Concurrent vibration attenuation and low-power electricity generation in a locally resonant metastructure

2022 ◽  
pp. 1045389X2110725
Author(s):  
Mohid Muneeb Khattak ◽  
Christopher Sugino ◽  
Alper Erturk
Keyword(s):  
Vibrational Energy ◽  
Laser Doppler Vibrometer ◽  
Total Power ◽  
Main Beam ◽  
Energy Harvesters ◽  
Piezoelectric Energy ◽  
Vibration Attenuation ◽  
Electrodynamic Shaker ◽  
Electrical Loads ◽  
Power Outputs

We investigate piezoelectric energy harvesting on a locally resonant metamaterial beam for concurrent power generation and bandgap formation. The mechanical resonators (small beam attachments on the main beam structure) have piezoelectric elements which are connected to electrical loads to quantify their electrical output in the locally resonant bandgap neighborhood. Electromechanical model simulations are followed by detailed experiments on a beam setup with nine resonators. The main beam is excited by an electrodynamic shaker from its base over the frequency range of0–150 Hz and the motion at the tip is measured using a laser Doppler vibrometer to extract its transmissibility frequency response. The formation of a locally resonant bandgap is confirmed and a resistor sweep is performed for the energy harvesters to capture the optimal power conditions. Individual power outputs of the harvester resonators are compared in terms of their percentage contribution to the total power output. Numerical and experimental analysis shows that, inside the locally resonant bandgap, most of the vibrational energy (and hence harvested energy) is localized near the excited base of the beam, and the majority of the total harvested power is extracted by the first few resonators.

scholarly journals DESIGN ANALYSIS AND CONSTRUCTION OF ENERGY HARVESTING COAXIAL HELICOPTER

Aviation ◽  
2013 ◽  
Vol 17 (4) ◽  
pp. 145-149
Author(s):  
Anvinder Singh ◽  
Varun Sharma
Keyword(s):  
Piezoelectric Sensor ◽  
Base Station ◽  
The Body ◽  
Total Power ◽  
Energy Harvesters ◽  
Piezoelectric Energy ◽  
Aerial Vehicle ◽  
And Performance ◽  
A Charge ◽  
Coaxial Helicopter

With the growing need for technology, the tendency for errors has increased many times, which often results in loss of human lives. Our main aim of this paper is to show the implementation of a coaxial rotor aerial vehicle that can be controlled by a radio frequency transmitter. The helicopter is capable of manoeuvring in an area where real helicopters cannot. The area could be a flooded region, a place hit by an earthquake, or a building on fire. The main aim is to transmit video of that place to a base station by the camera attached to the helicopter. Various factors required to make a safe and successful coaxial helicopter are discussed and extensive flight testing proves that this flying machine is better in efficiency and performance than a traditional single rotor aerial vehicle. The relation of flight parameters like torque, induced power, rpm, pitch, and total power are discussed. A piezoelectric sensor is used to determine the vibrations occurring in the body so that they can be minimised. A successful attempt to convert the vibrations into a charge by piezoelectric energy harvesters is made.

A Distributed Parameter Electromechanical Model for Cantilevered Piezoelectric Energy Harvesters

2008 ◽  
Vol 130 (4) ◽  
Author(s):  
A. Erturk ◽  
D. J. Inman
Keyword(s):  
Electromechanical Coupling ◽  
Mechanical Response ◽  
Exact Analytical Solution ◽  
Short Circuit ◽  
Open Circuit ◽  
Distributed Parameter ◽  
Energy Harvesters ◽  
Piezoelectric Energy ◽  
Cantilevered Beams ◽  
Power Outputs

Cantilevered beams with piezoceramic layers have been frequently used as piezoelectric vibration energy harvesters in the past five years. The literature includes several single degree-of-freedom models, a few approximate distributed parameter models and even some incorrect approaches for predicting the electromechanical behavior of these harvesters. In this paper, we present the exact analytical solution of a cantilevered piezoelectric energy harvester with Euler–Bernoulli beam assumptions. The excitation of the harvester is assumed to be due to its base motion in the form of translation in the transverse direction with small rotation, and it is not restricted to be harmonic in time. The resulting expressions for the coupled mechanical response and the electrical outputs are then reduced for the particular case of harmonic behavior in time and closed-form exact expressions are obtained. Simple expressions for the coupled mechanical response, voltage, current, and power outputs are also presented for excitations around the modal frequencies. Finally, the model proposed is used in a parametric case study for a unimorph harvester, and important characteristics of the coupled distributed parameter system, such as short circuit and open circuit behaviors, are investigated in detail. Modal electromechanical coupling and dependence of the electrical outputs on the locations of the electrodes are also discussed with examples.

scholarly journals The Effect of Axial Displacement of Magnets in Piezoelectric Energy Harvester

