Abstract

The objective of this research project is divided in four parts: (1) to design a piezoelectric actuator based de-icing system integrated to a flat plate experimental setup, develop a numerical model of the system and validate experimentally; (2) use the experimental setup to investigate actuator activation with frequency sweeps and transient vibration analysis; (3) add an ice layer to the numerical model, predict numerically stresses at ice breaking and validate experimentally; and (4) implement the concept to a blade structure for wind tunnel testing. This paper presents the second objective of this study, in which the experimental setup designed in the first phase of the project is used to study transient vibration occurring during frequency sweeps. Acceleration during different frequency sweeps was measured with an accelerometer on the flat plate setup. The results obtained showed that the vibration pattern was the same for the different sweep rate (in Hz/s) tested for a same sweep range. However, the amplitude of each resonant mode increased with a sweep rate decrease. Investigation of frequency sweeps performed around different resonant modes showed that as the frequency sweep rate tends towards zero, the amplitude of the mode tends toward the steady-state excitation amplitude value. Since no other transient effects were observed, this signifies that steady-state activation is the optimal excitation for a resonant mode. To validate this hypothesis, the flat plate was installed in a cold room where ice layers were accumulated. Frequency sweeps at high voltage were performed and a camera was used to record multiple pictures per second to determine the frequencies where breaking of the ice occur. Consequently, the resonant frequencies were determined from the transfer functions measured with the accelerometer versus the signal of excitation. Additional tests were performed in steady-state activation at those frequencies and the same breaking of the ice layer was obtained, resulting in the first ice breaking obtained in steady-state activation conditions as part of this research project. These results confirmed the conclusions obtained following the transient vibration investigation, but also demonstrated the drawbacks of steady-state activation, namely identifying resonant modes susceptible of creating ice breaking and locating with precision the frequencies of the modes, which change as the ice accumulates on the structure. Results also show that frequency sweeps, if designed properly, can be used as substitute to steady-state activation for the same results.

Highlights

  • As a solution to in flight icing problematics, the current project investigates the use of piezoelectric actuators as a low-energy de-icing system that could be implemented on small rotorcraft

  • Error.ToTobetter betterunderstand understand the the phenomena phenomena occurring during frequency sweeps and the reasons for the successful de-icing, an investigation occurring during frequency sweeps and the reasons for the successful de-icing, an investigation of of the thevibration vibrationresponse responseof ofthe theflat flatplate platestructure structureto tofrequency frequencysweeps sweepswas wasperformed performedexperimentally

  • The two plots show that the vibration pattern is similar for all the different sweep durations when excited by the same actuator

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Summary

Introduction

As a solution to in flight icing problematics, the current project investigates the use of piezoelectric actuators as a low-energy de-icing system that could be implemented on small rotorcraft. The amplitude of transient vibrations obtained during frequency sweeps is investigated and compared to steady-state activation case to determine optimal actuator excitation for de-icing. [4] showed a proof of concept for de-icing with actuator patches using frequency sweeps. They succeeded in total or partial de-icing for flat plates, a thinned Bell 206 main rotor and a Bell 206 tail rotor blade. The frequency range and duration for the frequency sweeps used for de-icing were obtained mostly on trial and error and no guidelines were available or obtained to help with the determination of an optimal excitation

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