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Flow and coherent structures generated by a circular array of rigid, emerged cylinders in a shallow channel

Published online by Cambridge University Press:  23 September 2024

Kyoungsik Chang
Affiliation:
School of Mechanical Engineering, University of Ulsan, Ulsan, 44610, Korea
Chenyu Jiang
Affiliation:
Water Conservancy Development Research Center of Taihu Basin Authority of Ministry of Water Resources, Shanghai 200438, PR China IIHR-Hydroscience and Engineering and Department of Civil and Environmental Engineering, The University of Iowa, Iowa City, IA 52240, USA
George Constantinescu*
Affiliation:
IIHR-Hydroscience and Engineering and Department of Civil and Environmental Engineering, The University of Iowa, Iowa City, IA 52240, USA
Yeong-Ki Jung
Affiliation:
Mechanical R&D Laboratory, LIG Nex1, Seongnam, 13488, South Korea
*
Email address for correspondence: sconstan@engineering.uiowa.edu

Abstract

The study investigates the flow structure, dynamics of the large-scale coherent structures, drag forces and sediment entrainment mechanisms generated by a circular array of diameter D containing rigid emerged circular cylinders of diameter d placed in a smooth-bed channel of depth h under strong shallow flow conditions (D/h = 20, d/D = 0.0125 and 0.025). Eddy resolving simulations are conducted with different values of the solid volume fraction 0.025 ≤ SVF ≤ 0.1 and non-dimensional frontal area per unit volume (2.56 ≤ aD ≤ 10.2, where for the present configuration, a = SVF(1/d)4/${\rm \pi}$) and a fixed channel Reynolds number (Reh = 10 000). The flow conditions are such that a vortex street (VS)-type of shallow wake is expected to form for a solid cylinder of diameter D. Findings are compared with previous results obtained for cases with moderately shallow conditions 2.5 ≤ D/h ≤ 3.5 and with the limiting case of flow past a solid cylinder with D/h = 20. For moderately shallow conditions, the core of the main horseshoe vortex (HV) forming around the array occupies a small fraction of the water column and its coherence is the largest in front of the array. By contrast, for very shallow conditions, multiple HVs form around the array and their cores occupy a large fraction of the water column. Moreover, the coherence of most of these HVs peaks close to the sides of the array. Only for relatively large aD values, the main HV extends over the whole upstream face of the array, similar to the limiting case of a solid cylinder. For sufficiently high aD, a secondary instability is present inside the near wake that leads to the formation of parallel horizontal vortices in the vicinity of the wake roller vortices. The changes in the wake structure with decreasing SVF and aD are qualitatively similar to those observed for cases with moderately shallow flow conditions, with the antisymmetric wake shedding mode being suppressed for aD ≤ 2.5. However, the Strouhal number associated with the shedding of wake rollers, which is still close to 0.2 for a solid cylinder with D/h = 20, can be as high as 0.4 for aD = 2.5. The paper also discusses how the steady wake and total wake lengths and the strength of the bleeding flow vary with the SVF. Simulation results show that the capacity of the flow to entrain sediment inside and around the array peaks for SVF = 0.05 and aD = 5.2, with sediment entrainment monotonically increasing with the SVF outside the array and monotonically decreasing inside the array. Despite the differences in the flow structure next to and inside the array, the variation of the mean, time-averaged streamwise drag coefficient of the solid cylinders ${\bar{C}_d}$ with aD is close to that observed for arrays with moderately shallow flow conditions. The combined drag coefficient for the array decreases with increasing flow shallowness, with the decay being stronger for relatively large values of aD.

Information

Type
JFM Papers
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2024. Published by Cambridge University Press.
Figure 0

Figure 1. Sketch of the computational domain containing a circular array of solid cylinders. The emerged array of diameter D is placed in an open channel with incoming bulk velocity U and flow depth h. The polar angle ϕ is measured with respect to the symmetry plane (y/D = 0) upstream of the centre of the array.

