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Frictional energy dissipation in contact of nominally flat rough surfaces under harmonically varying loads
Publikationstyp
Journal Article
Date Issued
2011-10-01
Sprache
English
Institut
Volume
59
Issue
12
Start Page
2442
End Page
2454
Citation
Journal of the Mechanics and Physics of Solids 59 (12): 2442-2454 (2011)
Publisher DOI
Scopus ID
Publisher
Elsevier Science
If the nominal contact tractions at an interface are everywhere below the Coulomb friction limit throughout a cycle of oscillatory loading, the introduction of surface roughness will generally cause local microslip between the contacting asperities and hence some frictional dissipation. This dissipation is important both as a source of structural damping and as an indicator of potential fretting damage. Here we use a strategy based on the Ciavarella-Jäger superposition and a recent solution of the general problem of the contact of two half spaces under oscillatory loading to derive expressions for the dissipation per cycle which depend only on the normal incremental stiffness of the contact, the external forces and the local coefficient of friction. The results show that the dissipation depends significantly on the relative phase between the oscillations in normal and tangential load - a factor which has been largely ignored in previous investigations. In particular, for given load amplitudes, the dissipation is significantly larger when the loads are out of phase. We also establish that for small amplitudes the dissipation varies with the cube of the load amplitude and is linearly proportional to the second derivative of the elastic compliance function for all contact geometries, including those involving surface roughness. It follows that experimental observations of less than cubic dependence on load amplitude cannot be explained by reference to roughness alone, or by any other geometric effect in the contact of half spaces.
Subjects
Contact problems
Coulomb friction
Fretting
Hysteretic damping
Rough surfaces
DDC Class
600: Technik
620: Ingenieurwissenschaften