Dual-pin electrohydrodynamic generator driven by alternating current

Ion wind velocity at time 0.02 ms after switching the polarity of electrodes. [Display omitted] •Alternating current (AC) driven corona based air-flow generator using symmetrically arranged electrodes was studied.•When the AC frequency exceeds a threshold value, the electrode gap is less critical an...

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Bibliographic Details
Published in:Experimental thermal and fluid science 2018-10, Vol.97, p.290-295
Main Authors: Dau, Van Thanh, Dinh, Thien Xuan, Tran, Canh-Dung, Terebessy, Tibor, Bui, Tung Thanh
Format: Article
Language:English
Subjects:
AC generators
Air flow
Alternating current
Bipolar discharge
Circuit design
Configurations
Direct current
Electric fields
Electric potential
Electrodes
Electrohydrodynamics
Fluid mechanics
Generators
High voltage
High voltages
Impurities
Ion wind
Ions
Parallel pin
Robust design
Tips
Tolerances
Voltage
Wind power
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Summary:Ion wind velocity at time 0.02 ms after switching the polarity of electrodes. [Display omitted] •Alternating current (AC) driven corona based air-flow generator using symmetrically arranged electrodes was studied.•When the AC frequency exceeds a threshold value, the electrode gap is less critical and stronger ion wind is achieved.•The electric field is enhanced by AC driven system.•Transient simulation by OpenFOAM demonstrates the effect of space charge. We report a unique alternating current (AC) driven corona based air-flow generator using symmetrically arranged electrodes. Unlike the conventional configuration where one electrode generates charged ions moving towards the reference electrode, this configuration allows both negative and positive charges to simultaneously move away from the device and generate ion wind in parallel with the electrodes. In comparison with the direct current (DC) driven corona generator, the time oscillating AC field allows the device a better stabilization owing to the independence of ion wind strength from the inter-electrode spacing. Our results by both simulation and experiment showed that when the AC frequency exceeds a threshold value of 1100 Hz, the electric field at the electrode tips is determined dominantly by the charge cloud created in the previous half-cycle, resulting in stronger net electric field and thus stronger ion wind. In addition, the electrode separation in the AC driven corona based generator is less critical above the frequency threshold, yielding a more robust design with minimized susceptibility to manufacturing tolerances and impurities on the electrodes. Moreover, lower voltage levels of the AC driven system allow simpler and more economical design in the high voltage circuit of the AC generator.
ISSN:0894-1777
1879-2286
DOI:10.1016/j.expthermflusci.2018.04.028