Investigating the Role of Clasts on the Movement of Sand in Gravel Bed Rivers
Publication: Journal of Hydraulic Engineering
Volume 137, Issue 9
Abstract
The bed morphology of mountain rivers is characterized primarily by the presence of distinguishable isolated roughness elements, such boulders or clasts. The objective of this experimental study was to provide a unique insight into the role of an array of clasts in regulating sand movement over gravel beds for low relative submergence conditions, , and flow depth, , to the diameter of the clast, , a process that has not been studied thoroughly. To assess the role of clasts in controlling incoming sand movement, detailed flume experiments were conducted by placing 40 equally spaced clasts atop a well-packed glass bead bed for replicating the isolated roughness flow regime. The experiments were performed for moderate ( where is the critical dimensionless bed shear stress) and high () applied bed shear stress conditions, representative of gravel bed rivers. For comparison purposes, experiments were also repeated for nearly identical flow conditions but without the presence of clasts to discern the potential effects that clasts may have on sediment movement and hydraulics within the clast array region and also in the upstream section of the clast region where few observations exist. The experimental results revealed the formation of two distinguishable bed morphological features, namely a funnel shaped “sand ridge” upstream from the clast array region and small depositional “sand patches” around individual clasts. The sand patches were formed in the stoss region of the clasts, which contradicted previous observations of depositional patterns around clasts under high relative submergence conditions () where, in this case, depositional patches were observed to have formed in the clast wake region. Furthermore, most of the incoming sand was found to be intercepted by the evolving sand ridge upstream from the clast array region with implications in the amount of sand entering the clast array region. The exiting bed-load rate was found to be reduced by a factor of , depending on the prevailing flow conditions when experiments with and without clasts were compared under nearly identical flow conditions. The findings of this research, although limited to the isolated roughness regime, may have significant ramifications in stream restoration projects for the design of engineered riffle sections, which typically consist of an array of clasts installed to improve degraded waterways and aquatic habitat.
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Acknowledgments
The authors would like to acknowledge the support provided by the NSF Hydroscience Division under NSF Grant No. NSFEAR-0208358 and the support of The Paul C. and Sara Jane Benedict Fellowship for Study of Alluvial River Processes provided to the second author. The authors would also like to express their gratitude to the two anonymous reviewers for their excellent suggestions, which strengthened the paper.
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Information
Published In
Journal of Hydraulic Engineering
Volume 137 • Issue 9 • September 2011
Pages: 871 - 883
Copyright
© 2011 American Society of Civil Engineers.
History
Received: Feb 18, 2009
Accepted: Dec 14, 2010
Published online: Aug 15, 2011
Published in print: Sep 1, 2011
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