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Abstract

With advances in wireless communications and low power electronics there is an ever increasing need for efficient self-contained power systems. Traditional batteries are often selected for this purpose; however, there are limitations due to finite life-spans and the need to periodically recharge or replace the spent power source. One method to address this issue is the inclusion of an energy harvesting strategy that can scavenge energy from the surrounding environment and convert it into usable electrical energy. Since civil, industrial, and aerospace applications are often plagued with an overabundance of ambient vibrations, electromechanical transducers are often considered a viable choice for energy scavengers. In this study, two classes of transducer are considered: the piezoelectric polymer polyvinylidene fluoride and the ionically conductive ionic polymer transducer. Analytical models are formed for each material assuming axial loading and simulation results are compared with experimental results for each test. Each material is then compared to examine the effectiveness of their mechanoelectric conversion properties.

Keywords

electroactive polymers energy harvesting ionic polymers PVDF.

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References

Akle, B.J. , Leo, D.J. , Hickner, M.A. and McGrath, J.E. 2005. ``Correlation of Capacitance and Actuation in Ionomeric Polymer Transducers,'' Journal of Materials Science, 40:3715-3724.

Akle, B.J. , Bennett, M.D. and Leo, D.J. 2006. ``High-strain Ionomeric-Ionic Liquid Electroactive Actuators ,'' Sensors and Actuators A, 126:173-181.

Anton, S.R. and Sodano, H.A. 2007. ``A Review of Power Harvesting Using Piezoelectric Materials (2003-2006),'' Smart Materials and Structures, 16:R1-R21.

Bennett, M.D. and Leo, D.J. 2004. ``Ionic Liquids as Stable Solvents for Ionic Polymer Transducers ,'' Sensors and Actuators A, 115:79-90.

Buechler, M.A. and Leo, D.J. 2007. ``Characterization and Variational Modeling of Ionic Polymer Transducers,'' Journal of Vibration and Acoustics , 129:113-120.

Dogruer, D. , Tiwari, R. and Kim, K. 2007. ``Ionic Polymer Metal Composites as Energy Harvesters ,'' In: Proceedings of SPIE, Vol. 6524, Paper No. 65241C-1.

Farinholt, K.M. and Leo, D.J. 2004. ``Effects of Counter-ion, Solvent Type and Loading Condition on the Material Response of Ionic Polymer Transducers,'' In: Proceedings of SPIE, Paper No. 5387-2.

Granstrom, J. , Feenstra, J. , Sodano, H. and Farinholt, K. 2007, ``Energy Havesting from a Backpack Instrumented with Piezoelectric Shoulder Straps,'' Smart Materials and Structures, 16:1810-1820.

Grisso B.L. , Martin L.A. and Inman D.J. 2005. ``A Wireless Active Sensing System for Impedance-based Structural Health Monitoring,'' In: Proceedings of the IMAC-XXIII.

10.

Inman, D.J. (2001). Engineering Vibration, 2nd edn, Prentice Hall, Upper Saddle River, NJ.

11.

Lynch, J.P. and Loh, K.J. 2006. ``A Summary Review of Wireless Sensors and Sensor Networks for Structural Health Monitoring,'' The Shock and Vibration Digest, 38:91-128.

12.

Mateu, L. and Moll, F. 2005. ``Review of Energy Harvesting Techniques and Applications for Microelectronics,'' Circuits and Systems II, Proceedings of the SPIE, 5837:359-373.

13.

Newbury, K. and Leo, D. 2003a. ``Linear Electromechanical Model of Ionic Polymer transducers - Part I: Model Development,'' Journal of Intelligent Material Systems and Structures, 14:333-342.

14.

Newbury, K. and Leo, D. 2003b. ``Linear Electromechanical Model of Ionic Polymer transducers - Part II: Experimental Validation,'' Journal of Intelligent Material Systems and Structures, 14:343- 357.

15.

Overly, T.G.S. , Park, G. and Farrar, C.R. 2007. ``Development of Signal Processing Tools and Hardware for Piezoelectric Sensor Diagnostic Processes,'' In: Proceedings of the SPIE, Vol. 6530.

16.

Paquette, J.W. , Kim, K.J. , Nam, J.D. and Tak, Y.S. 2003. ``An Equivalent Circuit Model for Ionic Polymermetal Composites and their Performance Improvement by a Clay-based Polymer Nano-Composite Technique ,'' Journal of Intelligent Material Systems and Structures , 14:633-642.

17.

Paradiso, J.A. and Starner, T. 2005. ``Energy Scavenging for Mobile and Wireless Electronics ,'' IEEE Pervasive Computing, 4(1):18- 27.

18.

Park, G. , Farrar, C.R. , Todd, M.D. , Hodgkiss, W. and Rosing, T. 2007. ``Energy Harvesting for Structural Health Monitoring Sensor Networks,'' Los Alamos National Laboratory Report, LA-14314-MS.

19.

Roundy, S.J. 2003. ``Energy Scavenging for Wireless Sensor Nodes with a Focus on Vibration to Electricity Conversion,'' Ph.D. Dissertation, Department of Mechanical Engineering, University of California , Berkeley.

20.

Roundy, S. 2005. ``On the Effectiveness of Vibration-based Energy Harvesting ,'' Journal of Intelligent Material Systems and Structures , 16:809-823.

21.

Sodano, H.A. , Inman, D.J. and Park, G. 2004. ``A Review of Power Harvesting from Vibration using Piezoelectric Materials,'' The Shock and Vibration Digest , 36(3):197-205.

An Energy Harvesting Comparison of Piezoelectric and Ionically Conductive Polymers

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