Numerical and Experimental Investigation of the Design of a Piezoelectric De-Icing System for Small Rotorcraft Part 2/3: Investigation of Transient Vibration during Frequency Sweeps and Optimal Piezoelectric Actuator Excitation

Villeneuve, Éric; Volat, Christophe; Ghinet, Sebastian

doi:10.3390/aerospace7050049

Cited by 19 publications

(15 citation statements)

References 15 publications

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“…This comprehensive study allowed to develop a numerical model for a simple flat plate and a better understanding and optimization of the actuators driving strategies in preparation for the design and instrumentation of an experimental piezoelectric-based de-icing system for small rotorcraft. The experimental setup designed is used in the next phase of the project to study transient vibration and frequency sweeps [22]. The numerical model is used in the third phase of the project by adding ice layers for numerical and experimental investigation of vibration-based de-icing [23], with the final objective of developing and integrating a piezoelectric actuator de-icing system to a rotorcraft blade structure.…”

Section: Discussionmentioning

confidence: 99%

“…The experimental tests were performed under the piezoelectric actuators excitation using sinusoidal signals at fixed frequencies to obtain steady-state mode deployment to compare with the numerical analysis results. The experimental results, given by the laser vibrometer software, present the upwards displacements in different shades of red, with lighter shades for higher magnitudes, and downwards displacements in different shades of green, also with lighter shades for higher magnitudes (see Figures 16,17,19,and 22). The operating voltage of the piezoelectric actuator was set to 200 Vpp, both experimentally and in the numerical model.…”

Section: Numerical Model Validationmentioning

confidence: 99%

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Numerical and Experimental Investigation of the Design of a Piezoelectric De-Icing System for Small Rotorcraft Part 1/3: Development of a Flat Plate Numerical Model with Experimental Validation

2020

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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 and develop a numerical model of the system with experimental validation, (2) use the experimental setup to investigate actuator activation with frequency sweeps and transient vibration analysis, (3) add ice layer to the numerical model and predict numerically stresses for different ice breaking with experimental validation, and (4) bring the concept to a blade structure for wind tunnel testing. This paper presents the first objective of this study. First, preliminary numerical analysis was performed to gain basic guidelines for the integration of piezoelectric actuators in a simple flat plate experimental setup for vibration-based de-icing investigation. The results of these simulations allowed to optimize the positioning of the actuators on the structure and the optimal phasing of the actuators for mode activation. A numerical model of the final setup was elaborated with the piezoelectric actuators optimally positioned on the plate and meshed with piezoelectric elements. A frequency analysis was performed to predict resonant frequencies and mode shapes, and multiple direct steady-state dynamic analyses were performed to predict displacements of the flat plate when excited with the actuators. In those steady-state dynamic analysis, electrical boundary conditions were applied to the actuators to excite the vibration of the plate. The setup was fabricated faithful to the numerical model at the laboratory with piezoelectric actuator patches bonded to a steel flat plate and large solid blocks used to mimic perfect clamped boundary condition. The experimental setup was brought at the National Research Council Canada (NRC) for testing with a laser vibrometer to validate the numerical results. The experimental results validated the model when the plate is optimally excited with an average of error of 20% and a maximal error obtained of 43%. However, when the plate was not efficiently excited for a mode, the prediction of the numerical data was less accurate. This was not a concern since the numerical model was developed to design and predict optimal excitation of structures for de-icing purpose. This study allowed to develop a numerical model of a simple flat plate and understand optimal phasing of the actuators. The experimental setup designed is used in the next phase of the project to study transient vibration and frequency sweeps. The numerical model is used in the third phase of the project by adding ice layers for investigation of vibration-based de-icing, with the final objective of developing and integrating a piezoelectric actuator de-icing system to a rotorcraft blade structure.

