Hostname: page-component-76d6cb85b7-mgxrv Total loading time: 0 Render date: 2026-07-12T07:01:01.057Z Has data issue: false hasContentIssue false

The effect of spanwise heterogeneous surfaces on mixed convection in turbulent channels

Published online by Cambridge University Press:  24 October 2022

Kay Schäfer*
Affiliation:
Institute of Fluid Mechanics, Karlsruhe Institute of Technology, 76131 Karlsruhe, Germany
Bettina Frohnapfel
Affiliation:
Institute of Fluid Mechanics, Karlsruhe Institute of Technology, 76131 Karlsruhe, Germany
Juan Pedro Mellado
Affiliation:
Meteorological Institute, University of Hamburg, 20146 Hamburg, Germany
*
Email address for correspondence: kay.schaefer@kit.edu

Abstract

Turbulent mixed convection in channel flows with heterogeneous surfaces is studied using direct numerical simulations. The relative importance of buoyancy and shear effects, characterised by the bulk Richardson number $Ri_b$, is varied in order to cover the flow regimes of forced, mixed and natural convection, which are associated with different large-scale flow organisations. The heterogeneous surface consists of streamwise-aligned ridges, which are known to induce secondary motion in the case of forced convection. The large-scale streamwise rolls emerging under smooth-wall mixed convection conditions are significantly affected by the heterogeneous surfaces and their appearance is considerably reduced for dense ridge spacings. It is found that the formation of these rolls requires larger buoyancy forces than over smooth walls due to the additional drag induced by the ridges. Therefore, the transition from forced convection structures to rolls is delayed towards larger $Ri_b$ for spanwise heterogeneous surfaces. The influence of the heterogeneous surface on the flow organisation of mixed convection is particularly pronounced in the roll-to-cell transition range, where ridges favour the transition to convective cells at significantly lower $Ri_b$. In addition, the convective cells are observed to align perpendicular to the ridges with decreasing ridge spacing. We attribute this reorganisation to the fact that flow parallel to the ridges experience less drag than flow across the ridges, which is energetically more beneficial. Furthermore, we find that streamwise rolls exhibit a very slow dynamics for $Ri_b=1$ and $Ri_b=3.2$ when the ridge spacing is of the order of the rolls’ width. For these cases the up- and downdrafts of the rolls move slowly across the entire channel instead of being fixed in space, as observed for the smooth-wall cases.

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), 2022. Published by Cambridge University Press
Figure 0

Figure 1. Schematic of different large-scale structures in the cross-sectional plane. In (a) streamwise rolls can emerge in flows with buoyancy effects over smooth walls, while in (b) secondary motions appear over rough walls in form of streamwise-aligned ridges. The direction of gravitational acceleration $g$ is given by the downward arrow.

Figure 1

Figure 2. Sketch of the numerical channel domain with streamwise-aligned Gaussian ridges at the walls.

Figure 2

Figure 3. Parameter space of Rayleigh $Ra$ and bulk Reynolds number $Re_b$ in (a). The green marks in (a) indicate the flow parameters of the present simulations and solid and dashed black lines represent isolevels with constant $Ri_b$. The dashed lines highlight $Ri_b$ values, for which $Re$-effects are investigated. The Nusselt number $Nu$ over bulk Reynolds number $Re_b$ of the turbulent mixed convection channel flow from Pirozzoli et al. (2017) for various Rayleigh numbers is shown in (b). The vertical solid black line separates the transitional and turbulent range for pure forced convection flows.

Figure 3

Table 1. List of simulation configurations with flow parameters and resulting global flow properties.

Figure 4

Figure 4. Nusselt number $Nu$ as a function of Rayleigh number $Ra$ in (a) and bulk Reynolds number $Re_b$ in (b) for different ridge spacings $S$. In (a) the bulk Reynolds number $Re_b = 2800$ and in (b) the Rayleigh number $Ra=10^{7}$ is kept constant.

Figure 5

Figure 5. Stanton number $St$ in (a) and ratio of $St$ to $C_f$ in (b) as a function of bulk Richardson number $Ri_b$ for different ridge spacings $S$. The selected cases have values of the Reynolds number $Re_k$ in a similar range.

Figure 6

Figure 6. Instantaneous temperature fluctuation fields at the half-channel height position $y=\delta$ for varying Richardson number $Ri_b$ and different spanwise spacings $S$ of the Gaussian ridges. The spanwise position of the ridges is indicated by the black lines on the right outer frame of the figures. The horizontal sections show the full simulation domain of size $16\delta \times 8\delta$.

