Electro-mechanical actuation of primary flight control
surfaces is expected to increase the efficiency of future
commercial aircraft. More specifically, the effort and cost of
manufacture and maintenance will be reduced due to the
omission of hydraulic supply and actuation systems.
However, backlash is inherent to electro-mechanical
actuation, whereas it does not occur in conventional
hydraulic servo-actuation. Due to wear, backlash increases
over the lifetime. With regard to electro-mechanical
actuation of primary flight control surfaces, excessive
backlash can cause detrimental effects such as limit cycle
oscillations or, as a worst case, lead to jamming. Therefore,
efficient and simple-to-deploy methods for monitoring
backlash are sought after.
This paper describes time domain methods for automated
measurement of backlash and stiffness that use available
sensor signals of an electro-mechanical aileron actuation
system. So far, feasibility of the methods has been verified
by experiments on appropriate test benches.
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42nd IEEE International Conference on Decision and Control (IEEE Cat. No.03CH37475).