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Computer simulation of plate cooling by ionic wind from the wire electrode and its experimental verification. / Elagin, I.A.; Ashikhmin, I.A.; Samusenko, A.V.; Stishkov, Y.K.; Yakovlev, V.V.

2016 International conference on dielectrics. 2016. стр. 151-154.

Результаты исследований: Публикации в книгах, отчётах, сборниках, трудах конференцийстатья в сборнике материалов конференциинаучнаяРецензирование

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BibTeX

@inproceedings{57b9ee2269f043d88a63aedf7f61c3ef,
title = "Computer simulation of plate cooling by ionic wind from the wire electrode and its experimental verification",
abstract = "Computer simulation of ionic wind in the wire-plane electrode system is followed by its experimental verification. The complete set of equations for ionic wind is considered, with convective and conductive heat transfer in the air taken into account. Air velocity distributions are obtained using the Particle Image Velocimetry method. Flow patterns in simulation and experiment are similar. The main jet of ionic wind splits into two side streams after impacting the plate. The resulting drained thermal power due to ionic wind convection is up to 5 times greater than the heat power dissipated due to natural convection. The computed outgoing heat power is in good correspondence with experimental measurements.",
keywords = "Cooling, Corona discharge, EHD, Heat transfer, Ionic wind, PIV method, Plate, Wire",
author = "I.A. Elagin and I.A. Ashikhmin and A.V. Samusenko and Y.K. Stishkov and V.V. Yakovlev",
year = "2016",
doi = "10.1109/ICD.2016.7547566",
language = "English",
pages = "151--154",
booktitle = "2016 International conference on dielectrics",

}

RIS

TY - GEN

T1 - Computer simulation of plate cooling by ionic wind from the wire electrode and its experimental verification

AU - Elagin, I.A.

AU - Ashikhmin, I.A.

AU - Samusenko, A.V.

AU - Stishkov, Y.K.

AU - Yakovlev, V.V.

PY - 2016

Y1 - 2016

N2 - Computer simulation of ionic wind in the wire-plane electrode system is followed by its experimental verification. The complete set of equations for ionic wind is considered, with convective and conductive heat transfer in the air taken into account. Air velocity distributions are obtained using the Particle Image Velocimetry method. Flow patterns in simulation and experiment are similar. The main jet of ionic wind splits into two side streams after impacting the plate. The resulting drained thermal power due to ionic wind convection is up to 5 times greater than the heat power dissipated due to natural convection. The computed outgoing heat power is in good correspondence with experimental measurements.

AB - Computer simulation of ionic wind in the wire-plane electrode system is followed by its experimental verification. The complete set of equations for ionic wind is considered, with convective and conductive heat transfer in the air taken into account. Air velocity distributions are obtained using the Particle Image Velocimetry method. Flow patterns in simulation and experiment are similar. The main jet of ionic wind splits into two side streams after impacting the plate. The resulting drained thermal power due to ionic wind convection is up to 5 times greater than the heat power dissipated due to natural convection. The computed outgoing heat power is in good correspondence with experimental measurements.

KW - Cooling

KW - Corona discharge

KW - EHD

KW - Heat transfer

KW - Ionic wind

KW - PIV method

KW - Plate

KW - Wire

U2 - 10.1109/ICD.2016.7547566

DO - 10.1109/ICD.2016.7547566

M3 - Conference contribution

SP - 151

EP - 154

BT - 2016 International conference on dielectrics

ER -

ID: 7597153