SU1019113A1 - Fluidic pump - Google Patents

Abstract

JET HACOG, containing an active nozzle with an outlet, a mixing chamber, made in the form of channels B, a cylindrical rotor installed with the possibility of free rotation, and a diffuser, characterized in that, in order to increase efficiency, the active nozzle has the shape of an annular segment and is provided with end partitions , limiting its outlet, and the channels in the rotor are made in a spiral. (L 1 Figure 1 co oo

Description

The invention relates to inkjet technology.

The closest to the proposed technical essence and the achieved result is a jet pump containing an active nozzle with an outlet, a mixing chamber made in the form of channels in a cylindrical rotor installed with the possibility of free rotation, and a diffuser [1].

However, the known jet pump has a relatively low efficiency, which is associated with energy losses during the mixing of active and passive media.

The aim of the invention is to increase the efficiency of the jet pump.

This goal is achieved by the fact that for a jet pump containing an active nozzle with an outlet, a mixing chamber made in the form of channels in a cylindrical rotor mounted with the possibility of free rotation and a diffuser, the active nozzle has the shape of an annular segment and is equipped with end walls that limit its output hole, and the channels in the rotor are made in a spiral.

In FIG. 1 shows the proposed jet pump, a longitudinal section; in FIG. 2 — section A — A in FIG. 1.

The jet pump contains an active nozzle 1 with an outlet 2, a mixing chamber made in the form of channels 3 in a cylindrical rotor 4, mounted with 30 free rotation, and a diffuser 5. The active nozzle 1 has the shape of an annular segment and is equipped with end walls 6 restricting it the outlet 2, and the channels 3 in the rotor 4 are made in a spiral.

The pump operates as follows.

The active gaseous medium, flowing out of the nozzle 1, enters one of the channels 3 of the mixing chamber located at ⁵ against the outlet 2. As a result of the movement along the channel 3, made in a spiral, the rotor comes into rotation and the input of the channel 3 is shifted relative to the outlet 2 of the nozzle 1. When the active medium moves along the channel 3, a vacuum forms at the entrance to it and a passive medium enters the channel. Further, during the rotation of the rotor 4, this channel 3 again falls opposite the outlet 2 of the nozzle 1 15 and a new portion of the active medium pushes out a portion of the gas already existing in the channel. In diffuser 5, the kinetic energy of the flow is partially converted into potential energy. In other channels of the mixing chamber, similar processes take place. The presence of end walls 6 in the active nozzle 1 having the shape of an annular segment with an opening angle of the latter exceeding the opening angle of the mixing chamber channel 3 prevents the ejection process 25 in the interchannel space during rotation of the rotor 4 relative to the nozzle 1.

Thus, by performing an active nozzle having the shape of an annular segment with end walls restricting its outlet, and executing the channels of the mixing chamber in a spiral, a reduction in impact energy losses and, therefore, an increase in the efficiency of the jet pump is achieved.

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Figure 2

Claims (1)

A JET PUMP containing an active nozzle with an outlet, a mixing chamber made in the form of channels in a cylindrical rotor mounted for free rotation, and a diffuser, characterized in that, in order to increase the efficiency, the active nozzle has the shape of an annular segment and is equipped with end partitions, limiting its outlet, and the channels in the rotor are made in a spiral. with