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A finite element model for temperature induced electrohydrodynamic pumping horizontal pipes

Journal Article · · J. Heat Transfer; (United States)
DOI:https://doi.org/10.1115/1.3246663· OSTI ID:6741633
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The electrohydrodynamic (EHD) pumping created by an axially traveling electric wave superimposed on a dielectric fluid with a transverse temperature field has abeen investigated using a finite element technique. Both forward wave (cooled wall) and backward wave (heated wall) modes of operation have been considered. The secondary flow generated by buoyancy effects in the cross section were included in the calculations. The driving effects of the traveling wave were calculated by assuming that only the average electric shear stress produced movement while the sinusoidally varying transient effects cancelled out. The results show that effective pumping can be achieved without the use of a grounding electrode along the axis of the tube but the design parameters have to be carefully selected. Increasing the diameter-to-wavelength ratios increases the velocities. The flow rate is maximum at an optimum frequency, about 0.8 Hz in our typical cases, but it drops off rather quickly as he frequency is either decreased or increased. The velocities were much less sensitive to heating/cooling rates (i.e., Rayleigh numbers) or changes in the magnitude of the electrical conductivity values. Although the pumping effect increases approximately as the square of the maximum applied electric potential, in practice, the electric gradients are limited by the dielectric strength of the fluid. The results indicate the EHD heat exchanger/pumps can be feasible alternatives to mechanical pumps in certain circumstances when dielectric liquids require both heat transfer and circulation.

Research Organization:
Bachtel Power Corporation, San Francisco, California 94101
OSTI ID:
6741633
Journal Information:
J. Heat Transfer; (United States), Journal Name: J. Heat Transfer; (United States) Vol. 106:1; ISSN JHTRA
Country of Publication:
United States
Language:
English

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Related Subjects

640440* -- Fluid Physics-- Electrohydrodynamics
75 CONDENSED MATTER PHYSICS
SUPERCONDUCTIVITY AND SUPERFLUIDITY
DIELECTRIC MATERIALS
ELECTRIC FIELDS
ELECTROHYDRODYNAMICS
FINITE ELEMENT METHOD
FLUID MECHANICS
HYDRODYNAMICS
MATERIALS
MECHANICS
NUMERICAL SOLUTION
PIPES
PUMPING
TRAVELLING WAVES