RU3563U1 - Injector Jet Mixer - Google Patents

Abstract

1. Injection jet mixer containing a mixing chamber, in the bottom end wall of which a hole for input of the first medium is made, and on the side wall is a hole for input of the second medium, and a homogenization chamber of the resulting mixture with an output nozzle, characterized in that it is equipped with an exit device the flow of the resulting mixture, including blades located in the outlet nozzle of the homogenization chamber, and the mixing chamber in the cross section is made in the form of a spiral. 2. The mixer according to claim 1, characterized in that the mixing chamber is made with an additional hole on the side wall for supplying a second medium. The mixer according to claim 1, characterized in that the inlet of the first medium is located along the axis of the mixing chamber.

Description

 BOIP 5/04

Injection jet mixer.

The utility model relates to devices for mixing liquid of one kind of fluid and can be used for treating wastewater for technical and domestic needs both on ships and on offshore drilling platforms, in the chemical industry for sintering alkaline carriers and other chemical solutions.

Known injector jet mixer containing a mixing chamber in the bottom of the tertiary wall with a hole located input passive medium / tar in the liquid state of aggregation /, and on its side wall holes are made for tangential inlet of the active medium. / air / and a homogenization chamber with an outlet nozzle having a perimeter window for the exit of the mixture. / Authors certificate ССС2 1113160, BOIF 5/04. 1984 /.

This mixer does not provide cost-effective mixing of two fluids with simultaneous heating due to the formation of a cavity of bubbles as a result of local decrease in extinction during hydrodynamic cavitation due to an increase in the speed of movement of the fluid.

Moving with the flow into the region with a higher pressure, the bubble closes, radiating a shock wave, which provides a local temperature increase.

The utility model is designed to expand technological capabilities by increasing the temperature of the mixture and dispersing one passive medium into another active medium.

In the end face wall of the mixing chamber; which in the cross section is made in the form of a spiral, a homogenization chamber, along the axis of the curtain there is an opening below the passive medium, and an outlet nozzle, between the windows of which there are vanes of the guide vane.

The practical implementation of the mixer, intended for thermooxidizing liquid-phase neutralizing wastewater with atmospheric oxygen, is presented in the attached drawings and in the detailed description,

Figure 1 shows a longitudinal section of a mixer.

W figure 2 - cross section of the mixing chamber along the cross-section aa of figure 1.

In this case, wastewater is an active medium, which is supplied by a pump under pressure, and air is a passive medium, because comes from the discharge.

The injection jet mixer / Fig. 1/ contains a flat mixing chamber 1, in the bottom end wall 2 of which there is an air inlet 3, and on the side wall 4 there is a hole 5 for the tangential supply of wastewater, a homogenization chamber 6, closed with a lint 7. Around the perimeter the side wall 8 of the chamber 6 has windows 9 made, the blades on the guide vanes are located between the meshes, forming a stitch for the outlet of the resulting mixture.

The boshovaya wall 4 of the chamber 1 in cross section / Fig.2/ has the shape of a spiral, uniformly tapering along the flow stream. The air inlet opening 3 is located along the axis of the homogenizing chamber 6.

The mixer works as follows.

Wastewater through the hole 5 in the battle wall 4 enters the chamber 1, creating a turbulent eddy movement in it. As a result of this, in the central part of the chamber 1 above the opening 3 there is a cavitation cavity in the curtain:; .-.: pressure below atmospheric is maintained. Air is drawn into chamber t and mixed with wastewater.

SoM, that in the cavitation cavity, the oxidation of organic impurities begins under local exposure to a higher temperature and pressure than the original components.

From the mixing chamber t, the mixture enters the homogenization chamber b, where the oxidation process is completed.

After passing through the chamber 6, the mixture flows out through the radially located side windows 9. This eliminates the occurrence of reactive lumbar, and therefore additional axial load on the structure.

This mixing can be increased due to additional openings of the taccentric supply of the active medium located in different W10 SPEEDS of the cross sections of the mixing chamber 1.

The mixer allows the oxidation process to proceed without the use of a separate heater and without a pump under high pressure.

Claims (3)

1. Injection jet mixer containing a mixing chamber, in the bottom end wall of which a hole for input of the first medium is made, and on the side wall is a hole for input of the second medium, and a homogenization chamber of the resulting mixture with an output nozzle, characterized in that it is equipped with an exit device the flow of the mixture, including blades located in the outlet nozzle of the homogenization chamber, and the mixing chamber in cross section is made in the form of a spiral.  2. The mixer according to claim 1, characterized in that the mixing chamber is made with an additional hole on the side wall for supplying a second medium.  3. The mixer according to claim 1, characterized in that the inlet of the first medium is located along the axis of the mixing chamber.