RU29248U1 - Hydrocyclone microflotator - Google Patents

Description

This is achieved by the fact that in the known hydrocyclone microflotator containing a cylindrical conical body with a tangential inlet pipe, a condensate discharge pipe and a concentrically mounted cyclone separator with a central pipe, and a light fraction and purified water discharge pipes, according to a utility model, a cavitator is connected to the inlet pipe through a diffuser -mixer, to which the pipeline for supplying gas containing oxygen is connected, and the cavitator-mixer is made in the form of a closed chamber, in which the second end of the central pipe with an axial clearance relative to the upper bottom of the cyclone separator is located.

In this case, a tangentially connected coagulant supply pipe is connected to the housing.

In addition, the oxygen-containing gas supply line is connected to the atmosphere or to the ozonizer outlet.

In FIG. 1 shows a sectional hydrocyclone-microflotator, and FIG. 2 section A - A of a hydrocyclone-flotator.

The hydrocyclone microflotator contains a vertically arranged cylinder-shaped housing 1 with a solid sludge outlet pipe 2. A cyclone separator 3 connected to the body 1 is made in the form of a closed chamber with nozzles for the removal of sludge 4 and purified water 5 through a receiving chamber 6. To the housing 1

the inlet pipe 7 is tangentially connected to which the cavitort RchSolROb “A, 9 is connected. MISCELLANEOUS and mixer b. To the cavitator-mixer about connecting 1 pipe 10, in communication with

the atmosphere. The cavities of the housing 1 and the cyclone-separator 3 are communicated by a central pipe 11 mounted with an axial clearance relative to the upper bottom of the cyclone-separator 3. In addition, the coagulant supply pipe 12 is tangentially connected to the housing 1.

Hydrocyclone-microflotator during the treatment of oily wastewater works as follows.

Wastewater with the oil products contained in it flows under pressure to the inlet of the cavitator-mix. For S, where it is accelerated, creating a vacuum in the pipeline 10 through which atmospheric air is sucked into the cavity of the cavitator-mixer 8. Due to the process of mixing gas with liquid in the field of intense pressure pulsations with a frequency close to ultrasonic, a high rate of gas dissolution and chemical reactions of the oxidation of impurities are ensured. At the same time, a significant part of under-oxidized and dissolved: impurities goes into a solid state with a particle density greater or less than the density of water. Further

microflotator, where due to a sharp decrease in static pressure and large shear stresses in the paraxial zone of the vortex flow, intense dissolution of dissolved gas occurs in the form of tiny bubbles (microflotation effect). In this case, solid heavy particles under the action of centrifugal forces move to the periphery of the vortex flow, descend along the conical wall of the housing 1 and are discharged through the nozzle 3 from the hydrocyclone-microflotator. Gas bubbles with trapped (including dissolved) impurities together with a vortex stream of purified water through the central pipe 11 enter the cyclone separator 3, from which flotation sludge (foam with oil impurities) is discharged through the pipe 4, and the purified water into the receiving chamber 6 and further through pipe 5 for use. Depending on the composition of the impurities in the treated wastewater, a coagulant corresponding to them is supplied through the nozzle 12 to the housing 1 to transfer the impurities to a solid state.

Thus, the combination of two functions and two cleaning effects in the claimed hydrocyclone microflotator: centrifugal separation of phases with different densities and the removal of dissolved and unoxidized impurities by flotation, improves the efficiency and quality of wastewater treatment from oil and grease products.

As a result of the fact that microflotation is carried out in the field of centrifugal forces, several orders of magnitude greater than the acceleration of gravity, this allows us to reduce the overall dimensions of the hydrocyclone-microflotator in comparison with the known flotation units.

Claims (4)

1. Hydrocyclone-microflotator containing a cylindrical conical housing with a tangential inlet pipe, a condensate discharge pipe and a concentrically installed cyclone separator with a central pipe, and a light fraction pipe and purified water discharge pipes, characterized in that a cavitator-mixer is connected to the inlet pipe through a diffuser to which the oxygen-containing gas supply pipeline is connected, and the cavitator-mixer is made in the form of a closed chamber in which the second end of the central pipe with sowing clearance relative to the upper bottom of the cyclone-separator. 2. The hydrocyclone according to claim 1, characterized in that the coagulant supply pipe is tangentially connected to the housing. 3. The hydrocyclone according to claim 1, characterized in that the pipeline for supplying gas containing oxygen is connected to the atmosphere. 4. The hydrocyclone according to claim 1, characterized in that the pipeline for supplying gas containing oxygen is connected to the outlet of the ozonizer.