Abstract

Detailed experimental results are presented for the initial impact force on a sphere striking a horizontal liquid surface vertically at speeds in the range 1-3 m s −1 . Results are discussed in terms of an impact drag coefficient. Liquids having viscosities in the range 10 −3 −10 2 Pa s have been studied. For low viscosities the results have been compared with the theoretical calculations of Shiffman & Spencer. Good agreement has been found in most respects; in particular the impact force varies as the square root of the depth for depths less than a tenth of the radius. The impact drag coefficient has also been studied through the transition from inertia to viscosity-dominated conditions. The variation of the impact drag coefficient is presented as a function of Reynolds number, and its variation in the range 5 × 10 −2 < Re < 5 × 10 3 is shown to resemble that of a fully immersed sphere moving steadily in a homogeneous fluid.