Amirkabir University of Technology Amirkabir Journal of Mechanical Engineering 2008-6032 47 2 2016 01 21 Investigation of Vibration Behavior and Crack Detection of a Cracked Short Cantilever Beam under the Axial Load Investigation of Vibration Behavior and Crack Detection of a Cracked Short Cantilever Beam under the Axial Load 1 12 599 10.22060/mej.2016.599 FA Mousa Rezaee Hossein Javadian Vahid A. Maleki Journal Article 2009 12 23 In this research, firstly, the vibrational behavior of a cracked short cantilever beam under the axial load <br />is investigated, and then, an analytical approach for the crack identification based on the vibration <br />analysis is proposed. The cracked section of the beam is considered as a flexible element, which divides <br />the beam into two segments. Using the fracture mechanics theory, the local flexibility of the crack is <br />modeled as a mass-less tensional spring. By applying the boundary conditions and the inner conditions at <br />the crack location, and taking into account the effects of shear deformation and rotary inertia, the <br />governing equation of motion for the cracked beam is derived. The influence of the axial load and the <br />crack parameters on the vibration behavior of the cracked beam is studied by establishing and solving the <br />corresponding eigenvalue problem, directly. Then in order to predict the crack depth and location through <br />the known natural frequencies of the cracked beam, which are obtained by the experimental tests, the <br />corresponding inverse problem is established and solved analytically. The Results have been validated by <br />the experimental and theoretical data reported in the literatures. In this research, firstly, the vibrational behavior of a cracked short cantilever beam under the axial load <br />is investigated, and then, an analytical approach for the crack identification based on the vibration <br />analysis is proposed. The cracked section of the beam is considered as a flexible element, which divides <br />the beam into two segments. Using the fracture mechanics theory, the local flexibility of the crack is <br />modeled as a mass-less tensional spring. By applying the boundary conditions and the inner conditions at <br />the crack location, and taking into account the effects of shear deformation and rotary inertia, the <br />governing equation of motion for the cracked beam is derived. The influence of the axial load and the <br />crack parameters on the vibration behavior of the cracked beam is studied by establishing and solving the <br />corresponding eigenvalue problem, directly. Then in order to predict the crack depth and location through <br />the known natural frequencies of the cracked beam, which are obtained by the experimental tests, the <br />corresponding inverse problem is established and solved analytically. The Results have been validated by <br />the experimental and theoretical data reported in the literatures. Cracked beam Axial load Timoshenko beam crack detection https://mej.aut.ac.ir/article_599_3435c378bb76d4357324dd7e69f3cd18.pdf