Abstract
The first studies on shocks and vibrations were carried out at the beginning of the 1930s to improve the behavior of buildings during earthquakes. Vibration tests on aircraft were developed from 1940 to verify the resistance of parts and equipments prior to their first use. Flutter is a well-known example of dynamic aero elasticity, where when oscillation of structure interacted with unsteady aerodynamic forces the flutter will occur. Vibration on any structure without damping means that self-harmonic oscillation will occur, and in most cases the oscillation may start to increase until structural failure. This behavior is very similar to resonance phenomena if only the oscillation is being studied as a vibration case. In vibration suppression, the active vibration control is one of the more effective technique which is used for attenuating bad effects of disturbances on structure. In this work, two different composite wings have been used; one of them is made of Glass-fiber random matt and the other is made of woven ({0/90} Glass-fiber). The proportional-integral-derivative (PID) control is employed here for studying the suppression of active vibration wing affected by wind velocity flow through wind tunnel in the laboratory of mechanical engineering department at the university of Baghdad. Piezoelectric (PZT (transducers are used as sensors and actuators in vibration control systems. The attack angle was 10 degrees and three different velocities (15, 20, 35 m/s) have been taken to show their effect on the wings vibrations suppression. Is noticed that the suppression of the wing amplitude is reduced when the wind velocity increases for both woven and random composite wing matt. This is happened due to the vortex which has became more violent increase in wind velocity. It is concluded that the composite woven wing has high resistance more than the composite random wing. Also, the maximum control amplitude of woven matt is 1.9 cm and the damping is about 33% at 25 m/s wind velocity while the amplitude is 2.22 cm and the damping is about 53% at 10 m/s wind velocity for random wing.
Highlights
All the mechanical systems suffer external effects like structure moves through the air
The study is aimed for evaluating the performance of an active regulator for suppression of undesired vibrations. This suppression is carried out via controlling loop and PZT as sensors and actuators totally formulated in finite element (FE) environment
The displacement responses of tested wing is sensed as voltage by piezoelectric, forwarded this voltage to an analog input (NI 9215) which is used for noise filtering and acquiring data
Summary
All the mechanical systems suffer external effects like structure moves through the air. Show that proportional regulator has high effectiveness in vibration suppression with 31% and 25% for free and forced responses respectively. The study is aimed for evaluating the performance of an active regulator for suppression of undesired vibrations. This suppression is carried out via controlling loop and PZT as sensors and actuators totally formulated in finite element (FE) environment. First group of PZT were used to measure feedback signal, and another group were for applying controlling force Such tested model is used in some aerospace applications in which system stability is an important issue. Results show high degree of effectiveness in using linear quadratic regulator for attenuation of system oscillation where about 70% of free body oscillation is eliminated with control on mode.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
