Numerical investigation of flow hydraulics in the side weir of a sharp edge with variable crown height
Subject Areas : Analysis, design and construction of water structures
Mohamad Hossein Ahmadi
1
,
Roozbeh Aghamajidi
2
,
Gholamreza Saeedifar
3
1 - Department of Civil Engineering, Beyza Branch, Islamic Azad University, Beyza, Iran.
2 - Department of Civil Engineering, Sepidan Branch, Islamic Azad University, Sepidan, Iran
3 - Department of Civil Engineering, Beyza Branch, Islamic Azad University, Beyza, Iran
Keywords: Lateral weir, Flow modeling, Crown height ,
Abstract :
The flow on the lateral weirs is of a spatially variable type with a decreasing flow rate. Lateral weirs are made in different ways. These structures are usually built in a rectangular shape. Rectangular lateral weirs have a fixed crown width, while in circular lateral weirs; the width of the water surface passing through the weir is a function of the water depth. In this research, to numerically investigate the hydraulics of the flow over the side weir of a sharp edge, a trapezoidal channel with a length of 12 meters, a width of 2.5 meters, and a height of 1.25 meters was used in the wall of the channel. To investigate the effect of the water level behind the weir on the flow modeling, water levels of 1.9 meters and 2 meters were used. Based on the results, by increasing the height of the sharp edge weir in the trapezoidal channel from 0.6 meters to 0.8 meters with the shape of the rectangular weir crown, the pressure increases by 5.3%, the shear speed decreases by 7%, and the horizontal speed increases by 13.5%. In addition, it was found that by increasing the height of the trapezoidal sharp edge weir from 0.8 meters to 1 meters with the shape of the rectangular weir crown, the pressure increased by 5.4%, the shear speed decreased by 2.5%, and the horizontal speed increased by 11.24%. Also, the changes in the Froud number for the mentioned situations have shown a 23% decrease and an 8.8% decrease, respectively.
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