Journal of Theoretical and Applied Mechanics

Journal of Theoretical
and Applied Mechanics
0, 0, pp. , Warsaw 0

In this study vibration control of isotropic truncated conical shell containing magnetostrictive actuators is discussed. First-order shear deformation theory and Hamilton principle are handled to obtain vibration equations. The semi analytical Ritz method is utilized to obtain the results of system vibration. Moreover, the shell vibration is controlled using a simple negative velocity feedback control to actively suppress the vibration. The results are validated by comparison with the results of literature and finite element software. The effects of control gain, magnetostrictive layers thickness, length and radius of the large edge of the shell in vibration attenuation are obtained in details.

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