static Strength of Structurally-Anisotropic Composite Panels According to a Refined Theory
Authors: L. M. Gavva
V. V. Firsanov
Publication date: 06-07-2023
Publisher: Springer US
Published in: Mechanics of Composite Materials / Issue 3/2023
Print ISSN: 0191-5665
Electronic ISSN: 1573-8922
DOI: https://doi.org/10.1007/s11029-023-10115-9

Springer Professional

Abstract

Please log in to get access to your license.

Dont have a licence yet? Then find out more about our products and how to get one now:

Springer Professional "Wirtschaft+Technik"

Springer Professional "Technik"

Other articles of this Issue 3/2023

Axisymmetric Stress State of an Adhesive Joint of Two Coaxial Pipes. An Improved Theory

Compression Mechanics for Carbon-Fiberreinforced Epoxy Resin Composites Under Inplane and Out-Of-Plane Quasi-Static and Dynamic Loadings

A Comparative Study of the Estimated Bending Strength of Sandwich Panels by an Artificial Neural Network and an Adaptive Neuro-Fuzzy Inference System

Generalization of a Nonlinear Maxwell-Type Viscoelastoplastic Model and Simulation of Creep and Recovery Curves

Mixed Bending-Shear Buckling Modes of a Sandwich Beam under the Axial Compression of its Outer Layers

Numerical and Analytical Investigation Into the Effects Of Stacking Sequences on the Distortion of Asymmetric Composite Laminates in the Curing Cycle

Premium Partners