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Dynamic Stability and Response of Inclined Beams Under Moving Mass and Follower Force

D.S. Yang, C.M. Wang, J. D. Yau

2020International Journal of Structural Stability and Dynamics26 citationsDOI

Abstract

This paper is concerned with the dynamic stability and response of an inclined Euler–Bernoulli beam under a moving mass and a moving follower force. The extended Hamilton’s principle is used to derive the governing equation of motion and the boundary conditions for this general moving load/force problem. Considering a simply supported beam, one can solve the problem analytically by approximating the spatial part of the deflection with a Fourier sine series. Based on the formulation and method of solution, sample dynamic responses are determined for a beam that is inclined at 30[Formula: see text] with respect to the horizontal. It is shown that the dynamic response of the beam under a moving mass is rather different from an equivalent moving follower force. Also investigated herein are the dynamic stability of inclined beams under moving load/follower force which are described by four key variables, viz. the speed of the moving mass/follower force, concentrated mass to the beam distributed mass, vibration frequency and the magnitude of the moving mass/follower force. The critical axial load and the critical follower force are different when they are located at different positions in the beam; except for the special case when they are at the end of the beam.

Topics & Concepts

Moving loadBeam (structure)Deflection (physics)VibrationPhysicsAdded massConservative forceFictitious forceForce dynamicsMechanicsFourier seriesClassical mechanicsControl theory (sociology)MathematicsMathematical analysisEngineeringComputer scienceOpticsAcousticsControl (management)Mechanical engineeringArtificial intelligenceRailway Engineering and DynamicsStructural Health Monitoring TechniquesStructural Engineering and Vibration Analysis
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