RU109129U1 - FLOATING WATER TREATMENT COMPLEX - Google Patents

Abstract

 1. Floating water treatment complex, including a tank connected to a pontoon, modules for thin-layer sedimentation and water treatment, a suction pipe, a pump and a pressure pipe, located in the tank, characterized in that the tank is made in the form of separate blocks connected and interconnected to form overflow, each block is made with the formation of at least one lower overflow. ! 2. The complex according to claim 1, characterized in that the pontoon is made collapsible, and the connection between the blocks and the pontoon is equipped with fixing devices. ! 3. The complex according to claim 1, characterized in that the water treatment modules are placed in blocks, include reagent, and / or aerobic, and / or anaerobic treatment. ! 4. The complex according to claim 2, characterized in that the blocks with aerobic and / or anaerobic treatment are equipped with carriers for immobilizing microorganisms. ! 5. The complex according to claim 1, characterized in that it is equipped with at least a second module of thin-layer sedimentation, while one module of thin-layer sedimentation is located at the beginning of the complex, and the other at its end. ! 6. The complex according to claim 1, characterized in that it is equipped with at least one heating system. ! 7. The complex according to claim 5, characterized in that the heating system is installed in the first block of the complex. ! 8. The complex according to claims 1 and 5, characterized in that the module and / or modules of thin-layer sedimentation are made in the form of rows of parallel inclined plates. ! 9. The complex according to claim 1, characterized in that one of the blocks, or part of the blocks, or all blocks are made of polymer material.

Description

The utility model relates to biological wastewater treatment and can be used to treat industrial and domestic wastewater from a wide range of dissolved and suspended organic compounds. The complex can be installed in reservoirs with a wide range of fluctuations in the level of wastewater.

A known installation of microbiological wastewater treatment, including a heating system, an anaerobic water treatment section, an aerobic water treatment section with an aeration system and a water purification section, which are made in the form of a series of hydraulically connected adjacent chambers separated by vertical partitions, sequentially located in the casing along the wastewater . The anaerobic and aerobic water treatment sections are equipped with carriers for immobilizing microorganisms. In the case, in front of the anaerobic water treatment section, a sedimentation section is located, divided by a partition with the formation of a lower overflow into hydraulically connected primary and thin-layer sedimentation chambers, the aftertreatment section includes a second thin-layer sedimentation chamber, the thin-layer sedimentation chambers are equipped with nozzles in the form of rows of parallel inclined plates (RU Patent No. 2238247).

The known installation is intended for stationary use, therefore, the possibilities of its movement are limited by a large amount of installation and dismantling. Another disadvantage is the limitation of the passage of treated water at peak times. In addition, the material consumption and strength of the housing is determined by the hydrostatic pressure of the liquid inside the housing, depending on the height of the housing.

Known floating water intake-clarifier adopted as a prototype, including a tank connected to a pontoon, modules of thin-layer sedimentation and water treatment, placed in the tank, suction pipe, pump and pressure pipe (Patent for invention RU No. 2310726).

The known device provides only preliminary clarification of the water, while the pollution resulting from the purification is again discharged into the water to be cleaned.

The objective of the utility model is the comprehensive treatment of industrial and domestic wastewater from a wide range of dissolved and suspended organic compounds in water bodies with a large range of fluctuations in the level of wastewater. The technical result is achieved by performing capacity in the form of separate blocks, each of which can perform various wastewater treatment operations. Another technical result is achieved by reducing the material consumption of the complex, as well as reducing costs for transport and installation and dismantling.

To achieve a technical result in a floating water treatment complex, including a tank connected to a pontoon, modules for thin-layer sedimentation and water treatment, a suction pipe, a pump and a pressure pipe, placed in the tank, according to a utility model, the tank is made in the form of separate blocks connected and connected to each other with the formation of the upper overflow, with each block made with the formation of at least one lower overflow. The pontoon is made collapsible, and the connections between the blocks and the pontoon are equipped with fixing devices. Water treatment modules are placed in blocks and include reagent and, or aerobic and, or anaerobic treatments. Blocks with aerobic and anaerobic treatment are equipped with carriers for immobilization of microorganisms. The complex is equipped with at least a second module of thin-layer sedimentation, while one module of thin-layer sedimentation is located at the beginning of the complex, and the other at its end. The complex is equipped with at least one heating system. The heating system is installed in the first block of the complex. The module and, or the modules of thin-layer sedimentation are made in the form of rows of parallel inclined plates. One of the blocks or part of the blocks or all blocks are made of polymer material.

Figure 1 shows a schematic longitudinal section of a floating water treatment complex; figure 2 is a cross section aa in figure 1; figure 3 is a top view of B in figure 1; figure 4 - remote section In figure 3.

