Analysis of a Symmetrical Ferrofluid Sloshing Vibration Energy Harvester

Ferrofluid sloshing vibration energy harvesters use ferrofluid sloshing movement as a moving magnet between a fixed coil to induce current and, in turn, harvest energy from external excitations. A symmetric ferrofluid sloshing vibration energy harvester configuration is introduced in this study which utilizes four external, symmetrically placed, permanent magnets to magnetize a ferrofluid inside a tank. An external sinusoidal excitation of amplitude 1 m/s(2) is imparted, and the whole system is studied numerically using a level-set method to track the sharp interface between ferrofluid and air. The system is studied for two significant length scales of 0.1 m and 0.05 m while varying the four external magnets' polarity arrangements. All of the system configuration dimensions are parametrized with the length scale to keep the system configuration invariant with the length scale. Finally, a frequency sweep is performed, encompassing the structure's first modal frequency and impedance matching to obtain the system's energy harvesting characteristics.

Automated summary

This study introduces a symmetric ferrofluid sloshing vibration energy harvester configuration utilizing external permanent magnets to magnetize ferrofluid inside a tank, with numerical analysis conducted. Varying the polarity arrangements of the external magnets at different length scales reveals the system's energy harvesting characteristics.