The overtopping of low-crested breakwater is investigated by means of
hydraulic and mathematical models.
A conventional laboratory wavemaker with a wedge-type paddle is converted
into an absorbing wavemaker so that it can be used to investigate
accurately wave overtopping of reflective coastal structures. The
absorption system is achieved by use of a feedback loop added to the
control circuit. The design criteria and implementation of the circuit are
presented in detail. Enhanced control software is used to generate
different 'random' sea states with the same statistical properties.
The absorption system is validated by ail extensive series of tests made
possible by the development of automated data acquisition and analysis
software. Particular attention is given to the derivation of incident and
reflected wave spectra. The results show over 90% success in reducing
reflected waves. It is also possible to establish stable standing wave
patterns over a wide frequency range. The results show significant
improvement over similar existing wavemakers and in effect create an
open-ended channel in the sense that the test structure hardly influences
incident wave conditions.
A closely controlled series of overtopping tests was carried out using the
absorption system to prevent any re-reflections. Equipment and software
were designed to quantify the overtopping rates for the structures used.
The design and implementation of all aspects of the tests is fully
described.
Overlapping tests were carried out on breakwaters with smooth l:l and 1:2
seaward slopes. The results are tabulated and plotted in a dimension less
form which permits comparison with earlier work carried out at Hydraulics
Research Ltd. The range of available data is extended and the new data for
fully-developed sea states shown to be compatible with a linear
extrapolation of the earlier results. It is believed that the earlier
results were obtained using fully developed sea states but this is not
known for certain. The importance of rigorously defining and publishing
both test conditions and analysis techniques is highlighted.
In the numerical study the 1-D mass and continuity equations were solved by
a hybrid finite element/finite difference scheme. Whilst a good comparison
is achieved between the physical and numerical tests for breakwater slopes
of 1:2 and less, realistic results are not achieved for steeper slopes.
The reasons for this are discussed and the results presented.
Both sets of model tests add valuable data to an area presently lacking
detailed information.
Date of Award | 1991 |
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Original language | English |
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Awarding Institution | |
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WAVE OVERTOPPING: A COMPARISON OF PHYSICAL AND NUMERICAL STUDIES
Murton, G. J. (Author). 1991
Student thesis: PhD