SU1110945A1 - Jet pump - Google Patents

Abstract

JET PUMP containing active nozzle and successively located non-return valve and electrodes connected to a high-voltage pulse discharge source, characterized in that, in order to increase efficiency, the non-return valve and the internal active nozzle surface adjacent to it have the shape of a paraboloid of rotation, and The electrodes are located in a plane passing through its focus perpendicular to the axis of the nozzle.

Description

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The invention relates to inkjet technology.

A jet pump is known that contains an active sonlo and electrodes located in it that are connected to a high-voltage pulse discharge source 1.

However, this jet pump has a relatively low productivity and is laborious to manufacture.

The closest to the invention in terms of its technical essence and the achieved result is a jet pump containing an active nozzle and successively located in it a check valve and electrodes connected to a high-voltage pulse discharge source 2.

The known jet pump has a relatively low efficiency, which is due to the incomplete use of high-voltage pulse discharge energy due to the energy losses that occur in the nozzle due to the non-optimality of its shape.

The aim of the invention is to increase the efficiency.

This goal is achieved by the fact that in the jet pump containing an active nozzle and successively located in it a check valve and electrodes connected to a high-voltage pulse discharge source, the check valve and the adjacent inner surface of the active nozzle have the shape of a paraboloid of rotation, and the electrodes are located in the plane passing through its focus lepneH dikarno axis of the nozzle.

The drawing shows the proposed jet pump, a longitudinal section.

The jet pump contains an active nozzle I and successively located in it a check valve 2 and electrodes 3 connected to the source 4 of a high-voltage pulse discharge. The check valve 2 and the inner surface of the active nozzle 1 adjoining it have the shape of a paraboloid of rotation, and the electrodes 3 are located B plane passing through its focus perpendicular to the axis of the nozzle 1.

The active medium enters the nozzle 1 through the check valve 2 and, having flowed out of the active nozzle 1, carries the pumped medium to the pump. Periodically, when current pulses are applied from source 4 to electrodes 3, a high-voltage discharge occurs between them, which is the center of formation of a shock wave, from which the valve 2 closes and serves as a reflector and opens in the rarefaction zone of the shock wave, which causes pulsed emissions of the active medium from the nozzle 1.

The implementation of the check valve and the adjacent inner surface of the active nozzle 1 in the form of a paraboloid of rotation and the location of the electrodes 3 of the high-voltage pulse discharge in the plane passing through its focus, causes it to be reflected from the check valve 2

 directional shock wave, formed and propagated according to the principle of quasi-impulsive charge. The energy of the shock wave is concentrated in one direction, which increases the pressure of the active jet.

In this way, by performing a non-return valve and an adjacent inner surface of the active nozzle in the form of a paraboloid of rotation and positioning the electrodes in a plane passing through its focus, an increase in energy is achieved.

5 of the active medium, and hence the efficiency of the jet pump.

Claims (1)

A JET PUMP containing an active nozzle and a check valve and electrodes sequentially located in it and connected to a source of high voltage pulse discharge, characterized in that, in order to increase the efficiency, the check valve and the inner surface of the active nozzle adjacent to it have the shape of a rotation paraboloid, and the electrodes located in a plane passing through its focus perpendicular to the axis of the nozzle. >