SU971806A1 - Apparatus for purifying effluents - Google Patents

Description

The invention relates to installations for the purification of liquid media and can be applied, for example, for sewage treatment by flotation using electrocoagulation,

A device for wastewater treatment is known, comprising a collecting tank, electrocoagulators, flotation tanks, a filter, a foam collector, a piping system for connecting electrocoagulators, flotation cells, a filter 1.

However, this device is characterized by bulkiness, complexity in manufacturing and maintenance, and insufficiently high efficiency of wastewater treatment due to the fact that the effect of electroflotation (bubbling) is partially lost during the passage of fluid from electrocoagulators into the flotation tank.

The closest to the proposed technical essence and the achieved result is a device for wastewater treatment, including an inlet chamber with a damper grille, above which an electrocoagulant, a flotation cell and a sump box 12 are installed.

However, this device has large dimensions due to the significant volume of the flotation chamber, through which all the processed liquid passes. Due to the large surface of the liquid mirror in the flotation chamber, the thickness of the foam layer is insignificant, which complicates the process of foam removal and worsens cleaning performance due to

10, long-term accumulation of foam, which collapses, and contaminants adhering to gas bubbles are transferred to the treated liquid. In a recap. Of what's through the camera

15 the flotation undergoes a fully processed liquid and the volume of the chamber is considerable, the concentration of suspended solids, including flakes of metal hydroxides absorbing contamination, as well as the concentration of gas bubbles in the chamber, are small, which largely reduces the cleaning performance.

The purpose of the invention is to reduce the size of the device, increasing its

25 throughput and improving the quality of cleaning liquids

The goal is achieved by the fact that in the wastewater treatment device, which includes an inlet chamber with a quench grating, an electrocoagulator, a flotation cell and a sump, the flotation cell is equipped with an internal chamber with a conical perforated bottom and a filter and is made with a constriction at the top.

The image shows a cut; on the same top view

The wastewater treatment device contains a tank 1, which includes an inlet chamber 2, a damper lattice 3 with 4pH openings in which the electrode system 5 (electric coagulator) is located, a flotation chamber 6 with a foam container 7 and a device for blowing off the foam 8 and inside the flotation chamber 6 placed in communication with her camera 9, made with a tapered perforated perforated bottom filter 10.

Along the perimeter, the chamber 9 is provided with a tray 11 for collecting the cleaned / thinness with holes 12 in the wall.

The device is equipped with fittings 13 for supplying reagents, fitting 14 for discharging the cleaned liquid, fitting 15 for discharging foam, fitting 16 for supplying the cleaned fluid, supports 17 for installing the device on the foundation.

A device for wastewater treatment works as follows.

Electrode system 5 is supplied with power from a DC source. The processed fluid is supplied through the fitting 16 to the inlet chamber 2. Passage through the holes 4 of the quench grating 3, the stabilized flow of the treated fluid enters the interelectrode space of the electrode system 5, where it is subjected to electrical treatment. At the same time, the anodes dissolve with the formation of metal hydroxide and gas bubbles are released. The bulk of the liquid passes through the perforated bottom of chamber 9, which is made inclined, and the filter 10 attached to it, made, for example, of polystyrene, does not let suspended particles.

Another small volume of fluid passes into the flotation cell 6, where suspended solids and gas bubbles are carried along with the fluid flow.

Due to the sloping surface of the perforated bottom with the filter 10, suspended substances not passed by the filter, as well as gas bubbles rising directly to the surface of the filter, are easily removed by the flow of liquid washing the bottom of the chamber 9

Due to the small volume in the flotation cell 6, a high concentration of suspended substances is achieved, including the number of flakes of heavy metal hydroxides adsorbing on its

the surface of the abutmentable contamination liquid, and gas bubbles, which contributes to the intensive aggregation (adhesion) of particles and gas bubbles, their rapid ascent and the formation of a stable foam layer

Intensive foaming on the surface of the water mirror, and, therefore, the formation of a high and stable layer of foam is provided by the narrowing of the flotation chamber 6 in the upper part, significantly reducing the water mirror.

The removal of foam from the surface of the water is performed by a device for blowing off the foam 8, made in the form of an air duct with openings, into a foam container 7, through which the foam flows further to the fitting 15 to discharge the foam.

The liquid purified in the flotation cell through the opening 12 is poured into the tray 11, and the filtered liquid is drained from the inner container into the same tray. Purified liquid is discharged through fitting 14 attached to tray 11,

Reagents are supplied to the electrocoagulator to improve the flotation process or to give the treated liquid a neutral reaction.

This wastewater treatment unit with the same g-barite with the known has a high throughput due to the small volume of the flotation XAMERA 6 and allows to significantly improve the quality of purification by filtering the main amount of liquid, creating optimal conditions for flotation through the concentration of contaminants and gas bubbles, as well as through the formation of a high and stable foam layer.

Claims (1)

1. USSR Author's Certificate No. 372182, cl. C 02 C 5/12, 1970. 2, Yakovlev SV, Karelin Ya.A., Laskov Yu.M., Voronov .. Industrial wastewater treatment .M.CTpofizdat, 1979, p. 136-138, fig. 4.15 (prototype) S; fif. //