Total Deformation, Plane-Strain Contact Analysis of Macroscopically Homogeneous, Compositionally Graded Materials With Constant Power-Law Strain Hardening

Plane-strain contact analysis is presented for compositionally graded materials with power-law strain hardening. The half-space, y≤0, is modeled as an incompressible, nonlinear elastic material. The effective stress, σe, and the effective total strain, εe, are related through a power-law model, σe=K0εeμ;0<μ≤min(1,(1+k)). The material property K0 changes with depth, |y|, as K0=A|y|k;A>0,0≤|k|<1. This material description attempts to capture some features of the plane-strain indentation of elastoplastic or steady-state creeping materials that show monotonically increasing or decreasing hardness with depth. The analysis starts with the solution for the normal line load (Flamant’s problem) and continues with the rigid, frictionless, flat-strip problem. Finally, the general solution of normal indentation of graded material by a convex, symmetric, rigid, and frictionless two-dimensional punch is given. Applications of the present results range from surface treatments of engineering structures, protective coatings for corrosion and fretting fatigue, settling of beam type foundations in the context of soil and rock mechanics, to bioengineering as well as structural applications such as contact of railroad tracks.

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The Stress Field Due to a Line Load Acting on a Half Space of a Power-Law Hardening Material (A Comparison Between Plane Strain and Plane Stress)

Journal of Applied Mechanics ◽

10.1115/1.3422942 ◽

1973 ◽

Vol 40 (1) ◽

pp. 288-290 ◽

Cited By ~ 1

Author(s):

C. Atkinson

Keyword(s):

Exact Solution ◽

Stress Field ◽

Plane Strain ◽

Half Space ◽

Power Law ◽

Elastic Material ◽

Plane Stress ◽

Strain Fields ◽

Line Load ◽

Hardening Material

The exact solution is given for a line load acting on a half space of a power-law elastic material under conditions of plane stress. This solution is compared with the corresponding solution under plane-strain conditions; see Aruliunian [1]. A marked difference is found between the plane-stress and plane-strain fields for different values of the hardening exponent.

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Elastic Foundation Analysis of Uniformly Loaded Functionally Graded Viscoelastic Sandwich Plates

Journal of Mechanics ◽

10.1017/jmech.2012.53 ◽

2012 ◽

Vol 28 (3) ◽

pp. 439-452 ◽

Cited By ~ 28

Author(s):

A. M. Zenkour ◽

M. Sobhy

Keyword(s):

Power Law ◽

Sandwich Plate ◽

Plate Theory ◽

Functionally Graded ◽

Sandwich Plates ◽

Equilibrium Equations ◽

Graded Material ◽

Plate Aspect Ratio ◽

Type V ◽

Power Law Index

AbstractThis paper deals with the static response of simply supported functionally graded material (FGM) viscoelastic sandwich plates subjected to transverse uniform loads. The FG sandwich plates are considered to be resting on Pasternak's elastic foundations. The sandwich plate is assumed to consist of a fully elastic core sandwiched by elastic-viscoelastic FGM layers. Material properties are graded according to a power-law variation from the interfaces to the faces of the plate. The equilibrium equations of the FG sandwich plate are given based on a trigonometric shear deformation plate theory. Using Illyushin's method, the governing equations of the viscoelastic sandwich plate can be solved. Parametric study on the bending analysis of FG sandwich plates is being investigated. These parameters include (i) power-law index, (ii) plate aspect ratio, (iii) side-to-thickness ratio, (iv) loading type, (v) foundation stiffnesses, and (vi) time parameter.

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Exact solution by dynamic stiffness method for the natural vibration of porous functionally graded plate considering neutral surface

Proceedings of the Institution of Mechanical Engineers Part L Journal of Materials Design and Applications ◽

10.1177/1464420720988170 ◽

2021 ◽

pp. 146442072098817

Author(s):

Md. Imran Ali ◽

Mohammad Sikandar Azam

Keyword(s):

Power Law ◽

Functionally Graded Material ◽

Stiffness Matrix ◽

Natural Vibration ◽

Dynamic Stiffness ◽

Functionally Graded ◽

Neutral Surface ◽

Functionally Graded Plate ◽

Dynamic Stiffness Matrix ◽

Graded Material

This paper presents the formulation of dynamic stiffness matrix for the natural vibration analysis of porous power-law functionally graded Levy-type plate. In the process of formulating the dynamic stiffness matrix, Kirchhoff-Love plate theory in tandem with the notion of neutral surface has been taken on board. The developed dynamic stiffness matrix, a transcendental function of frequency, has been solved through the Wittrick–Williams algorithm. Hamilton’s principle is used to obtain the equation of motion and associated natural boundary conditions of porous power-law functionally graded plate. The variation across the thickness of the functionally graded plate’s material properties follows the power-law function. During the fabrication process, the microvoids and pores develop in functionally graded material plates. Three types of porosity distributions are considered in this article: even, uneven, and logarithmic. The eigenvalues computed by the dynamic stiffness matrix using Wittrick–Williams algorithm for isotropic, power-law functionally graded, and porous power-law functionally graded plate are juxtaposed with previously referred results, and good agreement is found. The significance of various parameters of plate vis-à-vis aspect ratio ( L/b), boundary conditions, volume fraction index ( p), porosity parameter ( e), and porosity distribution on the eigenvalues of the porous power-law functionally graded plate is examined. The effect of material density ratio and Young’s modulus ratio on the natural vibration of porous power-law functionally graded plate is also explained in this article. The results also prove that the method provided in the present work is highly accurate and computationally efficient and could be confidently used as a reference for further study of porous functionally graded material plate.

