2020
DOI: 10.3390/w12113233
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Effects of Secondary Currents on Turbulence Characteristics of Supercritical Open Channel Flows at Low Aspect Ratios

Abstract: In this paper, we present secondary current effects on the turbulence characteristics of supercritical narrow open channel flows over a smooth fixed bed. The main hydraulic parameters are low channel width to flow depth ratios varying between 1 and 2, and Froude numbers (F) ranging from 2 to 4. Detailed profiling of instantaneous streamwise and vertical flow velocities was conducted in a laboratory flume using a 2D laser Doppler anemometry. The cross-sectional distributions of mean flow velocities, turbulence … Show more

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Cited by 18 publications
(41 citation statements)
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“…In conditions where b/h < ~2, eight secondary cells develop and cause bed shear stress undulation (Figure 2c). Bed shear stresses are lowest near the tunnel walls, reach maxima, and then flatten towards the tunnel center (Figure 2c, [62]). For ratios 2 ≤ b/h < 4 to 5, four secondary cells have been found to develop [61], resulting in high bed shear stresses near the tunnel walls.…”
Section: Sediment Bypass Tunnelsmentioning
confidence: 98%
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“…In conditions where b/h < ~2, eight secondary cells develop and cause bed shear stress undulation (Figure 2c). Bed shear stresses are lowest near the tunnel walls, reach maxima, and then flatten towards the tunnel center (Figure 2c, [62]). For ratios 2 ≤ b/h < 4 to 5, four secondary cells have been found to develop [61], resulting in high bed shear stresses near the tunnel walls.…”
Section: Sediment Bypass Tunnelsmentioning
confidence: 98%
“…This is the result of the presence of non-homogeneity and anisotropy of turbulence in the tunnel. These secondary currents superimpose the primary flow influencing mean flow velocities, turbulence intensities, and Reynolds and bed shear stresses [59][60][61][62]. In conditions where b/h < ~2, eight secondary cells develop and cause bed shear stress undulation (Figure 2c).…”
Section: Sediment Bypass Tunnelsmentioning
confidence: 99%
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“…These velocities were normalized with the cross-sectionally averaged approach flow velocity U0 of 0.59 m/s calculated from CS07, which was downstream of the fish pass exit. For S1 the maximum flow velocity lied at z/h0 = 0.6 (with h0 = 2.95 m) indicating the velocity dip-phenomena caused by secondary currents [36,37]. At S4 to S6, flow velocities were lower than at S1 as a portion of the flow passed the rack and the maximum velocities at S4 to S6 occurred closer to the water surface because of the backwater effect caused by the presence of the rack and bypass gate.…”
Section: Flow Field In Front Of Bypassmentioning
confidence: 95%
“…The highest velocities obtained from the cross-sectional velocity distributions occurred at z/h 0 = 0.88. The occurrence of maximum velocities below the water surface, the so-called velocity-dip phenomenon, is related to the secondary currents of Prandtl's second kind driven by turbulence anisotropy [35][36][37][38]. Such secondary currents exist when the channel width to water depth aspect ratio is less than 4 to 5, creating a 3D flow pattern.…”
Section: Flow Field Along Headrace Channelmentioning
confidence: 99%