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Active Piezoelectric Vibration Control of Subscale Composite Fan Blades (2012)

Provenza, Andrew J. ; Min, James B. ; Choi, Benjamin B. ; [et al.]

In: CASI

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Publication Date: 2019-07-13

Description: No abstract available

Keywords: Composite Materials; Mechanical Engineering

Type: E-663220 , ASME Turbo Expo; Jun 11, 2012 - Jun 15, 2012; Copenhagen; Denmark

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Mechanical and Vibration Testing of Carbon Fiber Composite Material with Embedded Piezoelectric Sensors (2012)

Wilmoth, Nathan G. ; Kray, Nicholas ; Gemeinhardt, Gregory ; [et al.]

In: CASI

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Publication Date: 2019-07-13

Description: Piezoelectric materials have been proposed as a means of decreasing turbomachinery blade vibration either through a passive damping scheme, or as part of an active vibration control system. For polymer matrix fiber composite (PMFC) blades, the piezoelectric elements could be embedded within the blade material, protecting the brittle piezoceramic material from the airflow and from debris. Before implementation of a piezoelectric element within a PMFC blade, the effect on PMFC mechanical properties needs to be understood. This study attempts to determine how the inclusion of a packaged piezoelectric patch affects the material properties of the PMFC. Composite specimens with embedded piezoelectric patches were tested in four-point bending, short beam shear, and flatwise tension configurations. Results show that the embedded piezoelectric material does decrease the strength of the composite material, especially in flatwise tension, attributable to failure at the interface or within the piezoelectric element itself. In addition, the sensing properties of the post-cured embedded piezoelectric materials were tested, and performed as expected. The piezoelectric materials include a non-flexible patch incorporating solid piezoceramic material, and two flexible patch types incorporating piezoelectric fibers. The piezoceramic material used in these patches was Navy Type-II PZT.

Keywords: Composite Materials

Type: E-18172 , SPIE Smart Structures and Materials Conference; Mar 11, 2012 - Mar 15, 2012; San Diego, CA; United States

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Optimal Topology and Experimental Evaluation of Piezoelectric Materials for Actively Shunted General Electric Polymer Matrix Fiber Composite Blades (2012)

Choi, Benjamin B. ; Duffy, Kirsten ; Kray, Nicholas ; [et al.]

In: CASI

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Publication Date: 2019-07-13

Description: NASA Glenn Research Center, in collaboration with GE Aviation, has begun the development of a smart adaptive structure system with piezoelectric (PE) transducers to improve composite fan blade damping at resonances. Traditional resonant damping approaches may not be realistic for rotating frame applications such as engine blades. The limited space in which the blades reside in the engine makes it impossible to accommodate the circuit size required to implement passive resonant damping. Thus, a novel digital shunt scheme has been developed to replace the conventional electric passive shunt circuits. The digital shunt dissipates strain energy through the load resistor on a power amplifier. General Electric (GE) designed and fabricated a variety of polymer matrix fiber composite (PMFC) test specimens. Investigating the optimal topology of PE sensors and actuators for each test specimen has revealed the best PE transducer location for each target mode. Also a variety of flexible patches, which can conform to the blade surface, have been tested to identify the best performing PE patch. The active damping control achieved significant performance at target modes. This work has been highlighted by successful spin testing up to 5000 rpm of subscale GEnx composite blades in Glenn s Dynamic Spin Rig.

Keywords: Aircraft Design, Testing and Performance

Type: NASA/TM-2012-217631 , SPIE83452G , E-18220 , Smart Structures and Materials and Nondestructive Evaluation and Health Monitoring 2012; Mar 11, 2012 - Mar 15, 2012; San Diego, CA; United States

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Active Piezoelectric Vibration Control of Subscale Composite Fan Blades (2012)

Kray, Nicholas ; Min, James B. ; Duffy, Kirsten P. ; [et al.]

In: Other Sources

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Publication Date: 2019-07-13

Description: As part of the Fundamental Aeronautics program, researchers at NASA Glenn Research Center (GRC) are investigating new technologies supporting the development of lighter, quieter, and more efficient fans for turbomachinery applications. High performance fan blades designed to achieve such goals will be subjected to higher levels of aerodynamic excitations which could lead to more serious and complex vibration problems. Piezoelectric materials have been proposed as a means of decreasing engine blade vibration either through a passive damping scheme, or as part of an active vibration control system. For polymer matrix fiber composite blades, the piezoelectric elements could be embedded within the blade material, protecting the brittle piezoceramic material from the airflow and from debris. To investigate this idea, spin testing was performed on two General Electric Aviation (GE) subscale composite fan blades in the NASA GRC Dynamic Spin Rig Facility. The first bending mode (1B) was targeted for vibration control. Because these subscale blades are very thin, the piezoelectric material was surface-mounted on the blades. Three thin piezoelectric patches were applied to each blade two actuator patches and one small sensor patch. These flexible macro-fiber-composite patches were placed in a location of high resonant strain for the 1B mode. The blades were tested up to 5000 rpm, with patches used as sensors, as excitation for the blade, and as part of open- and closed-loop vibration control. Results show that with a single actuator patch, active vibration control causes the damping ratio to increase from a baseline of 0.3% critical damping to about 1.0% damping at 0 RPM. As the rotor speed approaches 5000 RPM, the actively controlled blade damping ratio decreases to about 0.5% damping. This occurs primarily because of centrifugal blade stiffening, and can be observed by the decrease in the generalized electromechanical coupling with rotor speed.

Keywords: Composite Materials

Type: GT 2012-68639 , E-18244 , ASME Turbo Expo 2012: Power for Land, Sea and Air (GT2012); Jun 11, 2012 - Jun 15, 2012; Copenhagen; Denmark

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Piezoelectric Vibration Damping Study for Rotating Composite Fan Blades (2012)

Min, James B. ; Duffy, Kirsten P. ; Kray, Nicholas ; [et al.]

In: CASI

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Publication Date: 2019-07-13

Description: Resonant vibrations of aircraft engine blades cause blade fatigue problems in engines, which can lead to thicker and aerodynamically lower performing blade designs, increasing engine weight, fuel burn, and maintenance costs. In order to mitigate undesirable blade vibration levels, active piezoelectric vibration control has been investigated, potentially enabling thinner blade designs for higher performing blades and minimizing blade fatigue problems. While the piezoelectric damping idea has been investigated by other researchers over the years, very little study has been done including rotational effects. The present study attempts to fill this void. The particular objectives of this study were: (a) to develop and analyze a multiphysics piezoelectric finite element composite blade model for harmonic forced vibration response analysis coupled with a tuned RLC circuit for rotating engine blade conditions, (b) to validate a numerical model with experimental test data, and (c) to achieve a cost-effective numerical modeling capability which enables simulation of rotating blades within the NASA Glenn Research Center (GRC) Dynamic Spin Rig Facility. A numerical and experimental study for rotating piezoelectric composite subscale fan blades was performed. It was also proved that the proposed numerical method is feasible and effective when applied to the rotating blade base excitation model. The experimental test and multiphysics finite element modeling technique described in this paper show that piezoelectric vibration damping can significantly reduce vibrations of aircraft engine composite fan blades.

Keywords: Structural Mechanics

Type: NASA/TM-2012-217648 , E-18326 , 2012 AIAA Structures Structural Dvnamics and Materials (SDM) Conference; Apr 23, 2012 - Apr 26, 2012; Honololo, HI; United States

Format: application/pdf

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