THE INFLUENCE OF VISCOELASTICITY ON VELOCITY-DEPENDENT RESTITUTIONS IN THE OBLIQUE IMPACT OF SPHERES

Emanuel Willert, Stephan Kusche, Valentin L. Popov

DOI Number
10.22190/FUME170420006W
First page
269
Last page
284

Abstract


We analyse the oblique impact of linear-viscoelastic spheres by numerical models based on the Method of Dimensionality Reduction and the Boundary Element Method. Thereby we assume quasi-stationarity, the validity of the half-space hypothesis, short impact times and Amontons-Coulomb friction with a constant coefficient for both static and kinetic friction. As under these assumptions both methods are equivalent, their results differ only within the margin of a numerical error. The solution of the impact problem written in proper dimensionless variables will only depend on the two parameters necessary to describe the elastic problem and a sufficient set of variables to describe the influence of viscoelastic material behaviour; in the case of a standard solid this corresponds to two additional variables. The full solution of the impact problem is finally determined by comprehensive parameter studies and partly approximated by simple analytic expressions.


Keywords

Oblique Impacts, Friction, Viscoelasticity, Standard Solid Model, Method of Dimensionality Reduction, Boundary Element Method

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References


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DOI: https://doi.org/10.22190/FUME170420006W

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