2018 ◽  
Vol 7 (3.7) ◽  
pp. 95
Author(s):  
Li Wah Thong ◽  
Yu Jing Bong ◽  
Swee Leong Kok ◽  
Roszaidi Ramlan
Keyword(s):  
Frequency Spectrum ◽  
Power Output ◽  
Energy Harvester ◽  
Vibrational Energy ◽  
Vibration Energy ◽  
Vibration Energy Harvester ◽  
Energy Harvesters ◽  
Piezoelectric Energy ◽  
Operational Frequency ◽  
And Performance

The utilization of vibration energy harvesters as a substitute to batteries in wireless sensors has shown prominent interest in the literature. Various approaches have been adapted in the energy harvesters to competently harvest vibrational energy over a wider spectrum of frequencies with optimize power output.   A typical bistable piezoelectric energy harvester, where the influence of magnetic field is induced into a linear piezoelectric cantilever, is designed and analyzed in this paper. The exploitations of the magnetic force specifically creates nonlinear response and bistability in the energy harvester that extends the operational frequency spectrum for optimize performance.  Further analysis on the effects of axial spacing displacement between two repulsive magnets of the harvester, in terms of x-axis (horizontal) and z-axis (vertical) on its natural resonant frequency and performance based on the frequency response curve are investigated for realizing optimal power output. Experimental results show that by selecting the optimal axial spacing displacement, the vibration energy harvester can be designed to produce maximized output power in an improved broadband of frequency spectrum.  

scholarly journals Experimental Characterization of Optimized Piezoelectric Energy Harvesters for Wearable Sensor Networks

Sensors ◽  
2021 ◽  
Vol 21 (21) ◽  
pp. 7042
Author(s):  
Petar Gljušćić ◽  
Saša Zelenika
Keyword(s):  
Sensor Networks ◽  
Kinetic Energy ◽  
Average Power ◽  
Wearable Devices ◽  
Specific Power ◽  
Medical Systems ◽  
Power Sources ◽  
Energy Harvesters ◽  
Piezoelectric Energy ◽  
Power Outputs

The development of wearable devices and remote sensor networks progressively relies on their increased power autonomy, which can be further expanded by replacing conventional power sources, characterized by limited lifetimes, with energy harvesting systems. Due to its pervasiveness, kinetic energy is considered as one of the most promising energy forms, especially when combined with the simple and scalable piezoelectric approach. The integration of piezoelectric energy harvesters, generally in the form of bimorph cantilevers, with wearable and remote sensors, highlighted a drawback of such a configuration, i.e., their narrow operating bandwidth. In order to overcome this disadvantage while maximizing power outputs, optimized cantilever geometries, developed using the design of experiments approach, are analysed and combined in this work with frequency up-conversion excitation that allows converting random kinetic ambient motion into a periodical excitation of the harvester. The developed optimised designs, all with the same harvesters’ footprint area of 23 × 15 mm, are thoroughly analysed via coupled harmonic and transient numerical analyses, along with the mostly neglected strength analyses. The models are validated experimentally via innovative experimental setups. The thus-proposed f = 50 mm watch-like prototype allows, by using a rotating flywheel, the collection of low-frequency (ca. 1 to 3 Hz) human kinetic energy, and the periodic excitation of the optimized harvesters that, oscillating at their eigenfrequencies (~325 to ~930 Hz), display specific power outputs improved by up to 5.5 times, when compared to a conventional rectangular form, with maximal power outputs of up to >130 mW and average power outputs of up to >3 mW. These power levels should amply satisfy the requirements of factual wearable medical systems, while providing also an adaptability to accommodate several diverse sensors. All of this creates the preconditions for the development of novel autonomous wearable devices aimed not only at sensor networks for remote patient monitoring and telemedicine, but, potentially, also for IoT and structural health monitoring.

Influence of Bias Angle on Output Performance of Nonlinear Asymmetric Energy Harvesters: Experimental Investigation

2018 ◽  
Author(s):  
Wei Wang ◽  
Junyi Cao ◽  
Ying Zhang ◽  
Chris R. Bowen
Keyword(s):  
Energy Harvesting ◽  
Power Output ◽  
Performance Enhancement ◽  
Vibrational Energy ◽  
Experimental System ◽  
Harmonic Excitation ◽  
Nonlinear Phenomena ◽  
Energy Harvesters ◽  
Output Performance ◽  
Piezoelectric Energy

