DYNAMIC LOAD ALLEVIATION OF FLEXIBLE AIRCRAFT IN WAKE VORTEX ENCOUNTERS

Henrik Hesse, Rafael Palacios

DOI Number: N/A

Conference number: IFASD-2015-133

This paper introduces an integrated approach for ﬂexible-aircraft time-domain aeroelastic simulation and controller design suitable for wake encounter situations. The dynamic response of the vehicle, which may be subject to large wing deformations in trimmed ﬂight, is described by a geometrically-nonlinear composite-beam ﬁnite-element model. The aerodynamics is modeled using the unsteady vortex lattice method and includes the arbitrary time-domain downwash distributions of a wake encounter. A consistent linearization in the structural degrees of freedom enables the use of balancing methods to reduce the problem size while retaining the nonlinear terms in the rigid-body equations. Numerical studies on a very ﬂexible aircraft demonstrate the reduced-order modeling approach for load calculations in wake vortex encounters over a large parameter space. Closed-loop results ﬁnally explore the potential of combining feedforward/feedback H∞ control and conventional control surfaces for load alleviation.

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aeroelastic control, ﬂexible aircraft dynamics, load alleviation, wake encounter

In Categories: 2. IFASD 2015, Loads Alleviation

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