Akademik Veri Yönetim Sistemi
APPLIED SCIENCES, cilt.14, sa.19, ss.1-34, 2024 (SCI-Expanded)
The use of smart materials and passive controllers in modern technologies has stimulated
the study of vibration in elastic systems with viscoelastic damping. It is also possible to create components with precise material distribution coefficients and distinct properties, such as Functionally
Graded Materials. This work investigates the resonant frequency characteristics of a beam supported
at its ends by Axially Functionally Graded (AFG) viscoelastic bars using the finite element method.
The set of equations governing motion is obtained by assuming Euler–Bernoulli beam theory for the
beam and bar theory for the bars using Lagrange’s equations. The material properties of the functionally graded bar is assumed to vary through the length according to the power law distribution.
The longitudinal loss factor values are used to define the internal damping coefficient, which is also
dependent on the Young’s modulus value varying along the bar. The effects of the length-varying
material properties and internal damping of the FG support bars on the force transmission TR and
frequency parameters λ are examined in detail. No study has been found in the literature on the
vibration of viscoelastic FG bar-supported beams subjected to a harmonic force at the centre point.
It is shown that using bars formed with combinations of different materials considering material
damping will be useful to keep the vibration level and force transmission at a certain value and
control the frequency parameters