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Communication Dans Un Congrès Année : 2017

Impact of solid and liquid balls on a solid surface: an unified description

Srishti Arora
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  • PersonId : 997398
Jean-Marc Fromental
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  • PersonId : 998366
Ty Phou
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  • PersonId : 1004633
Laurence Ramos

Résumé

We study experimentally the impact of ultra soft spherical gel balls of millimetric size d0 on a rigid substrate covered by a thin layer of liquid nitrogen to avoid viscous dissipation. The balls largely deform like a pancake at high impact velocities. We measure the maximally deformed size dmax and the the time needed to reach this maximal size after impact τmax, versus the impact velocity ui for various elastic moduli. We do the same type of experiments with liquid droplets of various surface tensions. The experiments reveal a universal scaling behavior of the maximum deformation dmax/d0 of both solid balls and liquid drops provided that both bulk and surface elasticity are properly taken into account. Moreover, we show that, in absence of viscous dissipation, the dynamics of the system can be understood as a conventional spring-mass system with a stiffness given by a combination of surface tension and bulk elasticity and a mass given by that of the ball (or drop); the deformation of the small ball (drop) during the impact linearly depends on the impact velocity, and the contact time scales as the period of this spring-mass system.
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Dates et versions

hal-01495935 , version 1 (27-03-2017)

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Paternité - Pas d'utilisation commerciale

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Srishti Arora, Jean-Marc Fromental, Serge Mora, Ty Phou, Laurence Ramos, et al.. Impact of solid and liquid balls on a solid surface: an unified description. APS March meeting 2017, Mar 2017, La Nouvelle-Orléans, United States. ⟨hal-01495935⟩
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