RU2132824C1 - Compact unit for biologic waste-water purification - Google Patents

Abstract

FIELD: biologic purification of waste water in aeration tanks. SUBSTANCE: unit has aeration tank 1 built up of at least two cylindrical modules accommodating aeration systems. Each aeration system has pipelines connected to fans 2 which may operate both sequentially and concurrently. Some of pipelines 3 are flexible which enables adjustment of insertion depth of air hose connected to sprayer 5. Aeration tank 1 holds shell 6 which provides for multiple cleaning of liquid. Air lift 10 of unit is made for controlling insertion depth of flexible hose 11. Mud separator 7 mounted in aeration tank and used to prevent active mud settling on tank bottom is provided with thin-layer module 7 and baffle 20 that functions as damper. EFFECT: increased capacity due to improved water circulation conditions and active saturation of water with atmospheric oxygen. 5 cl, 2 dwg

Description

 The invention relates to the biological treatment of domestic and industrial wastewater with activated sludge.

 A known installation for biological wastewater treatment, containing aeration tank, a secondary sump, a regenerator, a unit for supplying return sludge to a regenerator, pipelines for supplying source water, removal of excess biomass and purified water, fine bubble dispersers and a sludge compactor with a thin-layer module. In this case, the sludge compactor is connected to the regenerator on the inlet side, and is equipped with a partition on the outlet side, the lower edge of which reaches the bottom, and the upper edge is located below the liquid level and forms an overflow. To restore the working capacity of activated sludge, air is supplied by the blower station to the aeration tank to a constant depth, while air enters the aeration tank from the pipeline (A.S. N 1699957, class C 02 F 3/12, 1991).

 The known device has a number of significant disadvantages. One of the disadvantages is the aeration system, made in the form of rigid pipelines, which do not provide the ability to control the depth of immersion of the air ducts. The pipeline also lacks a spray system that provides more efficient operation of the aeration system. Air is supplied from the blower station, which has a low pressure, which does not allow ensuring a sufficient depth of the aeration system in the aeration tank. In addition, the airlift is made in the form of a rigid structure without the ability to control the depth of immersion.

 The invention consists in the following.

 A compact plant for biological wastewater treatment contains an aeration tank made in the form of at least two cylindrical modules with an aeration system located inside them. The aeration system is made in the form of pipelines with fans connected to them, which can work both in series and in parallel. Some of the pipelines are made flexible, which allows you to adjust the immersion depth of the air duct to which the nebulizers are connected. A shell is also installed in the aeration tank housing, which provides multiple cleaning of the liquid. The airlift of the installation is configured to control the depth of its immersion. The sludge separator located in the aeration tank is equipped with a thin-layer module and contains a partition that acts as a soothing agent.

 As a result of the invention, an increase in productivity is achieved by improving the conditions of circulation of water in the aeration tank, actively saturating the water with atmospheric oxygen and preventing the precipitation of activated sludge to the bottom of the aeration tank.

 In FIG. 1 shows a longitudinal section of the installation.

 In FIG. 2 is a section AA of FIG. 1.

 A compact device for biological wastewater treatment contains an aeration tank 1 made in the form of a group of at least two horizontal modules with an aeration system consisting of high-pressure fans 2, which are connected in series with the possibility of switching also in parallel and independently, and ducts. Part of the ducts connected to the fans is made in the form of vertical flexible hoses 3, which allows you to adjust the immersion depth of the aerators, which consist of central air ducts 4 and perforated atomizer tubes 5 installed in increments equal to the length l of these tubes.

 In the inner part of the aeration tank 1, along its body, at a distance of 0.25 diameter (D) of the cylindrical module, there is a shell 6, which has a curvature equal to the curvature of the cylindrical module. The upper forming shell 6 is located at the level of the static liquid level in the aeration tank, and the lower edge is at a height of 0.1 diameter (D) of the cylindrical module from the lower forming housing of the aeration tank. Between the housing of the aeration tank 1 and the shell 6, in its smaller part, at a distance of 0.125 diameter (D) of the cylindrical module, there is an air duct 4 with nozzles 5. A desilter 7 is adjacent to the end of the aeration tank 1, which is separated from it by a partition 8. In the partition 8 there are flow windows 9, made in such a way that 1/3 of their height is above the water level.

