Griffin Plots of vortex-induced vibrations: revealing self-similarity for quick estimation from transient displacement responses
Abstract
Griffin plot relates the peak amplitudes of vortex-induced vibration to structrual mass-damping parameter, known as the Scruton number. Griffin plot serves as a fundamental tool in many engineering fields. This study confirms a general self-similarity in Griffin plots, where plots derived from transient responses at any Scruton number converge to a single, consisten curve. This self-similarity arises from weak aeroelastic nonlinearity in vortex-induced vibration, manifasting as amplitude-dependent aerodynamic damping. Based on this self-similarity property, we propose a numerical method to estimate Griffin plots from transient displacement responses at any Scruton number. The resulting plots align closely with experimental data for both cross-flow and torsional vortex-induced vibrations, highlighting robust self-similar behavior across different Scruton numbers. Furthermore, we observe a consistent trend in Griffin plots for a rectangular cylinder, closed-box, and double-girder bridge deck: the reciprocal of peak amplitudes shows an approximately linear relationship with the Scruton number, especially in torsional vortex-induced vibration. To generate this linearity, we develop a simple empirical model of vortex-induced forces. This model accurately reproduces the Griffin plot for a rectangular cylinder using aeroelastic parameters derived from a single Scruton number, significantly reducing the need for extensive experimental measurements.
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