V. Ciaravola scite author profile

V. Ciaravola

5Publications

51Citation Statements Received

71Citation Statements Given

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General theory of frictional heating with application to rubber friction

Fortunato¹,

Ciaravola²,

Furno³

et al. 2015

J. Phys.: Condens. Matter

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The energy dissipation in the contact regions between solids in sliding contact can result in high local temperatures which may strongly effect friction and wear. This is the case for rubber sliding on road surfaces at speeds above 1 mm s(-1). We derive equations which describe the frictional heating for solids with arbitrary thermal properties. The theory is applied to rubber friction on road surfaces and we take into account that the frictional energy is partly produced inside the rubber due to the internal friction of rubber and in a thin (nanometer) interfacial layer at the rubber-road contact region. The heat transfer between the rubber and the road surface is described by a heat transfer coefficient which depends on the sliding speed. Numerical results are presented and compared to experimental data. We find that frictional heating results in a kinetic friction force which depends on the orientation of the sliding block, thus violating one of the two basic Leonardo da Vinci 'laws' of friction.

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Rubber friction directional asymmetry

Tiwari

Dorogin

Steenwyk

et al. 2016

EPL

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In rubber friction studies it is usually assumed that the friction force does not depend on the sliding direction, unless the substrate has anisotropic properties, like a steel surface grinded in one direction. Here we will present experimental results for rubber friction, where we observe a strong asymmetry between forward and backward sliding, where forward and backward refer to the run-in direction of the rubber block. The observed effect could be very important in tire applications, where directional properties of the rubber friction could be induced during braking.

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Dependency of Rubber Friction on Normal Force or Load: Theory and Experiment

Fortunato¹,

Ciaravola²,

Furno³

et al. 2017

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In rubber friction studies it is often observed that the kinetic friction coefficient µ depends on the nominal contact pressure p. We discuss several possible origins of the pressure dependency of µ: (a) saturation of the contact area (and friction force) due to high nominal squeezing pressure, (b) non-linear viscoelasticity, (c) non-randomness in the surface topography, in particular the influence of the skewness of the surface roughness profile, (d) adhesion, and (e) frictional heating. We show that in most cases the non-linearity in the µ(p) relation is mainly due to process (e) (frictional heating), which softens the rubber, increases the area of contact, and (in most cases) reduces the viscoelastic contribution to the friction. In fact, since the temperature distribution in the rubber at time t depends on on the sliding history (i.e., on the earlier time t ′ < t), the friction coefficient at time t will also depend on the sliding history, i.e. it is, strictly speaking, a time integral operator.The energy dissipation in the contact regions between solids in sliding contact can result in high local temperatures which may strongly affect the area of real contact and the friction force (and the wear-rate). This is the case for rubber sliding on road surfaces at speeds above 1 mm/s. In Ref. [14] we have derived equations which describe the frictional heating for solids with arbitrary thermal properties. In this paper the theory is applied to rubber friction on road surfaces. Numerical results are presented and compared to experimental data. We observe good agreement between the calculated and measured temperature increase.

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On the dependency of rubber friction on the normal force or load: theory and experiment

Fortunato¹,

Ciaravola²,

Furno³

et al. 2015

Preprint

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Influence of Surface Free Energy and Wettability on Friction Coefficient between Tire and Road Surface in Wet Conditions

Mazzola¹,

Galderisi²,

Fortunato³

et al. 2013

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V. Ciaravola

General theory of frictional heating with application to rubber friction

Rubber friction directional asymmetry

Dependency of Rubber Friction on Normal Force or Load: Theory and Experiment

On the dependency of rubber friction on the normal force or load: theory and experiment

Influence of Surface Free Energy and Wettability on Friction Coefficient between Tire and Road Surface in Wet Conditions

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