Transmission of vibration in beam systems

Previous research into structural vibration transmission paths has shown that it is possible to predict vibrational power transmission in simple beam and plate structures. However, in many practical structures transmission paths are composed of more complex curved elements; therefore, there is a nee

Previous research into structural vibration transmission paths has shown that it is possible to measure vibrational power transmission in simple beam and plate structures. However, in many practical structures transmission paths are composed of more complex, curved elements, therefore there is a nee

In the work presented here, a method is developed to predict the stationary random response of a beam which has been modi"ed by the attachment of a damped, lumped assembly of linear mechanical elements. The initial development treats a general beam system with attached linear elements. Two examples

An approach based on flexural wave motion has been developed to investigate vibrational power transmission in a uniform, multi-supported beam. The method can be applied to a finite beam with multiple, different supports subjected to harmonic forces and/or moments. In addition, the method is generall