SU1458326A1 - Cavitation aerator - Google Patents

Abstract

The invention relates to a device for dissolving gases in liquids, i.e. air oxygen in water. The purpose of the invention is to increase: productivity. The cavitation aerator contains a main rotor 10, made of two disks 11 and 12 with blades 13 between them, a hollow shaft 7 with longitudinal holes 8 for air supply and a pipe 3 located coaxial to the shaft. The cavitation aerator is equipped with an additional reactive ring rotor that is in the form of a Segner wheel, consisting of a casing, inside which are placed blades connected at the top and bottom of nmTHNra, and at the end of the shields are connected to the sidewall, and there is a gap between the side and peripheral ends of the blades and Wine contains outlets, counters combined with the casing sleeve, fitted on the hollow shaft with the ability to interact with the blade and the rotor blades through the working zazor.2 yl. and sl

Description

The invention relates to a device for dissolving gases in a liquid, namely oxygen, during biological treatment or after-treatment of wastewater.

The aim of the invention is to increase the productivity of cavitation aerator by creating increasing hydrodynamic vibrations of the treated fluid and the mixing action of the rotor.

Figure 1 shows a cavitation aerator, General view; in FIG. 2 - section aa in figure 1.

The cavitation aerator comprises a drive 1 with a support plate 2, an outer pipe 3 connected to a flange 4 and an intake pipe 5., a holder 6, a hollow shaft 7 with longitudinal holes 8, an oil seal 9, a main rotor 10 with upper 11 and lower 12 disks and blades 13 in between. On the upper 11 and lower 12 disks of the main rotor 10, respectively, arcuate blades 14 and 15 are fixed. Outside the main rotor 10 there is an additional reactive annular rotor 16 in the form of a Segner wheel, consisting of a casing 17 with blades 18 connected to each other by the upper 19 and lower 20 shields and a sidewall 21 with outlet openings 22. The jet ring rotor 16 is connected through a strut 23 to a sleeve 24 freely mounted on a hollow shaft 7 and locked up by a thrust ring 25 with a locking screw 26. Between the blades 13 of the rotor 10 and blades 18 of the rotor 16, the annular jet has a working gap 27.

Cavitation aerator works as follows.

When the drive 1 is turned on, the hollow shaft 7 rotates with the main rotor 10, through the intake pipe 5 and the longitudinal holes 8, air enters the main rotor 10, which throws it between the upper 11 and lower 12 disks. Arcuate blades 14 and 15, respectively placed on the upper 11 and lower 12 disks of the main rotor 10, capture liquid at the ends of the main rotor 10, send it to the blades 13 of the main rotor 10 and then pump it inside the casing 17. Moreover, they together with the blades 13 interact with the blades 18 of the reactive annular rotor 16, creating increasing hydrodynamic oscillations and crushing of air bubbles that enhance cavitation. The streams of 10 oxygen-enriched air coming out of the outlet openings 22 are discarded to the periphery, creating a mixing effect of the treated water in the structure. These flows of water-air mixture lead 15 casing 17 in motion, opposite to the rotation of the main rotrra 10.

This technical solution increases the productivity of the cavitation aerator by creating increasing hydrodynamic vibrations of the liquid being treated and the mixing action of the jets emanating from the jet ring rotor. The performance of the proposed 25 cavitation aerator is increased by 25-35% compared with the known ones.

Claims (1)

Claim A cavitation aerator comprising a rotor made of two disks with blades between them, arched blades located on the upper and lower disks of the rotor, a hollow shaft with longitudinal holes for air supply and a pipe located coaxially to the shaft, characterized in that, in order to increase productivity cavitation aerator by creating increasing hydrodynamic vibrations of the processed fluid and the mixing action of the rotor, it is equipped with an additional reactive ring rotor in the form of Setnerov’s ring and, consisting of two shields, fastened at the end by a sidewall, with blades placed inside the casing and connected by shields above and below, a sleeve worn on the hollow shaft with the possibility of rotation around the vertical axis, racks connecting the casing with the sleeve, while between the sidewall and There is no clearance at the peripheral ends of the blades55, and the sidewall contains outlet openings. ΑΆ