This paper demonstrates the influence of differential roughness on the boundary shear distribution for compound open channels. A mathematical relationship is derived between the percentage shear force carried by floodplains and five non-dimensional parameters (width ratio, relative flow depth, relative roughness, Reynolds number and Froude number). A procedure for assessing the flow distribution in terms of zonal boundary shear distribution and momentum transfer coefficients at the junction of a compound channel is presented. The efficiency of the model was tested by comparisons with published datasets and large experimental flood channel facility datasets. Compared with other standard approaches, the proposed method provided the least error in the predictions of both boundary shear and flow. The approach was also verified using actual river data and was found to provide good predictions in real-world applications.
Article navigation
December 2020
Research Article|
April 16 2020
Boundary shear distribution in a compound channel with differential roughness
Kamalini Devi, PhD
;
Kamalini Devi, PhD
Associate Professor, Department of Civil Engineering, Vidya Jyothi Institute of Technology, Hyderabad, India (corresponding author: kamalinidevi1@gmail.com)
Search for other works by this author on:
Kishanjit Kumar Khatua, PhD
Kishanjit Kumar Khatua, PhD
Professor, Department of Civil Engineering, National Institute of Technology Rourkela, Rourkela, India
Search for other works by this author on:
Publisher: Emerald Publishing
Received:
May 31 2019
Accepted:
March 13 2020
Online ISSN: 1751-7729
Print ISSN: 1741-7589
ICE Publishing: All rights reserved
2020
Proceedings of the Institution of Civil Engineers - Water Management (2020) 173 (6): 274–292.
Article history
Received:
May 31 2019
Accepted:
March 13 2020
Citation
Devi K, Khatua KK (2020), "Boundary shear distribution in a compound channel with differential roughness". Proceedings of the Institution of Civil Engineers - Water Management, Vol. 173 No. 6 pp. 274–292, doi: https://doi.org/10.1680/jwama.19.00035
Download citation file:
Suggested Reading
Development of a reach scale two-dimensional finite element model for floodplain sediment deposition
Proceedings of the Institution of Civil Engineers - Water and Maritime Engineering (September,2000)
Simulation of channel confluence and bifurcation using the CCHE2D model
Proceedings of the Institution of Civil Engineers - Water and Maritime Engineering (June,2000)
Mathematical modelling of alluvial rivers: reality and myth. Part 2: Special issues
Proceedings of the Institution of Civil Engineers - Water and Maritime Engineering (December,2002)
Mathematical modelling of alluvial rivers: reality and myth. Part 1: General review
Proceedings of the Institution of Civil Engineers - Water and Maritime Engineering (September,2002)
A TVD MacCormack scheme for transcritical flow
Proceedings of the Institution of Civil Engineers - Water and Maritime Engineering (September,2001)
Related Chapters
Steady uniform flow in open channels
ICE Core Concepts: Hydraulics for Civil Engineers
Open-channel flow with varying conditions
ICE Core Concepts: Hydraulics for Civil Engineers
Building a resilient system of defence against flooding from the Rhône
ICE Themes Flood Resilience
Recommended for you
These recommendations are informed by your reading behaviors and indicated interests.
