RU2299863C2 - Apparatus for biological purification of sewage water - Google Patents

Abstract

FIELD: agricultural engineering and community facilities.

SUBSTANCE: apparatus has reservoir 1, basic sewage water feeding system 2 and purified sewage water discharge system 3. Reservoir 1 is partly open and comprises closed receptacle chamber, methane tank chamber, clarification chamber 6, and biofilter chamber 7, said chambers being hydraulically communicated with one another. Biofilter chamber 7 has at least two sections hydraulically communicated with one another. Longitudinal separating partition 10 positioned between sections is equipped with drainage strip 11 provided in its upper part. Biofilter chamber 7 is equipped with throat communicating with atmosphere. Biofilter is positioned within both sections of chamber 7. One of sections of biofilter is used as inlet and is hydraulically communicating with methane tank chamber. Other section 33 of biofilter is used as outlet and is hydraulically communicating with clarification chamber 6.

EFFECT: compact construction, simplified manufacture and maintenance of single unit apparatus for purification of sewage water and bringing sewage purification quality to required level envisaged by sanitary regulations and norms of protecting surface water from contamination.

9 cl, 6 dwg

Description

The invention relates to the biological treatment of wastewater from suspended and dissolved organic substances using microflora and can be used in agriculture and public utilities for the treatment of domestic wastewater.

The biological method of wastewater treatment is used to treat industrial and domestic wastewater from organic and inorganic pollutants. This process is based on the ability of some microorganisms to use substances polluting wastewater for nutrition in the process of their life.

The main process that occurs during biological wastewater treatment is biological oxidation. This process is carried out by a biocenosis, consisting of many different bacteria, protozoan algae, fungi, etc., interconnected into a single complex by complex relationships (metabiosis, symbiosis, and antagonism). Biological wastewater treatment is carried out under aerobic and anaerobic conditions. When purified under anaerobic conditions, the community of microorganisms is represented by bacteria alone. When cleaned under aerobic conditions, protozoa develop in a community of microorganisms.

A known natural method of biological wastewater treatment in biological ponds, which are artificial ponds with a depth of usually not exceeding 1 m. These facilities are also used for deep treatment (post-treatment) of wastewater that has undergone biological treatment. In the oxidizing processes taking place in biological ponds, aquatic vegetation plays a significant role, which helps to reduce the concentration of nutrients and regulates the oxygen regime of the reservoir, see Krivoshein D.A. and others. "Engineering protection of surface water from industrial effluents", Textbook. allowance, M., High School, 2003 241-248.

The disadvantage of these structures is the low oxidizing ability, seasonality, the need for large areas, etc.

The closest analogue adopted for the prototype of the invention is a biological wastewater treatment plant, including a tank, source water supply system, purified water drainage system and a biofilter in the form of a network load, see RU No. 1731739, M. Cl. C02F 3/00, 1989

During the operation of this installation, wastewater washes a biofilter in the form of a stationary loading material, for example, a mesh with a film of mucous fouling that has grown on it, consisting of bacteria, fungi, yeast, and other organisms.

The disadvantage of this analogue is the low degree of purification, due to the relatively small specific working surface and, accordingly, the low mass transfer rate.

The technical problem solved by the invention is to increase the degree of purification by increasing the specific working surface to populate microorganisms and improve mass transfer.

The solution to this problem is ensured by the fact that the installation for biological wastewater treatment, including a tank, a system for supplying source wastewater, a drain of treated wastewater and a biofilter, according to the invention, the tank is partially open with hydraulically interconnected, closed by a receiving chamber, a meta chamber and a clarification chamber, as well as a biofilter chamber with at least two sections hydraulically interconnected, between which a longitudinal dividing wall with the willow shelf, made in its upper part, while the biofilter chamber is provided with a neck connected to the atmosphere, and the biofilter is placed in both sections of this chamber, one of the sections of which is made inlet and hydraulically connected with the metathenk chamber, and the other is made out and hydraulically communicated with a clarification chamber.