Figure 7

Figure 7. Instantaneous temperature fluctuation fields at $y=0.15\delta$ for varying Richardson number $Ri_b$ and different spanwise spacing $S$ of the Gaussian ridges.

Figure 8

Figure 8. Effect of Richardson number $Ri_b$ and $S$ on wall-normal profiles of streamwise mean velocity and mean temperature for different ridge spacings $S$ scaled in wall units.

Figure 9

Figure 9. Effect of spanwise spacing on mean streamwise velocity for forced convection case $Ri_b = 0$ ($Re_b = 2800$, $Ra=0$). The spanwise spacing of the Gaussian ridges is $S = 4\delta$ (a), $S = 2\delta$ (b), $S = \delta$ (c) and $S = 0.5\delta$ (d). Arrows indicate cross-sectional velocity components and are scaled by bulk velocity.

Figure 10

Figure 10. Effect of buoyancy on streamwise mean velocity and temperature for constant $Re_b=2800$ and $S=4\delta$ for different Richardson numbers. Arrows indicate cross-sectional velocity components and are scaled by bulk velocity.

Figure 11

Figure 11. Effect of ridge spacing $S$ on streamwise mean velocity and temperature for constant $Ri_b = 10$.

Figure 12

Figure 12. Volume-averaged coherent turbulent kinetic energy of the cross-sectional components for low $Ri_b$ cases scaled in wall units in (a) and for large $Ri_b$ cases scaled in free-fall units in (b).

Figure 13

Figure 13. Velocity and temperature variances scaled in inner units for low bulk Richardson number $Ri_b$ cases at transition from forced convection structures to streamwise rolls. Black vertical dotted line indicates the height of the Gaussian ridges.

Figure 14

Figure 14. Velocity and temperature variances scaled in free-fall units for high bulk Richardson number $Ri_b$ cases at transition from streamwise rolls to natural convection.

Figure 15

Figure 15. Short-time-averaged coherent kinetic energy $K^{s}_c$ of case $Ri_b = 1$ and different ridge spacings over time. The values of $K^{s}_c$ are averaged for time intervals ${\rm \Delta} t_s \approx 3.4t_f$.

Figure 16

Figure 16. Streamwise- and short-time-averaged temperature $\overline {T}^{s}$ over time and spanwise position at the wall-normal channel centre location $y=\delta$ for cases $Ri_b = 1$. The spanwise position of the ridges is indicated by the black lines on the top panels.

Figure 17

Figure 17. Effect of turbulent Reynolds number $Re_k$ and spanwise ridge spacing $S$ on mean temperature for case $Ri_b=0.024,\ Re_k = 252\unicode{x2013}263$ ($Ra=7.5\times 10^{5}$, $Re_b=2800$) on the left side and case $Ri_b=0.025,\ Re_k = 826\unicode{x2013}841$ ($Ra=10^{7}$, $Re_b=10\,000$) on the right side. The spanwise spacing of the Gaussian ridges is $S = 2\delta$ (a), $S = \delta$ (b) and $S=0.5\delta$ (c).

Figure 18

Figure 18. Instantaneous temperature fluctuation fields at the half-channel height position $y=\delta$ for cases $Ri_b = 3.2$ with $Re_k = 236\unicode{x2013}263$ ($Ra=10^{7}$, $Re_b=885$) in (a) and $Re_k = 695\unicode{x2013}792$ ($Ra=10^{8}$, $Re_b=2800$) in (b) for different spanwise ridge spacings $S$.

Figure 19

Table 2. Simulation parameters and global flow properties of validation study for Rayleigh–Bénard and mixed convection at $Ra = 10^{6}$ and $Ra=10^{7}$. The skin friction coefficient and Nusselt number of Pirozzoli et al. (2017) are given by $C_{f,{ref}}$ and $Nu_{{ref}}$.

Figure 20

Figure 19. Mean profiles for validation study for $Ra=10^{7}$ and different bulk Reynolds numbers. The marks indicate the reference data of Pirozzoli et al. (2017), for clarity every fifth data point is shown.

Figure 21

Table 3. Grid refinement study for pure forced convection, mixed convection and pure Rayleigh–Bénard flow with Gaussian ridges at each sidewall ($S/\delta = 1$). The domain size for the study is set to $L_x \times L_y \times L_z = 8\delta \times 2\delta \times 4\delta$.