RU2130901C1 - Sewage purification plant - Google Patents

Abstract

FIELD: biological purification of sewage. SUBSTANCE: sewage purification plant has tank 2 that houses primary settler 3, aerotank 4 with carrier 5 of attached microflora and aeration systems 6, secondary settler 7, system 8 of recirculation of activated sludge, systems 9, 10 and 11 of removal of purified water and sludge and self-cleaning grid 1 mounted in upper part of tank 2. Aerotank 4 is fitted with two mobile frames 13 as minimum to which carriers 5 of attached microflora manufactured in the form of parallel shutters 12 of fabric or film material are fixed. Fixing and pulling weights 14 are attached to their lower ends. Frames 13 are hung by ropes 15 that are linked to counterbalance weights 17 made in the form of hollow caps placed in caissons 18 with purified water. Aerotank 4 is divided downstream of sewage by partitions 19 into two parts as minimum. Sewage purification plant also has air receiver 20 which is connected via air distributors 21 separately to aeration systems 6 and to counterbalance weights 17 of each mobile frame 13. Air distributors 21 additionally have branch pipes 22 with valves. Source 23 of ultraviolet radiation is placed between secondary settler 7 and system 9 of removal of purified water. EFFECT: enhanced efficiency and reliability of plant with simultaneous simplification of design and reduced cost. 1 dwg

Description

 The invention relates to techniques for wastewater treatment and can be used in biological wastewater treatment plants.

 A known installation of wastewater treatment, containing a tank with biofilters installed in it from disks mounted on horizontal shafts with electric rotation drives / 1 /.

 The disadvantages of the known installation of wastewater treatment are quite significant operating costs (on the drive biodisk), limited by rotating nodes reliability and high cost.

 A known installation of wastewater treatment, containing a tank in which there is a primary sump, aerotek with a carrier of attached microflora and aeration system, a mechanized grate and a system for moving sludge with drive linkage mechanisms, a secondary sump, systems for removing purified water and sludge, and the carrier is attached microflora is made in the form of parallel curtains made of fabric or film material, to the lower part of which fixing tension weights are attached, with the upper part of the curtains They are fixed to a movable frame, which is connected via cables with blocks to balancing weights, and an ultraviolet radiation source / 2 / is installed between the secondary sump and the purified water removal system.

 A disadvantage of the known wastewater treatment plant is the inadequate level of reliability of its operation due to the presence of drive linkage mechanisms for cleaning the grate and moving sludge.

 The aim of the invention is to increase the efficiency and reliability of the installation while simplifying and cheapening its design.

 This goal is achieved by the fact that in a wastewater treatment plant containing a tank in which a primary sump is placed, an aeration tank with a carrier of attached microflora and an aeration system, a secondary sump, a system for removing purified water and sludge, the carrier of attached microflora is made in the form of parallel curtains of fabric or film material, to the lower part of which fixing tensioning weights are attached, the upper part of the curtains is fixed to a movable frame, which is connected through blocks with cables and with balancing weights, and between the secondary sedimentation tank and the purified water removal system, an ultraviolet radiation source is installed, the aeration tank of the installation is equipped with an activated sludge recirculation system, divided along the wastewater by at least two partitions, equipped with at least two moving frames with carriers of attached microflora, balancing weights are made in the form of hollow hoods installed in caissons with purified water, the installation additionally contains a self-cleaning grate located in the upper part of the tank in front of the primary settler, an air receiver, which is connected through the air distributors to the aeration systems and balancing weights of each movable frame, and the air distributors themselves are equipped with additional exhaust pipes with valves.

 The drawing conventionally shows a longitudinal section of a wastewater treatment plant.

 The wastewater treatment plant contains a self-cleaning grate 1, a container 2, in which a primary sump 3, aeration tank 4 with a carrier 5 of attached microflora and an aeration system 6, a secondary sump 7, activated sludge recirculation system 8, purified water removal system 9, and removal system 10 are placed sludge from the secondary sump 7 to the primary sump 3 and the system 11 for removing sludge from the primary sump.

 The aeration tank 4 is equipped with at least two movable frames 13, to which the carriers 5 of the attached microflora are fixed, made in the form of parallel curtains 12 of fabric or film material and to the lower part of which are fixed tension weights 14. The movable frames 13 are suspended on cables 15 which through blocks 16 are connected to balancing weights 17 made in the form of hollow caps installed in caissons 18 with purified water.

 Aerotank 4 is divided along the movement of wastewater by partitions 19, at least in two parts.

 Self-cleaning grate 1 is installed in the upper part of the tank 2 at the wastewater inlet to the installation in front of the primary settler 3 and is a free-rotating drum designed for mechanical treatment of wastewater from solid impurities.

 The wastewater treatment plant further comprises an air receiver 20, which is connected through air diffusers 21 separately to the aeration systems 6 and balancing weights 17 of each movable frame 13.

 The air distributors 21 further comprise nozzles 22 with valves for the release of balancing weights 17.

 In the wastewater treatment plant between the secondary sump 7 and the purified water removal system 9, an ultraviolet radiation source 23 is installed.

 The activated sludge recirculation system 8 contains an intake manifold 24 mounted above the hopper of the secondary sump 7 and connected to a pump inlet 25, the discharge pipe of which is connected to an exhaust manifold 26 installed at the wastewater inlet to the aeration tank 4. The activated sludge recirculation ensures its working concentration in aeration tank.

 The sludge removal system 10 connects the storage hopper of the secondary sump 7 through the pump 27 with the primary sump 3.

 The system 11 connects the storage hopper of the primary sump 3 through the pump 28 with the installation of drying and disinfection of sludge sludge (not shown).

 A turbo blower 29 is connected to the receiver 20.