In preferred embodiments, the height of the neck of the biofilter chamber is made from the condition that its inlet slice is located above the soil surface with a reservoir buried in the soil; the neck of the biofilter chamber is equipped with a vapor tight cover; the receiving chamber, the metaten chamber, the biofilter chamber and the clarification chamber are hydraulically interconnected due to perforated sections made in the lower parts of the walls between adjacent chambers; the perforated wall section between the adjacent metaten chamber and the biofilter chamber is made in the form of vertical slots with a width of at least 20 mm and a height of up to 0.5 m; loading of the biofilter is made in the form of frame blocks of rectangular plastic frames with a polymer grid, fastened together in a parallelepiped, while inside the parallelepiped, in planes perpendicular to its longitudinal axis and along this axis with a pitch of at least 15 mm, transverse grids are fixed; the mesh size of the polymer mesh is not more than 10 mm · 10 mm; bundles of polymer fibers are fixed in the cells of the polymer mesh, the bundle length of which is not more than the step of securing the transverse networks in the frame blocks; loading the biofilter is made of bulk material, for example gravel, expanded clay or slag with a grain size of fractions of 15-80 mm, placed in containers with permeable walls, connected in a garland.

The technical result from the use of the proposed invention is to provide a compact and easy to manufacture and maintain a one-piece installation of domestic wastewater treatment for the disposal of wastewater of economic fecal origin and to bring their quality to the requirements stipulated by sanitary rules and standards for the protection of surface water from pollution.

The invention is illustrated by drawings, where:

1 and 2 show a General view (longitudinal section) and a plan view (transverse section) of the proposed installation;

figure 3 - frame for network-shaped loading;

figure 4, 5 is a General view and a plan view of a network-shaped loading unit;

Fig.6 is a fragment of the biofilter chamber (longitudinal section).

Installation for biological wastewater treatment consists of a partially open tank 1 with a pipe 2 for supplying the source wastewater and a pipe 3 for discharge of treated water. The tank 1 is made with the receiving chamber 4 communicated with each other and closed, the metaten camera 5 and the clarification chamber 6, as well as the open two-section chamber 7 with sections 8 and 9 and biofilters located in these sections. Sections 8 and 9 are made, respectively, in the form of direct (top-down) and reverse (bottom-up) wastewater flows, between which a dividing wall 10 is installed. The return biofilter is placed in section 9 of chamber 7 above the biofilter in section 8, with this dividing wall 10 is equipped with a removable drain shelf 11 installed in its upper part, with the orientation of the drain of the shelf in the center of the biofilter in section 8. The biofilters in sections 8 and 9 can be made in the form of blocks of frame rectangles interconnected in a parallelepiped x plastic frames 12 (see Figs. 3 and 4) with a network-shaped load fixed to them in the form of a polymer net 13, while inside the box, in planes perpendicular to its longitudinal axis and along this axis, transverse are fixed with a pitch of at least 15 mm polymer nets 14. The size of the cells of the longitudinal and transverse nets is not more than 10 mm · 10 mm. Cross meshes are knotted to longitudinal meshes as shown in FIG. 4. Bundles of 15 polymer fibers are fixed in the cells of the longitudinal and transverse grids, the length of which should be no more than the step of securing the transverse grids in the frame blocks. Each biofilter can be formed either by one block, or several (smaller in size) blocks with a network-like loading. The chamber 4 is in communication with the chamber 5 by means of a perforated section 16 made in the lower part of the wall of the chamber 5. Section 9 of the biofilter of the chamber 7 is made inlet and communicated by means of the perforated section 17 made in its lower part, with the chamber - metatenk 5, and the upper overflow in the form a drain shelf 11, with a section 8, made outlet and communicated with the clarification chamber 6 by means of a perforated section 18, made in its lower part. The perforated section of the wall between the adjacent - chambers - metatenka and the open chamber is made in the form of vertical slots with a width of at least 20 mm and a height from the bottom of the tank of up to 0.5 m, which eliminates possible clogging by sediment and large mechanical impurities. The tank 1 is made on the basis of calculating its penetration into the soil, while the length of the neck 19 communicated with the atmosphere is made from the condition of the location of its upper cut above the soil surface. The neck of the open chamber of the biofilter can be equipped with a vapor tight cover 20. In an embodiment, the loading of the biofilter is made of bulk material, for example gravel, expanded clay or slag, with a grain size of 15-80 mm fractions, placed in containers 21 with permeable walls. It is advisable that the containers 21 were connected at least in two garlands, for example, by means of flexible rods 22 (see Fig. 6), the ends of the upper upper rods of which were brought out to the upper cut of the neck 19 for raising or lowering the garlands in the chamber section biofilter. This greatly simplifies and facilitates the installation and dismantling of raising and lowering the biofilter when cleaning the reactor. The same applies to frame blocks with network-like loading.

