A Tuned Mass Damper Design Based on Eddy Current Damping
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Date
2023Author
Sak, Yunus Gökhan
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All dynamic structures encounter vibration during their operation. A structure
experiences the vibration load in an amplified manner at structure’s natural frequencies.
If the amplitude of vibration load is high enough, this may damage the structure. Tuned
mass dampers (TMD’s) are one of the passive vibration control methods to prevent
mechanical failure.
A TMD, which has good applicability in space applications, is designed in this study.
Reliability is chosen as the key concept of the design since the TMD is going to operate
at space, where maintenance is not an option. A literature survey is carried out to find the
best concept for the application. It is found that a passively controlled classical TMD with
eddy current damping (ECD) mechanism is the best candidate for the application.
In ECD, a permanent magnet which moves in proximity of a conductive material creates
eddy currents within the conductor. These eddy currents create electromagnetic force on
the magnet and this force tries to counter act to the motion of the magnet. Therefore,
damping is achieved which is analogues to the viscous damping. ECD is created by
placing a permanent magnet inside of a conductive tube in this thesis.
After the system architecture of the damping mechanism is determined, analytical model
of the TMD is prepared. This model consists of mass, damping coefficient and stiffness
of the TMD. It is found in the literature that as the frequency of the excitation increases,
damping coefficient of the ECD decreases. This phenomenon is called as the skin effect.
A dynamic damping coefficient model which includes the skin effect is found. Although
the effect of the skin effect on the ECD is known, it seems that there is no detailed study
related to couple the skin effect with the damping coefficient in a scenario where a magnet
is moving inside of a conductive tube.
In order to observe the effect of the TMD, a test structure is required in which the dynamic
characteristics around its natural frequency are to be controlled. This structure is chosen
to be a simple cantilever beam which has a rectangular cross section. Fundamental natural
frequency of this cantilever beam is chosen to be controlled. Analytical model of this
cantilever beam is prepared. Then, coupling of the TMD and cantilever beam is modeled
to simulate the assembly of the TMD to the cantilever beam. Afterwards, response of this
system is modeled. In order to observe the effects of the TMD, response of the cantilever
beam alone is also modeled. These responses are modeled under a harmonic sweep
forcing excitation.
The design of the TMD is optimized to have maximum ECD possible. After the design
of the TMD, two dedicated experimental setups are designed to measure steady-state
damping coefficient and the system response. It is shown that the experimental results are
found to be consistent with respect to theoretical results. Therefore, it can be concluded
that a TMD based on ECD was successfully designed, analyzed and tested.