Assessment of a River Reach for Environmental Fluid Dynamics Studies
Publication: Journal of Hydraulic Engineering
Volume 136, Issue 11
Abstract
Turbulence is the fundamental mechanism governing energy transfer in river flows that was conventionally examined in laboratory flumes. Recently, a trend has been observed for constructing larger scale and outdoor facilities that tend to avoid the problems of upscaling of experimental results. This paper presents the results of an experimental study performed on a river reach used as an environmental field laboratory. The study is focused on the understanding of the spatial arrangement of the flow structure and its dependency on the temporal variability of the flow. Detailed measurements were taken using acoustic Doppler velocimeters and their analysis was completed applying the theory of open-channel flows. The obtained results reveal that the flow structure on the river reach resembles characteristics of a typical three-dimensional open-channel flow. Away from the riverbanks, the flow behaves as a quasi-two-dimensional fully developed turbulent open-channel flow thus providing conditions favorable for field experimental studies of shallow mixing layers and flows over patches of submerged aquatic plants. An interesting observation in the seasonal dynamics of turbulent shear stress patterns was that the height of the roughness layer was reduced in the central part of the flow, though the overall roughness coefficient was increased. At the same time, the structure of the secondary flow near the banks was also substantially altered as the secondary circulations observed at low water levels were replaced by flow separation and internal boundary layers at medium water levels.
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Acknowledgments
The writers acknowledge the help of T. Sukhodolova and I. Schnauder in the field works. Financial support was provided by the Deutsche Forschungsgemeinschaft (DFGSU 405/2, DFGSU 405/3, and DFGSU 629/1) and by Netherlands Organization for Scientific Research, NWO (UNSPECIFIEDDN 66-143).
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Information & Authors
Information
Published In
Journal of Hydraulic Engineering
Volume 136 • Issue 11 • November 2010
Pages: 880 - 888
Copyright
© 2010 ASCE.
History
Received: Nov 19, 2008
Accepted: Apr 25, 2010
Published online: Apr 29, 2010
Published in print: Nov 2010
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