Renewable mobile charger using piezoelectric transducer

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Renewable mobile charger using piezoelectric transducer

Author Affiliations

¹Electronics and Communication Engineering Department, College of Science and Technology Rinchenching: Phuntsholing, Bhutan
²Electronics and Communication Engineering Department, College of Science and Technology Rinchenching: Phuntsholing, Bhutan

Res. J. Recent Sci., Volume 7, Issue (8), Pages 20-23, August,2 (2018)

Abstract

The paper propose to generate electrical energy through the mechanical stress on the screen of cellular phone. The mechanical stress applied on the touch screen of cellular phone while using is converted to electrical energy using the proposed transparent piezoelectric transducer. The location of the transducer is proposed for its attachment at the back of the cell phone screen. Though it may not generate enough power for successful running of the cellular phone, the method generates sufficient amount of power for automatic and gradual cell phone charging. The charging through such proposal increases the battery life of the cellular phone for longer use time.

References

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[ref1] Ashna Joseph, Bony Tom, Devika P.V., Femin Joseph and Jithin A.J. (2007)., Electrical Energy Production., International Journal of Advanced Research in Electrical, Electronics and Instrumentation Engineering.

[ref2] Ashna Joseph, Bony Tom, Devika P.V., Femin Joseph and Jithin A.J. (2016)., Electrical Energy Production., International Journal of Advanced Research in Electrical, Electronics and Instrumentation Engineering.

[ref3] Dhanalakshmi G. and Sangeetha T.M.M.M.S. (2017)., Footstep Power Generation System., International Journal of Engineering and Computer Science, 6(4). ISSN: 2319-7242. doi:10.18535/ijecs/v6i4.38
Google Scholar

[ref4] Brodie G., Qiu Y., Cochran S., Spalding G. and Macdonald M. (2014)., Optically transparent piezoelectric transducer for ultrasonic particle manipulation., IEEE transactions on ultrasonics, ferroelectrics, and frequency control, 61(3), 389-391.
Google Scholar

[ref5] Brodie G., Qiu Y., Cochran S., Spalding G. and Macdonald M. (2014)., Optically Transparent Piezoelectric Transducer., IEEE Transac TIons on UlTrasonIcs, FErroElEcTrIcs and FrEqUEncyconTrol. doi:http://dx.doi.org/10.1109/ TUFFc. 2014.2923

[ref6] Kim H.W., Batra A., Priya S., Uchino K., Markley D., Newnham R.E. and Hofmann H.F. (2004)., Energy harvesting using a piezoelectric "cymbal" transducer in dynamic environment., Japanese journal of applied physics, 43(9R), 6178.
Google Scholar

[ref7] Park K.I., Son J.H., Hwang G.T., Jeong C.K., Ryu J., Koo M. and Lee K.J. (2014)., Highly‐efficient, flexible piezoelectric PZT thin film nanogenerator on plastic substrates., Advanced materials, 26(16), 2514-2520. doi: DOI: 10.1002/adma.201305659
Google Scholar

[ref8] Saranya M. and Selvarasu S. (2016)., Piezo Electric Based Energy Harvesting., International Journal of Innovative Research in Science, Enginnering and Technology. doi:10.15680/IJIRSET.2016.0504169

[ref9] Saranya M. and Selvarasu S. (2016)., Piezo Electric Based Energy Harvesting from Footsteps., International Journal of Innovative Research in Science, Engineering and Technology. doi:10.15680/IJIRSET.2016.0504169

[ref10] Shiraz Afzal and Farrukhhafeez (2014)., Power Generation Footstep., International Journal of Advancements in Research & Technology.
Google Scholar