In recent decades, the technique of piezoelectric energy harvesting has drawn a great deal of attention since it is a promising method to convert vibrational energy to electrical energy to supply lower-electrical power consumption devices. The most commonly used configuration for energy harvesting is the piezoelectric cantilever beam. Due to the inability of linear energy harvesting to capture broadband vibrations, most researchers have been focusing on broadband performance enhancement by introducing nonlinear phenomena into the harvesting systems. Previous studies have often focused on the symmetric potential harvesters excited in a fixed direction and the influence of the gravity of the oscillators was neglected. However, it is difficult to attain a completely symmetric energy harvester in practice. Furthermore, the gravity of the oscillator due to the change of installation angle will also exert a dramatic influence on the power output. Therefore, this paper experimentally investigates the influence of gravity due to bias angle on the output performance of asymmetric potential energy harvesters under harmonic excitation. An experimental system is developed to measure the output voltages of the harvesters at different bias angles. Experimental results show that the bias angle has little influence on the performance of linear and monostable energy harvesters. However, for an asymmetric potential bistable harvester with sensitive nonlinear restoring forces, the bias angle influences the power output greatly due to the effect of gravity. There exists an optimum bias angle range for the asymmetric potential bistable harvester to generate large output power in a broader frequency range. The reason for this phenomenon is that the influence of gravity due to bias angle will balance the nonlinear asymmetric potential function in a certain range, which could be applied to improve the power output of asymmetric bistable harvesters.

A Practical Power Maximization Design Guide for Piezoelectric Energy Harvesters Inspired by Avian Bio-Loggers

2012 ◽  
Author(s):  
Michael W. Shafer ◽  
Matthew Bryant ◽  
Ephrahim Garcia
Keyword(s):  
Vibrational Energy ◽  
Damping Ratio ◽  
Computational Design ◽  
Energy Harvesters ◽  
Beam Geometry ◽  
Piezoelectric Energy ◽  
Simple Question ◽  
Power Maximization ◽  
State Of Research ◽  
The Ideal

Vibrational energy harvesting has been the subject of significant recent research, and has even begun commercial deployment. Despite the research community’s understanding of the fundamental mechanics of piezoelectric systems under base excitation, proper design methods and guidelines for applied systems are nonexistent. This leaves engineers with the options of either using non-ideal beams, or developing complex heuristic computational design programs. Such options are untenable given the state of research. We seek to answer a relatively simple question: Given mass, frequency, and size requirements, what would be the dimensions of the ideal bimorph harvester? By using approximations for the first natural frequency and mode shape, we are able to determine the unknown beam dimensions and modal parameters in terms of the system requirements and material properties. The result is a power equation that only depends on relative piezoelectric material thickness, and the mechanical damping ratio. With only two dependent variables, the equations can be swept in order to find the ideal beam geometry for any given damping ratio. In addition to presenting this method, two design case studies are provided as examples.

scholarly journals A Micromachined Coupled-Cantilever for Piezoelectric Energy Harvesters

2018 ◽  
Author(s):  
Agin Vyas ◽  
L. G. H. Staaf ◽  
Cristina Rusu ◽  
Thorbjörn Ebefors ◽  
Jessica Liljeholm ◽  
...  
Keyword(s):  
Degrees Of Freedom ◽  
Mechanical Response ◽  
Vibrational Energy ◽  
Energy Conversion Efficiency ◽  
High Energy ◽  
Energy Harvesters ◽  
Piezoelectric Energy ◽  
Dual Resonance ◽  
Self Powered ◽  
Micro Cantilever

This paper presents a demonstration of the feasibility of fabricating micro-cantilever harvesters with extended stress distribution and enhanced bandwidth by exploiting an M-shaped two-degrees-of-freedom design. The measured mechanical response of the fabricated device displays the predicted dual resonance peak behavior with the fundamental peak at the intended frequency. This design has the features of high energy conversion efficiency in a miniaturized environment where the available vibrational energy varies in frequency. It makes such a design suitable for future large volume production of integrated self powered sensors nodes for the Internet-of-Things.

A Multiple-Degree-of-Freedom Velocity-Amplified Vibrational Energy Harvester: Part A — Experimental Analysis

2014 ◽  
Author(s):  
Declan O’Donoghue ◽  
Valeria Nico ◽  
Ronan Frizzell ◽  
Gerard Kelly ◽  
Jeff Punch
Keyword(s):  
Gaussian Noise ◽  
Vibrational Energy ◽  
Electrical Power ◽  
Laser Doppler Vibrometer ◽  
Degree Of Freedom ◽  
Maximum Power ◽  
Resistive Load ◽  
Energy Harvesters ◽  
Transduction Mechanisms ◽  
Sinusoidal Excitation

