Theoretical and Experimental Analysis of Wave Impact Pressures on Curved Seawalls
Abstract
Experimental model tests were performed in a
wave flume with regular waves to measure the magnitude and
distribution of impact pressures caused by breaking waves on
a curved seawall model having different radii of curvatures.
The base structure of the wall has a foreshore slope of 1/10.
Theoretical studies based on pressure impulse theory were
carried out to obtain the numerical results of breaking wave
impact pressures on curved seawalls. The boundary element
method was used for the numerical solution of the governing
equation. The novel aspect of this study was to investigate the
applicability of pressure impulse theory to curved seawalls.
The results showed that the pressure impulse model can be
used to model the wave impact pressures and their distribution on curved seawall models with good accuracy. A slight
decrease has been observed in pressures for increasing radii
of curvatures, especially for the case which the water depth
at wall was 14 cm. The location of the maximum impact
pressure was found to occur above the still water level for all
cases tested in this study