RU2229926C1 - Double chamber jet-type aerator - Google Patents

Abstract

FIELD: production of gas-liquid mixtures in different fields of engineering. SUBSTANCE: the invention presents a double-chamber jet-type aerator pertinent to the fields of mixing engineering, that may be used for purification of polluted runoffs, production of gas-liquid mixes in different fields of engineering, in particular at production of bitumens or fish protection systems. The double-chamber jet-type aerator contains a cylindrical collector and an air supply channel with, at least, one inlet aperture. The collector is made with the apertures uniformly spaced along generatrix. The air channel is made in the form of a U-shape profile with the outlet apertures uniformly located along the base placed on the surface of the collector. Apertures of the collecting channel are in the cavity of the air channel. Technical result: expansion of sphere of application of the double-chamber jet-type aerator due to creation of a stream of a gas-liquid mixture elongated in a direction perpendicular to the axes of the collector and formation of the even elongated streams of a gas-liquid mixtures. EFFECT: the invention allows to form the even elongated streams of a gas-liquid mixtures. 7 cl, 2 dwg, 1 tbl

Description

The invention relates to the field of mixing technology and can be used to clean contaminated effluents, to obtain gas-liquid mixtures in various fields of technology, in particular in the production of bitumen or fish protection devices.

Known ejector aerator containing a pump, the output of which is connected to an outlet pipe made with an external conical axial nozzle forming with the outlet pipe the first air intake pipe (see RF patent No. 2142433 C1, class C 02 F 3/22, publ. 10.19. 99).

The disadvantage of this device is the low mixing efficiency (primarily due to the fact that large air bubbles about 1-2 mm in size fall into the liquid), as well as the inability to control the air flow over a wide range, which is due to both the air supply to the pipe, and a jet method of supplying a water-air mixture to a liquid medium.

Known aerators with several chambers or a chamber and a dispersant in which compressed air is supplied to the chamber (see RF patent No. 2189364, C 02 F 3/08, 7.3.2000 and RF patent No. 2112753, C 02 F 3/20, 2.5. 1998).

The disadvantages of such devices include low efficiency due to the low kinetic energy of the jets and the ability to form only large air bubbles.

Closest to the proposed is a two-chamber jet aerator containing a manifold in the form of a cylindrical body with a nozzle for liquid (first chamber), an air channel in the form of a nozzle with an inlet (second chamber) and an exhaust nozzle (see RF patent No. 2187381, C 02 F 3/18, 6.4.2001).

The disadvantage of this device is the inability to create a stream extended in the direction perpendicular to the axis of the collector, as well as to control the size of the bubbles and the total air content in the water-air mixture. This limits the possibility of using the known aerator to create long and uniform flows of the air-water mixture with a given air content and bubble size, which is extremely important for applications in the field of wastewater treatment and fish protection devices.

Thus, the technical result expected from the use of the invention is to expand the scope of application of the two-chamber aerator by creating a gas-liquid mixture stream, extended in the direction perpendicular to the axis of the collector, to obtain uniform extended flows of the gas-liquid mixture. An additional result is the control of the size of the bubbles and the total air content in the mixture.

This result is achieved by the fact that in the known two-chamber jet aerator containing a cylindrical collector and an air channel with at least one inlet, the collector is made with holes uniformly spaced along the generatrix, and the air channel is made in the form of a U-shaped profile with outlet openings evenly spaced along the base located on the surface of the manifold, the manifold openings being located in the cavity of the air channel.

In addition, the aerator can be equipped with an input source of water-air pulp.

In addition, the collector may be made open.

In this case, the inlets of the air channel can be made with flow controllers.

In addition, the openings of the air channel can be located on the axis of the openings of the manifold.

Moreover, the edges of the openings of the air channel can be located on straight lines passing through the edges of the holes of the collector and intersecting on the axis of symmetry of the collector in its cavity.

In particular, the ratio of the radii of the holes of the collector and the air channel can lie in the range from 2.8 to 1.9.

Figure 1 shows a cross section of a two-chamber aerator, figure 2 is a General view of the aerator with an input source of water-air pulp.

The two-chamber jet aerator contains a perforated cylindrical manifold 1 with holes 2 (Fig. 1), an air channel 3 with exhaust holes 4, made in the form of a U-shaped profile. At the inlet 5 of the air channel 3 (Fig.2) installed flow regulator 6. As shown in FIG. 2, holes 2 and 4 are aligned. At the inlet of the aerator, an input source 7 of air-water pulp and a pump 8 are installed. In the working state, the cavity of the collector 1 is filled with liquid or a finely dispersed gas-liquid pulp (emulsion) 9, which enters the inlet of the aerator. The jet 10 of the pulp 9 is surrounded by a coarser gas-liquid mixture 11. The base of the air channel 3 is indicated by 12 (Fig. 1).

The dotted line in figure 1 shows the straight lines intersecting on the axis of symmetry of the collector 1 and passing through the upper edges of the holes 2, 4. The ratio of the diameter of the holes 4 to the diameter of the holes 2 is in the range from 2.8 to 1.9.

As the input source 7 of the water-air pulp, any aerator can be used, for example, known by application No. 2000129745/12 (031730) of 11.29.2000 or by RF patent No. 2187381, C 02 F 3/18, 6.4.2001.

The device operates as follows. In the initial state, the cavity of the collector 1 (first chamber) and the air channel 3 (second chamber) are filled with water. When the pump 8 is turned on, the liquid or water-air pulp formed by the input source 7 of the water-air pulp enters the cavity of the housing 1 and is forced through the holes (nozzles) 2, 4, entraining the liquid located in the cavity of the air channel 3. At the same time, it forms in the cavity of the air channel 3 vacuum and it is filled with air through the hole (s) 5 located in the inoperative zone of the collector 1.

The suction of air during the passage of the jet 10 through the hole 4 leads to the formation of a mixture of 11 along the periphery of the jet 10. Moreover, the gas-filled air channel 3, being located above the outlet openings 2, provides a high degree of uniformity of flows from the holes (nozzles) 4 around the perimeter of the collector 1, and the regulator 6, made, for example, in the form of a diaphragm, allows you to vary within wide limits the air content in the pulp and the size of the air bubbles.

The specified result was confirmed by tests, the results of which are presented in the table.

Thus, the proposed aerator allows not only to efficiently aerate liquids, but also to create a uniform and controllable in such essential parameters as the output energy of the jet, the size of the gas bubbles and gas flow, the flow of gas-liquid mixture.

Claims (7)

1. Two-chamber jet aerator containing a cylindrical manifold and an air channel with at least one inlet, characterized in that the collector is made with holes uniformly spaced along the generatrix, and the air channel is made in the form of a U-shaped profile with outlet openings, evenly spaced along the base located on the surface of the collector, and the holes of the collector are placed in the cavity of the air channel. 2. Two-chamber jet aerator according to claim 1, characterized in that it is equipped with an input source of water-air pulp. 3. The two-chamber jet aerator according to claim 1, characterized in that the collector is made open. 4. Two-chamber jet aerator according to claim 1, characterized in that the inlets of the air channel are made with flow controllers. 5. Two-chamber jet aerator according to claim 1, characterized in that the openings of the air channel are located on the axis of the openings of the collector. 6. The two-chamber jet aerator according to claim 1, characterized in that the edges of the holes of the air channel are located on straight lines passing through the edges of the holes of the collector and intersecting on the axis of symmetry of the collector in its cavity. 7. The two-chamber jet aerator according to claim 1, characterized in that the ratio of the radii of the holes of the collector and the air channel lies in the range of 2.8-1.9.

Images