Abstract
Time-dependent forces applied by 2 and 4.5 mm diameter drops of water (with velocities up to terminal velocity) impacting upon a glass plate with or without a water layer (up to 10 mm depth) have been measured using two different approaches, force transduction and wavelet deconvolution. Both approaches are in close agreement for drops falling on dry glass. However, only the wavelet approach is able to measure natural features of the splash on shallow water layers that impart forces to the plate after the initial impact. At relatively high velocities (including terminal velocity) the measured peak force from the initial impact is significantly higher than that predicted by idealised drop shape models and models from Roisman et al. and Marengo et al. Hence empirical formulae are developed for the initial time-dependent impact force from drops falling at (a) different velocities up to and including terminal velocity onto a dry glass surface, (b) terminal velocity onto dry glass or glass with a water layer and (c) different velocities below terminal velocity onto dry glass or glass with a water layer. For drops on dry glass, the empirical formulae are applicable to a glass plate or a composite layered plate with a glass surface, although they apply to other plate thicknesses and are applicable to any plate material with a similar surface roughness and wettability. The measurements also indicate that after the initial impact there can be high level forces when bubbles are entrained in the water layer.
Highlights
1.1 MotivationUnderstanding liquid drop impacts on dry or wet surfaces is important in many different areas of engineering such as blade erosion in steam turbines, soil splash from raindrops, ink jet printing, spray coating of paper and medical applications such as drop impacts onto the eye
A drop shape is conveniently represented by the combination of two oblate semi-spheroids (Clift et al 1978) 2 mm drops at terminal velocity are approximately spherical
The peak force increases and the pulse width decreases with increasing drop velocity
Summary
1.1 MotivationUnderstanding liquid drop impacts on dry or wet surfaces is important in many different areas of engineering such as blade erosion in steam turbines, soil splash from raindrops, ink jet printing, spray coating of paper and medical applications such as drop impacts onto the eye. It is necessary to have knowledge of the force applied by the liquid drop upon impact to allow an assessment of erosion, damage, or the efficacy of the impact process. Prediction of the sound and vibration resulting from the impact of raindrops requires knowledge of the time-dependent force that is applied to a structure when it is dry or covered with a shallow surface layer of water. This provides the motivation for the current study to experimentally determine the time-dependent forces that are applied by drops at high velocities
Sign-in/Register to view highlights & summary 
Published Version (
Free)
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call