Development of highly efficient energy harvester based on magnetic field emanating from a household power line and its autonomous interface electronics

Development of highly efficient energy harvester based on magnetic field emanating from a household power line and its autonomous interface electronics

A magnetic energy harvester and its interface electronics are developed to operate a surface acoustic wave (SAW) oscillator sensor that requires at least 5 to 6 V DC (50 ~ 100 mW) to drive and transmit the measured sensor signals to the reader system wirelessly via antennas. The developed energy har...

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Bibliographic Details
Published in:IEEE sensors journal Vol. 23; no. 7; p. 1
Main Authors: Jung, Seyoon, Kim, Sihyeok, Cho, Wonjun, Lee, Keekeun
Format: Journal Article
Language:English
Published: New York IEEE 01-04-2023
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects:
autonomous interface electronics
Capacitors
Circuit boards
Electronics
Energy
Energy harvesting
Energy storage
Flux density
full wave rectifier
Household power line
Magnetic cores
magnetic field energy harvester
Magnetic flux
Magnetic sensors
Oscillators
Power lines
Power management
power-on reset
Printed circuits
SAW oscillator sensor
Sensor systems
Sensors
Surface acoustic waves
wireless transmission
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Description
Summary:A magnetic energy harvester and its interface electronics are developed to operate a surface acoustic wave (SAW) oscillator sensor that requires at least 5 to 6 V DC (50 ~ 100 mW) to drive and transmit the measured sensor signals to the reader system wirelessly via antennas. The developed energy harvester system comprises a magnetic energy harvester with a coil wound around a magnetic core, an energy storage interface, and a power management interface. From a 220 V, 3 A household AC power line, a 12 V DC is harvested in the storage capacitor via a 5 min energy scavenging process to activate the SAW oscillator sensor. After 2 min of operation using the sensor system, the power management interface is completely shut down to recharge the storage capacitor and then restarted after sufficient charges are accumulated in the storage capacitor to reoperate the SAW oscillator sensor. This autonomous sequence is continuously repeated. The entire interface electronics is developed on a single printed circuit board to reduce the energy loss by the board and to facilitate installation in the desired applications. A simulation is performed in COMSOL to determine the optimal energy harvester parameters and to predict the magnetic flux density that forms the induced current around the ferrite magnetic core based on the magnetic core shape. Experimental results show that the developed energy harvester system can harvest sufficient energy from the household power line in a short period to operate the complex RF SAW sensor and the sensor interface electronics. Furthermore, it can be used to operate the SAW oscillator sensor for the time required to obtain valid information to be transmitted wirelessly to the reader system.
ISSN:1530-437X
1558-1748
DOI:10.1109/JSEN.2023.3244224