 Installation of wastewater treatment works as follows.

 Wastewater through a self-cleaning grate 1 enters the primary sump 3, where sand and other solids are deposited, and then enter the tank 2 of the aeration tank 4. After biological treatment from the aeration tank 4, the waste water flows into the secondary sump 7, where it is deposited from the stream into the storage hopper silt sediment, and purified water enters the system 9, from where it is removed to a reservoir or for reuse.

 In aeration tank 4, biological wastewater treatment is carried out attached to the curtains 12 microflora. Biomass is transferred to the film when the curtains 12 are immersed in the tank 2 of the aerotank 4, and microflora in the oxygen film is consumed when the curtains 12 are raised to the upper position. When the curtains 12 are immersed, an additional (to the aeration systems 6) saturation of the water volume of the aeration tank 4 with oxygen is carried out, which ensures the flow of cleaning processes in the water volume by free-floating microflora with less energy consumption for supplying air for aeration to the system 6.

 The mechanism of periodic immersion of the curtains 12 in the water bath of the aeration tank 4 is as follows.

 In the initial position, the carriers of the attached microflora 5 of all parts of the aeration tank 4 are in the upper position under the action of balancing weights 17, which are located in the lower part of the internal volumes of the caissons 18. The turbo blower 29 is turned on, the receiver 20 is under operating pressure and the air through the air distributors 21 enters the aeration systems 6 all parts (cleaning steps) of the aeration tank 4.

 When you switch in the first part of the aeration tank 4 of the operating mode of the air distributor 21, the air supply to the aeration system 6 of the first degree is switched off and the air supply starts under the caps of the balancing weights 17 of the moving frame 13 of this part of the aeration tank.

 Due to the increasing buoyant force (caps), the weight of the balancing weights 17 will begin to decrease and they will evenly move to the upper position, and the carrier 5 of the attached microflora of the first stage will move to the lower position, immersing the curtains 12 with the attached microflora in the wastewater, while fixing tension loads 14 ensure the preservation of equal distances between the curtains 12.

 Upon reaching the lower position, the frame 13 of the first stage will simultaneously switch the operating modes of the air distributors 21 of the first and second stages, due to which the air supply to the caps of balancing weights 17 will be switched off in the first stage, the air supply to the aeration system 6 of this stage will open and the valve of the pipe 22 will open, through which air from the caps of balancing goods 17 of the first stage will go into the atmosphere. At the same time, in the second stage, the air supply to its aeration system 6 is turned off and the air supply opens under the caps of its balancing weights 17. As a result of this switching, the carrier 5 of the attached microflora in the first stage will rise to the upper position, and the second stage will fall to the lower position. The frame 13 of the second stage, when reaching the lower position, will simultaneously switch the operation mode of the air diffusers 21 of the second and third stages, as a result of which the installation will continue in a similar manner. When the lower position is reached in the last stage, the frame 13 will switch the operation modes of the air distributors 21 of its own and the first stage, which will ensure continuous operation of the installation as a whole.

 Turning off the air supply to the aeration systems 6 at the moment the carrier 5 of the attached microflora is immersed in the water volume prevents washing of the attached microflora from the curtains 12.

 The separation of the water volume of the aeration tank by 4 partitions 19 into parts (steps) in combination with the integrated use of attached and free-floating microflora provides a deeper and more comprehensive wastewater treatment due to the formation of more varieties of working microorganisms, and also makes the installation less sensitive to interruptions in the supply of wastewater and fluctuations in the concentration of pollution in them.

The presence of an air receiver 20 and air distributors 21 with nozzles 22 provides a more reliable and economical operation of the installation as a whole. So, for example, if in the well-known best analogues with a capacity of 200 m ³ / day, the total electric drive power of the carriers of attached microflora (4 cleaning stages) is 1.5 kW and another 4 kW is required to supply air to the aeration tank, then in the proposed installation, an electric turbo-blower 29 with power 1.48 kW provides movement of frames with carriers of attached microflora and air supply to the aeration tank (6 steps).

 The presence of the system 8 of recycling activated sludge in combination with the proposed design of the aeration tank 4 allows you to adjust the concentration of activated sludge in a wider range, which increases the degree of wastewater treatment.

 The presence in the blowers 21 of additional exhaust pipes 22 with valves simplifies the design of the pneumatic drive of the carriers of the attached microflora, which increases the reliability of its operation, due to the use of a single hose both for supplying air under the hoods of cargo 17 and for its removal.

 At the exit from the secondary sump 7 to the system 9, the purified water is treated with ultraviolet radiation, which destroys the pathogenic flora.

 Thus, the proposed (comprehensively) technical solutions increase the efficiency and reliability of the wastewater treatment plant while simplifying its design, reducing cost and operating costs.

Claims (1)

 A sewage treatment plant comprising a container in which a primary sump is placed, an aeration tank with a carrier of attached microflora and an aeration system, a secondary sump, a system for recirculating activated sludge, a system for removing purified water and sludge, and the carrier of attached microflora is made in the form of parallel curtains from fabric or film material, to the lower part of which fixing tension weights are attached, with their upper part the curtains are fixed to a movable frame, which is connected via cables to blocks with balancing weights, and between the secondary sedimentation tank and the purified water removal system a source of ultraviolet radiation is installed, characterized in that the aeration tank of the installation is divided along at least two parts by wastewater, equipped with at least two movable frames with carriers of attached microflora, balancing the loads are made in the form of hollow hoods installed in caissons with purified water, the installation additionally contains a self-cleaning grate located in the upper part capacity before the primary clarifier, an air receiver that is connected through the diffusers separately with aeration systems and balance weights of each of the movable frame, and themselves diffusers are equipped with additional discharge pipes with valves.