Vortex shedding induced by polygonal cylinders

Vortex shedding induced by polygonal cylinders

Polygonal cylinders are widely used in many engineering fields. However, the identification of the flow pattern induced by the vortex shedding is always limited to the case of a single or multiple circular cylinders. In the present study, numerical simulations were conducted using the PHOENICS code...

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Bibliographic Details
Published in:The European physical journal. ST, Special topics Vol. 232; no. 4; pp. 403 - 414
Main Authors: Nouri, Saliha, Boulaaras, Salah, Hafsia, Zouhaier
Format: Journal Article
Language:English
Published: Berlin/Heidelberg Springer Berlin Heidelberg 01-04-2023
Springer Nature B.V
Subjects:
Atomic
Circular cylinders
Classical and Continuum Physics
Condensed Matter Physics
Drag
Drag coefficients
Drag reduction
Flow distribution
Fluid flow
IMA10 - Interfacial Fluid Dynamics and Processes
Materials Science
Mathematical analysis
Measurement Science and Instrumentation
Molecular
Negative lift
Optical and Plasma Physics
Physics
Physics and Astronomy
Polygons
Regular Article
Reynolds number
Vortex shedding
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Summary:Polygonal cylinders are widely used in many engineering fields. However, the identification of the flow pattern induced by the vortex shedding is always limited to the case of a single or multiple circular cylinders. In the present study, numerical simulations were conducted using the PHOENICS code to characterize the wake dynamics behind a single and two polygonal cylinders at Reynolds number R e = 100 : circular and face-oriented octagonal (8F) and hexagonal (6F). The simulations were conducted for two side-by-side and tandem polygonal cylinders. For each flow configuration, two gaps between the cylinders are considered: 1.5 D and 3 D where D is the cylinder diameter. Numerical results show that the drag and lift forces are well reproduced for a single and two circular cylinders in side-by-side and tandem arrangements. The single cylinder (8F) leads to 9.3% drag force reduction compared to the circular one. For a transverse gap T = 1.5 D , the variations of drag forces are irregular for the different cylinder shapes (circular, 8F or 6F). In all cylinder shapes, the lower cylinder leads to a negative lift and for the upper one, the lift is positive. For the same longitudinal gap L = 1.5 D , a constant drag force is obtained as obtained by previous numerical studies of two circular cylinders in tandem arrangement. By increasing the gap distance between the two inline cylinders to L = 3 D , the drag coefficient of the downstream cylinder is negative except for the (8F) shape. For the same gap distance and two side-by-side circular cylinders, the drag coefficient is almost the same for the upper and lower cylinders due to the small interaction between the two cylinders. The (8F) tandem cylinders lead to a drag force of about 14.3% compared to the circular cylinder.
ISSN:1951-6355
1951-6401
DOI:10.1140/epjs/s11734-023-00793-w