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Mistuning analysis and uncertainty quantification of an industrial bladed disk with geometrical nonlinearity

Abstract : This paper deals with the dynamical analysis and uncertainty quantification of a mistuned industrial rotating integrally bladed disk, for which the operating regime under consideration takes into account the nonlinear geometrical effects induced by large displacements and deformations. First, a dedicated mean nonlinear reduced-order model of the tuned structure is explicitly constructed using the finite element method. The random nature of the mistuning is then modeled by using the nonparametric probabilistic approach extended to the nonlinear geometric context. Secondly, a detailed dynamic analysis and uncertainty propagation are conducted in order to quantify the impact of the nonlinear geometrical effects on the mistuned structure. The results show that the dynamic amplification in the frequency band is significant outside the frequency band of excitation due to the presence of geometric nonlinearities combined with mistuning effects.
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Submitted on : Friday, August 7, 2015 - 6:47:19 PM
Last modification on : Saturday, January 15, 2022 - 4:01:04 AM
Long-term archiving on: : Wednesday, April 26, 2017 - 9:40:17 AM


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Evangéline Capiez-Lernout, Christian Soize, Moustapha Mbaye. Mistuning analysis and uncertainty quantification of an industrial bladed disk with geometrical nonlinearity. Journal of Sound and Vibration, Elsevier, 2015, 356, pp.124-143. ⟨10.1016/j.jsv.2015.07.006⟩. ⟨hal-01183415⟩



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