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Investigations on the Trajectory of Large Sandbags in Open Channel Flow
Investigations undertaken to understand the mechanics of the motion of large sandbags and to compute their trajectories are reported in this paper, along with the details of the experimental setup and procedures. The motion of sandbags is recorded from the side of a flume by a high-definition charge-coupled device (CCD) camera, and the digital particle tracking velocimetry (DPTV) technique is used to track the motion of the bags. An equation is developed for the normalized maximum horizontal settling distance from the experimental data. It is found that the particle velocity normal to the flow depends mainly on the characteristic diameter of the particle and the Froude number of the flow, whereas the particle velocity in the streamwise direction shows lower dependency on the Froude number. Analysis of the particle tumbling shows that the Magnus force may be neglected for the purpose of modeling the trajectories of sandbags in uniform flows. A model of particle motion is developed by solving the Lagrangian equation numerically. Two approaches to computing the trajectory of sandbags are investigated. The results show that the approach in which the drag coefficient is varied based on the orientation of a particle gives better results than if the drag coefficient is kept constant and is based on the broadside orientation of the particle. The results also show that the change in the drag coefficient may be as low as 28% to as high as 76% based on the orientation of the particle with respect to the flow.
Investigations on the Trajectory of Large Sandbags in Open Channel Flow
Investigations undertaken to understand the mechanics of the motion of large sandbags and to compute their trajectories are reported in this paper, along with the details of the experimental setup and procedures. The motion of sandbags is recorded from the side of a flume by a high-definition charge-coupled device (CCD) camera, and the digital particle tracking velocimetry (DPTV) technique is used to track the motion of the bags. An equation is developed for the normalized maximum horizontal settling distance from the experimental data. It is found that the particle velocity normal to the flow depends mainly on the characteristic diameter of the particle and the Froude number of the flow, whereas the particle velocity in the streamwise direction shows lower dependency on the Froude number. Analysis of the particle tumbling shows that the Magnus force may be neglected for the purpose of modeling the trajectories of sandbags in uniform flows. A model of particle motion is developed by solving the Lagrangian equation numerically. Two approaches to computing the trajectory of sandbags are investigated. The results show that the approach in which the drag coefficient is varied based on the orientation of a particle gives better results than if the drag coefficient is kept constant and is based on the broadside orientation of the particle. The results also show that the change in the drag coefficient may be as low as 28% to as high as 76% based on the orientation of the particle with respect to the flow.
Investigations on the Trajectory of Large Sandbags in Open Channel Flow
Elkholy, M. (author) / Chaudhry, M. Hanif (author)
Journal of Hydraulic Engineering ; 138 ; 1060-1068
2012-04-26
92012-01-01 pages
Article (Journal)
Electronic Resource
English
Investigations on the Trajectory of Large Sandbags in Open Channel Flow
| British Library Online Contents | 2012
Investigations on the Trajectory of Large Sandbags in Open Channel Flow
| Online Contents | 2012
Settling Distance and Incipient Motion of Sandbags in Open Channel Flows
| Online Contents | 2004
Settling Distance and Incipient Motion of Sandbags in Open Channel Flows
| British Library Online Contents | 2004
Drag and Added-Mass Coefficients of Large Sandbags
| British Library Online Contents | 2011