Abstract
Fluid-induced vibrational energy harvesting usually concerns small-scale wind energy extraction. A few efforts have been made into energy harnessing from low-velocity water flows. In this study, low-speed galloping and vortex induced vibration (VIV) are investigated for energy harvesting in an open channel via the macro fiber composite glued on the surface of a cantilever beam. A cylindrical or triangular-prism bluff body is attached at the free tip of the beam and fully immersed in the water. Beam’s deflection is perpendicular to the fluid flow. The flowrate of the water channel is measured by a built-in rectangular sharp-crested weir, and the average flow velocity is controlled by the inlet valve and weir plate. The fluid-structure interaction and electromechanical coupling at different flow velocities and load resistances are analyzed. At small flow velocities, the cylindrical bluff body exhibits better performance than the triangular-prism bluff body since it has been shown in previous work [So et al., J. Fluid Struct. 24, 481–495 (2008) and Daniels et al., J. Wind Eng. Ind. Aerod. 153, 13–25 (2016)] that for the same turbulence intensity the cylinder under VIV performs better than the triangular prism. As the flow velocity increases, the power of the triangular-prism case harvested from the interaction of low-speed galloping and VIV overtakes the power of the cylindrical case converted from the VIV motion that is usually smaller than the cylinder diameter. One dominant vibration frequency is noticed and associated with lock-in or wake capture, which increases with the flow velocity owing to the decreasing added mass. High efficient energy harvesting from the low-velocity water flow is realized via the integration of galloping and VIV.
Highlights
Vibrational energy scavenging using piezoelectric materials provides a solution for self-powered small electrical devices, wireless sensor networks and Internet of Things.[1,2,3] It is valuable to develop intelligent offices and homes, build smart cities, and create an environmentally-friendly and sustainable society though the micro-energy harvesting and Internet of things
A piezoelectric generator was designed with a cantilever beam bonded by macro fiber composite (MFC) and two cylinders made in carbon fibers.[10]
Low-speed galloping and vortex induced vibration (VIV) are investigated for piezoelectric energy harvesting from the water flow in an open channel
Summary
Vibrational energy scavenging using piezoelectric materials provides a solution for self-powered small electrical devices, wireless sensor networks and Internet of Things.[1,2,3] It is valuable to develop intelligent offices and homes, build smart cities, and create an environmentally-friendly and sustainable society though the micro-energy harvesting and Internet of things. A piezoelectric generator was designed with a cantilever beam bonded by macro fiber composite (MFC) and two cylinders made in carbon fibers.[10] Fluid-solid interaction, i.e., Von-Karman Vortex, was studied for such underwater energy harvesting. Canal testings with an average flow speed of 0.5 m/s showed that the harvester was functional to satisfy modest power requirements. Another MFC energy harvesting device using the piezoelectric cantilever beam immersed into the water vortex field shedding from an upstream cylinder was explored.[11] A maximum power of 1.32 μW was recorded with the cylinder diameter of 30 mm at the flow velocity of 0.5 m/s. Low-speed galloping and VIV are investigated for piezoelectric energy harvesting from the water flow in an open channel
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