SU1125416A1 - Ejector - Google Patents

Abstract

EJECTOR containing a nozzle for supplying a passive medium, active nozzles installed around it and a mixing chamber with longitudinal grooves on the inner surface, the inlet section of each of which is located in the cutting plane of the active nozzle, the grooves and active nozzles at an angle to the axis of the mixing chamber, differing in that, in order to increase the ejection ratio, the grooves and have a variable width increasing towards the exit of the mixing chamber.

Description

This invention relates to ink jet apparatus.

A known ejector, comprising a housing with a central nozzle for supplying an active medium, a nozzle block, the nozzles of which are arranged around the nozzle obliquely to the axis of the ejector, the mixing chamber and the diffuser 1.

The disadvantage of this ejector is a low ejection coefficient.

Also known is an ejector containing a nozzle for supplying a passive medium, active nozzles mounted around it, and a mixing chamber with longitudinal grooves on the inner surface, the inlet section of each of which is placed in the cutting plane of the active nozzle, with the grooves and active nozzles at an angle to the axis of the mixing chamber 2 .

However, the presence of these grooves allows only a slight increase in the ejection coefficient.

The aim of the invention is to increase the ejection coefficient.

This goal is achieved by the fact that in an ejector containing a nozzle for supplying a passive medium, active nozzles and a mixing chamber with longitudinal slots on the inner surface are installed around it, the inlet section of each of which is located in the plane of the active nozzle section, and the grooves and active nozzles are angled to the axis of the mixing chamber, the grooves have a variable width increasing towards the exit of the mixing chamber.

FIG. 1 shows an ejector, longitudinal section; in fig. 2 shows the internal surface of the mixing chamber with the slots.

The ejector contains a nozzle 1 for supplying a passive medium, active nozzles 2 installed around it, and a mixing chamber 3 with longitudinal grooves 4 on the inner surface, the inlet section of each of which is located in the cutting plane of the active nozzle 2, and the grooves 4 and active nozzles 2 are angled to the axes of the mixing chamber 3, the grooves 4 have a variable ir, increasing towards the exit of the mixing chamber 3. To supply an active medium to the nozzles, there is a collector with an inlet

5 with a nozzle 6, the mixing chamber 3 ends with a diffuser 7.

The ejector works as follows. The active medium, supplied through the nozzle b to the collector 5, expires from the nozzles 2, ejecting a passive medium. The arrangement of the nozzles 2 and the grooves 4 at an angle to the axis of the ejector and the expanding shape of the grooves 4 allows to intensify the exchange of energy between the active jets and the passive flow and increase the ejection coefficient. Further

the mixture enters the diffuser 7, where it is braked and the potential energy increases.

Thus, the implementation of grooves with a variable width, increasing to the exit of the mixing chamber, allows to increase the ejection coefficient.

Claims (1)

An EJECTOR containing a passive medium supply pipe, active nozzles installed around it and a mixing chamber with longitudinal grooves on the inner surface, the input section of each of which is placed in the cut plane of the active nozzle, the grooves and active nozzles being angled to the axis of the mixing chamber, characterized in that, in order to increase the ejection coefficient, the grooves have a variable width, increasing towards the exit of the mixing chamber. 5S ω 7 / ρτ Figure 1 to Οι>