Small wind energy harvesting

Remote sensing equipment are widely used in buildings to monitor building health and collect usage data. A lot of interest has been generated in self-powered remote sensing equipments due to the fact that these sensing devices are embedded inside the building and replacing their batteries can become...

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Main Author: Asm Ashraful Abedin.
Other Authors: Yang Yaowen
Format: Final Year Project
Language:English
Published: 2013
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Online Access:http://hdl.handle.net/10356/53836
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Institution: Nanyang Technological University
Language: English
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spelling sg-ntu-dr.10356-538362023-03-03T17:20:55Z Small wind energy harvesting Asm Ashraful Abedin. Yang Yaowen School of Civil and Environmental Engineering DRNTU::Engineering::Civil engineering Remote sensing equipment are widely used in buildings to monitor building health and collect usage data. A lot of interest has been generated in self-powered remote sensing equipments due to the fact that these sensing devices are embedded inside the building and replacing their batteries can become impractical of costly. Self-powered devices convert various forms of energy from the surrounding environment and convert them to electrical energy. The sources of energy in the ambient environment include solar, heat, vibration and wind. Among them vibration energy is the most ubiquitous and underutilized sources of energy. Electromagnetic, electrostatic and more recently piezoelectric transduction mechanisms can be used to convert vibration energy to electrical energy. The high energy density of piezoelectric transduction mechanism makes it the most suitable method of harvesting energy from vibrations. Strain in a piezomaterial caused by vibrations generates electrical energy. Various types of wind action produce vibration. They include vortex shedding, buffeting, fluttering and galloping. One of traditional design for wind energy harvester consists of a cantilever beam with a proof mass attached to one end of the beam. Previous studies have shown that a cantilevered beam with a square shaped tip mass with the piezoelectric material bonded to the cantilever beam is able to produce electricity based on the translational galloping phenomenon. Translational galloping is a self-excited aerolastic phenomenon, giving rise to transverse oscillations normal to the direction of wind flows in structures with weak damping when wind velocity exceeds a critical value. The study concluded that energy harvesting based on this design is superior to some of the other methods mentioned and the power generated is sufficient to power remote sensing equipment(Zhao, Tang, & Yang, 2012). The harvester mentioned above is known as a linear vibration resonator. It can be modeled as a spring mass system with a single degree of freedom (SDOF) which utilizes resonance phenomenon to obtain peak amplitude. A single vibrating body inherently has more than one degree of freedom (DOF), up to six in space and three in plane. It may be possible to further improve the efficiency of this type of harvester by utilizing multiple DOF’s and obtaining multiple peak amplitude for power output.In addition, as part of an effort to improve the efficiency of Piezoelectric Harvesters, this project will study the effectiveness of using mechanical frequency up conversion techniques using magnets. Frequency conversion techniques have been used in the past to increase the frequency, hence the effectiveness of low frequency vibrating body energy harvesters to higher frequencies with increased outputs (Zorlu, et al., 2011). Bachelor of Engineering (Civil) 2013-06-07T07:58:03Z 2013-06-07T07:58:03Z 2013 2013 Final Year Project (FYP) http://hdl.handle.net/10356/53836 en Nanyang Technological University 35 p. application/pdf
institution Nanyang Technological University
building NTU Library
continent Asia
country Singapore
Singapore
content_provider NTU Library
collection DR-NTU
language English
topic DRNTU::Engineering::Civil engineering
spellingShingle DRNTU::Engineering::Civil engineering
Asm Ashraful Abedin.
Small wind energy harvesting
description Remote sensing equipment are widely used in buildings to monitor building health and collect usage data. A lot of interest has been generated in self-powered remote sensing equipments due to the fact that these sensing devices are embedded inside the building and replacing their batteries can become impractical of costly. Self-powered devices convert various forms of energy from the surrounding environment and convert them to electrical energy. The sources of energy in the ambient environment include solar, heat, vibration and wind. Among them vibration energy is the most ubiquitous and underutilized sources of energy. Electromagnetic, electrostatic and more recently piezoelectric transduction mechanisms can be used to convert vibration energy to electrical energy. The high energy density of piezoelectric transduction mechanism makes it the most suitable method of harvesting energy from vibrations. Strain in a piezomaterial caused by vibrations generates electrical energy. Various types of wind action produce vibration. They include vortex shedding, buffeting, fluttering and galloping. One of traditional design for wind energy harvester consists of a cantilever beam with a proof mass attached to one end of the beam. Previous studies have shown that a cantilevered beam with a square shaped tip mass with the piezoelectric material bonded to the cantilever beam is able to produce electricity based on the translational galloping phenomenon. Translational galloping is a self-excited aerolastic phenomenon, giving rise to transverse oscillations normal to the direction of wind flows in structures with weak damping when wind velocity exceeds a critical value. The study concluded that energy harvesting based on this design is superior to some of the other methods mentioned and the power generated is sufficient to power remote sensing equipment(Zhao, Tang, & Yang, 2012). The harvester mentioned above is known as a linear vibration resonator. It can be modeled as a spring mass system with a single degree of freedom (SDOF) which utilizes resonance phenomenon to obtain peak amplitude. A single vibrating body inherently has more than one degree of freedom (DOF), up to six in space and three in plane. It may be possible to further improve the efficiency of this type of harvester by utilizing multiple DOF’s and obtaining multiple peak amplitude for power output.In addition, as part of an effort to improve the efficiency of Piezoelectric Harvesters, this project will study the effectiveness of using mechanical frequency up conversion techniques using magnets. Frequency conversion techniques have been used in the past to increase the frequency, hence the effectiveness of low frequency vibrating body energy harvesters to higher frequencies with increased outputs (Zorlu, et al., 2011).
author2 Yang Yaowen
author_facet Yang Yaowen
Asm Ashraful Abedin.
format Final Year Project
author Asm Ashraful Abedin.
author_sort Asm Ashraful Abedin.
title Small wind energy harvesting
title_short Small wind energy harvesting
title_full Small wind energy harvesting
title_fullStr Small wind energy harvesting
title_full_unstemmed Small wind energy harvesting
title_sort small wind energy harvesting
publishDate 2013
url http://hdl.handle.net/10356/53836
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