Figure 1

Table 1. Main geometrical and flow variables of the test cases (N is the number of cylinders in the array; d is diameter of the solid cylinders; D is the diameter of the circular array; h is the flow depth, U is the channel bulk velocity, Reh = Uh/ν, ReD = UD/ν, Red = Ud/ν, ν is the molecular viscosity, aD is the non-dimensional frontal area per unit volume for the array; U1 is the centreline streamwise velocity at the upstream end of the steady wake region; U2 is the maximum streamwise velocity of the flow on the sides of the array; ${L_{sw}}$ and ${L^{\prime}_{sw}}$ are the steady wake lengths defined based on mean velocity and spanwise normal stresses, respectively; ${L^{\prime}_w}$ is the total wake length; StD is the Strouhal number defined with U and D corresponding to the most energetic frequency in the wake of the array; CD is the mean solid cylinder streamwise drag coefficient; ${\varGamma _D} = {C_D}aD/(1 - \textrm{SVF})$ is the combined drag parameter for the array.

Figure 2

Figure 2. Visualization of the horseshoe vortex system using a Q isosurface (Q = 0.1). (a) SVF = 1.0 mean flow; (b) SVF = 0.1 mean flow; (c) SVF = 0.1(2d) mean flow; (d) SVF = 0.05 mean flow; (e) SVF = 0.025 mean flow; ( f) SVF = 0.025, instantaneous flow. BV indicates a bottom-attached vortex. The colour contours represent the distance from the top boundary, z/D. Note the large-scale hairpins generated along the legs of the largest HV, V1 in panel (f).

Figure 3

Figure 3. Visualization of flow structure inside the horseshoe vortex system in selected polar planes. (a) SVF = 0.1; (b) SVF = 0.1(2d); (c) SVF = 0.05; (d) SVF = 0.025; (e) SVF = 1.0. Top panels show the mean out of plane vorticity, ωnh/U, 2-D streamlines for ϕ = 70°. Middle panels show the TKE, k/U2, for ϕ = 70°. Bottom panels show the TKE for ϕ = 0°. The vertical dashed line indicates the boundary of the array. The interior of solid cylinders is represented in grey. The horizontal to vertical aspect ratio in all frames is 1:2.5. The radial distance measured from the origin of the array is r.

Figure 4

Figure 4. Mean pressure, p/ρU2, at the top boundary (z/h = 0). (a) SVF = 0.1; (b) SVF = 0.025.

Figure 5

Figure 5. Non-dimensional vertical vorticity, ωzh/U, in the instantaneous flow close to the top boundary (z/h = −0.1). (a) SVF = 1.0; (b) SVF = 0.1; (c) SVF = 0.025.

Figure 6

Figure 6. Visualization of coherent structures in the instantaneous flow using a Q isosurface (Q = 0.002). (a) SVF = 1.0; (b) SVF = 0.1. The black lines in panels (a) and (b) show the position of the x/h = constant planes shown in figure 7.

Figure 7

Figure 7. Streamwise vorticity, ωxh/U, (top panel) and streamwise velocity, u/U, (bottom panel) in an instantaneous flow field. (a) SVF = 1.0, x/h = 90; (b) SVF = 0.1, x/h = 120. The red arrows point towards patches of high streamwise vorticity associated with some of the streamwise-oriented vortices visualized in figure 6.

Figure 8

Figure 8. Non-dimensional mean vertical velocity, w/U, at mid depth (z/h = −0.5). Regions with |w/U| < 0.04 are blanked. (a) SVF = 0.1; (b) SVF = 0.025.

Figure 9

Figure 9. Non-dimensional TKE, k/U2, close to the top boundary (x/h = −0.1, top half) and the channel bed (z/h = −0.9, bottom half). (a) SVF = 1.0; (b) SVF = 0.1; (c) SVF = 0.05; (d) SVF = 0.025. The red circle shows the boundary of the array region.

Figure 10

Figure 10. 2-D mean flow streamline patterns close to the top boundary (z/h = −0.1). (a) SVF = 1.0; (b) SVF = 0.1; (c) SVF = 0.05; (d) SVF = 0.025. The red circle shows the boundary of the array region.

