Affiliation:
1. Michigan State University Department of Mechanical Engineering, , East Lansing, MI 48824
Abstract
Abstract
The present study deals with the response of a forced Mathieu equation with damping, with weak harmonic direct excitation at the same frequency as the parametric excitation. A second-order perturbation analysis using the method of multiple scales unfolds parametric amplification at primary resonance. The parametric effect on the primary resonance behavior occurs with a slow time scale of second-order, although the effect on the steady-state response is of order 1. As the parametric excitation level increases, the response at primary resonance stretches before becoming unbounded and unstable. Analytical expressions for predicting the response amplitudes are presented and compared with numerical results for a specific set of system parameters. Dependence of the amplification behavior, and indeed possible deamplification, on parameters is examined. The effect of parametric excitation on the response phase behavior is also presented.
Funder
Division of Chemical, Bioengineering, Environmental, and Transport Systems
Division of Civil, Mechanical and Manufacturing Innovation
Reference39 articles.
1. In-Plane Nonlinear Dynamics of Wind Turbine Blades;Ramakrishnan,2011
2. Output-Only Modal Analysis of Linear Time-Periodic Systems With Application to Wind Turbine Simulation Data;Allen;Mech. Syst. Signal Process.,2011
3. Ramakrishnan, V.
, 2017, “Analysis of Wind Turbine Blade Vibration and Drivetrain Loads,” Ph.D. thesis, Michigan State University, East Lansing.
4. Bend-Bend-Twist Vibrations of a Wind Turbine Blade;Acar;Wind Energy,2018
5. Nonlinear Vibration Analysis of the Wind Turbine Blade (Occurrence of the Superharmonic Resonance in the Out-of-Plane Vibration of the Elastic Blade);Inoue;ASME J. Vib. Acoust.,2012
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