Average power output and the power law: identifying trends in the behavior of fluidic harvesters in grid turbulence

While the majority of the literature in energy harvesting is dedicated to resonant harvesters, non-resonant harvesters, especially those that use turbulence-induced vibration to generate energy, have not been studied in as much detail primarily due to their comparatively small power output, general non-tunability and difficulty in associating flow conditions to harvester behavior. In this extensive study, we look at the behavior of piezoelectric cantilever beams in different types of grid turbulence with the intention of identifying trends in the harvester output. Our results show that the power-law decay of the harvester output that had previously been observed for rectangular grids holds for a wide variety of fractal grids as well. Additionally, experimental data shows that the average harvester output in grid turbulence follows a power-law growth with respect to the mean flow velocity for relative short and stiff piezoelectric beams.

[1]  N. Elvin,et al.  Interaction of side-by-side piezoelectric beams in quiescent flow and grid turbulence , 2017 .

[2]  Maurizio Porfiri,et al.  Energy exchange between a vortex ring and an ionic polymer metal composite , 2012 .

[3]  Yiannis Andreopoulos,et al.  Energy harvesting prospects in turbulent boundary layers by using piezoelectric transduction , 2015 .

[4]  Y. Andreopoulos,et al.  Fluidic energy harvesting beams in grid turbulence , 2015 .

[5]  Christos Vassilicos,et al.  The decay of turbulence generated by a class of multiscale grids , 2011, Journal of Fluid Mechanics.

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

[7]  Yiannis Andreopoulos,et al.  Parametric analysis of fluidic energy harvesters in grid turbulence , 2016 .

[8]  Kevin Ferko,et al.  Feasibility study of interacting side-by-side piezoelectric harvesters in low-intensity grid-generated turbulence , 2018, Smart Structures and Materials + Nondestructive Evaluation and Health Monitoring.

[9]  Daniel J. Inman,et al.  On the energy harvesting potential of piezoaeroelastic systems , 2010 .

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

[11]  A. Barrero-Gil,et al.  Energy harvesting from transverse galloping , 2010 .

[12]  P. Monkewitz,et al.  A novel tethered-sphere add-on to enhance grid turbulence , 2011 .

[13]  Kevin Ferko,et al.  Interaction of side-by-side fluidic harvesters in fractal grid-generated turbulence , 2018, Smart Structures and Materials + Nondestructive Evaluation and Health Monitoring.

[14]  Yiannis Andreopoulos,et al.  The Effects of Turbulence Length Scale on the Performance of Piezoelectric Harvesters , 2015, HRI 2015.

[15]  S. Ling,et al.  Decay of Isotropic Turbulence Generated by a Mechanically Agitated Grid , 1972 .

[16]  A. Townsend,et al.  Decay of isotropic turbulence in the initial period , 1948, Proceedings of the Royal Society of London. Series A. Mathematical and Physical Sciences.

[17]  Yiannis Andreopoulos,et al.  Green׳s function method for piezoelectric energy harvesting beams , 2014 .

[18]  S. Corrsin,et al.  The use of a contraction to improve the isotropy of grid-generated turbulence , 1966, Journal of Fluid Mechanics.

[19]  John Christos Vassilicos,et al.  Scalings and decay of fractal-generated turbulence , 2007 .

[20]  Daniel J. Inman,et al.  Artificial piezoelectric grass for energy harvesting from turbulence-induced vibration , 2012 .