SU1730044A2 - Waste water treatment facility - Google Patents

Abstract

The invention relates to the treatment of waste water from heavy metal ions, suspended and emulsified impurities and other contaminants. The installation consists of a flotation chamber, made in the form of vertical perforated cylinders, equipped with sludge-collecting tubes having the same upper level, and a horizontal reaction chamber connected to the electrode chamber with soluble electrodes and a flotation chamber. The effluent is fed into the reaction tube through a special distributor with nozzles installed at the bottom of the reaction chamber. The dispenser waste is made in the form of a rod with nozzles placed on one side of the distributor and directed along the tangent to the circumference of the reaction tube. The unit is compact, easy to operate, and allows you to increase the degree of sewage treatment from chromium ions. 2 ill., 1 tab.

Description

The invention relates to the field of wastewater treatment from heavy metal ions, oils, suspended solids and other impurities, and can be used to purify contaminated aqueous solutions in engineering enterprises.

The aim of the invention is to increase the degree of wastewater treatment.

Figures 1 and 2 show a schematic diagram of the installation and its individual components.

The wastewater treatment plant consists of an electrode chamber 1 with soluble electrodes 2 connected to a horizontal reaction chamber 3, which enters a cylindrical body 4, in which a flotation chamber 5 with perforated cylinders 6 and conical devices 7 with sludge pipes 8 are placed. Cylindrical sludge pipes 8 exit at the same height in front of the suction inlet 9 of the ejector 10. The polystyrene foam loading 11 is between the flotation chamber and the housing 4 and is held by a perforated sheet 12. In the bottom of the housing 4 The cylinders are equipped with insoluble secondary purification electrodes 13 and an annular distributor 14 connected to a gearbox 15, a saturator 16, a compressed air supply nozzle 17 and a pump 18. Under the central cylinder 6 in the bottom of the body 4 a discharge pipe 19 is installed. the ejector 10, the suction pipe 9 of which is connected to an external cone device 7. Charges are set along the perimeter of the cylindrical body 4

annular tray 20. The cylinders 6 are perforated with perimeter holes, the placement of which along the cylinder height alternates - in the central cylinder in the upper part, in the next - in the lower part, later - in the upper chatsi, etc. The horizontal reaction tube 3 passes through the cylinders 6 and has openings which are located in the central cylinder. In the lower part of the reaction chamber 3, a dispenser 21 of wastewater is installed with a nozzle 22 for supplying wastewater for cleaning and conical nozzles 23 placed on one side of the dispenser.

The installation works as follows.

The waste water enters the reaction chamber 3 through the nozzle 22, and a part of the purified water is directed to the electrode chamber 1, in which the electrodes dissolve under the action of direct current

2i, coagulant (reductant-reducing agent) and fine gas bubbles are released. The coagulum reacts with the contaminants that are in the wastewater. In order to increase the efficiency of coagulum interaction and contamination, the wastewater is supplied to the reaction chamber by means of a dispenser 21 effluent. At the same time, the discharge of wastewater from the distributor 21 is carried out using nozzles 23 placed on one side of the distributor. This placement is most optimal, since rotational movement of the liquid in the reaction chamber is formed.

3 throughout its length. The speed of rotation of the fluid is increased by the nozzle 23, directed tangentially to the circumference of the reaction chamber.

The cleaning efficiency is significantly affected by the placement of the dispenser 21 effluent in the cross section of the reaction chamber 3. Testing the operation of the dispenser 21 effluent showed that its placement in the upper part of the reaction chamber 3 leads to the destruction of flotation complexes, since a significant part of metal hydroxides in horizontal movement in flo - The current chamber is in the form of flotation sludge at the top of the reaction tube. Placing the effluent dispenser 21 in the middle of the reaction chamber 3 improves the cleaning efficiency, but when treating wastewater with dissolved impurities, for example hexavalent chromium, a high dose of iron (II) is required. The most optimal placement of the distributor 21 effluent in the lower part of the reaction chamber 3.

In the central cylinder 6, the horizontal reaction tube 3 has a perforation through which the neutralized effluents enter the clarification. Non-floated impurities precipitate and through the pipe 19 discharge of sludge into the sludge tank. The floated impurities, large gas bubbles enter through the conical device 7 into the central collection tank 8, which is brought into the suction inlet 9 of the ejector 10. Partially clarified water enters the next perforated cylinder through the perforation in the side of the cylinder 6, diameter

which is more than the previous one. As a result, the velocity of the fluid flow decreases and flotation of smaller particles and gas bubbles occurs, which are collected by the next cone device 7 and discharged by a sludge collecting tube 8 into the suction inlet 9 of the ejector 10 ..

Thanks to the connection of conical devices with vertical slurry tanks

By tubes 8 directly to the suction inlet 9 of the ejector 10, the oiled contaminants cannot get into the water clarified by the previous purification stage. In addition, more

favorable conditions for compacting the flotation sludge and retaining it in the flow chamber 5, since the vertical sludge tubes 8 will be in the denser layers of the flotation sludge, keeping it in a dense state. This allows for improved cleaning efficiency.

Ungraded small particles of coagulum and contamination through perforations enter the bottom of the next cylinder 6, in which the ring distributor 14 is located. Ring distributor 14 is connected through a gearbox 15 with a saturator 16 into which a portion of the clarified liquid is transported

from collecting tray 20.

Compressed air also enters the saturator from the production network through fitting 17. In the saturator 16, an overpressure of 0.3 ... 0.4 MPa is created, under the influence of which a part of the air is dissolved in the liquid. Next, the gas-saturated liquid through the reducer 15, which reduces the pressure to atmospheric, enters the liquid distributor 14. As a result

The pressure is reduced from the liquid to the clarified effluent by micro gas bubbles that float the contaminants. Flotation slurry on the cone device 7 is fed to the slurry tube 8, and then

into the suction inlet 9 of the ejector 10 and hit the sludge trap.

The clarified effluent through the upper perforation enters the external cylinder 6, in the lower part of which insoluble electrodes 13 are installed, connected to a direct current source, insoluble electrodes 13 generate gas bubbles that reduce the concentration of suspended solids in water to 8 ... 25 mg / dm3 Floated contaminants through the cone 7 and the sludge pipe 9 enter the suction inlet 9 of the ejector 10.

The electroflotation-treated fluid is filtered through a layer of expanded polystyrene 11, which is held in the housing 4 with a perforated sheet 12.

The filtered water is collected in collection tray 20 and not recycled.

Primer p. Chromium-containing wastewater was treated with a total chromium concentration of 42 mg / dm3, pH 6.6, and a salinity of 1280 mg / dm3.

The current consumption in the electrode chamber is 850 C / dm3, the anodic current density is 180 A / m2. Current consumption on insoluble electrodes

0

five

0

five

200 C / dm, cathode current density of 200 A / m2.

The table shows the results of wastewater treatment, obtained in the known and proposed installation.

The proposed installation is compact, does not require additional equipment placement area, and allows for various technological operations for wastewater treatment. This makes it possible to increase the degree of purification and economic performance of the process.

Claims (1)

Invention Formula Installation for wastewater treatment by ed. St. No. 1701641, from the fact that, in order to increase the degree of purification, the chamber with soluble electrodes is connected to the flotation chamber by a horizontal reaction tube in the lower part of which a waste distributor is installed, made in the form of a rod with nozzles placed on one side of the distributor and directed by. tangent to the circumference of the reaction tube, in addition, the upper parts of the conical devices of the flotokamery are equipped with vertically arranged tubes, the ends of which are located at the same level. w : 15 17 Shigl