Abstract
Owing to its effective energy dissipation and aeration, a stepped spillway is commonly used for flood release in hydraulic projects. Its conventional design features horizontal step surfaces. Designed for certain flow rates, it does not function satisfactorily at larger discharges. To improve this, layouts with inclined step surfaces, both downward and upward, are proposed. Computational fluid dynamics (CFD) modelling in 3D is performed to examine and compare their flow properties in the skimming flow. The results suggest that a shift from a downward to an upward layout leads to a gradual decrease in the flow velocity at the chute end; the latter exhibit higher energy dissipation efficiency. Moreover, equations are developed to estimate the velocity and energy loss. The flow velocity in the developing zone, described by a power law, shows a decline with an increase in the angle of inclination. The downward layout is subjected to somewhat higher risk of cavitation if implemented in a prototype. The extreme pressure loads acting upon an upward layout are larger, and a correlation is proposed for its prediction. On an inclined surface, either upward or downward, the pressure demonstrates an S-shaped distribution. On a vertical surface, the flow pressure increases, after an initial decline over a short distance, towards the chute bottom.
Highlights
A spillway is a flood discharge structure that has been applied in hydropower and irrigation projects for decades
The layouts are simulated to look into the effects of θ on hydraulic behaviors expressed in terms of flow velocity, flow pressure and energy dissipation
Due to large dam heights, the cavitation risk associated with local low pressure is often an issue of concern in design
Summary
A spillway is a flood discharge structure that has been applied in hydropower and irrigation projects for decades. Traditional stepped spillways are, in certain situations, insufficient to effectively dissipate energy and prevent cavitation risk. This leads to higher flood magnitudes, which requires that the spillway discharge capacity should be enlarged. Another contributing factor is the climate changes. Felder and Chanson conducted model tests on a pooled stepped spillway and examined its two-phase air–water flow properties [8]. Based on the geometrical layout of a stepped chute spillway examined elsewhere, CFD modelling in 3D is made, with emphasis on the step angling of the horizontal surfaces. The upward layout is found an effective alternative to improve energy dissipation and mitigate cavitation risks
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