An experimental and numerical study of channel flow with rough walls

Krogstad, Per‐Åge; Andersson, Helge I.; Bakken, Ole Martin; Ashrafian, Alireza

doi:10.1017/s0022112005003824

Cited by 168 publications

(81 citation statements)

References 47 publications

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“…Turbulent flows within and above regular obstacle arrays have been investigated by direct numerical simulations (Miyake et al 2001;Nagano et al 2004;Krogstad et al 2005;Coceal et al 2006), LES (Hanna et al 2002;Cui et al 2003;Kanda et al 2004b;Kanda 2006a), and RANS (Lien and Yee 2004;Hamlyn and Britter 2005). Results from LES applications (Kanda et al 2004b;Kanda 2006a) suggest some important physical aspects that are currently not emphasized in simpler CFD simulations: i.e., large dispersive momentum flux within the urban canopy layer due to a mean stream such as recirculation, intermittent urban canyon flow, non-persistent stream patterns, and longitudinally elongated streaks of low speed over building arrays with a scale an order of magnitude larger than individual buildings (Fig.…”

Section: Recent Technique a Simulation Techniquementioning

confidence: 99%

Progress in Urban Meteorology :A Review

Kanda

2007

Journal of the Meteorological Society of Japan

101

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This paper reviews the progress made in urban meteorology over the past few decades. The focus is on the impact of urban surfaces on the overlying atmosphere along the conventional meteorological frameworks. Section 1 details the difficulties in generalizing urban surfaces in a meteorological sense because of surface diversity, and considers whether conventional similarity law is applicable. Section 2 describes the characteristics of urban surfaces as the bottom boundary of the atmosphere and includes a discussion of land surface parameters and the resultant surface energy partitioning. Section 3 explains characteristics of the urban atmosphere, including temperature fields, local circulations and rainfall. Section 4 describes recent progress in numerical modeling and promising new technologies, thus revealing a possible future direction for urban meteorological studies.

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Section: Recent Technique a Simulation Techniquementioning

confidence: 99%

Progress in Urban Meteorology :A Review

Kanda

2007

Journal of the Meteorological Society of Japan

101

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“…Antonia & Krogstad (2001) conducted measurements in the boundary layers developed over two walls with different roughnesses but with matching U + , and found significant differences in the observed turbulence characteristics in the outer layer, though the surfaces had similar values of k/δ ≈ 1.8 and 2.1 %. However, the combined experimental and numerical study of Krogstad et al (2005) found that, for a rough-wall channel with k/δ = 3.4 % and a surface topology similar to the transverse grooves of Bhaganagar et al (2004), the influence of the roughness did not extend beyond approximately five roughness heights from the surface, and the outer layer was unaffected. The authors attributed the apparent discrepancy to fundamental differences between channel and boundary layer flows.…”

Section: Introductionmentioning

confidence: 98%

“…By expressing the roughness size in terms of the equivalent sandgrain roughness, k s (which is associated with the total losses in fully developed turbulent pipe flow rather than any geometric parameter, Nikuradse 1933), Wu & Christensen showed that the relative roughnesses, k s /δ, of Krogstad et al (1992), Keirsbulck et al (2002) and Bhaganagar et al (2004) were 6.7, 13 and 13 %, respectively, and so that the application of the Townsend (1976) scaling assumptions may have been inappropriate in these cases. For the turbulent channel case of Krogstad et al (2005), Wu & Christensen noted that k s /δ was as high as 25 %, rendering the lack of observed effects of the roughness upon the turbulent flow structures even more surprising, regardless of boundary conditions. Clearly, the effect of large roughness upon turbulence structure is still not well understood, especially in the case of internal flows.…”

Section: Introductionmentioning

confidence: 99%

Similarity of the streamwise velocity component in very-rough-wall channel flow

Birch

Morrison

2010

J. Fluid Mech.

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The streamwise velocity component is studied in fully developed turbulent channel flow for two very rough surfaces and a smooth surface at comparable Reynolds numbers. One rough surface comprises sparse and isotropic grit with a highly nonGaussian distribution. The other is a uniform mesh consisting of twisted rectangular elements which form a diamond pattern. The mean roughness heights (± the standard deviation) are, respectively, about 76(±42) and 145(±150) wall units. The flow is shown to be two-dimensional and fully developed up to the fourth-order moment of velocity. The mean velocity profile over the grit surface exhibits self-similarity (in the form of a logarithmic law) within the limited range of 0.04 6 y/ h 6 0.06, but the profile over the mesh surface does not, even though the mean velocity deficit and higher moments (up to the fourth order) all exhibit outer scaling over both surfaces. The distinction between self-similarity and outer similarity is clarified and the importance of the former is explained. The wake strength is shown to increase slightly over the grit surface but decrease over the mesh surface. The latter result is contrary to recent measurements in rough-wall boundary layers. Single-and twopoint velocity correlations reveal the presence of large-scale streamwise structures with circulation in the plane orthogonal to the mean velocity. Spanwise correlation length scales are significantly larger than corresponding ones for both internal and external smooth-wall flows.

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“…For a flow of given bulk Reynolds number, R, over two-dimensional roughness elements, the transition between d-and k-type roughness depends solely on the streamwise spacing of the elements. Many researchers have chosen to focus on square bar roughness to investigate the effect of spacing on turbulence structure and mean flow characteristics, both experimentally (Coleman, Nikora, McLean, & Schlicke, 2007;Djenidi, Antonia, Amielh, & Anselmet, 2008;Djenidi, Elavarasan, & Antonia, 1999;Krogstad, Andersson, Bakken, & Ashrafian, 2005;Okamoto, Seo, Nakaso, & Kawai, 1993;Roussinova & Balachandar, 2011) and numerically (Cui, Patel, & Lin, 2003;Ikeda & Durbin, 2007;Stoesser & Nikora, 2008;Stoesser & Rodi, 2004). Simpson (1973), Tani (1987), Jiminez (2004) and Coleman et al (2007) all proposed that the transition from d-to k-type roughness occurs at around l/k = 5, where l is the crest-to-crest bar spacing and k is the roughness height.…”

Section: Introductionmentioning

confidence: 99%

Free surface flow over square bars at intermediate relative submergence

McSherry

Chua

Stoesser

et al. 2018

Journal of Hydraulic Research

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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.

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An experimental and numerical study of channel flow with rough walls

Cited by 168 publications

References 47 publications

Progress in Urban Meteorology :A Review

Progress in Urban Meteorology :A Review

Similarity of the streamwise velocity component in very-rough-wall channel flow

Free surface flow over square bars at intermediate relative submergence

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