The floating water treatment complex includes a tank made in the form of individual blocks 1, 2, 3, and 4. The number of blocks is determined by the given capacity, and also depends on the spectrum of dissolved and suspended organic compounds in the reservoir and the adopted technology for their purification. The pontoon is made collapsible and consists of two transverse parts 5 and two longitudinal parts 6. This design provides a reliable connection of parts 5 and 6 of the pontoon with blocks 1, 2, 3 and 4. The connection of parts 5 and 6 of the pontoon can be performed, for example, using bolted connections 7. Reliability of communication between blocks 1, 2, 3 and 4 and parts 5 and 6 of the pontoon can be enhanced by fixing devices, for example, local bulges 8 on the blocks. On the extreme blocks 1 and 4, three such local thickenings 8, and on the intermediate blocks 2 and 3, two local thickenings 8. In Figs. 1 and 2, local thickenings 8 made in the upper parts of blocks 1, 2 are shown as an example , 3 and 4 with support on the upper planes of the parts 5 and 6 of the pontoon. However, local bulges 8 can be located simultaneously on the upper and lower planes of the pontoon parts 5 and 6, as well as in the recesses of the inner planes of the pontoon parts 5 and 6 (these options are not shown in the drawings). In blocks 1 and 3 are modules of thin-layer sedimentation 9, made in the form of rows of parallel inclined plates. In block 2 there is an anaerobic processing module equipped with carriers 10 for immobilizing microorganisms. In block 3 there is an aerobic treatment module equipped with carriers 11 for immobilizing microorganisms and an aeration system 12. The complex is equipped with at least one heating system 13 located in block 1. To ensure the operation of the complex at low temperatures, heating systems 13 can be placed and in other blocks. In the upper parts of blocks 1, 2, 3, and 4, windows 14 are made, providing an upper overflow of treated water between the blocks. In blocks 1, 2, 3, and 4, partitions 15 are fixed, providing a lower overflow of treated water inside each block. Water from the reservoir 16 is fed to the complex for cleaning by the suction pipe 17 and the pump 18. The purified water and the complex can be pumped into the reservoirs with purified water or the technical water supply systems using the pump 19 and the pressure pipe 20. To remove solid deposits deposited at the bottom of blocks 1, 2, 3 and 4, a suction pipe 21 and pump 22 are provided. One of the blocks or part of the blocks or all blocks 1, 2, 3 and 4 can be made of polymer material, including elastic. Such a choice of block materials is possible due to the equality of the hydrostatic pressure inside and outside the block walls, and the reliability of the connection of the blocks with the pontoon is ensured by the stiffness of the covers 23. In addition, the covers 23 serve to secure the partitions 15 and ensure the stability of the temperature regime inside the complex. Block 4 may be redundant, for example, for placing filters 24 in it.

The complex works as follows

Wastewater flows through the suction pipe 17 and pump 18 into unit 1, where the flow rate is reduced and equalized, its direction of movement changes and the primary separation of the largest and heaviest suspended substances occurs. Wastewater heated in block 1 using a heating system 13 to the required temperature, providing optimal conditions for the life of microorganisms, through the lower overflow enters the thin-layer sedimentation module 9 for deep clarification of water. The velocity of the upward flow of wastewater passing through the thin-layer sedimentation module 9 sharply decreases, resulting in a “stratification” of the flow and intensive sedimentation of suspended solids on the upper surface of the plates, while due to the inclined position of the plates, sediment flows into the bottom of unit 1. At the same time, in the thin-layer sedimentation module 9, where optimal temperature and other conditions are provided for anaerobic microorganisms contained in wastewater (yeast, microscopic fungi, sulfate-reducing and rot bacteria), the process of fermentation of dissolved organics begins and its partial destruction to simpler compounds (amino acids, phosphorus and nitrogen compounds). The main processes of destruction of organic substances occur in blocks 2 and 3 of anaerobic and aerobic treatment of water with the help of freely floating and immobilized carriers 10 and 11 forms of microorganisms - destructors of specific types of pollution. The clarified water with partially decomposed organics from the thin-layer sedimentation module 9 enters through an overflow 14 into anaerobic water treatment unit 2 with 10 anaerobic microorganisms immobilized on carriers — destructors of specific pollutants contained in the treated effluents, where more complete decomposition of the dissolved organics to simpler ones takes place substances. After successive passage of wastewater through anaerobic treatment unit 2, the clarified wastewater with decomposed organics enters the aerobic treatment unit 3, where the final decomposition of organic substances occurs (redox process), in particular, denitrifying microorganisms of free-floating and 11 forms immobilized on carriers decompose nitrogenous compounds to nitrates and nitrites. Moreover, due to the lack of suspended solids, favorable conditions are created for the biocenosis of activated sludge (lack of siltation, stagnant zones). In block 3 of the aerobic treatment, air enters through the aeration system 12 to ensure the vital activity of aerobic microorganisms and the removal of gaseous decomposition products. After the aerobic treatment module, purified water enters the second module of thin-layer sedimentation 9, where sedimentation of silt particles occurs in the bottom of block 3. The completion of the cleaning process occurs in the filtration block 4. The purified water is discharged using a pump 19 and a pressure pipe 20.

Claims (9)

1. Floating water treatment complex, including a tank connected to a pontoon, modules for thin-layer sedimentation and water treatment, a suction pipe, a pump and a pressure pipe, located in the tank, characterized in that the tank is made in the form of separate blocks connected and interconnected to form overflow, each block is made with the formation of at least one lower overflow. 2. The complex according to claim 1, characterized in that the pontoon is made collapsible, and the connection between the blocks and the pontoon is equipped with fixing devices. 3. The complex according to claim 1, characterized in that the water treatment modules are placed in blocks, include reagent, and / or aerobic, and / or anaerobic treatment. 4. The complex according to claim 2, characterized in that the blocks with aerobic and / or anaerobic treatment are equipped with carriers for immobilizing microorganisms. 5. The complex according to claim 1, characterized in that it is equipped with at least a second module of thin-layer sedimentation, while one module of thin-layer sedimentation is located at the beginning of the complex, and the other at its end. 6. The complex according to claim 1, characterized in that it is equipped with at least one heating system. 7. The complex according to claim 5, characterized in that the heating system is installed in the first block of the complex. 8. The complex according to claims 1 and 5, characterized in that the module and / or modules of thin-layer sedimentation are made in the form of rows of parallel inclined plates. 9. The complex according to claim 1, characterized in that one of the blocks, or part of the blocks, or all blocks are made of polymer material.