In general, the proposed installation is a monoblock in the form of a solid rectangular self-supporting tank with a neck and partitions, made of sheet plastic, for example homogeneous polypropylene, with a sheet thickness of 5-20 mm. Homogeneous polypropylene does not rot, has a long (at least 50 years) service life, is easy to process and has ample mechanical characteristics.

The installation is as follows.

The treated wastewater by gravity pipe 2 flows by gravity into the receiving chamber 4, where coarse mechanical impurities are deposited from drains. From the chamber 4, wastewater, by gravity (through holes in the perforated section 16 in the lower part of the wall between chambers 4 and 5) enters the chamber - meta-tank 5, in which anaerobic decomposition of organic substances contained in water occurs. Then, the wastewater through the perforations in section 17 in the lower part of the partition between chambers 5 and 7 enters sections 8 and 9 of the open two-section chamber 7, in contact with biofilters. As a result of contact of the charge with wastewater, a biofilm of immobilized microorganisms is formed on its surface. The high physiological activity of the attached microorganisms is associated with intensive sorption on the surfaces of the net-like loading of organic substances, enzymes, bacteria, and the special arrangement of microorganisms at the interface, which is advantageous from the point of view of the energy consumption of bacteria. All of the above leads to an increase in the resistance of attached microorganisms to adverse environmental conditions, prolongation of action and acceleration of their metabolic activity. The processed fluid freely flows around the mesh threads and bundles of fibers fixed on it, thereby achieving (due to the developed interaction surface) the necessary mass transfer between wastewater and microorganisms attached to the surface of the network-like loading. With excessive fouling of the surface of the grid and beams, the plaque is separated from the load under the influence of gravity and the movement of water, which ensures self-regeneration of the network-shaped load. Due to the organization of the reverse and direct currents of the movement of wastewater through the biofilter, as well as when overflowing through the drain shelf 11 of the partition 10, at the entrance to the outlet section 8, the wastewater is aerated to a degree sufficient for biological oxidation processes to occur. In general, with the passage of waste water through sections 8 and 9, the necessary (for its purification) duration and degree of mass transfer is achieved. The number of net-shaped loading panels in the biofilter blocks depends on the value of the initial indicators of wastewater pollution, the hydraulic load on the installation, the required value of the indicators of wastewater pollution at the outlet of the installation.

The mechanism of operation of a biofilter with loading from a bulk material (gravel, expanded clay or slag) is similar to the operation of a biofilter with a net-like loading, with the only difference being that loading from a bulk material does not have the property of self-regeneration. In addition, the mass transfer surface of this load is less than that of a network-like one, however, volumetric loading is cheaper and less labor-consuming to manufacture (in comparison with a network-like one).

The wastewater that has passed the purification stage in the biofilter enters (through the perforation of the section 18 in the lower part of the wall between chambers 7 and 6) into the clarification chamber 6, where it finally settles from the suspended sludge and is discharged from the unit through the pipe 3.

