Add to ORKGA promising harvesting technique, in terms of simplicity and efficiency, is the conversion of ambient kinetic energy through piezoelectric materials. This work aims to design and investigate a piezoelectric converter conform to a fractal-inspired, multi-frequency structure previously presented by the author. A physical prototype of the converter is built and experimentally examined, up to 120 Hz, in terms of modal response and power output. Three eigenfrequencies are registered and the power output is particularly good at the fundamental eigenfrequency. Also the effect of the resistive load applied to the converter is investigated
A novel design of a multifrequency mechanical resonator with piezoelectric materials for energy harv...
This paper presents results of numerical and experimental investigations related to the piezoelectri...
Over the past decade, the use of remote wireless sensing electronics has grown steadily. One main co...
A promising harvesting technique, in terms of simplicity and efficiency, is the conversion of ambien...
A promising harvesting technique, in terms of simplicity and efficiency, is the conversion of ambien...
In order to develop self-powered wireless sensor nodes, many energy harvesting devices, able to conv...
In order to develop self-powered wireless sensor nodes, many energy harvesting devices that are able...
An important issue in the field of energy harvesting through piezoelectric materials is the design o...
Harvesting energy from ambient vibrations in order to power autonomous sensors is a challenging issu...
An important issue in the field of energy harvesting through piezoelectric materials is the design o...
Energy harvesting devices capable of converting freely-available ambient energy into electrical ener...
Harvesting kinetic ambient energy from vibrations or impact loads to obtain electrical energy useful...
Energy harvesting from ambient vibrations exploiting piezoelectric materials is an efficient solutio...
Harvesting energy from ambient vibrations in order to power autonomous sensors is a challenging issu...
This work presents a simple and innovative piezoelectric energy harvester, inspired by fractal geome...
A novel design of a multifrequency mechanical resonator with piezoelectric materials for energy harv...
This paper presents results of numerical and experimental investigations related to the piezoelectri...
Over the past decade, the use of remote wireless sensing electronics has grown steadily. One main co...
A promising harvesting technique, in terms of simplicity and efficiency, is the conversion of ambien...
A promising harvesting technique, in terms of simplicity and efficiency, is the conversion of ambien...
In order to develop self-powered wireless sensor nodes, many energy harvesting devices, able to conv...
In order to develop self-powered wireless sensor nodes, many energy harvesting devices that are able...
An important issue in the field of energy harvesting through piezoelectric materials is the design o...
Harvesting energy from ambient vibrations in order to power autonomous sensors is a challenging issu...
An important issue in the field of energy harvesting through piezoelectric materials is the design o...
Energy harvesting devices capable of converting freely-available ambient energy into electrical ener...
Harvesting kinetic ambient energy from vibrations or impact loads to obtain electrical energy useful...
Energy harvesting from ambient vibrations exploiting piezoelectric materials is an efficient solutio...
Harvesting energy from ambient vibrations in order to power autonomous sensors is a challenging issu...
This work presents a simple and innovative piezoelectric energy harvester, inspired by fractal geome...
A novel design of a multifrequency mechanical resonator with piezoelectric materials for energy harv...
This paper presents results of numerical and experimental investigations related to the piezoelectri...
Over the past decade, the use of remote wireless sensing electronics has grown steadily. One main co...