Turbulence structure of open channel flows over permeable and impermeable beds: A comparative study

Manes, Costantino; Pokrajac, Dubravka; McEwan, Ian; Nikora, Vladimir

doi:10.1063/1.3276292

Cited by 124 publications

(161 citation statements)

References 31 publications

(38 reference statements)

Supporting

Mentioning

141

Contrasting

Order By: Relevance

“…This makes C. Manes, D. Poggi and L. Ridolfi the results of the present study directly comparable with the literature pertaining to aquatic and atmospheric canopy flows (Ghisalberti & Nepf 2002;Poggi et al 2004;Finnigan et al 2009), and also with the DNS of Breugem et al (2006), but to a lesser extent with flows over permeable granular walls (Manes et al 2009;Sarkar & Dey 2010;Detert, Nikora & Jirka 2010). The reason is that the latter class of porous media is characterized by large roughness elements, which makes the effects of roughness and permeability both significant.…”

Section: Discussionsupporting

confidence: 79%

“…In the literature, this problem has been overcome by following two approaches. The first, particularly used in the study of flows over granular beds, involves a comparative analysis between flow statistics measured over rough impermeable and rough permeable walls characterized by the same surface roughness texture (Zagni & Smith 1976;Manes et al 2009). For example Manes et al (2009) present a comparison between statistics of velocities measured in open channel flows over an impermeable wall made of one layer of beads and a permeable wall made of five of such layers.…”

Section: Introductionmentioning

confidence: 99%

“…The first, particularly used in the study of flows over granular beds, involves a comparative analysis between flow statistics measured over rough impermeable and rough permeable walls characterized by the same surface roughness texture (Zagni & Smith 1976;Manes et al 2009). For example Manes et al (2009) present a comparison between statistics of velocities measured in open channel flows over an impermeable wall made of one layer of beads and a permeable wall made of five of such layers. The rationale behind this approach lies in the concept that (i) a wall is considered as permeable (impermeable) if its thickness is significantly larger (comparable or smaller) than the characteristic size of its constitutive components; (ii) the comparison between flow statistics measured over the two beds highlights the effects of wall permeability since the surface roughness is kept the same.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Turbulent boundary layers over permeable walls: scaling and near-wall structure

2011

View full text Add to dashboard Cite

This paper presents an experimental study devoted to investigating the effects of permeability on wall turbulence. Velocity measurements were performed by means of laser Doppler anemometry in open channel flows over walls characterized by a wide range of permeability. Previous studies proposed that the von Kármán coefficient associated with mean velocity profiles over permeable walls is significantly lower than the standard values reported for flows over smooth and rough walls. Furthermore, it was observed that turbulent flows over permeable walls do not fully respect the widely accepted paradigm of outer-layer similarity. Our data suggest that both anomalies can be explained as an effect of poor inner-outer scale separation if the depth of shear penetration within the permeable wall is considered as the representative length scale of the inner layer. We observed that with increasing permeability, the near-wall structure progressively evolves towards a more organized state until it reaches the condition of a perturbed mixing layer where the shear instability of the inflectional mean velocity profile dictates the scale of the dominant eddies. In our experiments such shear instability eddies were detected only over the wall with the highest permeability. In contrast attached eddies were present over all the other wall conditions. On the basis of these findings, we argue that the near-wall structure of turbulent flows over permeable walls is regulated by a competing mechanism between attached and shear instability eddies. We also argue that the ratio between the shear penetration depth and the boundary layer thickness quantifies the ratio between such eddy scales and, therefore, can be used as a diagnostic parameter to assess which eddy structure dominates the near-wall region for different wall permeability and flow conditions.

show abstract

Section: Discussionsupporting

confidence: 79%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Turbulent boundary layers over permeable walls: scaling and near-wall structure

2011

View full text Add to dashboard Cite

show abstract

“…Turbulent eddies in the water column of a stream, for example, can cause flow across the sediment-water interface in the presence or absence of bed forms. 33 Third, plants and animals colonizing the hyporheic zone can exert profound impacts on stream-sediment exchange, by forming mounds across which pumping occurs, inducing pore water flow within sediments, and structuring the permeability field with burrows and roots (reviewed in 34 ). Fourth, at a larger scale geomorphic features of a stream such as riffle-pool sequences, debris dams, meander bends, and regional groundwater flow all influence hyporheic exchange.…”

Section: ■ Introductionmentioning

confidence: 99%

First-Order Contaminant Removal in the Hyporheic Zone of Streams: Physical Insights from a Simple Analytical Model

Grant

Stolzenbach

Azizian

et al. 2014

Environ. Sci. Technol.

