Experimental and numerical studies of synthetic jets driven by a dual-diaphragm piezoelectric actuator

Yang, A-S; Ro, J-J; Wh, Chang

doi:10.1243/09544062jmes1272

Cited by 3 publications

(1 citation statement)

References 18 publications

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“…Synthetic jet actuators (SJAs) have been applied in various fields including flow separation control, jet vector maneuvering, virtual aeroshaping and enhancement of mixing/heat transfer [1][2][3][4][5][6][7][8]. In effect, the SJA is a zero-net-mass-flux fluidic device for active flow separation control without need of a tank and plumbing system.…”

Section: Introductionmentioning

confidence: 99%

Study of a Crossflow over a Zero-Net-Mass-Flux Synthetic Jet Driven by a Vibrating Diaphragm

2011

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Miniature synthetic jet actuators are low operating power, zero-net-mass-flux and very compact devices which have demonstrated their capability in modifying the subsonic flow characteristics for boundary layer flow control. In order to improve the design active flow control systems, the present study aims to examine the formation and interaction of unsteady flowfield of a synthetic jet with external crossflow. In view of a single synthetic jet emitting into a turbulent boundary layer crossflow via a circular orifice, the theoretical model utilized the transient three-dimensional conservation equations of mass and momentum for compressible, turbulent flows with a negligible temperature variation over the computational domain. The motion of a movable membrane plate was also treated as the moving boundary by prescribing the displacement on the plate surface. The predictions by the computational fluid dynamics (CFD) software ACE ® were compared with the measured transient phase-averaged velocities in literature for code validation. The predictions showed the time evolution of the large vortical structure originating from the jet orifice and its successive interaction with the crossflow to change the flow structure inside the boundary layer.

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Section: Introductionmentioning

confidence: 99%

Study of a Crossflow over a Zero-Net-Mass-Flux Synthetic Jet Driven by a Vibrating Diaphragm

2011

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High-speed air microjet arrays produced using acoustic streaming for micro propulsion

Yee

Peterson

Bernal

et al. 2013

2013 Transducers &Amp; Eurosensors XXVII: The 17th International Conference on Solid-State Sensors, Actuators and Microsystems

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Characterization of Impingement Heat/Mass Transfer to the Synthetic Jet Generated by a Biomimetic Actuator

Trávníček

Broučková

2019

Journal of Heat Transfer

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Two biomimetic synthetic jet (SJ) actuators were designed, manufactured, and tested under conditions of a jet impingement onto a wall. Nozzles of the actuators were formed by a flexible diaphragm rim, the working fluid was air, and the operating frequencies were chosen near the resonance at 65 Hz and 69 Hz. Four experimental methods were used: phase-locked visualization of the oscillating nozzle lips, jet momentum flux measurement using a precision scale, hot-wire anemometry, and mass transfer measurement using the naphthalene sublimation technique. The results demonstrated possibilities of the proposed actuators to cause a desired heat/mass transfer distribution on the exposed wall. It was concluded that the heat/mass transfer rate was commensurable with a conventional continuous impinging jets (IJs) at the same Reynolds numbers.

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Experimental and numerical studies of synthetic jets driven by a dual-diaphragm piezoelectric actuator

Cited by 3 publications

References 18 publications

Study of a Crossflow over a Zero-Net-Mass-Flux Synthetic Jet Driven by a Vibrating Diaphragm

Study of a Crossflow over a Zero-Net-Mass-Flux Synthetic Jet Driven by a Vibrating Diaphragm

High-speed air microjet arrays produced using acoustic streaming for micro propulsion

Characterization of Impingement Heat/Mass Transfer to the Synthetic Jet Generated by a Biomimetic Actuator

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