https://doi.org/10.22190/FUME190115006W

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Percussive and erosive wear by repetitive impacting of solid particles damages surfaces even at low impact velocities. As the impact wear is often directly related to the energy loss during the collision and therefore to the coefficients of normal and tangential restitution, in the present study the oblique low-velocity impact of a rigid sphere onto an elastic half-space is analyzed based on the known respective contact-impact solution and with regard to the energy loss during the impact. Simple analytic expressions are derived for the total impact wear volume. It is found that the portion of kinetic energy lost in frictional dissipation has a well-located maximum for configurations with weak forward pre-spin. The distribution of frictional dissipation over the contact area has a complex dependence on the impact parameters. For pronounced local slip (e.g. due to a small coefficient of friction) the dissipation accumulated over the collision is localized in the center of impact whereas for dominance of sticking, most energy is lost away from the center.

Elastic Impacts, Friction, Energy Dissipation, Wear

Souilliart, T., Rigaud, E., Le Bot, A., Phalippou, C., 2017, Energy-based wear law for oblique impacts in dry environment, Tribology International, 105, pp. 241-249.

Tarbe, R., Kulu, P., 2008, Impact wear tester for the study of abrasive erosion and milling processes, 6th International DAAAM Baltic Conference Industrial Engineering, Tallin.

Finnie, I., 1960, Erosion of surfaces by solid particles, Wear, 3(2), pp. 87-103.

Neilson, J.H., Gilchrist, A., 1968, Erosion by a stream of solid particles, Wear, 11(2), pp. 111-122.

Engel, P.A., 1978, Percussive impact wear: A study of repetitively impacting solid components in engineering, Tribology International, 11(3), pp. 169-176.

Talia, M., Lankarani, H., Talia, J.E., 1999, New experimental technique for the study and analysis of solid particle erosion mechanisms, Wear, 225-229 (Part 2), pp. 1070-1077.

Hertz, H., 1882, Über die Berührung fester elastischer Körper, Journal für die reine und angewandte Mathematik, 92, pp. 156-171.

Johnson, K.L., Pollock, H.M., 1994, The role of adhesion in the impact of elastic spheres, Journal of Adhesion Science and Technology, 8(11), pp. 1323-1332.

Thornton, C., Ning, Z., 1998, A theoretical model for the stick/bounce behaviour of adhesive, elastic-plastic spheres, Powder Technology, 99(2), pp. 154-162.

Hunter, S.C., 1957, Energy absorbed by elastic waves during impact, Journal of the Mechanics and Physics of Solids, 5(3), pp. 162-171.

Ghanbarzadeh, A., Hassanour, A., Neville, A., 2018, A numerical model for calculation of the restitution coefficient of elastic-perfectly plastic and adhesive bodies with rough surfaces, Powder Technology, accepted manuscript, doi: https://doi.org/10.1016/j.powtec.2018.12.079 .

Maw, N., Barber, J.R., Fawcett, J.N., 1976, The oblique impact of elastic spheres, Wear, 38(1), pp. 101-114.

Mindlin, R.D., Deresiewicz, H., 1953, Elastic Spheres in Contact under Varying Oblique Forces, Journal of Applied Mechanics, 20, pp. 327-344.

Gorham, D.A., Kharaz, A.H., 2000, The measurement of particle rebound characteristics, Powder Technology, 112(3), pp. 193-202.

Lyashenko, I.A., Willert, E., Popov, V.L., 2018, Mechanics of collisions of solids: influence of friction and adhesion. I. Review of experimental and theoretical works, PNRPU Mechanics Bulletin, 2, pp. 44-61, doi: http://dx.doi.org/10.15593/perm.mech/2018.2.05 .

Popov, V.L., Heß, M., 2015, Method of Dimensionality Reduction in Contact Mechanics and Friction, Springer-Verlag, Berlin Heidelberg, 265 p.

Willert, E., Popov, V.L., 2016, Impact of an elastic sphere with an elastic half space with a constant coefficient of friction: Numerical analysis based on the method of dimensionality reduction, ZAMM Zeitschrift für Angewandte Mathematik und Mechanik, 96(9), pp. 1089-1095.

Doménech-Carbó, A., 2013, Analysis of oblique rebound using a redefinition of the coefficient of tangential restitution coefficient, Mechanics Research Communications, 54, pp. 35-40.

Pishkenari, H.N., Rad, H.K., Shad, H.J., 2017, Transformation of sliding motion to rolling during spheres collision, Granular Matter, 19:70, doi: https://doi.org/10.1007/s10035-017-0755-0 .

Brach, R.M., 1988, Impact dynamics with applications to solid particle erosion, International Journal of Impact Engineering, 7(1), pp. 37-53.

Archard, J.F., Hirst, W., 1956, The wear of metals under unlubricated conditions, Proceedings of the Royal Society of London, Series A, 236, pp. 397-410.

Khrushchov, M.M., Babichev, M.A., 1960, Investigation of Wear of Metals, Russian Academy of Sciences, Moscow, 252 p.

Honda, K., Yamada, K., 1925, Some experiments on the abrasion of metals, Journal of the Institute of Metals, 33(1), pp. 49-68.

Argatov, I.I., Dmitriev, N.N., Petrov, Y.V., Smirnov, V.I., 2009, Threshold erosion fracture in the case of oblique incidence, Journal of Friction and Wear, 30(3), pp. 176-181.

Hunter, S.C., 1957, Energy absorbed by elastic waves during impact, Journal of the Mechanics and Physics of Solids, 5(3), pp. 162-171.

Benad, J., 2018, Fast numerical implementation of the MDR transformations, Facta Universitatis, Series Mechanical Engineering, 16(2), pp. 127-138.

Willert, E., Popov, V.L., 2017, The oblique impact of a rigid sphere on a power-law graded elastic half-space, Mechanics of Materials, 109, pp. 82-87.

Ghaednia, H., Marghitu, D.B., 2016, Permanent deformation during the oblique impact with friction, Archive of Applied Mechanics, 86(1-2), pp. 121-134.

Wu, Y.-C., Thornton, C., Li, L.-Y., 2009, A semi-analytical model for oblique impacts of elastoplastic spheres, Proceedings of the Royal Society of London, Series A, 465, pp. 937-960.