It is advisable that the treatment plant be equipped with an alarm for blockages in the discharge pipe. In addition, the equipment of the neck 19 of the biofilter chamber with a vapor-tight insulated lid 20 allows you to place the installation near residential buildings and ensure operability in the winter. In this embodiment, the release of unpleasant odor is completely eliminated, because the exhaust gases are discharged into the supply sewer pipe. To ventilate the internal sewer network above each riser, it is necessary to equip the hood, which is displayed on the roof of a residential building to a height of at least 0.3 m.

Thus, the installation provides complete oxidation of wastewater by aerobic-anaerobic microflora. The use of a biofilter with a network-like or volumetric loading allows to achieve a degree of wastewater treatment of more than 95% by BOD, more than 93% by suspended solids, more than 60% by nitrates and phosphates, regardless of the initial values of wastewater pollution indicators.

Installation of the installation is carried out in a pit on a compacted underlying layer, followed by sprinkling. Depending on the specific conditions, the treated effluents are filtered in the ground or discharged to the terrain after the cleaning step in a sand-gravel filter or UV disinfectant. A feature of the proposed installation is the simplicity of technology, environmental friendliness, minimal cost and lack of need for power supply under favorable local hydrological conditions. Under unfavorable hydrological conditions, the clarification chamber 6 performs the function of a storage tank - a settler of purified water, while water is drained by means of a submersible drainage pump into the distribution network of the filtration trench (not shown conditionally).

The installation is carried out in automatic mode and does not require daily maintenance. Visual control of the correct operation of the installation is carried out no more than once every two weeks with the lid open. Sludge removal from the installation is carried out approximately once a year, when the removable shelf 11 is removed and the biofilter is loaded, after which the contents of the tank are pumped out. The installation of the shelf 11 and the loading of the biofilter is carried out in the reverse order. The installation provides the purification of domestic and industrial biologically treated wastewater from organic impurities to the level of requirements of regulatory documents in force in Russia.

Claims (9)

1. Installation for biological wastewater treatment, including a reservoir, a system for supplying source wastewater, a discharge of treated wastewater and a biofilter, characterized in that the reservoir is partially open with hydraulically interconnected, closed by a receiving chamber, a meta-tank and a clarification chamber, as well as a biofilter chamber with at least two sections, hydraulically interconnected, between which a longitudinal dividing wall is installed with a drain shelf, made in its upper part and, while the biofilter chamber is provided with a neck in communication with the atmosphere, and the biofilter is placed in both sections of this chamber, one of the sections of which is made inlet and hydraulically connected to the metaten chamber, and the other is made out, and hydraulically connected to the clarification chamber. 2. Installation according to claim 1, characterized in that the height of the neck of the biofilter chamber is made from the condition that its inlet slice is located above the soil surface with a reservoir buried in the soil. 3. Installation according to claim 1, characterized in that the neck of the biofilter chamber is equipped with a vapor tight cover. 4. Installation according to claim 1, characterized in that the receiving chamber, the camera is a metaten, the biofilter chamber and the clarification chamber are hydraulically interconnected due to perforated sections made in the lower parts of the walls between adjacent chambers. 5. Installation according to claim 4, characterized in that the perforated section of the wall between the adjacent chamber - metaten and the biofilter chamber is made in the form of vertical slots with a width of at least 20 mm and a height of up to 0.5 m 6. Installation according to claim 1, characterized in that the biofilter loading is made in the form of frame blocks of rectangular plastic frames with a polymer mesh fastened together in a parallelepiped, while inside the parallelepiped, in planes perpendicular to its longitudinal axis and along this axis with pitch not less than 15 mm, transverse grids are fixed. 7. Installation according to claim 6, characterized in that the mesh size of the polymer mesh is not more than 10 mm × 10 mm. 8. Installation according to claim 6, characterized in that in the cells of the polymer mesh are fixed bundles of polymer fibers, the bundle length of which is not more than the step of fixing the transverse grids in the frame blocks. 9. Installation according to claim 1, characterized in that the biofilter loading is made of bulk material, for example, gravel, expanded clay or slag with a grain size of fractions of 15-80 mm, placed in containers with permeable walls, connected in a garland.

Images