Prediction of Aeroelastic Limit-Cycle Oscillations Based on Harmonic Forced-Motion Oscillations

Rooij, A.C.L.M. van; Nitzsche, Jens; Dwight, Richard P.

doi:10.2514/1.j055852

Cited by 7 publications

(2 citation statements)

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“…Furthermore, unstable LCOs as well as multiple nested LCOs cannot be found directly from coupled fluid-structure interaction simulations. Therefore, the well-known p-k method, used in classical (linear) flutter analysis, has been extended for the prediction of limit-cycle oscillations, see van Rooij et al [1][2][3] This method allows one to extensively study the Hopf bifurcation behaviour of limit-cycle oscillation solutions, due to the reduced computational time once the aerodynamic response is known as a function of the frequencies, amplitudes and phase differences of the degrees of freedom. Figure 1 shows a sketch of the LCO amplitude as a function of the airspeed (after Dowell et al 4 ).…”

Section: Introductionmentioning

confidence: 99%

“…This results in a total of 1280 sample points for the viscous flow test case and 1120 sample points for the inviscid flow test cases. Is is noted here that the response surface is set up at a certain reference velocity and hence the results obtained with ADePK are non-matched, see van Rooij et al 3 Interpolation of the response surface is applied using cubic spline interpolation. …”

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confidence: 99%

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Bifurcations of limit-cycle oscillations of a two degree-of-freedom airfoil caused by aerodynamic non-linearities

Rooij

Nitzsche

Dwight

2017

58th AIAA/ASCE/AHS/ASC Structures, Structural Dynamics, and Materials Conference

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Flutter is usually predicted using linearised theory. In reality, flutter is always non-linear and might already occur below the linearly predicted flutter boundary. Whether this is the case for limit-cycle oscillations (LCOs) caused by aerodynamic non-linearities is not known, since these LCOs can only be predicted using expensive wind-tunnel tests or coupled Computational Fluid Dynamics (CFD)-Computational Structural Mechanics (CSM) simulations. However, it is important to know whether a sufficiently large disturbance can already cause LCOs below the flutter boundary predicted from linearised theory. Furthermore, since structural properties and the flow conditions will vary, it is necessary to study the resulting variations of the Hopf bifurcation behaviour of the LCO solutions near the flutter point. In this work viscous and inviscid transonic flows are considered. The LCO bifurcation behaviour was found to vary significantly when the uncoupled structural natural frequency ratio and the location of the elastic axis are changed. When the non-linearity is relatively weak, a change in the Hopf bifurcation type might result. A Mach number variation in inviscid flow showed that the effective flutter boundary might significantly deviate from that predicted using linearised theory. For both the structural parameter variations and the Mach number variation, LCOs were observed below the linearly predicted flutter boundary. At the nominal structural parameters, the amplitude-dependent behaviour of the phase of the lift was found to be responsible for the type of bifurcation of the LCO solution that occurs. Inspection of the local force distributions at various pitch amplitudes showed that the motion of the shock wave on the lower surface is responsible for the behaviour of the phase of the lift and hence for the bifurcation behaviour of the LCOs observed in this work.

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Section: Introductionmentioning

confidence: 99%

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confidence: 99%