2008
DOI: 10.1017/s0022112008002899
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Trapping of air in impact between a body and shallow water

Abstract: Near-impact behaviour is investigated for a solid body approaching another solid body with two immiscible incompressible viscous fluids occupying the gap in between. The fluids have viscosity and density ratios which are extreme, the most notable combination being water and air, such that either or both of the bodies are covered by a thin film of water. Air–water interaction and the commonly observed phenomenon of air trapping are of concern in the presence of the two or three thin layers and one or two interf… Show more

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Cited by 51 publications
(56 citation statements)
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“…A similar relationship between the free-surface height and the pressure holds for the air cushioning of solid bodies coated by shallow liquid layers. 35 The leading order behavior for small h is shown in Figure 5(a) and is identical to the case of droplet impact with a solid wall. This figure shows the maximum deformation of the droplet free-surface and the largest pressures at each integer time-step of the five layer depths considered.…”
Section: B the Small H Limitmentioning
confidence: 66%
“…A similar relationship between the free-surface height and the pressure holds for the air cushioning of solid bodies coated by shallow liquid layers. 35 The leading order behavior for small h is shown in Figure 5(a) and is identical to the case of droplet impact with a solid wall. This figure shows the maximum deformation of the droplet free-surface and the largest pressures at each integer time-step of the five layer depths considered.…”
Section: B the Small H Limitmentioning
confidence: 66%
“…In particular, it has been explained that dimple formation leading to the bubble entrapment was due as a first approximation to the viscous cushioning of the gas beneath the drop (Smith et al 2003;Purvis & Smith 2004;Korobkin et al 2008;Mandre et al 2009;Mani et al 2010;Duchemin & Josserand 2011). The lubrication pressure in the gas deforms the drop before contact, forming a dimple, so that contact occurs along a circle entrapping a gas bubble, as observed experimentally (Thoroddsen et al 2005;Driscoll & Nagel 2011;Bouwhuis et al 2012;Kolinski et al 2012;Tran et al 2013).…”
Section: Introductionmentioning
confidence: 89%
“…Since then, numerous studies have investigated the mechanism by which gas pressure influences the splash dynamics. These studies have involved and combined theoretical, experimental and numerical approaches (Korobkin et al 2008;Mandre et al 2009;Mani et al 2010;Hicks & Purvis 2010;Duchemin & Josserand 2011;Driscoll & Nagel 2011;Kolinski et al 2012;Duchemin & Josserand 2012;Hicks et al 2012;Riboux & Gordillo 2014;Kim et al 2014;Liu et al 2015;Guo et al 2016). It has been demonstrated that splashing was closely linked with the dynamics of the thin film of gas, either beneath the drop before impact but also during the fast spreading of the drop after impact.…”
Section: Introductionmentioning
confidence: 99%
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“…The theoretical treatment of the air-cushioning, started by Smith et al (2003), is based on balancing the viscous lubrication in the thin air layer and the rapid deceleration of the drop inertia. Korobkin et al (2008) added two deformable surfaces and Hicks & Purvis (2010) reformulated the above 2-D theories for the axisymmetric case, to allow quantitative comparison with theory. They predicted the initial radius of the air-disc L o at first contact, as (Hicks et al (2012), Hicks & Purvis (2013))…”
Section: Introductionmentioning
confidence: 99%