CURVED OPEN CHANNEL FLOW ON VEGETATION ROUGHENED INNER BANK

A RNG numerical model together with a laboratory measurement with Micro ADV are adopted to investigate the flow through a 180o curved open channel(a 4 m straight inflow section,a 180o curved section,and a 4m straight outflow section)partially covered with rigid vegetations on its inner bank.Under th...

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Bibliographic Details
Published inJournal of hydrodynamics. Series B Vol. 24; no. 1; pp. 124 - 129
Main Authors HUAI, Wen-xin, LI, Cheng-guang, ZENG, Yu-hong, QIAN, Zhong-dong, YANG, Zhong-hua
Format Journal Article
LanguageEnglish
Published Singapore Elsevier Ltd 01.02.2012
Springer Singapore
State Key Laboratory of Water Resources and Hydropower Engineering Science, Wuhan University, Wuhan 430072, China
Subjects
Banks
bend flow
Channels
Circulation
Curved
Engineering
Engineering Fluid Dynamics
Freshwater
Hydrology/Water Resources
Mathematical models
non-submerged rigid vegetation
Numerical and Computational Physics
Numerical prediction
River banks
RNG k – ɛ numerical model
shear stress
Simulation
stream-wise velocities
Vegetation
内部银行
实验室测量
数值模型
数值预报
明渠流量
植被覆盖
流场结构
粗糙
non-submerged rigid vegetation
RNG k – ɛ numerical model
stream-wise velocities
shear stress
bend flow
ε numerical model
RNG
RNG k-ε numerical model
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Summary:A RNG numerical model together with a laboratory measurement with Micro ADV are adopted to investigate the flow through a 180o curved open channel(a 4 m straight inflow section,a 180o curved section,and a 4m straight outflow section)partially covered with rigid vegetations on its inner bank.Under the combined action of the vegetation and the bend flow,the flow structure is complex.The stream-wise velocities in the vegetation region are much smaller than those in the non-vegetation region due to the retardation caused by the vegetation.For the same reason,no clear circulation is found in the vegetated region,while in the non-vegetation region,a slight counter-rotating circulation is found near the outer bank at both 90o and downstream curved cross-sections.A comparison between the numerical prediction and the laboratory measurement shows that the RNG model can well predict the flow structure of the bend flow with vegetation.Furthermore,the shear stress is analyzed based on the numerical prediction.The much smaller value in the inner vegetated region indicates that the vegetation can effectively protect the river bank from scouring and erosion,in other words,the sediment is more likely to be deposited in the vegetation region.
Bibliography:31-1563/T
A RNG numerical model together with a laboratory measurement with Micro ADV are adopted to investigate the flow through a 180o curved open channel(a 4 m straight inflow section,a 180o curved section,and a 4m straight outflow section)partially covered with rigid vegetations on its inner bank.Under the combined action of the vegetation and the bend flow,the flow structure is complex.The stream-wise velocities in the vegetation region are much smaller than those in the non-vegetation region due to the retardation caused by the vegetation.For the same reason,no clear circulation is found in the vegetated region,while in the non-vegetation region,a slight counter-rotating circulation is found near the outer bank at both 90o and downstream curved cross-sections.A comparison between the numerical prediction and the laboratory measurement shows that the RNG model can well predict the flow structure of the bend flow with vegetation.Furthermore,the shear stress is analyzed based on the numerical prediction.The much smaller value in the inner vegetated region indicates that the vegetation can effectively protect the river bank from scouring and erosion,in other words,the sediment is more likely to be deposited in the vegetation region.
RNG numerical model,non-submerged rigid vegetation,bend flow,stream-wise velocities,shear stress
ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 23
ISSN:1001-6058
1878-0342
DOI:10.1016/S1001-6058(11)60226-6