RU209814U1 - Biological wastewater treatment plant - Google Patents

Abstract

The utility model relates to the biological treatment of household wastewater and wastewater close to them in composition and can be used to treat wastewater from individual residential buildings, cottages, recreation centers, sanatoriums, shift camps to the standards for discharge into fishery water bodies. The technical result of the proposed utility model is to improve the maintainability of the installation. The claimed technical result is achieved due to the fact that the biological wastewater treatment plant contains a housing divided into technological compartments and equipped with an air compressor, while a module for accommodating electrical elements is attached to the housing on its outer side, which is adapted to accommodate a socket for connecting a compressor and a connector for connecting an external power supply, and the compressor is installed in the module for accommodating electrical elements.

Description

The utility model relates to the biological treatment of household wastewater and wastewater close to them in composition and can be used to treat wastewater from individual residential buildings, cottages, recreation centers, sanatoriums, shift camps to the standards for discharge into fishery water bodies.

Known station for deep biochemical treatment of domestic wastewater [utility model patent RU 130603, publ. 07/27/2013], which includes a sewage inlet pipe, a plastic case with a lid. A three-section sump is located in the housing, including the first, second and third chambers separated by vertical walls with holes for wastewater overflow, a circulation pump located in the third chamber, while the pressure pipe of the circulation pump is connected to the bioreactor sprinkler. The station additionally includes a sealed module for placing electrical elements attached to the wall of the bioreactor, which is adapted to accommodate at least one socket for connecting a circulation pump and at least one connector for connecting an external power supply.

The disadvantage of the known station is the low maintainability due to the location of the pump (aerator) inside the sump, since when the sump is filled, access to the pump is limited.

The technical result of the proposed utility model is to improve the maintainability of the installation.

The claimed technical result is achieved due to the fact that the biological wastewater treatment plant contains a housing divided into technological compartments and equipped with an air compressor, while a module for accommodating electrical elements is attached to the housing on its outer side, which is adapted to accommodate a socket for connecting a compressor and a connector for connecting an external power supply, and the compressor is installed in the module for accommodating electrical elements.

Possible options for the implementation of the main technical solution, consisting in the fact that:

in the module for placing electrical elements, one more compressor is additionally placed;

in the module for placing electrical elements, an alarm block is additionally placed;

the module for accommodating electrical elements is made in the form of a cover for the housing;

the body is a single tank with compartments;

the body consists of two tanks with compartments combined with each other.

Thus, by installing a compressor in a module for placing electrical elements and fixing this module on the outside of the case, it was possible to increase the maintainability of the installation, i.e. it is possible to repair electrical equipment without releasing the body from the liquid. In addition, the reliability of the installation is increased, due to the fact that electrical equipment is not subject to flooding with liquid inside the housing.

The essence of the proposed technical solution is shown in the figures.

In FIG. 1 shows a side view of the installation with one of the options for attaching a module for placing electrical elements.

In FIG. 2 shows a general view of the installation with another version of the housing (two tanks).

In FIG. 3 shows a general view of the installation with another option for attaching a module for placing electrical elements (in the cover).

The biological wastewater treatment plant (Fig. 1-3) contains a housing 1, divided into technological compartments, and equipped with an air compressor (not shown in the figure).

At the same time, a module 2 is attached to the housing 1 from its outer side (side or top) to accommodate electrical elements, which is adapted to accommodate a socket (not shown in the figure) for connecting a compressor (not shown in the figure) and a connector (not shown in the figure) to connect an external power supply.

A compressor (not shown in the figure) is installed in module 2 to accommodate electrical elements. Additionally, one more compressor can be installed in module 2 (not shown in the figure).

In module 2, for placing electrical elements, an alarm block (not shown in the figure) can additionally be placed.

Module 2 for placement of electrical elements can be made in the form of a cover 3 for housing 1 (Fig. 3).

Housing 1 is a single tank with compartments (Fig. 1) or two combined tanks with compartments (Fig. 2).

The body 1 can be made in any shape, for example, cylindrical or rectangular.

Inside the building 1, the following blocks can be installed (not shown in the figure): a sludge pre-fermentation unit, an equalizer and a primary settling tank, an aerotank with anaerobic - aerobic treatment zones, a settling tank for the separation of activated sludge and purified water, devices for recycling and returning activated sludge, post-treatment and wastewater disinfection. Additionally, a device can be installed to prevent the formation of a crust and caking of the sludge in the sludge prefermentation unit. The device for generating air bubbles can be made using membranes. In this case, there is a post-treatment stage using a thin-layer sump, or fabric filters, or feed materials, or a combination of them. The plant provides a constant flow of discharged purified water and includes a stage of wastewater disinfection with uniform dissolution of the tableted chlorine reagent. The resulting sludge in the wastewater treatment process is mixed with quicklime (at least 30%), which allows them to be used as fertilizers for agricultural applications.

A high degree of purification, as well as complete biological disinfection of wastewater, makes it possible to reuse purified water for domestic and technical needs for irrigation and to use sewage sludge as fertilizers.

The inventive device is used for wastewater treatment, for example, as follows.

Waste water is fed into the plant, including the stage of receiving waste water, the stage of hydrolysis and pre-fermentation of sediments for the extraction of easily oxidizable organics, where water treatment is carried out using activated sludge in suspension, or a purification method with attached sludge is used; with carrying out the processes of denitrification, dephosphatization and nitrification in one structure without partitions or in a structure with partitions, in which the processes of denitrification and dephosphatization are provided by precipitation and sludge formed during the treatment process with a decrease in the amount of precipitation formed in the wastewater treatment process, with separation of the active sludge in the sump and subsequent sludge recycling.

Claims (6)

1. The biological wastewater treatment plant contains a housing divided into technological compartments and equipped with an air compressor, while a module for accommodating electrical elements is attached to the housing on its outer side, which is adapted to accommodate a socket for connecting a compressor and a connector for connecting an external power supply, which differs the fact that the compressor is installed in the module for placing electrical elements. 2. Installation of biological wastewater treatment according to claim 1, characterized in that another compressor is additionally placed in the module for accommodating electrical elements. 3. Installation of biological wastewater treatment according to claim 1, characterized in that an alarm block is additionally placed in the module for accommodating electrical elements. 4. Installation of biological wastewater treatment according to claim 1, characterized in that the module for accommodating electrical elements is made as part of a cover for the housing. 5. Installation of biological wastewater treatment according to claim 1, characterized in that the body is a single tank with compartments. 6. Installation of biological wastewater treatment according to claim 1, characterized in that the housing is two tanks with compartments combined with each other.

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