SU804576A1 - Device for biological purification of waste liquid - Google Patents

Description

The invention relates to the biological treatment of wastewater and can be used at wastewater treatment plants in order to protect water resources from pollution.

A device for the biological treatment of wastewater, containing a reservoir and mounted on a shaft with a drive semi-loaded hard drive [1].

However, the known device does not provide effective wastewater treatment, since the mass transfer process is limited by a small surface · 5 biofilms. ·

The purpose of the invention is to increase the cleaning efficiency due to the intensification of mass transfer. 20

This goal is achieved by the fact that the device is equipped with conical shape rolls * 5 with radial spacing on both sides of the disk at an angle of 45 * to the horizontal, with a device for changing the distance between them, and the disk is made with holes and provided with a coating of elastic material with an open-porous structure. 3®

Figure 1 shows the proposed device, a longitudinal section; figure 2 is a section aa in figure 1; on figs - a device for mounting and changing the distance between the squeeze rolls; figure 4 -. placement of squeeze rolls with offset, side view; figure 5 is the same end view; in Fig.6 - a disk with round holes of the same diameter; in Fig.7 - a disk with holes, the diameter of which increases from the center to the periphery; on Fig - disk with holes in the form of radial slots) in Fig.9 - Disk with holes in the form of concentric slots; 10,11 and 12 - options for placing disks in the tank, plan view; in Fig.13 the reservoir, combined with the sump; on Fig - tray with a separate settling tank "*, a longitudinal section.

In the tank 1 on the shaft 2, connected with the power drive 3, a semi-submerged hard disk 4 is fixed, the surface of which is covered with a layer 5 of elastic material with an open-porous structure, for example, a layer of polyurethane foam. 1'a shaft 2 is installed upper squeeze rolls 6 and lower squeeze rolls 1, interacting with a layer 5 of elastic material. Rolls b and 7 are spring-loaded and installed at an angle of 45 ° to the horizontal and with the possibility of changing the distance between them, which determines the degree of elastic material. The hard disk 4 has holes 8. Moreover, if the holes are round, their diameter is determined from the relation d £ ₌ hd ₂ 1 ₂ 'and the axes of each pair of squeeze rolls are offset by an angle d. which is determined from the relation barest η; ₁₅ where and d ₂ are the diameters of the holes located from the axis of the disk at a distance of respectively Ts and.

In addition, the holes can be made in the form of radial or con- centric slots.

To supply the original waste fluid *, there is a pipe 9, to discharge the purified liquid - pipe 10. The sump 11 is designed to further clarify the biologically purified waste fluid.

Disks can be placed perpendicular to the general direction of movement of the waste fluid in the tank 1 from the falling pipe 9 to the outlet pipe 30 (Figs. 1, 2, 10 and 11), and in parallel (Figs. 12-14).

The device operates as follows. _χ

When the electric drive 3 35 is turned on, the shaft 2 and the disk 4 are driven, the elastic material layer 5 on the surface of which is in contact with the waste fluid supplied to the reservoir 1 through the nozzle 9. Microorganisms develop in the pore space of the elastic material, which are extracted from the waste fluid and oxide contaminants.

When the disk 4 leaves the liquid, the elastic material is partially squeezed out by the upper rollers 6, and air, which is the source of oxygen for the biooxidation process, penetrates into its pore space. The liquid flowing during the spin cycle on the surface of the elastic material is additionally saturated with oxygen.

When the disk 4 is immersed in the liquid located in the tank 1, the elastic material is repeatedly subjected to partial extraction using the lower rollers 7, and the air in the pore space is replaced by a liquid. The air pushed from the pores is dispersed in the wastewater, which contributes to its mixing in the tank and oxygen saturation.

When the squeeze rolls and 7 are located at an angle of 45 ° to the horizontal plane, the largest volume of liquid is aerated. Holes or slots 8 in the hard disk 4 contribute to an increase in the effective working volume of the elastic material, and when the squeeze rolls 6 and 7 are displaced, as shown in FIGS. 4 and 5, the fluid and air enter the pore space alternately throughout the thickness of both layers 5 of the elastic material. The purified wastewater from the tank 1 is discharged through the pipe 10 into a secondary settling tank 11 located separately or combined with the tray.

The proposed device provides in comparison with the known significant increase in cleaning efficiency.

Claims (1)

squeezing rolls 7, interacting with the layer 5 of elastic material. The rolls b. And 7 are spring-loaded and set at an angle of 45 to the horizonts and with the possibility of changing the distance between them, which determines the degree of elastic material. The hard disk 4 has holes 8. In this case, if the holes are round, their diameter is determined from the ratio iL Jl dj) 2 and the axes of each pair of squeeze rolls are shifted by an angle oL, which is determined from the ratio d-. di-B resin where d. and d, are the diameters of the holes located from the disk axis at a distance, respectively, C and Ij,. In addition, the holes can be made in the form of radial or concentric slots. To supply the original waste liquid, serves as a pipe 9., to drain cleaned capacity, - pipe 10 A sump 11 is designed to further clarify the biologically purified waste liquid. The discs 1 "will be placed as perpendicular to the general direction of movement of the waste fluid in reservoir 1 from the pad 9 to the discharge pipe 10 (Fig. 1,2,10 and 11 and parallel) (Fig. 12-14). The device works as follows When electric drive 3 is turned on, shaft 2 and disk 4 are rotated, layer 5 of elastic material on whose surface is in contact with waste liquid supplied to tank 1 through nozzle 9. Microorganisms develop in the pore space of elastic material, which are removed from contaminants are contaminated and oxidized.When disk 4 leaves the liquid, the elastic material is partially pressed by upper bales and air is drawn into its pore space, which is an oxygen source for the biooxidation process. the elastic material is additionally saturated with oxygen. When the disc 4 is immersed in the liquid in the tank 1, the elastic material is again subjected to partial pressing with the help of the lower rolls 7, and the air in the pore space is replaced fluid. The air that is squeezed out of the pores is dispersed in the wastewater: liquids, which promotes its mixing in the tank and oxygenation. When the squeeze rolls 6 and 7 are located at an angle of 45 ° to the horizontal plane, the largest volume of fluid is subjected to aeration. The holes or slots 8 in the hard disk 4 contribute to an increase in the effective working volume of the elastic material, and when the squeeze rolls 6 and 7 are displaced, as shown in FIGS. 4 and 5, fluid and air are alternately introduced into the pore space throughout the entire thickness of both elastic layers 5 material. The cleaned waste liquid from the tank 1 is discharged through the nozzle 10 into a secondary settling tank 11 separately located or combined with a tray. The proposed device provides a significant increase in the cleaning efficiency compared to the known. The invention The device for biological treatment of waste liquid, containing a reservoir and a semi-immersed hard disk mounted on a shaft with a drive, characterized in that in order to improve the cleaning efficiency due to the intensification of mass exchange, it is equipped with spacers radially on either side of the disk rolls of conical shape with a device for changing the distance between them, and the disk is made with holes and provided with a coating of elastic material with an open-cell structure kturoy. Sources of information taken into account during the examination 1. Dmitrievsky N. G. Some questions of the theory and calculation of disk filters of biological filters. Water supply and sanitary equipment, 1977, No. 2, p.4. S j it ii / s / .eleven S 1 2/74 / V. //. / E fff 3 Ul. 12 6 6