Wall and Bed Shear Force in Rectangular Open Channels

TL;DR

This paper introduces a new method to accurately determine shear force distribution between walls and bed in rectangular open channels by accounting for secondary currents and velocity gradients, improving prediction accuracy.

Contribution

The paper presents a novel approach that incorporates secondary currents and velocity gradients to better predict shear force distribution in rectangular channels.

Findings

Method achieves less than 5% average relative error.

Results align well with experimental data.

Provides a physics-based range covering observed data.

Abstract

This paper studies the effects of velocity gradients and secondary currents on the distribution of the shear force between the walls and bed of rectangular open channels. We show that neglecting the effect of secondary currents and assuming zero-shear division lines does not yield acceptable results. We, accordingly, introduce a method to determine the percentage of the total shear force acting on the walls and bed of rectangular open channels, which takes both the velocity gradients and secondary currents into account. Using the channel bisectors, along which there is no secondary flows effect, and orthogonal trajectories to isovels, along which there is no shear stress, we divide the channel cross section into three major subsections, namely bed area, walls area, and shared area. The geometry of each subsection is derived given the location of the maximum velocity. The share of the bed and wall shear forces from the shared area, are calculated afterward. The results for bed and walls shear forces agree well with the experimental data with an average relative error less than 5% for both regular flows and flows carrying suspended sediment. This method also provides a physics-driven range for the wall and bed shear forces which nicely covers the experimental data.