Nonlinear dynamics of galloping-based piezoaeroelastic energy harvesters
- 281 Downloads
The normal form is proposed as a tool to analyze the performance and reliability of galloping-based piezoaeroelastic energy harvesters. Two different harvesting systems are considered. The first system consists of a tip mass prismatic structure (isosceles 30° or square cross-section geometry) attached to a multilayered cantilever beam. The only source of nonlinearity in this system is the aerodynamic nonlinearity. The second system consists of an equilateral triangle cross-section bar attached to two cantilever beams. This system is designed to have structural and aerodynamic nonlinearities. The coupled governing equations for the structure’s transverse displacement and the generated voltage are derived and analyzed for both systems. The effects of the electrical load resistance and the type of harvester on the onset speed of galloping are quantified. The results show that the onset speed of galloping is strongly affected by the load resistance for both types of harvesters. The normal form of the dynamic system near the onset of galloping (Hopf bifurcation) is then derived. Based on the nonlinear normal form, it is demonstrated that smaller levels of generated voltage or power are obtained for higher absolute values of the effective nonlinearity. For the first harvesting system, the results show a supercritical Hopf bifurcation for both isosceles 30° or square cross-section geometries. The nonlinear normal form shows that the isosceles triangle section (30°) is more efficient than the square section. For the second harvesting system, the normal form is used to identify the values of the nonlinear torsional spring which changes the harvester’s instability. It is demonstrated that this critical value of the nonlinear torsional spring depends strongly on the load resistance.
KeywordsNormal Form Hopf Bifurcation European Physical Journal Special Topic Cantilever Beam Load Resistance
Unable to display preview. Download preview PDF.
- 10.A. Abdelkefi, Ph.D. Dissertation, Virginia Tech, 2012Google Scholar
- 16.J.P. Den Hartog, Mechanical vibrations (McGraw-Hill, New York, 1956)Google Scholar
- 17.IEEE, Standard on Piezoelectricity IEEE, 1987Google Scholar
- 18.E. Naudascher, D. Rockwell, Flow-induced vibrations, An engineering guide (Dover Publications, New York, 1994)Google Scholar
- 23.A.H. Nayfeh, B. Balachandran, Applied nonlinear dynamics (Wiley series in nonlinear science, NY, 1994)Google Scholar