TY - JOUR
T1 - Aerodynamic mechanisms of galloping of an inclined square cylinder
AU - Hu, Gang
AU - Tse, K. T.
AU - Kwok, K. C. S.
PY - 2016
Y1 - 2016
N2 - The aerodynamic mechanism of galloping of an inclined square cylinder was investigated using both experimental and numerical methods. Experimentally, pressure measurements on the inclined cylinder were taken in the wind tunnel. Numerically, a large eddy simulation was used to investigate the flow field around the cylinder. When the inclination is forward to the approaching wind, it significantly increases the curvature of the shear layer near the free end of the cylinder where as decreases it near the base. Conversely, when the inclination is backward, it decreases the curvature near the free end while increases it near the base. The variation in the curvature has remarkably influenced the pressure distributions on the side faces and hence the transverse force coefficient, which governs the galloping behaviour of the cylinder. The particular curvature of the shear layer in the forward inclination case is a consequence of an inverted V-shaped span wise vorticity distribution, which is induced by an “extended tip vortex pair” with an inverted V-shaped stream wise vorticity distribution. However, in the backward inclination case, the shear layer curvature is attributable to a V-shaped span wise vorticity distribution caused by an “extended base vortex pair” with a V-shaped stream wise vorticity distribution.
AB - The aerodynamic mechanism of galloping of an inclined square cylinder was investigated using both experimental and numerical methods. Experimentally, pressure measurements on the inclined cylinder were taken in the wind tunnel. Numerically, a large eddy simulation was used to investigate the flow field around the cylinder. When the inclination is forward to the approaching wind, it significantly increases the curvature of the shear layer near the free end of the cylinder where as decreases it near the base. Conversely, when the inclination is backward, it decreases the curvature near the free end while increases it near the base. The variation in the curvature has remarkably influenced the pressure distributions on the side faces and hence the transverse force coefficient, which governs the galloping behaviour of the cylinder. The particular curvature of the shear layer in the forward inclination case is a consequence of an inverted V-shaped span wise vorticity distribution, which is induced by an “extended tip vortex pair” with an inverted V-shaped stream wise vorticity distribution. However, in the backward inclination case, the shear layer curvature is attributable to a V-shaped span wise vorticity distribution caused by an “extended base vortex pair” with a V-shaped stream wise vorticity distribution.
KW - aeroelasticity
KW - cylinders
KW - transverse forces
KW - vibration
UR - http://handle.uws.edu.au:8081/1959.7/uws:32722
U2 - 10.1016/j.jweia.2015.10.011
DO - 10.1016/j.jweia.2015.10.011
M3 - Article
SN - 0167-6105
VL - 148
SP - 6
EP - 17
JO - Journal of Wind Engineering and Industrial Aerodynamics
JF - Journal of Wind Engineering and Industrial Aerodynamics
ER -