Vishay 2310 Guia do Utilizador descarregar pdf (Página 105)

A simple method of approximating the natural frequency of cantilever beams is shown

below. The method also estimates equivalent stiffness and equivalent mass of the beam.

Recall the generic expression of natural frequency in rad/sec is 











. To find the

natural frequency of a cantilever beam, the equivalent stiffness and equivalent mass are needed.

As given in section 2.1.2, the deflection w at the tip of a cantilever beam (x=L) is























Using Hook’s law, the deflection at the end of the cantilever can be expressed as



where k is the stiffness of the cantilever beam. Combining eq. 17 and eq. 18, k can be

given as









Therefore, the frequency of a cantilever with a point load m at length x can be given as















The same frequency can be provided by a load 



at the end of beam



















Consider a cantilever beam with constant cross section and uniformly distributed mass of

value m per meter along the length. At any time t during vibration, the relationship between

generic deflection (measured at an abscissa y from free end), denoted by 



 and the

deflection at the free end, denoted by 



 can be expressed as:











 











 





















The kinetic energy of the distributed parameter cantilever is expressed as:

























































 











 

























Eq.23

Eq.24

Eq.25

Eq.26

Eq.27

Eq.28

Eq.29

1 2 ... 100 101 102 103 104 105 106 107 108 109 110 ... 142 143

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Vishay 2310 Guia do Utilizador Página 105

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