Journal of Applied Science and Engineering

Published by Tamkang University Press

1.30

Impact Factor

2.10

CiteScore

Ulku Babuscu Yesil This email address is being protected from spambots. You need JavaScript enabled to view it.1 and Mehmet Can Atasayanlar1

11,2-Yildiz Technical Uni., Faculty of Chemical and Metallurgical Eng., Dep. of Mathematical Engineering, Istanbul, Turkey 


 

Received: April 20, 2020
Accepted: June 16, 2020
Publication Date: December 1, 2020

 Copyright The Author(s). This is an open access article distributed under the terms of the Creative Commons Attribution License (CC BY 4.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are cited.


Download Citation: ||https://doi.org/10.6180/jase.202012_23(4).0007  

ABSTRACT


A static analysis of a pre-stressed plate-strip made from functionally-graded material (FGM) containing a circular hole has been investigated under bending forces. The plate-strip is simply supported on two opposite ends and the pre-stresses are formed by the uniformly distributed forces which acts on these two ends before the main loading. The influences of pre-stresses in the plate-strip on the distributions of displacements and stresses around the hole caused by the additional bending forces acting on the upper face-plane of the FGM platestrip are investigated. The Linearized Three-Dimensional Elasticity Theory and the generalized plane-strain conditions are assumed for the modelling of the theoretical investigations. Young’s modulus of the medium varies continuously in the horizontal and vertical directions according to power law distribution, but the Poisson’s ratio and material density are assumed to be constant. The solution of the considered problem is obtained numerically with the help of the Finite Element Method (FEM). Numerical results of distributions of the displacements and stresses around the hole are presented and discussed for various problem parameters such as, material property, plate size, initial effect and position of the hole.


Keywords: Functionally graded material; Initial stress; Circular hole; Static analysis; FEM


REFERENCES


  1. [1] M Koiwumi. The concept of FGM, Ceram. Trans. Func. Grad. Mater., 34, 3-10. In Linear Networks and Systems, pages 123–135. Berlmont, CA, 1993.
  2. [2] F Erdogan and B. H. Wu. The surface crack problem for a plate with functionally graded properties. Journal of Applied Mechanics,Transactions ASME, 64(3):449–456, 1997.
  3. [3] JNReddy, CMWang, and SKitipornchai. Axisymmetric bending of functionally graded circular and annular plates. European Journal of Mechanics-A/Solids,18(2):185– 199, 1999.
  4. [4] M H Santare and J Lambros. Use of graded finite elements to model the behavior of nonhomogeneous materials. Journal of Applied Mechanics, Transactions ASME, 67(4):819–822, 2000.
  5. [5] Jeong Ho Kim and G H Paulino. Isoparametric graded finite elements for nonhomogeneous isotropic and orthotropic materials. Journal ofApplied Mechanics, Transactions ASME, 69(4):502–514, 2002.
  6. [6] Shyang Ho Chi and Yen Ling Chung. Mechanical behavior of functionally graded material plates under transverse load-Part I: Analysis. International Journal of Solids and Structures, 43(13):3657–3674, 2006.
  7. [7] Shyang Ho Chi and Yen Ling Chung. Mechanical behavior of functionally graded material plates under transverse load-Part I: Analysis. International Journal of Solids and Structures, 43(13):3657–3674, 2006.
  8. [8] D. V. Kubair and B. Bhanu-Chandar. Stress concentration factor due to a circular hole in functionally graded panels under uniaxial tension. International Journal of Mechanical Sciences, 50(4):732–742, 2008.
  9. [9] B Yang, H.J Ding, and W.Q Chen. Elasticity solutions for a uniformly loaded annular plate of functionally graded materials. Structural Engineering and Mechanics, 30(4):501–512, 2008.
  10. [10] Quanquan Yang, Cun Fa Gao, and Wentao Chen. Stress analysis of a functional graded material plate with a circular hole. Archive of Applied Mechanics, 80(8):895–907, aug 2010.
  11. [11] Quan Quan Yang, Cun Fa Gao, and Wen Tao Chen. Stress concentration in a finite functionally graded material plate. In Science China: Physics, Mechanics and Astronomy, volume 55, pages 1263–1271, jul 2012.
  12. [12] GururajaUdupa, S.ShrikanthaRao, and K.V.Gangadharan. Functionally Graded Composite Materials: An Overview. Procedia Materials Science, 5:1291–1299, 2014.
  13. [13] DinhKienNguyen, BuntaraS.Gan, and ThanhHuong Trinh. Geometrically nonlinear analysis of planar beam and framestructures made of functionally graded material. Structural Engineering and Mechanics,49(6):727–743, 2014.
  14. [14] AChegenizadeh, BGhamidi, HNikraz, and MSimsek. A novel two-dimensional approach to modelling functionally graded resting on a soil medium. Structural Engineering and Mechanisms, 51(5):727–741, 2014.
  15. [15] TranMinhTu, TranHuuQuoc, and NguyenVanLong. Bending analysis of functionally graded plates using new eight-unknown higher order shear deformation theory. In Structural Engineering and Mechanics, volume 62, pages 311–324, 2017.
  16. [16] Emrah Madenci. A refined functional and mixed formulation to static analyses of fgm beams. Structural Engineering and Mechanics, 69(4):427–437, 2019.
  17. [17] Mourad Khebizi, Hamza Guenfoud, Mohamed Guenfoud, and Rached El Fatmi. Three-dimensional modelling of functionally graded beams using SaintVenant’s beam theory. Structural Engineering and Mechanics, 72(2):257–273, 2019.
  18. [18] Pınar Aydan Demirhan and Vedat Tas¸kin. Static analysis of simply supported functionally graded sandwich plates by using four variable plate theory. Teknik Dergi/Technical Journal of Turkish Chamber of Civil Engineers, 30(2):8987–9007, 2019.
  19. [19] S.D. Akbarov and A.N. Guz. Mechanics of curved composites. Kluwer Academic Publishers, Dordrecht, The Netherlands, 2000.
  20. [20] O.C Zienkiewicz and R.L Taylor. The Finite Element Methods: basic Formulation Linear Problems. Oxford, mc graw-hi edition, 1989.
  21. [21] G.N Savin. Stress Concentration Around Holes. Oxford, pergamon edition, 1951.
  22. [22] S D Akbarov, N Yahnioglu, and U Babuscu Yesil. Interaction between two neighboring circular holes in a prestretched simply supported orthotropic strip under bending. Mechanics of Composite Materials, 44(6):581– 590, 2008.
  23. [23] S.P Timoshenko and J.N Goodier. Theory ofElasticity. London, third edit edition, 1970.


    



 

2.1
2023CiteScore
 
 
69th percentile
Powered by  Scopus

SCImago Journal & Country Rank

Enter your name and email below to receive latest published articles in Journal of Applied Science and Engineering.