The influence of air and scale on wave impact pressures

Both laboratory and field tests that are described provide new information on the characteristics of wave impacts. Laboratory drop tests conducted using seawater and freshwater demonstrate that maximum impact pressures and rise times are influenced by both the level of aeration and the violence of t...

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Bibliographic Details
Published in:Coastal engineering (Amsterdam) 2001-04, Vol.42 (4), p.291-312
Main Authors: Bullock, G.N, Crawford, A.R, Hewson, P.J, Walkden, M.J.A, Bird, P.A.D
Format: Article
Language:English
Subjects:
Air entrainment
Applied sciences
Breaking waves
Breakwaters
Buildings. Public works
Exact sciences and technology
Hydraulic constructions
Impact pressures
Port facilities and coastal structures. Lighthouses and beacons
Scale effects
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Summary:Both laboratory and field tests that are described provide new information on the characteristics of wave impacts. Laboratory drop tests conducted using seawater and freshwater demonstrate that maximum impact pressures and rise times are influenced by both the level of aeration and the violence of the impact. A relationship is derived which enables the reduction in impact pressure caused by aeration to be estimated. This relationship is shown to provide a better means of predicting impact pressures in laboratory seawater wave tests from freshwater tests than either the Froude or Cauchy laws. Measurements are presented which show that, due to the different properties of seawater and freshwater, aeration levels are higher in seawater breakers than in freshwater breakers, even at a 1:25 model scale. The ways in which this affects the temporal variation in pressure and the scale relationships are discussed in some detail. Aeration and pressure measurements are also presented for full-scale wave impacts on a breakwater exposed to Atlantic waves. Attention is drawn to the likely role of expelled air and data included which indicate that the equivalent of up to 55% of entrained air does not necessarily prevent the occurrence of high impact pressures with short rise times.
ISSN:0378-3839
1872-7379
DOI:10.1016/S0378-3839(00)00065-X