RU156666U1 - DEEP BIOLOGICAL WASTE WATER TREATMENT STATION - Google Patents

Abstract

1. A station for deep biological wastewater treatment, containing a receiving tank, an aeration tank and a sump, separated by partitions, while the aeration tank and the sump are separated by a cutoff set at an angle to the bottom of the body, characterized in that the sump is equipped with an airlift with an outlet channel directed to the aerotank. 2. A deep biological wastewater treatment plant according to claim 1, characterized in that the angle between the cut-off planes and the bottom is from 5 to 45 degrees. A deep biological wastewater treatment plant according to claim 1, characterized in that the cut-off is not connected to the bottom and the gap between the lower edge of the cut-off and the bottom is from 50 to 150 mm. A deep biological wastewater treatment plant according to claim 1, characterized in that the cut-off does not reach the upper edge of the housing and the gap between the upper edge of the cut-off and the upper edge of the housing is from 100 to 500 mm. Station of deep biological wastewater treatment according to PP. 1-4, characterized in that it contains a stabilization camera. 6. Station of deep biological wastewater treatment according to PP. 1-4, characterized in that the body, cutoff and baffles are made of polymeric materials.

Description

The proposed utility model relates to the design of domestic wastewater treatment plants designed for deep biological wastewater treatment by wastewater treatment plants.

The designs of biological wastewater treatment plants are based on a number of standard elements: a casing consisting of a bottom, side and front walls, internal partitions dividing the casing into separate, hydraulically interconnected compartments - a receiving compartment, aeration tank and a sump. Also, the stations contain a number of elements located inside the case: airlifts, aerators, pumps, level sensors, sensors of electrical and hydraulic equipment, pipelines and others. The above elements can be made of various materials, mainly from polymers.

As the closest analogue, the device according to utility model No. 137778, C02F 3/12, “STATION OF DEEP BIOLOGICAL WASTE WATER TREATMENT” was adopted. The deep biological wastewater treatment plant contains hydraulically communicating compartments: a receiving tank, an aeration tank and a sump, while the aeration tank and a sump are separated by a cut-off installed at an angle to the bottom of the body, while the angle is from 5 to 45 degrees, while the cut-off is not connected to the bottom , and the gap between the lower edge of the cutoff and the bottom is from 50 to 150 mm. It is possible to perform a station in which the cut-off does not reach the upper edge of the housing and the gap between the upper edge of the cut-off and the upper edge of the housing is from 100 to 500 mm.

This device solves its task of excluding from the wastewater treatment operation to mechanically remove excess sludge from the sump, but has its drawbacks in the form of insufficient wastewater treatment and the possibility of clogging the drainage system.

The technical task of the proposed utility model are:

- improving wastewater treatment by reducing the concentration of waste sludge in the sump;

- preventing overflow of the sump with spent sludge, by increasing the thickness of the layer of clean water in the sump from 3-5 cm to 7-10 cm,

- preventing clogging of the drainage system.

The problem is solved as follows.

The deep biological wastewater treatment plant contains hydraulically communicating compartments: a receiving tank, an aeration tank and a sump, while the aeration tank and a sump are separated by a cut-off installed at an angle to the bottom of the body, while the angle is from 5 to 45 degrees, while the cut-off is not connected to the bottom , and the gap between the lower edge of the cutoff and the bottom is from 50 to 150 mm, while the sump is equipped with an airlift with an outlet channel directed to the aeration tank, that is, the possibility of pumping the waste sludge into the aeration tank. It is also possible to perform a station in which the cut-off does not reach the upper edge of the housing and the gap between the upper edge of the cut-off and the upper edge of the housing is from 100 to 500 mm.

An embodiment of the station is also possible, in which, in addition to the above compartments, a compartment of the stabilization chamber is contained, hydraulically connected to the aeration tank.

The utility model is illustrated by drawings (Fig. 1), which shows a general view of the station (one of the external walls is not displayed), the following elements are shown:

- receiving tank 10; aeration tank 11, sump 12, stabilization chamber 13,

- internal partitions; cutoff 22;

- aerators 30, airlifts 32, 33, 34;

- inlet 40, drain 41, emergency overflows, electric and hydraulic control unit.

Wastewater enters the receiving tank 10, where the primary stage of purification by means of an aerator takes place, then, with the help of airlift 32, partially purified water enters the aerotank 11, where the main wastewater treatment is carried out.

From the aeration tank 11, water, through the gap between the cut-off 22 and the bottom, flows by gravity to the sump 12, where the separation of sludge and purified water occurs; purified water by gravity leaves the system through drain 41, and the sludge settles on at least part of the bottom of the sump 12. If the sump 12 reaches a predetermined level with liquid (for example, in the case of a large one-time discharge of sewage into the station), airlift 33 turns on and starts pumping liquid from the sump 12 to the aeration tank 11. The achievement of a predetermined level is determined, for example, by a float switch or a sensor of another known type (not shown in the drawing).

The proposed modification of the station ensures its operation, in which the sludge does not clog the sump chamber and, therefore, there is no need for its mechanical periodic removal. In the case of accumulation of excess sludge in the aeration tank 11, it is removed by airlift 34 into the stabilization chamber 13. This increases the thickness of the layer of clean water in the sump from 3-5 cm to 7-10 cm, and, consequently, the level of water purification from the station, which also prevents clogging of the drainage system.

The system also preferably comprises an electric and hydraulic control unit located inside it, which controls the water treatment cycles; in the partitions between compartments emergency overflows (not shown) can be performed.

The material of most of the elements of the housing are mainly polymeric materials, for example, polypropylene: homogeneous, foamed three-layer integral; standard aerated devices are used as aerators and airlifts.

Claims (6)

1. Station for deep biological wastewater treatment, containing a receiving tank, aeration tank and sump separated by partitions, while the aeration tank and sump are separated by a cut-off installed at an angle to the bottom of the casing, characterized in that the sump is equipped with an airlift with an outlet channel directed into the aeration tank. 2. Station for deep biological wastewater treatment according to claim 1, characterized in that the angle between the cut-off and bottom planes is from 5 to 45 degrees. 3. The station for deep biological wastewater treatment according to claim 1, characterized in that the cut-off is not connected to the bottom and the gap between the lower cut-off edge and the bottom is from 50 to 150 mm. 4. The station for deep biological wastewater treatment according to claim 1, characterized in that the cut-off does not reach the upper edge of the housing and the gap between the upper edge of the cut-off and the upper edge of the housing is from 100 to 500 mm. 5. Station for deep biological wastewater treatment in paragraphs. 1-4, characterized in that it contains a stabilization chamber. 6. Station for deep biological wastewater treatment in paragraphs. 1-4, characterized in that the housing, cut-off and partitions are made of polymeric materials.

Images