One-degree-of-freedom galloping instability of a 3D bluff body pendulum at high Reynolds number

The cross -flow swinging dynamics of a cube pendulum is studied experimentally in a flow at high Reynolds numbers ( Re similar to 10 5 ) with a low free -stream turbulence intensity. A galloping instability is observed and results in the exponential growth of the swinging motion. The onset of galloping is found to be very sensitive to the static yaw angle of the cube. Despite the 3D geometry of the cube, flow mechanisms similar to the case of a square cylinder appear to govern the onset of the instability. A quasi -steady linear model of the motion is assessed to predict the stability of the pendulum. For the lowest reduced velocity investigated ( U & lowast; = 18 5 ), unsteady phenomena arise during the saturation phase of the pendulum oscillations. From the analysis of the unsteady loads and the pressure distribution on the faces of the cube, an unsteady phase delay between the wake and the pendulum dynamics is identified. It produces an energy loss in the pendulum motion which favors its saturation.