Wireless sensor networks play a very important role in environmental monitoring, structural
health monitoring, smart city construction, smart grid, and ecological agriculture. The …

This paper highlights the advancement in wind energy harvesting using piezoelectric
materials to produce sustainable power generation. It is a highly encouraging, fascinating …

Microelectromechanical systems (MEMS) powered by conventional batteries are
disadvantaged in terms of scope of application and environmental friendliness because their …

Wind energy harvesting using piezoelectric transduction is becoming a promising alternative
for battery-free portable and wireless electronics. A novel non-contact vortex-induced …

An energy harvester comprising a cantilever attached to piezoelectric patches and a proof
mass is developed for wind energy harvesting, from a cross wind-induced vibration of the …

Energy harvesting from wind-induced vibration energy using piezoelectric materials has
received great attention because of the self-powered demand for wireless sensor networks …

The interaction between vortex-induced vibration (VIV) and galloping could enhance the
performance of wind energy harvesters (WEHs). Though VIV-galloping interaction may …

Piezoelectric wind energy harvesting is a promising strategy for developing self-powered
small electromechanical systems. In this paper, a curved-plate bluff body is studied for …

Variations in the wind direction over time mean that it is essential to improve the directional
adaptability of wind energy harvesters (WEHs) based on wind-induced vibration (WIV) to …

Harvesting flow energy by exploiting transverse galloping of a bluff body attached to a
piezoelectric cantilever is a prospective method to power wireless sensing systems. In order …