 In the sludge separator 7, an activated sludge return unit is installed, consisting of an airlift 10, made in the form of a flexible hose 11 connected to the perforated pipe 12. The outlet pipe 13 of the airlift is located in the lower part of the sludge separator 7. A receiving pocket 14 is installed between the aeration tank 1 and the sludge separator 7, which from the side of the aeration tank 1 is connected to the sludge supply pipe 15, which ensures its transportation to the middle of the aeration tank, to its bottom part. An airlift chamber, in the form of a perforated pipe 12, and a receiving pocket 14 are interconnected by means of a vertically movable partition 16, which provides metering of the return of activated sludge. In the end part of the sludge separator 7, a thin-layer module 17 is installed, made of flat inclined plates 18. The first plate 19 of the module is raised above the water level in the direction of the liquid. In the sludge separator in front of the thin-layer module, there is a directing baffle 20, which at the same time plays the role of a fluid flow damper. At the outlet of the sludge separator 7, a collection chute 21 is installed, connected to the purified sewage water pipe 22. Wastewater is supplied to the aeration tank through a pipe 23.

 A compact installation for biological wastewater treatment works as follows.

 Mechanical wastewater flows through a pipe 23 to the aeration tank 1, consisting of at least two horizontally located modules. Fans 2 through the ducts 4 and flexible hoses 3, through the nozzles 5, air is supplied to the aeration tank. At the same time, the liquid level in the air supply zone rises, and it overflows through the upper edge of the shell 6. Simultaneously, a new portion of the liquid enters through the bottom gap between the shell 6 and the aeration tank body, which ensures transverse circulation of the liquid in the aeration tank 1. As a result, the liquid to be cleaned passes repeatedly through air supply zone and is repeatedly saturated with oxygen. Then the waste water through the window 9 enters the sludge separator, made in the form of a sump. Water passes under the flow guide 20 and moves towards the thin layer module. When this occurs, the precipitation of activated sludge in the conical part of the desilter. The return of activated sludge from the sludge separator to the aeration tank is carried out continuously and is controlled by changing the immersion depth of the flexible airlift hose 11 and changing the height of the vertically movable partition 16. The sludge supply pipe 15 carries it out to the middle of the aeration tank 1 to its bottom part. Next, the water passes through a thin-layer module 17, where water is purified and clarified. The passage of all the liquid through the thin-layer module 17 is ensured by performing the first plate 19 of the thin-layer module elevated above the water level while it is moving along the water. The purified water enters the collection chute 21 and then is discharged through a pipe 22.

 The installation in the form of cylindrical modules with an aeration system located in them allows to increase the concentration of air oxygen and activated sludge in the aeration tank and to increase the speed of pollution cleaning. Thus, the use of the installation allows to increase the productivity of the structure without additional costs.

Claims (5)

 1. A compact installation for biological wastewater treatment, containing an aeration tank, a sludge separator with a return sludge supply unit in the form of airlift and a collection chute, a thin-layer module, aeration system and pipelines for supplying source water and removal of excess biomass and purified water, characterized in that the aeration tank is made in the form of at least two horizontal cylindrical modules with an aeration system located inside them.  2. The compact installation according to claim 1, characterized in that the aeration system is made in the form of air ducts with fans connected to them, connected in series or parallel or working independently, part of the air ducts are made in the form of vertical flexible hoses with a horizontally located air duct and mounted on perforated spray tubes with a step equal to their length.  3. The compact installation according to claim 1, characterized in that it is equipped with a shell located inside the aeration tank along its body, the upper edge of the shell is located at the static water level in the aeration tank, the lower edge is at a distance from the lower generatrix of the aeration tank between the shell and the body , and in its upper part an air line with sprayers is installed.  4. The compact installation according to claim 1, characterized in that the airlift is in communication with the bottom middle part of the aeration tank and is made of a flexible hose in a perforated pipe, installed with the possibility of changing the depth of its immersion.  5. The compact installation according to claim 1, characterized in that the desilter is equipped with a flow guiding partition-damper, a thin-layer module is installed in the end part of the desilter in front of the collecting chute and is made of flat inclined plates, the first of which is raised above the water level in the direction of water flow.

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