radial pattern, which differs from the linear arrangement of the hydrofoil. This work further extends to a

radial arrangement of the hydrofoils to study the impact of the

radial pattern during resonance conditions.

Damping is divided into three categories: (1) fluid added (hydrodynamic) damping, (2) structural (friction) damping, and (3) material damping. Hydrodynamic damping depends on changes in mode shape due to fluid pressure, convection through vortex shedding, viscous effects within the boundary layer, flow velocity, surface roughness, proximity of nearby structures, and submergence level. When a structure is subjected to a specific mode shape, it deforms, affecting the flow field, particularly near the antinode boundary of the vibrating structure. This results in rapid changes in pressure and velocity. It is crucial to understand what happens in the boundary layer when a structure vibrates at resonant frequency and undergoes different mode shapes, such as changes in viscosity, inertia, and shear stress within the boundary layer. During resonance, amplitudes near the vibrating wall follow a sinusoidal pattern, with small amplitudes at the node point and high amplitudes at the antinode point. Consequently, the pressure gradient constantly shifts from favorable to adverse, along with changes in Reynolds stresses and viscous effects. In the boundary layer, a three-dimensional fluid element travels upstream and downstream as the flow accelerates and decelerates depending on the mode shape. Reverse flow occurs in regions of low kinetic energy (near the vibrating node point), and large eddies bring outer-region momentum towards the wall, supplying some downstream flow. Generally, three regions are created when backflow occurs.

to close the knowledge gap on the behavior of hydrodynamic damping, focusing mainly on changes in the boundary layer during resonance and its effect on damping. Boundary layer flow instability, primarily caused by kinetic energy functions resulting from high-frequency vibration of the blade structure, will be studied to understand the relationship between the boundary layer and the damping effect. To achieve this, coupled fluid-structure interaction simulations using ANSYS will be conducted to understand the flow physics around the vibrating body. Then, a small test rig with simple geometry will be built in the laboratory, where PIV measurements will be implemented for flow characteristics. Excitation will be provided by piezoelectric patches, and the response will be registered with the help of strain gauges. Later, the experiments will be scaled to a hydrofoil-type structure to study the impact of the pressure gradient. Stepped sine frequency excitation will be used to avoid transients. For numerical investigation, high-quality simulations will be used. Initially, the simulation will be carried out using a relatively simple model, and complexity will gradually be increased to achieve the desired results.

The boundary layer plays an essential role in creating the damping effect. We have developed a dedicated benchmark test rig in the Waterpower Laboratory to study flow phenomena in an isolated environment. The test rig is highly versatile, allowing us to conduct numerous experiments addressing the fundamentals of fluid dynamics and fluid-structure interactions. We plan to use this test rig with a rectangular cross-section and aim to integrate a reverberating longitudinal plate into the test section to investigate the boundary layer at different Reynolds numbers.