Spectral Analysis of Two-Dimensional Contact Problems

Ju, Yongqing; Farris, T. N.

doi:10.1115/1.2831303

Cited by 150 publications

(49 citation statements)

References 16 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Björklund and Andersson (Andersson & S. Björklund, 1994) extended the conventional matrix inversion approach by incorporating friction induced deformations. Alternative techniques that aim to solve the elastic contact of rough surfaces are the Fast Fourier Transform (FFT)-based method introduced by Ju and Farris (Ju & Farris, 1996) and a follow-up extension, based on a varia-tional principle (Kalker, 1977), proposed by Stanley and Kato (Stanley & Kato, 1997). The contact between solids with realistic surface topographies under relatively small loads usually leads to plastic deformations.…”

Section: Introductionmentioning

confidence: 99%

Interfacial separation between elastic solids with randomly rough surfaces: Comparison between theory and numerical techniques

Almqvist¹,

Campañá²,

Prodanov³

et al. 2011

Journal of the Mechanics and Physics of Solids

156

145

View full text Add to dashboard Cite

We study the distribution of interfacial separations P (u) at the contact region between two elastic solids with randomly rough surfaces. An analytical expression is derived for P (u) using Persson's theory of contact mechanics, and is compared to numerical solutions obtained using (a) a half-space method based on the Boussinesq equation, (b) a Green's function molecular dynamics technique and (c) smart-block classical molecular dynamics. Overall, we find good agreement between all the different approaches.

show abstract

Section: Introductionmentioning

confidence: 99%

Interfacial separation between elastic solids with randomly rough surfaces: Comparison between theory and numerical techniques

Almqvist¹,

Campañá²,

Prodanov³

et al. 2011

Journal of the Mechanics and Physics of Solids

156

145

View full text Add to dashboard Cite

show abstract

“…The radii of curvature and peak density in a surface profile are dependent on the sampling interval of the scanning instrument [21]. As the sampling interval for a given instrument decreases, more details of the surface are captured.…”

Section: Surface Topography Analysismentioning

confidence: 99%

An experimentally validated thermo-mechanical model for the prediction of thermal contact conductance

Singhal

Litke

Black

et al. 2005

International Journal of Heat and Mass Transfer

View full text Add to dashboard Cite

A predictive model for estimating thermal contact conductance between two nominally flat metallic rough surfaces has been developed and experimentally validated. The predictive model consists of two complementary parts, the first of which is a surface deformation analysis to calculate the actual area of contact for each contact spot, while the second accounts for the effects of constriction resistance and gas gap conductance between the contacting surfaces. A surface characterization technique is developed which generates an equivalent 3-D surface profile from multiple 2-D profiles and determines the unique wavelengths of importance for the surface deformation and constriction resistance models. For given surface profiles and material properties of two contacting surfaces, and a specified contact pressure, the surface characterization technique filters out non-essential wavelengths on the surface, after which the surface deformation analysis calculates the deformation and contact area of each contacting asperity by considering three different modes of deformation, namely, elastic, elastic-plastic, and plastic. The constriction resistance model is then used to calculate the constriction resistance for each contacting asperity based on the area of contact and radius of curvature of the asperity. The constriction resistance values for all the contacting asperities are then used to calculate the total thermal contact conductance. An experimental facility has also been constructed to measure thermal contact conductance of interfaces to

show abstract

“…Thomas [7] showed that these properties are not unique for a given surface, but change with the sampling rate of the instrument used to characterize the surface. Ju and Farris [8] also demonstrated the dependence of RMS curvature and slope on the sampling frequency. They showed that the RMS curvature can vary by more than three orders of magnitude and the RMS slope can vary by almost two orders of magnitude while the RMS height stays essentially constant as the sampling interval goes from 0.1 to 0.0001 mm.…”

Section: Intrinsic Surface Characterizationmentioning

confidence: 99%

Characterization of Rough Engineering Surfaces for Use in Thermal Contact Conductance Modeling

Black

Garimella

2006

Journal of Thermophysics and Heat Transfer

View full text Add to dashboard Cite

Most surface properties used in the calculation of contact conductance are not intrinsic to the surface, but vary with the sampling frequency of the instrument used to characterize the surface. This paper offers a methodology for characterizing a surface based on intrinsic surface characterization properties (the self-affine fractal dimension and topothesy), intrinsic material properties, and applied load. A surface characterization model is developed to predict the wavelengths on a surface that are of significance in the prediction of thermal contact conductance. The surface characterization model is combined with surface deformation and constriction resistance models to predict contact conductance across nominally flat, metallic surfaces. The long-wavelength cutoff in the surface characterization is set by the dimensions of the contact area. A theoretical correlation for the short-wavelength cutoff as a function of surface and material properties and load is developed, and then improved by a least-squares fit to experimental data. The integrated model developed predicts contact conductance in three modules: defining the unique asperity geometries important in the deformation modeling; calculating the mode of deformation of asperities; and taking into account the actual geometry of asperities in the constriction resistance model. The predicted contact conductance compares well to experimental data over a range of surface roughnesses, pressures, and substrate materials.

show abstract

Spectral Analysis of Two-Dimensional Contact Problems

Cited by 150 publications

References 16 publications

Interfacial separation between elastic solids with randomly rough surfaces: Comparison between theory and numerical techniques

Interfacial separation between elastic solids with randomly rough surfaces: Comparison between theory and numerical techniques

An experimentally validated thermo-mechanical model for the prediction of thermal contact conductance

Characterization of Rough Engineering Surfaces for Use in Thermal Contact Conductance Modeling

Contact Info

Product

Resources

About