The performance of a self-excited fluidic energy harvester

The available power in a flowing fluid is proportional to the cube of its velocity, and this feature indicates the potential for generating substantial electrical energy by exploiting the direct piezoelectric effect. The present work is an experimental investigation of a self-excited piezoelectric energy harvester subjected to a uniform and steady flow. The harvester consists of a cylinder attached to the free end of a cantilevered beam, which is partially covered by piezoelectric patches. Due to fluid?structure interaction phenomena, the cylinder is subjected to oscillatory forces, and the beam is deflected accordingly, causing the piezoelectric elements to strain and thus develop electric charge. The harvester was tested in a wind tunnel and it produced approximately 0.1?mW of non-rectified electrical power at a flow speed of 1.192?m?s?1. The aeroelectromechanical efficiency at resonance was calculated to be 0.72%, while the power per device volume was 23.6?mW?m?3 and the power per piezoelectric volume was 233?W?m?3. Strain measurements were obtained during the tests and were used to predict the voltage output by employing a distributed parameter model. The effect of non-rigid bonding on strain transfer was also investigated. While the rigid bonding assumption caused a significant (>60%) overestimation of the measured power, a non-rigid bonding model gave a better agreement (<10% error).

[1]  E. Crawley,et al.  Detailed Models of Piezoceramic Actuation of Beams , 1989 .

[2]  N. Elvin,et al.  Energy Harvesting from Highly Unsteady Fluid Flows using Piezoelectric Materials , 2010 .

[3]  M. Pietrzakowski Active damping of beams by piezoelectric system: effects of bonding layer properties , 2001 .

[4]  Jianqiao Ye Interfacial shear transfer of RC beams strengthened by bonded composite plates , 2001 .

[5]  N. Elvin,et al.  A General Equivalent Circuit Model for Piezoelectric Generators , 2009 .

[6]  R. Blevins,et al.  Flow-Induced Vibration , 1977 .

[7]  Alfredo R. de Faria,et al.  TECHNICAL NOTE: The impact of finite-stiffness bonding on the sensing effectiveness of piezoelectric patches , 2003 .

[8]  C. Norberg Fluctuating lift on a circular cylinder: review and new measurements , 2003 .

[9]  E. A. Bedia,et al.  Elastic analysis of interfacial stresses for the design of a strengthened FRP plate bonded to an RC beam , 2010 .

[10]  Y. Andreopoulos,et al.  Wake of a cylinder: a paradigm for energy harvesting with piezoelectric materials , 2010 .

[11]  Daniel J. Inman,et al.  An experimentally validated bimorph cantilever model for piezoelectric energy harvesting from base excitations , 2009 .

[12]  D. Rockwell,et al.  On vortex formation from a cylinder. Part 2. Control by splitter-plate interference , 1988, Journal of Fluid Mechanics.

[13]  Daniel J. Inman,et al.  A Distributed Parameter Electromechanical Model for Cantilevered Piezoelectric Energy Harvesters , 2008 .

[14]  Jianqiao Ye,et al.  An improved closed-form solution to interfacial stresses in plated beams using a two-stage approach , 2010 .

[15]  D. Inman,et al.  A Review of Power Harvesting from Vibration using Piezoelectric Materials , 2004 .

[16]  Daniel J. Inman,et al.  Piezoelectric Energy Harvesting , 2011 .

[17]  Yi-Chung Shu,et al.  Efficiency of energy conversion for a piezoelectric power harvesting system , 2006 .

[18]  G. Karniadakis,et al.  DNS of flow past a stationary and oscillating cylinder at Re=10000 , 2005 .

[19]  M. Zuo,et al.  The dynamic behavior of a surface-bonded piezoelectric actuator with a bonding layer , 2009 .

[20]  Daniel J. Inman,et al.  Piezoaeroelastic Modeling and Analysis of a Generator Wing with Continuous and Segmented Electrodes , 2010 .

[21]  Xiaodong Wang,et al.  The Effect of Adhesive Layers on the Dynamic Behavior of Surface-bonded Piezoelectric Sensors with Debonding , 2011 .

[22]  Henry A. Sodano,et al.  A review of power harvesting using piezoelectric materials (2003–2006) , 2007 .