TY - JOUR
T1 - Finite Element Analysis of a Fluid Flow Based Micro Energy Harvester
AU - Islam, Shabiul AU - Bhuyan, M.S. AU - Majlis, B.Y. AU - Othman, M. AU - Ali, Sawal H. Md.
JO - Research Journal of Applied Sciences
VL - 8
IS - 10
SP - 507
EP - 515
PY - 2013
DA - 2001/08/19
SN - 1815-932x
DO - rjasci.2013.507.515
UR - https://makhillpublications.co/view-article.php?doi=rjasci.2013.507.515
KW - Multi-physics
KW -micro fluig channel
KW -D-shaped
KW -voltage
KW -ultra-low-power
AB - This study presents multi-physics three-dimensional finite
element simulation of a fluid flow based self-excited micro energy harvester.
This micro energy harvester is modeled inside a micro fluid channel to convert
fluid flow energy into fluid oscillations. Investigations are carried out for
the impact of low fluid flow velocity ranging 1-5 m sec-1, associated
voltage generation by piezoelectric means and various mechanical analyses to
enhance the performance and robust design considerations. The piezoelectric
micro cantilever is attached to a D-shaped bluff body. An axial fluid flow and
the D-shaped bluff body interaction generate Karman Vortex Street in the wake
of the bluff-body. Vortex shedding causes an asymmetry in pressure distribution
on the surface of the bluff body which results in time-dependent forces acting
on the attached flexible micro cantilever. Due to structural vibrations induced
by the uniform and steady fluid flow, periodic strains are generated in the
piezoelectric cantilever which converts the strain energy into electrical charge.
Finite Element Analysis Software namely COMSOL Multiphysics are used for the
Harvester Model and simulation. In a 200x150x150 μm3 rectangular
duct, at 5 m sec-1 fluid velocity, the 50x40x2 μm3
piezoelectric cantilever experienced 3088 Pa stress with cantilever tip displacement
around 60 μm. A maximum voltage of 2.9 mV was recorded at 5 m sec-1
fluid velocity that is sufficient to drive an ultra-low-power rectifier circuit
for a complete energy harvesting system. This study in detail describes the
harvester device modeling and finite element analysis in COMSOL. Instead of
using ambient parasitic vibration, this Energy Harvester Model directly utilize
fluid flow energy to improve harvesting capability. The micro energy harvester
self-charging capability makes it possible to develop untethered sensor nodes
that do not require any wired connection or battery replacement or supplement
batteries. Integration of fluid flow based micro energy harvester device for
the autonomous sensor network such as automotive temperature and humidity sensor
networks.
ER -