Pervasive Power: A Radioisotope-Powered Piezoelectric Generator

Lal, Amit; Duggirala, R.; Li, H.

doi:10.1109/mprv.2005.21

Cited by 67 publications

(37 citation statements)

References 7 publications

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“…Other solutions: Micro fuel cells [4], nuclear cells [5] and micro turbine generators [6] would seem to be able to power mobile devices, however the reliance on chemicals to generate energy, is unpopular with users, for example having to refuel when supplies run out.…”

Section: A Battery Technologymentioning

confidence: 99%

Energy Harvesting for In-Ear Devices Using Ear Canal Dynamic Motion

Delnavaz

Voix

2014

IEEE Trans. Ind. Electron.

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Abstract-In this paper, we study the possibility of using energy harvesting from ear canal dynamic motion as a source of power to replace the use of batteries for in-ear devices. Two handmade micro-power generators capable of scavenging energy from ear canal deformation are presented in this paper: (1) a hydroelectromagnetic energy harvester and (2) a flexible piezoelectric generator. The experimental results show that 3.3 mJ of energy per mouth opening and closing cycle is available from ear canal dynamic motion. If we consider that possibly thousands of such cycles occur daily, ear canal dynamic motion could prove a likely source of energy for in-ear applications.Index Terms-ear canal dynamic motion, electromagnetic energy harvester, piezoelectric energy harvester. I. INTRODUCTIONT HE most limiting aspect in mobile technology is the electrical power supply. It restricts autonomy and has a direct impact on the weight and size of electronic devices. Although the use of batteries is still widespread, their cost and impact on the environment is an increasing problem.According to the World Health Organization [1], hundreds of millions of people suffer from various types of hearing impairment and tens of millions of hearing aids are currently in use. Hearing aids and other types of in-ear devices such as digital earplugs, smart hearing protectors and Bluetooth communication earpieces typically have low power consumption and strict size limitations. In recent years, they have been substantially modified and are becoming less energy consuming. Since energy harvesting technologies are usually suitable for low power portable devices, they are gaining interest as an alternative to batteries for in-ear devices.In general, batteries and energy harvesting from the environment or the human body are the only possible ways to power in-ear devices. In this paper, we investigate a new source of energy harvesting for in-ear devices that would come from the wearer: ear canal dynamic motion. This paper is organized as follows: Section II provides an overview of recent advances in various known energy source technologies for in-ear applications. Ear canal dynamic motion as an unexploited source of energy is studied in section III. A hydro-electromagnetic power generator and a piezo-ring energy harvester were designed, modeled, built, and finally tested. Their results are presented in sections IV and V and are discussed in section VI. Finally, the conclusion is drawn in section VII.

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Section: A Battery Technologymentioning

confidence: 99%

Energy Harvesting for In-Ear Devices Using Ear Canal Dynamic Motion

Delnavaz

Voix

2014

IEEE Trans. Ind. Electron.

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“…Another approach commonly employed with micro-scale radioactive power sources to harness energy is to combine the radioactive materials with a piezoelectric harvester. Such systems are referred to as a radioisotope-powered piezoelectric generator [73,74]. The principle behind this technique is to capture the kinetic energy of particles emitted by radioactive materials to actuate a piezoelectric cantilever beam that produces electricity in the range of tens of μW.…”

Section: Converting Thermal Energy To Electrical Energymentioning

confidence: 99%

Energy Harvesting for Structural Health Monitoring Sensor Networks

Park

Rosing

Todd

et al. 2008

J. Infrastruct. Syst.

361

181

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This paper reviews the development of energy harvesting for low-power embedded structural health monitoring (SHM) sensing systems. A statistical pattern recognition paradigm for SHM is first presented and the concept of energy harvesting for embedded sensing systems is addressed with respect to the data acquisition portion of this paradigm. Next, various existing and emerging sensing modalities used for SHM and their respective power requirements are summarized followed by a discussion of SHM sensor network paradigms, power requirements for these networks and power optimization strategies. Various approaches to energy harvesting and energy storage are discussed and limitations associated with the current technology are addressed. The paper concludes by defining some future research directions that are aimed at transitioning the concept of energy harvesting for embedded SHM sensing systems from laboratory research to field-deployed engineering prototypes. Finally, it is noted that much of the technology discussed herein is applicable to powering any type of low-power embedded sensing system regardless of the application.

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“…It should be noted here that the eigenvalues in Eq. (18) and the mode functions in Eq. (17) are obtained under the case without the attached mass m 0 .…”

Section: Appendix a The Mode Function Representation Of The Solutionmentioning

confidence: 99%

“…There have been many investigations [5][6][7][8][9][10][11][12][13][14][15][16][17] on the behaviors of piezoelectric materials and their applications in developing piezoelectric devices. We have noted the work of Lal et al [18] on the potential of a piezoelectric uni-morph vibrating in a bending mode for scavenging energies from a fluctuating ambient pressure source. Roundy et at.…”

Section: Introductionmentioning

confidence: 98%

Coupled analysis for the harvesting structure and the modulating circuit in a piezoelectric bimorph energy harvester

Jiang

2007

Acta Mech. Solida Sin.

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The authors analyze a piezoelectric energy harvester as an electro-mechanically coupled system. The energy harvester consists of a piezoelectric bimorph with a concentrated mass attached at one end, called the harvesting structure, an electric circuit for energy storage, and a rectifier that converts the AC output of the harvesting structure into a DC input for the storage circuit. The piezoelectric bimorph is assumed to be driven into flexural vibration by an ambient acoustic source to convert the mechanical energies into electric energies. The analysis indicates that the performance of this harvester, measured by the power density, is characterized by three important non-dimensional parameters, i.e., the non-dimensional inductance of the storage circuit, the non-dimensional aspect ratio (length/thickness) and the non-dimensional end mass of the harvesting structure. The numerical results show that: (1) the power density can be optimized by varying the non-dimensional inductance for each fixed non-dimensional aspect ratio with a fixed non-dimensional end mass; and (2) for a fixed non-dimensional inductance, the power density is maximized if the non-dimensional aspect ratio and the non-dimensional end mass are so chosen that the harvesting structure, consisting of both the piezoelectric bimorph and the end mass attached, resonates at the frequency of the ambient acoustic source.

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Pervasive Power: A Radioisotope-Powered Piezoelectric Generator

Cited by 67 publications

References 7 publications

Energy Harvesting for In-Ear Devices Using Ear Canal Dynamic Motion

Energy Harvesting for In-Ear Devices Using Ear Canal Dynamic Motion

Energy Harvesting for Structural Health Monitoring Sensor Networks

Coupled analysis for the harvesting structure and the modulating circuit in a piezoelectric bimorph energy harvester

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