3D-Printed Piezoelectric Acoustic Energy Harvester

Michael A. Palmateer; Jacob Plesums; Ryan Santiago; Austin Miller; Reza Rashidi

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Conference: 2023 ASEE Annual Conference & Exposition
Location: Baltimore , Maryland
Publication Date: June 25, 2023
Start Date: June 25, 2023
End Date: June 28, 2023
Conference Session: Energy Conversion, Conservation and Nuclear Engineering Division (ECCNE) Technical Session 2
Tagged Divisions: Energy Conversion and Conservation and Nuclear Engineering Division (ECCNE)
Page Count: 16
DOI: 10.18260/1-2--42345
Permanent URL: https://strategy.asee.org/42345
Download Count: 172

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Dr. Reza Rashidi is an Associate Professor at SUNY University at Buffalo. He was an Associate Professor at SUNY Alfred State when he supervised the project presented in this paper. He received his Ph.D degree in Mechanical Engineering (MEMS development) from the University of British Columbia in 2010 and completed his Postdoctoral Fellowship in Development of Biomedical Sensing Devices in the Department of Electrical and Computer Engineering at the University of British Columbia in 2011. He also received a minor degree in Engineering Management and Entrepreneurship from the University of British Columbia in 2009. He has over 16 years of industrial experience. Before joining Alfred State, Dr. Rashidi was a Senior Engineer at Siemens, where he worked on research projects from 2011 to 2016. His expertise is in the development of nano, micro and mini sensors and actuators in Biomedical Engineering and Energy applications. Dr. Rashidi was a recipient of several awards including the 2008 British Columbia Innovation award, administered by BC province, Canada. He has written over 30 research articles and is currently a reviewer and technical committee member of several journals and conferences worldwide.

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Abstract

Energy harvesting has been widely researched in the past decade due to its significant usage for providing energy to remote areas and electronic devices. Harvesting energy from piezoelectric beams is one of the popular forms of energy conversion, enabling a wide range of applications. A team of four senior undergraduate students in a microfabrication course completed a project to develop a piezoelectric-based acoustic energy harvester. The students performed all development steps, including ideation, literature review, calculation, design, fabrication, assembly, testing, and writing. This paper investigates the plausibility of maximizing the generation of acoustically harvested energy by combining multiple generally known methods for harvesting acoustic energy from sound waves. One such method is using a Helmholtz resonator, a spherical device with one opening, which can create a region of considerable pressure variation when sound waves are directed inside. Another method for acoustic energy harvesting is utilizing the principles of resonance and antinodes in a cylindrical tube. Antinodes are areas of high sound pressure created by standing sound waves resonating through a cylindrical tube at specific frequencies. Our design combines these methods by placing a Helmholtz resonator at the closed end of a cylindrical tube to harvest energy from all areas of high pressure due to resonance; located at the antinodes along the cylinder. The open end of the cylinder expands outward in a parabolic fashion to increase the surface area for capturing as many incident sound waves as possible and directing them into the device. The acoustic energy harvester is fabricated using a three-dimensional (3D) print of the solid model constructed of PLA, a thermoplastic polyester. The device was tested using a speaker projecting known frequencies in the range of optimal frequencies of 600-2500Hz and a data acquisition card (DAQ) measuring voltages for each 100Hz increment. It was determined that the waveform amplitude of 12.13mV produced at 2300Hz was the highest compared to the ones taken at lower frequencies. This evidence proved that the device is more effective at higher frequencies.

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Palmateer, M. A., & Plesums, J., & Santiago, R., & Miller, A., & Rashidi, R. (2023, June), 3D-Printed Piezoelectric Acoustic Energy Harvester Paper presented at 2023 ASEE Annual Conference & Exposition, Baltimore , Maryland. 10.18260/1-2--42345

TY - CPAPER
AB - Energy harvesting has been widely researched in the past decade due to its significant usage for providing energy to remote areas and electronic devices. Harvesting energy from piezoelectric beams is one of the popular forms of energy conversion, enabling a wide range of applications. A team of four senior undergraduate students in a microfabrication course completed a project to develop a piezoelectric-based acoustic energy harvester. The students performed all development steps, including ideation, literature review, calculation, design, fabrication, assembly, testing, and writing. This paper investigates the plausibility of maximizing the generation of acoustically harvested energy by combining multiple generally known methods for harvesting acoustic energy from sound waves. One such method is using a Helmholtz resonator, a spherical device with one opening, which can create a region of considerable pressure variation when sound waves are directed inside. Another method for acoustic energy harvesting is utilizing the principles of resonance and antinodes in a cylindrical tube. Antinodes are areas of high sound pressure created by standing sound waves resonating through a cylindrical tube at specific frequencies. Our design combines these methods by placing a Helmholtz resonator at the closed end of a cylindrical tube to harvest energy from all areas of high pressure due to resonance; located at the antinodes along the cylinder. The open end of the cylinder expands outward in a parabolic fashion to increase the surface area for capturing as many incident sound waves as possible and directing them into the device. The acoustic energy harvester is fabricated using a three-dimensional (3D) print of the solid model constructed of PLA, a thermoplastic polyester. The device was tested using a speaker projecting known frequencies in the range of optimal frequencies of 600-2500Hz and a data acquisition card (DAQ) measuring voltages for each 100Hz increment. It was determined that the waveform amplitude of 12.13mV produced at 2300Hz was the highest compared to the ones taken at lower frequencies. This evidence proved that the device is more effective at higher frequencies.
AU - Michael A. Palmateer
AU - Jacob Plesums
AU - Ryan Santiago
AU - Austin Miller
AU - Reza Rashidi
CY - Baltimore , Maryland
DA - 2023/06/25
PB - ASEE Conferences
TI - 3D-Printed Piezoelectric Acoustic Energy Harvester
UR - https://strategy.asee.org/42345
DO - 10.18260/1-2--42345
ER -

3D-Printed Piezoelectric Acoustic Energy Harvester

Paper Authors

Michael A. Palmateer

Jacob Plesums

Ryan Santiago

Austin Miller

Reza Rashidi SUNY University at Buffalo orcid.org/0000-0002-7741-3140

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