Figure 11

Figure 11. Longitudinal profiles of: (a) mean streamwise velocity, $\bar{u}/U$; and (b) spanwise normal stress, $\overline {v^{\prime}v^{\prime}} /{U^2}$, at the top boundary. The profiles are shown along the centreline, y/D = 0. The grey region shows the extent of the array region (−10 < x/D < 10). The dashed arrows in panels (a) and (b) show the end of the steady wake region based on the predicted values of $\; {L_{sw}}/h$ and ${L^{\prime}_{sw}}/h$, respectively. The solid arrows in panel (b) show the end of the total wake region based on the predicted values of ${L^{\prime}_w}/h$.

Figure 12

Figure 12. Variation of the length of the near-wake region with the velocity ratio U1/U2. (a) Steady wake length, ${L^{\prime}_{sw}}/D$; (b) total wake length, ${L^{\prime}_w}/D$. In addition to the present test cases (D/h = 20) with d = 0.0125D (open red squares) and d = 0.025D (solid red squares), results are also included for DES conducted for an array with D/h = 2.5–3.3 (solid green diamonds) by Chang et al. (2017).

Figure 13

Figure 13. Non-dimensional bed friction velocity magnitude, uτ/U, in the instantaneous flow. (a) SVF = 1.0; (b) SVF = 0.1; (c) SVF = 0.05; (d) SVF = 0.025.

Figure 14

Figure 14. Non-dimensional bed friction velocity magnitude, $\overline {{u_\tau }} /U$, in the mean flow. (a) SVF = 1.0; (b) SVF = 0.1; (c) SVF = 0.05; (d) SVF = 0.025.

Figure 15

Figure 15. Non-dimensional root mean square of the bed friction velocity magnitude, $u_\tau ^{SD}/U$. (a) SVF = 1.0; (b) SVF = 0.025.

Figure 16

Figure 16. Non-dimensional flux of entrained sediment, $\overline {{E_\tau }} $, as a function of the solid volume fraction, SVF. The red line and red solid symbols show $\overline {{E_\tau }} $ calculated inside the array. The blue line and blue solid symbols show $\overline {{E_\tau }} $ calculated outside the array. The black line and black solid symbols show $\overline {{E_\tau }} $ calculated over the whole channel bed. The open symbols correspond to the SVF = 0.1(2d) case. Results are plotted for a critical bed friction velocity, uτc/U = 0.065.

Figure 17

Figure 17. Distribution of the normalized mean streamwise drag force acting on the solid cylinders forming the array. The force on each cylinder is normalized by the drag force acting on an isolated solid cylinder. The vertical axis shows the percentage of the cylinders forming the array for which the normalized drag force is in between (2i)/10 and (2i + 2)/10 with i = 0 to 5.

Figure 18

Figure 18. Non-dimensional time-averaged streamwise drag force. (a) Time-averaged total drag coefficient for the array, ${\bar{C}_{DG}}$ versus aD; (b) mean, time-averaged solid cylinder drag coefficient, ${\bar{C}_d} = ({\bar{C}_{DG}}/N)(D/d)$ versus aD; (c) ${\bar{C}_d}$ versus aD in log-linear scale; (d) combined drag parameter for the array, ${\Gamma _D} = {\bar{C}_d}(aD)/(1 - \textrm{SVF})$ versus aD; (e) $\varGamma_{D}$ versus 1 − U1/U2. In addition to the present test cases (D/h = 20) with d = 0.0125D (open squares) and d = 0.025D (solid squares), some of the frames show data from the 3-D LES predictions of Chang & Constantinescu (2015) conducted for an array of long porous cylinders (solid blue circles) and the 3-D DES of Chang et al. (2017) conducted for arrays with D/h = 2.5 and 3.3 (solid green diamonds). The dashed line in panel (c) shows a best fit to the numerical data, ${\bar{C}_d} = 0.75\hbox{--}0.248\ast \textrm{ln}(aD)$.