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The Elastic-Viscoelastic Correspondence Principle for Functionally Graded Materials, Revisited

Journal of Applied Mechanics ◽

10.1115/1.1533805 ◽

2003 ◽

Vol 70 (3) ◽

pp. 359-363 ◽

Cited By ~ 40

Author(s):

S. Mukherjee ◽

Glaucio H. Paulino

Keyword(s):

Functionally Graded Materials ◽

Functionally Graded Material ◽

Correspondence Principle ◽

Functionally Graded ◽

Graded Materials ◽

One Dimensional ◽

Space And Time ◽

Graded Material ◽

Nonhomogeneous Materials ◽

Exponentially Graded

Paulino and Jin [Paulino, G. H., and Jin, Z.-H., 2001, “Correspondence Principle in Viscoelastic Functionally Graded Materials,” ASME J. Appl. Mech., 68, pp. 129–132], have recently shown that the viscoelastic correspondence principle remains valid for a linearly isotropic viscoelastic functionally graded material with separable relaxation (or creep) functions in space and time. This paper revisits this issue by addressing some subtle points regarding this result and examines the reasons behind the success or failure of the correspondence principle for viscoelastic functionally graded materials. For the inseparable class of nonhomogeneous materials, the correspondence principle fails because of an inconsistency between the replacements of the moduli and of their derivatives. A simple but informative one-dimensional example, involving an exponentially graded material, is used to further clarify these reasons.

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Closed form solutions of the differential equations governing the plastic fracture field in a power-law hardening material with low strain-hardening exponent

Ingenieur-Archiv ◽

10.1007/bf00531255 ◽

1990 ◽

Vol 60 (7) ◽

pp. 444-462 ◽

Cited By ~ 3

Author(s):

D. E. Panayotounakos ◽

M. Markakis

Keyword(s):

Differential Equations ◽

Closed Form ◽

Strain Hardening ◽

Power Law ◽

Strain Hardening Exponent ◽

Hardening Material ◽

Closed Form Solutions

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Evidence of friction reduction in laterally graded materials

Beilstein Journal of Nanotechnology ◽

10.3762/bjnano.9.229 ◽

2018 ◽

Vol 9 ◽

pp. 2443-2456

Author(s):

Roberto Guarino ◽

Gianluca Costagliola ◽

Federico Bosia ◽

Nicola Maria Pugno

Keyword(s):

Material Properties ◽

Static Friction ◽

Hierarchical Organization ◽

Friction Reduction ◽

Graded Materials ◽

Biological Surfaces ◽

Graded Material ◽

Complex Structural ◽

Frictional Behaviour ◽

Elastic Surfaces

In many biological structures, optimized mechanical properties are obtained through complex structural organization involving multiple constituents, functional grading and hierarchical organization. In the case of biological surfaces, the possibility to modify the frictional and adhesive behaviour can also be achieved by exploiting a grading of the material properties. In this paper, we investigate this possibility by considering the frictional sliding of elastic surfaces in the presence of a spatial variation of the Young’s modulus and the local friction coefficients. Using finite-element simulations and a two-dimensional spring-block model, we investigate how graded material properties affect the macroscopic frictional behaviour, in particular, static friction values and the transition from static to dynamic friction. The results suggest that the graded material properties can be exploited to reduce static friction with respect to the corresponding non-graded material and to tune it to desired values, opening possibilities for the design of bio-inspired surfaces with tailor-made tribological properties.

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Incremental Melting and Solidification Process/Mechanical Characterization of Functionally Graded Al-Si Alloys

Materials Science Forum ◽

10.4028/www.scientific.net/msf.587-588.400 ◽

2008 ◽

Vol 587-588 ◽

pp. 400-404

Author(s):

P. Pinto ◽

L. Mazare ◽

Delfim Soares ◽

F.S. Silva

Keyword(s):

Mechanical Properties ◽

Functionally Graded Materials ◽

Phase Distribution ◽

Solidification Process ◽

Functionally Graded ◽

Graded Materials ◽

Graded Material ◽

Gradual Variation ◽

Melting And Solidification

The Incremental Melting and Solidification Process (IMSP) is a relatively new field for material processing for the production of functionally graded materials. In this process a controlled liquid bath is maintained at the top of the component where new materials are added changing the components composition. Thus, a functionally graded material is obtained with a varying composition along one direction of the component. This paper deals with the influence of one of the process parameters, namely displacement rates between heating coil and mould, in order to evaluate its influence on both metallurgical and mechanical properties of different Al-Si alloys. Hardness and phase distribution, along the main castings axis, were measured. To better assess and characterize the process, two different Al-Si alloys with and without variation of chemical composition along the specimen were analysed. Results demonstrate that a gradual variation of metallurgical and mechanical properties along the component is obtained. It is also shown that Al-Si functionally graded materials can be produced by the incremental melting and solidification process. Results show that the displacement rate is very important on metallurgical and mechanical properties of the obtained alloy.

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