TY - JOUR
T1 - A numerical study on dynamic flows past three tandem inclined elliptic cylinders near moving wall
AU - Duong, Viet Dung
AU - Nguyen, Van Luc
AU - Nguyen, Van Tien
AU - Palar, Pramudita Satria
AU - Zuhal, Lavi Rizki
AU - Ngo, Trung Thuc
AU - Dinh, Cong Truong
AU - Wang, Wei Cheng
N1 - Publisher Copyright:
© 2024 Author(s).
PY - 2024/2/1
Y1 - 2024/2/1
N2 - This numerical study focuses on the dynamic flows past three tandem inclined elliptic cylinders of equal spacing parallel to a moving wall using a lattice Boltzmann method. The gap ratio ( G / D = 0.6 - 2.5 , where G and D are the gap between the wall surface and cylinder center and major axis, respectively), spacing ratio ( L / D = 1.5 - 10 , where L is the distance of two adjacent cylinder centers), and inclination angle ( α = ± 15 ° , ± 30 ° , ± 45 ° —the angle between normal vector and cylinder's major-axis) are explored at Reynolds number Re = 150 (based on D). The intended analysis links hydrodynamic coefficients, wake structures, and spectral analysis in parameter space of α − G / D − L / D to fluid mechanics. The flow is highly adjustable in this space, dividing into seven regimes: overshoot, continuous reattachment, alternative reattachment, wavy, meandering, quasi-coshedding, and coshedding, which are spatially classified into four modes due to flow interference: shear layer, primary, two-layered, and secondary vortex shedding modes. Transitions between adjacent modes determine three boundaries; and hydrodynamic coefficients differ substantially in parameter space. Due to shadowing, the upstream cylinder has a larger drag coefficient than the middle and downstream cylinders, reducing the drag coefficient of upstream cylinder and the lift coefficient of middle and downstream cylinders. α = ± 45 ° has the highest lift oscillation among the three cylinders and a small drag coefficient of the upstream cylinder. The moving wall's proximity effect increases the upstream cylinder's lift coefficient for α < 0 ° , being negligible for high G/D across the full L/D range and stabilizing the lift oscillation of three cylinders.
AB - This numerical study focuses on the dynamic flows past three tandem inclined elliptic cylinders of equal spacing parallel to a moving wall using a lattice Boltzmann method. The gap ratio ( G / D = 0.6 - 2.5 , where G and D are the gap between the wall surface and cylinder center and major axis, respectively), spacing ratio ( L / D = 1.5 - 10 , where L is the distance of two adjacent cylinder centers), and inclination angle ( α = ± 15 ° , ± 30 ° , ± 45 ° —the angle between normal vector and cylinder's major-axis) are explored at Reynolds number Re = 150 (based on D). The intended analysis links hydrodynamic coefficients, wake structures, and spectral analysis in parameter space of α − G / D − L / D to fluid mechanics. The flow is highly adjustable in this space, dividing into seven regimes: overshoot, continuous reattachment, alternative reattachment, wavy, meandering, quasi-coshedding, and coshedding, which are spatially classified into four modes due to flow interference: shear layer, primary, two-layered, and secondary vortex shedding modes. Transitions between adjacent modes determine three boundaries; and hydrodynamic coefficients differ substantially in parameter space. Due to shadowing, the upstream cylinder has a larger drag coefficient than the middle and downstream cylinders, reducing the drag coefficient of upstream cylinder and the lift coefficient of middle and downstream cylinders. α = ± 45 ° has the highest lift oscillation among the three cylinders and a small drag coefficient of the upstream cylinder. The moving wall's proximity effect increases the upstream cylinder's lift coefficient for α < 0 ° , being negligible for high G/D across the full L/D range and stabilizing the lift oscillation of three cylinders.
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U2 - 10.1063/5.0180655
DO - 10.1063/5.0180655
M3 - Article
AN - SCOPUS:85185346553
SN - 1070-6631
VL - 36
JO - Physics of Fluids
JF - Physics of Fluids
IS - 2
M1 - 023615
ER -