Abstract
ABSTRACTOgee spillway is one of the most common types of the spillway. Researchers have attempted to investigate the hydraulics of ogee structure under hydraulic heads near the design head. Herein, an ogee-crested spillway is studied at heads significantly greater than the design head. The efforts are undertaken to study the hydrodynamic field under high head ratio conditions by conducting a numerical simulation using OpenFOAM with five turbulence closures including standard k–ε, realizable k–ε, RNG k–ε, k–ω SST and LRR. The comparisons of flow parameters under different head ratios with the experimental data demonstrated that the LRR model had the best performance, which shows its strength in cases dealing with flow separation or significant streamline curvature. It is found that with increasing hydraulic head, up to seven times that of the design head, the flow separation zone grows linearly. Discharge coefficients are studied for a wide range of head ratios. It is concluded that increasing head ratio up to five leads to an increase in the discharge coefficient due to decreasing pressure on the ogee crest. As head ratio increases to greater values, the discharge coefficient drops suddenly due to some changes in the pressure field.
Highlights
Spillways are designed for dams to release excess water or floods that cannot be contained in the storage volume
The particular aim of this paper is to study the flow over ogee crested spillways under high hydraulic head
Many researchers have attempted to investigate the hydraulics of ogee crest structure under hydraulic heads
Summary
Spillways are designed for dams to release excess water or floods that cannot be contained in the storage volume. The crest profile of ogee spillways corresponds to the trajectory of the lower nappe of a free ventilated sharp-crested weir (Hager, 1987). These weirs are designed for a single precise value of the upstream head, which is called the design head. When the reservoir level is below the design head, positive relative pressures develop over the spillway In this case, the water flows over the crest without any significant resistance to the crest surface, meaning that the discharge coefficient increases for heads lower than the design head. It should be noted that this happens mostly under specific conditions where abutment effects are not present (reservoir and crest with the same width), and when sidewalls prevent air supply to the bottom part of the nappe
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