Abstract
Pooled stepped spillway is known for high aeration efficiency and energy dissipation, but the understanding for the effects of pool weir configuration on the flow properties and energy loss is relatively limited, so RNG k − ε εturbulence model with VOF method was employed to simulate the hydraulic characteristics of the stepped spillways with four types of pool weirs. The calculated results suggested the flow in the stepped spillway with staggered configuration of` two-sided pooled and central pooled steps (TP-CP) was highly three dimensional and created more flow instabilities and vortex structures, leading to 1.5 times higher energy dissipation rate than the fully pooled configuration (FP-FP). In FP-FP configuration, the stepped spillway with fully pooled and two-sided pooled steps (FP-TP) and the spillway with fully pooled and central pooled steps (FP-CP), the pressure on the horizontal step surfaces presented U-shaped variation, and TP-CP showed the greatest pressure fluctuation. For FP-TP and FP-CP, the vortex development in the transverse direction presented the opposite phenomenon, and the maximum vortex intensity in TP-CP occurred at Z/W = 0.25, while FP-FP illustrated no significant change in the transverse direction. The overlaying flow velocity distribution in the spanwise direction demonstrated no obvious difference among FP-FP, FP-TP, and FP-CP, while the velocity in TP-CP increased from the axial plane to the sidewalls, but the maximum velocity for all cases were approximately the same.
Highlights
Stepped spillway, an important water-transferring hydraulic infrastructure, has long been used in water related projects owing to its high efficiency of energy dissipation and air entrainment, making it possible to release massive and high speed flood flows while reducing and preventing dangerous scour and cavitation
It can be noticed that, in all cases, the velocity distribution along the transverse direction was symmetrical and the overlaying flow over the pool weir showed the maximum velocity magnitude, while the minimum velocity value occurred near the bottom, but both the minimum and maximum indicated no apparent change in different configurations; In FP-FP, fully pooled and two-sided pooled steps (FP-TP) and fully pooled and central pooled steps (FP-CP), the velocity of the mainstream illustrated no significant difference along the spanwise direction, but the velocity in two-sided pooled and central pooled steps (TP-CP) fluctuated greatly with its value increasing from the axial plane to the sidewalls
Four types of pooled stepped spillway with different pool weirs were numerically investigated by using Renormalization Group (RNG) k − ε turbulence model with volume of fluid (VOF) method
Summary
An important water-transferring hydraulic infrastructure, has long been used in water related projects owing to its high efficiency of energy dissipation and air entrainment, making it possible to release massive and high speed flood flows while reducing and preventing dangerous scour and cavitation. For the past decades, stepped spillway has been studied globally by the means of laboratory experiments and numerical simulations [3,4,5,6,7], providing significant insights into the complicated air-water flow properties, momentum exchange process, and energy loss mechanism. The detailed air-water flow properties over several kinds of stepped pooled spillway were physically studied by Felder [7] and Felder and Chanson [9]. While the existing researches have gained understanding into this particular type of stepped spillway, little has been known about the impact of pool weir configurations on the flow properties. In order to expand the limited insights into the effect of pool weir’s geometrical properties on the flow characteristics, numerical investigations of pooled stepped spillways with different pool weir configurations were carried out
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