View full text Add to dashboard Cite

A simple analytical model is presented for the removal of stream-borne contaminants by hyporheic exchange across duned or rippled streambeds. The model assumes a steady-state balance between contaminant supply from the stream and first-order reaction in the sediment. Hyporheic exchange occurs by bed form pumping, in which water and contaminants flow into bed forms in highpressure regions (downwelling zones) and out of bed forms in low-pressure regions (upwelling zones). Model-predicted contaminant concentrations are higher in downwelling zones than upwelling zones, reflecting the strong coupling that exists between transport and reaction in these systems. When flow-averaged, the concentration difference across upwelling and downwelling zones drives a net contaminant flux into the sediment bed proportional to the average downwelling velocity. The downwelling velocity is functionally equivalent to a mass transfer coefficient, and can be estimated from stream state variables including stream velocity, bed form geometry, and the hydraulic conductivity and porosity of the sediment. Increasing the mass transfer coefficient increases the fraction of streamwater cycling through the hyporheic zone (per unit length of stream) but also decreases the time contaminants undergo first-order reaction in the sediment. As a consequence, small changes in stream state variables can significantly alter the performance of hyporheic zone treatment systems.

show abstract

“…Nikora (2009) extended the use of the double-averaging methodology to develop a theoretical expression that explicitly showed that the friction factor can be accounted for by six additive components, of which only three are present in two-dimensional uniform spatially-averaged flow without secondary currents: viscous stress, turbulent stress and forminduced stress. The contribution of the form-induced stress, ũw , has recently attracted substantial attention as it has been shown to play an important role in the overall streamwise momentum balance in the near-bed region (Aberle, Koll, & Dittrich, 2008;Dey & Das, 2012;Ferreira et al, 2010;GimenezCurto and Corniero, 1996;Gimenez-Curto and Corniero Lera, 2003;Manes, Pokrajac, Coceal, & McEwan, 2008;Manes, Pokrajac, & McEwan, 2007;Manes, Pokrajac, McEwan, & Nikora, 2009;Mignot, Barthelemy, & Hurther, 2009a,b;Nikora et al, 2007b;Sarkar & Dey, 2010). Indeed, Gimenez-Curto and Corniero (1996) and Gimenez-Curto and Corniero Lera (2003) suggested that at very low submergences the form-induced stress could become the dominant component in the streamwise momentum balance.…”

Section: Introductionmentioning

confidence: 99%

Free surface flow over square bars at intermediate relative submergence

McSherry

Chua

Stoesser

et al. 2018

Journal of Hydraulic Research

View full text Add to dashboard Cite

Results from large-eddy simulations and complementary flume experiments of turbulent open channel flows over bed-mounted square bars at intermediate submergence are presented. Scenarios with two bar spacings, corresponding to transitional and k-type roughness, and three flow rates, are investigated. Good agreement is observed between the simulations and the experiments in terms of mean free surface elevations and mean streamwise velocities. Contours of simulated time-averaged streamwise, streamfunction and turbulent kinetic energy are presented and these reveal the effect of the roughness geometry on the water surface response. The analysis of the vertical distribution of the streamwise velocity shows that in the lowest submergence cases no logarithmic layer is present, whereas in the higher submergence cases some evidence of such a layer is observed. For several of the flows moderate to significant water surface deformations are observed, including weak and/or undular hydraulic jumps which affect significantly to the overall streamwise momentum balance. Reynolds shear stress, form-induced stress and form drag are analysed with reference to the momentum balance to assess their contributions to the total hydraulic resistance of these flows. The results show that form-induced stresses are dominant at the water surface and can contribute significantly to the overall drag, but the total resistance in all cases is dominated by form drag due to the presence of the bars.

show abstract

Turbulence structure of open channel flows over permeable and impermeable beds: A comparative study

Cited by 124 publications

References 31 publications

Turbulent boundary layers over permeable walls: scaling and near-wall structure

Turbulent boundary layers over permeable walls: scaling and near-wall structure

First-Order Contaminant Removal in the Hyporheic Zone of Streams: Physical Insights from a Simple Analytical Model

Free surface flow over square bars at intermediate relative submergence

Contact Info

Product

Resources

About