Authors: A. Megalingam, M.M.Mayuram

Abstract:

Evaluation of contact pressure, surface and subsurface contact stresses are essential to know the functional response of surface coatings and the contact behavior mainly depends on surface roughness, material property, thickness of layer and the manner of loading. Contact parameter evaluation of real rough surface contacts mostly relies on statistical single asperity contact approaches. In this work, a three dimensional layered solid rough surface in contact with a rigid flat is modeled and analyzed using finite element method. The rough surface of layered solid is generated by FFT approach. The generated rough surface is exported to a finite element method based ANSYS package through which the bottom up solid modeling is employed to create a deformable solid model with a layered solid rough surface on top. The discretization and contact analysis are carried by using the same ANSYS package. The elastic, elastoplastic and plastic deformations are continuous in the present finite element method unlike many other contact models. The Young-s modulus to yield strength ratio of layer is varied in the present work to observe the contact parameters effect while keeping the surface roughness and substrate material properties as constant. The contacting asperities attain elastic, elastoplastic and plastic states with their continuity and asperity interaction phenomena is inherently included. The resultant contact parameters show that neighboring asperity interaction and the Young-s modulus to yield strength ratio of layer influence the bulk deformation consequently affect the interface strength.

Keywords: Asperity interaction, finite element method, rough surface contact, single layered solid

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1055559

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 2689

References:

[1] T. Merriman, and J. Kannel, "Analyses of the role of surface roughness on contact stresses between elastic cylinders with and without soft surface coating," ASME J.Tribol., vol. 111, pp. 87-94, 1989.
[2] T. Nogi, and T. Kato, "Influence of a hard surface layer on the limit of elastic contact .Part I. Analysis using a real surface model," ASME J. Tribol., vol. 119, pp. 493-500, 1997.
[3] M. R. Hestenes, and E. Stiefel, "Methods of conjugate gradients for solving linear systems," J. Res. Nat. Bur. Stand., vol. 49, pp. 409-436, 1952.
[4] R. Winther, "Some superlinear convergence results for the conjugate gradient method," Soc. Ind. Appl. Math. J. Numer., vol. 17, pp. 14-17, 1980.
[5] X. Tian, and B. Bhushan, "A numerical three-dimensional model for the contact of rough surfaces by variational principle," ASME J. Tribol., vol. 118, pp. 33-41, 1996.
[6] W. Peng, and B. Bhushan, "A numerical three dimensional model for the contact of layered elastic/plastic solids with rough surfaces by a variational principle," ASME J. Tribol., vol. 123, pp. 330-342, 2001.
[7] K. Komvopoulos, and N. Ye, "Three dimensional contact analysis of elastic-plastic layered media with fractal surface topographies," ASME J. Tribol., vol. 123, pp. 632-640, 2001.
[8] Z.Q. Gong, and K. Komvopoulos, "Effect of surface patterning on contact deformation of elastic-plastic layered media," ASME J. Tribol., vol. 125, pp. 16-24, 2003.
[9] Y. Z.Hu, and K. Tonder, "Simulation of 3D random rough surface by 2D digital filter and Fourier analysis," Int. J. Mach. Tools Manufact., vol. 32, pp. 83-90, 1992.
[10] T. W. Kim, B. Bhushan and Y.J. Cho, "The contact behavior of elastic/plastic non Gaussian rough surfaces," Tribology Letters, vol. 22, pp. 1-13, 2006.
[11] S. Cai, and B. Bhushan, "A numerical three dimensional contact model for rough, multilayered elastic/plastic solid surfaces," Wear vol. 259, pp. 1408-1423, 2005.
[12] L. Kogut and I. Etsion, "Elastic plastic contact analysis of sphere and a rigid flat," J. Appl. Mech. Trans., ASME, vol. 69, pp. 657-662, 2002.
[13] D. Tabor, "The hardness of materials," Oxford:Clarendon press,1951.