Welcome to the new version of CaltechAUTHORS. Login is currently restricted to library staff. If you notice any issues, please email coda@library.caltech.edu
Published April 30, 2004 | Submitted
Report Open

The Interaction of Breaking Solitary Waves with an Armored Bed

Abstract

This study investigates the interaction of breaking waves with a bed of loose angular material with a median grain size of 4.8 mm. It is motivated by the engineering problem of determining rock sizes for revetments used as protection for structures in the coastal zone and by the need for an understanding of the mechanics of material movement under waves. Both the effect of the bed on the velocities and accelerations in breaking and non-breaking waves, and the effect of breaking waves on the movement of bed material is measured. Velocities in breaking waves are measured at elevations approaching the bottom boundary, both for the case of a level bed of graded angular material and for a flat plate at the same location. By changing the water depth and the initial conditions of the incident wave, the relative size of the rock with respect to the breaking wave height is varied. Material movement resulting from the wave passage is measured and compared to the breaking wave height and to the turbulent shear determined near the bed. Using velocity and acceleration records near the rock bed together with observations of rock motion, the mechanics of material movement under waves are investigated. The roughness elements in the bed are found to have a large effect on both the mean and fluctuating velocities in the wave near the bottom. Evidence is shown of the existence of an inner layer where individual pieces of bed material influence the flow over the bed. A method for determining the maximum mean shear under a single wave is presented. Mean vertical velocities are measured to be not negligible near the bed and are shown to produce convective accelerations of the same order as the accelerations due to turbulent fluctuations. The movement of bed material is compared with the calculated shear on the bed and with local velocities and accelerations measured very close to the individual rocks. The mean size of the material moved in the bed is found to vary with the amount of shear on the bed. When adjusted for the mean size of the moved material, the calculated shears correspond well with the criterion for critical shear from the Shields curve used in steady flow. From the observed movement of particles during the passage of a wave and the measured velocities and accelerations in the wave, inertial forces are found to contribute to particle movement, especially in the regions before and after wave crest passage.

Additional Information

© 1993 W. M. Keck Laboratory of Hydraulics and Water Resources. California Institute of Technology. This report is essentially the thesis of the same title submitted by the writer on February 26,1993, to the California Institute of Technology, in partial fulfillment of the requirements for the degree of Doctor of Philosophy in Civil Engineering. This material is based upon work supported by the National Science Foundation under Award NO. CTS-8812187. This report was published with the assistance of the Miriam and Omar J. Lillevang fund at Caltech.

Attached Files

Submitted - TR000121.pdf

Files

TR000121.pdf
Files (45.6 MB)
Name Size Download all
md5:b6923c863bd08f32945eec598e264997
45.6 MB Preview Download

Additional details

Created:
August 20, 2023
Modified:
January 13, 2024