Secondary motions in turbulent ribbed channel flows
Secondary motions in turbulent ribbed channel flows
We present data from direct numerical simulations (DNS) of the fully turbulent flow through nominally two-dimensional channels containing longitudinal, surface-mounted, rectangular ribs whose widths (W) are either one third of or equal to the gap (S − W) between consecutive ribs across the domain, where S is the span (centre-to-centre spacing) of the ribs. A range of the ratio of channel half-height (H) to span (S) is considered, covering 0.25 ⩽ H/S ⩽ 2.5. In each case, a fixed rib height (h) of 0.1H was used, but a number of cases with much smaller heights, h/H = 0.025 or 0.05 were also studied. The secondary flows resulting from the presence of the ribs are examined, along with their sources in terms of the axial vorticity transport equation, which highlights the effects of spanwise inhomogeneity in the Reynolds stresses. We show that the strength of the secondary flows depends strongly on H/S (and, correspondingly, on W/S) and that the major sources of axial vorticity arise near the top corners of the ribs, with convection of that vorticity dominating its spread. We also show that for smaller ribs the secondary flow strengths are similar to those predicted by Zampino et al. (2022) using a linearised model of the Reynolds-averaged equations, which does not include the vorticity convection process; the behaviour of secondary flow topology and strength with varying W/H is thus noticeably different.
Castro, Ian P.
66e6330d-d93a-439a-a69b-e061e660de61
Kim, Jae Wook
fedabfc6-312c-40fd-b0c1-7b4a3ca80987
Castro, Ian P.
66e6330d-d93a-439a-a69b-e061e660de61
Kim, Jae Wook
fedabfc6-312c-40fd-b0c1-7b4a3ca80987
Castro, Ian P. and Kim, Jae Wook
(2024)
Secondary motions in turbulent ribbed channel flows.
Journal of Fluid Mechanics.
(In Press)
Abstract
We present data from direct numerical simulations (DNS) of the fully turbulent flow through nominally two-dimensional channels containing longitudinal, surface-mounted, rectangular ribs whose widths (W) are either one third of or equal to the gap (S − W) between consecutive ribs across the domain, where S is the span (centre-to-centre spacing) of the ribs. A range of the ratio of channel half-height (H) to span (S) is considered, covering 0.25 ⩽ H/S ⩽ 2.5. In each case, a fixed rib height (h) of 0.1H was used, but a number of cases with much smaller heights, h/H = 0.025 or 0.05 were also studied. The secondary flows resulting from the presence of the ribs are examined, along with their sources in terms of the axial vorticity transport equation, which highlights the effects of spanwise inhomogeneity in the Reynolds stresses. We show that the strength of the secondary flows depends strongly on H/S (and, correspondingly, on W/S) and that the major sources of axial vorticity arise near the top corners of the ribs, with convection of that vorticity dominating its spread. We also show that for smaller ribs the secondary flow strengths are similar to those predicted by Zampino et al. (2022) using a linearised model of the Reynolds-averaged equations, which does not include the vorticity convection process; the behaviour of secondary flow topology and strength with varying W/H is thus noticeably different.
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Accepted/In Press date: 27 March 2024
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Local EPrints ID: 489010
URI: http://eprints.soton.ac.uk/id/eprint/489010
ISSN: 0022-1120
PURE UUID: 8315bb83-93c6-47ba-bd6a-88c89017d065
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Date deposited: 11 Apr 2024 16:30
Last modified: 12 Apr 2024 01:39
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