An experimental investigation of oscillatory shallow-water flow around islands has
been undertaken to determine the dependence of wake formation on Keulegan–Carpenter
number, KC = UoT/D,
and stability parameter, S = cfD/h, where
Uo is amplitude of velocity oscillation, T is oscillation period,
D is a representative island diameter, cf
is friction coefficient and h is water depth. Two geometries are
investigated: a vertical cylinder and a conical island with a small side slope of 8°.
Existing experimental results for current flow around the same geometries have shown
the influence of the stability parameter. Predominantly laminar flows are investigated
and the flows are subcritical.Four modes of wake formation have been identified for both geometries: one with
symmetric attached counter-rotating vortices only forming in each half-cycle, one with
vortex pairs forming symmetrically in addition in each half-cycle, one with vortex
pairs forming with some asymmetry and one with complex vortex shedding. The last
results from one of the attached vortices crossing to the opposite side of the body
during flow reversal; in the other cases the attached vortices are convected back
on the same sides. For convenience these formations are called: symmetric without
pairing, symmetric with pairing, sinuous with pairing and vortex shedding. They are
shown on KC/S planes for both geometries. Numerical modelling of the flows for
the conical island, based on the three-dimensional shallow-water equations with the
hydrostatic pressure assumption, is undertaken in Part 2 (Stansby & Lloyd 2001).
Experimental Study of Body-Fin Interaction and Vortex Dynamics Generated by a Two Degree-Of-Freedom Fish Model