Vibrational energy harvesters (VEHs) are devices which convert ambient vibrational energy into electrical power, offering an alternative to batteries for powering wireless sensors. Detailed experimental characterisation of a 2-degree-of-freedom (2-Dof) VEH is presented in Part A of this paper, while a theoretical analysis is completed in Part B. This design employs velocity amplification to enhance the power harvested from ambient vibrations, while also seeking to increase the bandwidth over which power can be harvested. Velocity amplification is achieved through sequential collisions between free-moving masses. Electromagnetic induction was chosen as the transduction mechanism as it can be readily implemented in a velocity amplified system, although other transduction mechanisms can also be used. The VEH prototype was tested experimentally under both sinusoidal excitation and exponentially correlated Gaussian noise, with different VEH geometries. The maximum power generated under a sinusoidal excitation of arms = 0.6 g was 12.95 mW for a resistive load of 13.5 Ω at 12 Hz, while the maximum power under exponentially correlated Gaussian noise with σ = 0.8 grms, autocorrelation time τ = 0.01s and resistive load 13.5 Ω was 5.3 mW. Maximum bandwidths of 54% and 66%, relative to the central frequency, were achieved under sinusoidal and noise excitation, respectively. The device shows resonant peaks at approximately 15 and 30 Hz, while significant power is also generated in the 17–20 Hz range due to non-linear effects. The VEH component dynamics were analysed using a laser Doppler vibrometer (LDV), while Lab VIEW was used to control the electromagnetic shaker, read the LDV signal and record the VEH output voltage. The aim of this investigation is to achieve a more complete understanding of the dynamics of velocity-amplified systems to aid the optimization of velocity amplified VEH designs.

Piezoelectric Energy Harvesting from Floor Using Wounded PVDF Films

2014 ◽  
Vol 1030-1032 ◽  
pp. 3-7 ◽  
Author(s):  
E. Bischur ◽  
N. Schwesinger
Keyword(s):  
Energy Harvesting ◽  
Field Strength ◽  
Mechanical Energy ◽  
Wireless Systems ◽  
Process Step ◽  
Energy Harvesters ◽  
Piezoelectric Energy ◽  
Sufficient Energy ◽  
Polarization Temperature ◽  
Electrical Loads

Energy harvesters of PVDF can be used to power small electrical loads or wireless sensor systems. Simple technologies are sufficient for the fabrication of these harvesting modules. Critical process step is the polarization of the piezoelectric material. Main piezoelectric parameters depend strongly on the polarization material. Particularly, the electric field strength and the polarization temperature influence the remanent polarization of PVDF. Dielectric breakdowns of the film at higher temperatures prevent a sufficient polarization. At least, all modules were polarized at a field strength of 100 – 120 MV/m and a temperature of 90°C.Modules with dimensions of 165mm x 95mm x 1.5mm were used to power a commercial available “development kit for Energy Harvesting Wireless systems” (EnOcean ‘EDK 300’). The modules possess of 20 layers of PVDF. Each module was connected via a standard four diode full rectifier bridge with the development kit EDK 300. Positioned underneath a parquet floor (thickness=10mm), the modules converted mechanical energy of footsteps into electricity. Goal of these investigations were to find out configurations suited to generate a sufficient energy level to supply the operation of the EDK 300. Two capacitors in the development kit are used to start the operation of the kit (C1=470μF) and to store converted energy (C2=0.25F). Already a few steps onto one module were sufficient to charge C1 and to start the operation of the EDK 300. Following steps (>100) produced energy which was stored in C2.

Advances in Polymer-Based Piezoelectric Systems

2017 ◽  
pp. 139-157
Author(s):  
Nithin Kundachira Subramani ◽  
Shilpa K. N. ◽  
Sachhidananda Shivanna ◽  
Jagajeevan Raj B. M. ◽  
Siddaramaiah Hatna
Keyword(s):  
Vibrational Energy ◽  
Piezoelectric Materials ◽  
Filler Materials ◽  
Energy Harvesters ◽  
Piezoelectric Energy ◽  
Piezoelectric Polymer ◽  
High Efficient ◽  
State Of Research ◽  
Piezoelectric Behavior ◽  
Vibrational Energy Harvesting

Lately, polymer based piezoelectric materials that harness energy from mechanical vibrations and/or impact are being increasingly investigated as radical alternates to conventional batteries that are hard to service once deployed. Nevertheless, the optimization of energy outputs of piezoelectric energy harvesters is one of the prime challenges faced by the scientific community. This chapter provides an overview of polymer based piezoelectric energy harvesters with special emphasis on current state of research on polymer composites/nanocomposites for vibrational energy harvesting. A detailed summary of piezoelectric phenomenon in polymers is also presented. An in-depth narration detailing the enhancement of piezoelectric behavior of one of the most commonly employed piezoelectric polymer (PVDF) is presented with special emphasis on some of the promising filler materials towards realizing high efficient piezoelectric modules. This chapter is intended to give an insight on the recent advances in the field of polymer based piezoelectric materials.

Sign in / Sign up

Export Citation Format

Share Document