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Section: Discussionmentioning

confidence: 99%

Section: Numerical Model Validationmentioning

confidence: 99%

Numerical and Experimental Investigation of the Design of a Piezoelectric De-Icing System for Small Rotorcraft Part 1/3: Development of a Flat Plate Numerical Model with Experimental Validation

2020

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“…To study the initiation or propagation of ice fractures, it is necessary to have an approximate value of the cohesive tensile strength of the ice, of the adhesive shear strength of the ice with the substrate, and of the critical strain energy release rate. Although many experiments have been carried out to measure these values, there is a relatively wide range of ice strengths, and it is not easy to select a single value because ice strength depends on many factors: temperature [27][28][29], nature and roughness of the substrate [25], strain and strain rate [29,30], ice grain size [29], and flow speed [31]. Based on several articles [28,[32][33][34][35], the range of the ice tensile strength for fresh water is from [0.6-3] MPa, and the range of the ice adhesive shear strength for fresh water is from [0.2-1] MPa.…”

Section: Methodsmentioning

confidence: 99%

“…2). The ceramics were placed next to antinodes to get a high electromechanical coupling for these specific modes [25]. Another option would have been to place the ceramics in the middle of the sample where the stresses are also important.…”

Section: Ice Substratementioning

confidence: 99%

Electromechanical Resonant Ice Protection Systems: Energetic and Power Considerations

et al. 2021

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“…The present study represents an incremental improvement and complexification of previously presented experimental and Finite-Elements Analysis (FEA)-based numerical investigations where the principle of the proposed design method was demonstrated using a simple flat plate structure. The results of these experiments were published in [17][18][19], where a comprehensive literature study was presented, and the optimal integration and excitation of the actuators, the steady-state and transient vibration response and the stresses involved in icebreaking were extensively studied experimentally and numerically. In this new study, the developed and demonstrated concept was applied to a more complex structure, e.g., a rotating small-scale 22.9 cm (9 inches) long blade setup.…”

Section: Introductionmentioning

confidence: 99%

Experimental Study of a Piezoelectric De-Icing System Implemented to Rotorcraft Blades

2021

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A four-year project investigating the use of piezoelectric actuators as a vibration-based low power de-icing system has been initiated at the Anti-Icing Materials Laboratory. The work done preceding this investigation consisted of studying, numerically and experimentally, the system integration to a flat plate structure, the optimal excitation of the system, the resonant structural modes and the shear stress amplitudes to achieve de-icing for that structure. In this new investigation, the concepts and conclusions obtained on the flat plate structure were used to design and integrate the system into a rotating blade structure. An experimental setup was built for de-icing tests in rotation within an icing wind tunnel, and a finite-element numerical model adapted to the new geometry of the blade was developed based on the expertise accumulated using previous flat plate structure analysis. Complete de-icing of the structure was obtained in the wind tunnel using the developed de-icing system, and its power consumption was estimated. The power consumption was observed to be lower than the currently used electrothermal systems. The finite-elements numerical model was therefore used to study the case of a full-scale tail rotor blade and showed that the power reduction of the system could be significantly higher for a longer blade, confirming, therefore, the relevance of further de-icing investigations on a full-scale tail rotor.

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Numerical and Experimental Investigation of the Design of a Piezoelectric De-Icing System for Small Rotorcraft Part 2/3: Investigation of Transient Vibration during Frequency Sweeps and Optimal Piezoelectric Actuator Excitation

Cited by 19 publications

References 15 publications

Numerical and Experimental Investigation of the Design of a Piezoelectric De-Icing System for Small Rotorcraft Part 1/3: Development of a Flat Plate Numerical Model with Experimental Validation

Numerical and Experimental Investigation of the Design of a Piezoelectric De-Icing System for Small Rotorcraft Part 1/3: Development of a Flat Plate Numerical Model with Experimental Validation

Electromechanical Resonant Ice Protection Systems: Energetic and Power Considerations

Experimental Study of a Piezoelectric De-Icing System Implemented to Rotorcraft Blades

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