RU78790U1 - SEWAGE TREATMENT PLANT - Google Patents

Abstract

An installation for wastewater treatment, containing sequentially connected tanks made in the form of an aeration tank, a secondary settling tank, a thin-layer settler unit and a drainage tray connected to the purified water drainage pipeline, a purified wastewater supply pipeline connected to an aeration tank, in which cassettes with biofuel are installed, inter-volume partitions, aeration system, including an air duct and aerators located in the lower part of the aeration tank, an emptying line of the accumulating hopper located in the lower part of the installation, an airlift for supplying activated sludge to recirculation, made in the form of a pipeline connecting the accumulating hopper and aeration tank, and an airlift for the discharge of excess sludge, made in the form of a pipeline connected to the aeration tank, while overflow windows are made in the upper part of the aeration tank partition with a thin-layer cleaning unit.

Description

The utility model relates to wastewater treatment technology, in particular, to biochemical treatment of organic substances, and can be used for biochemical treatment of domestic and industrial wastewater.

A known wastewater treatment plant [1], comprising an aeration tank, an aerobic stabilizer and a centrally located secondary sump, traps with drainage trays installed in the aerobic stabilizer trap with the ability to move around a horizontal axis, an inclined shield with a hinge, and also horizontally located in the upper part installation of a pipeline connecting the drainage tray of the aerobic stabilizer and aeration tank.

The disadvantage of this installation is the low efficiency of wastewater treatment.

A known installation for wastewater treatment and treatment of sludge [2], containing a primary sump with pipelines for supplying wastewater and drainage of clarified water and sludge, aeration tanks of the first and second stages with aerators, frames with a filler made of nylon fiber and fiberglass in the form of "ruff ", With a mesh box with loading, thin-walled modules, as well as compressed air pipelines, aeration tanks aerators are located along and across the corridors of the latter, frames with a filler are placed in the primary settling tank with an adjacent Niemi to the aerators in the aeration tank of the second stage mesh ducts aerators placed over the aeration tank of the first stage, a thin-film modules - in the sump of the second stage, the sump of the second stage is connected to a conduit with a primary clarifier.

The disadvantage of such a wastewater treatment system is also the insufficient efficiency of wastewater treatment and a large amount of equipment.

Closest to the proposed technical solution is a known installation for wastewater treatment [3], containing a chamber for quenching the water head, an averager for the water flow with a quenching chamber for the water head and with a hydraulic system

mixing, including the first pump and pipelines, aeration tank, divided by a suitable partition into two stages, aeration system, including a compressor with pipelines and aerators, the first of which is located in the first stage of the aeration tank, the second pump, the inlet of which is connected to the suction manifold, and the output through the corresponding pipeline - with a denitrifier containing a load, a tank with purified water located at the outlet of the installation, while the sewage supply pipeline is connected to the inlet of the averager of the water flow, and the purified water drain pipe is connected to the outlet of the purified water tank, in the hydraulic mixing system, the inlet of the first pump is connected to the suction pipe for withdrawing wastewater from the averager, and the outlet of the specified pump is connected to a pipe for returning part of the wastewater to the averager and a sewage supply pipe to the denitrifier , a filtering membrane module with a vacuum manifold located in the second stage of the aeration tank, a third pump installed in the line for the selection of purified water from the filter a membrane module, a fourth pump installed in the washing water withdrawal line from the purified water tank, a vacuum gauge connected to the vacuum manifold, the outlet of the purified water extraction line from the filtering membrane module being connected to the purified water reservoir inlet, and the outlet of the washing water withdrawal line from the tank with purified water is connected to a filtering membrane module connected to the suction collector.

The disadvantage of this installation is the complexity of the treatment plant, due to the large amount of equipment.

The technical result, which consists in eliminating this drawback, is achieved in the proposed installation for wastewater treatment, containing series-connected containers made in the form of an aeration tank, a secondary sump, a block of a thin-layer sump and a catchment channel connected to the purified water discharge pipe, the pipeline for supplying the treated waste water connected to the aeration tank, in which there are bio-loaded cartridges, inter-capacity partitions, an aeration system, including an air duct and aerators, located dix the bottom of the aeration tank, discharge conduit collecting hopper arranged at the bottom

part of the installation, in that it contains an airlift for supplying activated sludge to recirculation, made in the form of a pipeline connecting the collecting hopper and aeration tank, and an airlift for removing excess sludge, made in the form of a pipeline connected to the aeration tank, while in the upper part of the partition of the aeration tank with the block thin-layer cleaning performed overflow windows.

The essence of the utility model is illustrated by drawings, where figure 1 shows the technological block diagram of the installation (front view in section); figure 2 presents a view of the installation from above.

The wastewater treatment plant contains series-connected containers made in the form of an aeration tank 1, a secondary sump 2, a block 3 of a thin-layer sump and a catchment tray 4 connected to a purified water discharge pipe 5, a purified sewage supply pipe 6 connected to the aeration tank 1, and accumulating hopper 7. In aeration tank 1, cassettes 8 with bio-loading are installed. Between the said containers, inter-capacity partitions 9, 10 and 11 are made. In the upper part of the partition 9 of the aeration tank 1, overflow windows 12 are made with a thin-layer cleaning unit 7. The installation also contains an aeration system including an air duct 13 and aerators 14 located in the lower part of the aeration tank 1, a pipeline 15 emptying the accumulating hopper 8 located in the lower part of the installation, the airlift 16 supplying activated sludge to recirculation, made in the form of a pipeline connecting the accumulating hopper 8 and the aeration tank 1, and the airlift 17 drainage th sludge formed as a pipe connected to the aeration tank 1.

Gates 18 and 19 are installed on pipelines 6 and 15.

The plant carries out biological wastewater treatment in the full oxidation mode, which provides a high degree of purification.

Installation works as follows.

Purified wastewater from the pumping station (not shown in the drawing) or by gravity flows through open valve 18 (shown by an arrow) through pipeline 6

in the aeration tank 1. For biological wastewater treatment, a multi-stage process with an attached biocenosis of microorganisms is provided in the installation.

A characteristic feature of the attached biocenosis is its high resistance to changes in hydraulic loads, concentrations and temperature.

Aerotank 1 removes the bulk of organic contaminants using attached aerobic microflora. Part of the volume of the aeration tank 1 is filled with bio-loading in the form of cassettes 8.

The aeration tank 1 is equipped with a pneumatic system of fine-bubble aeration of the Polypor type manufactured by NPF'ETEK containing an air duct 13 and aerators 14 located in the lower part of the aeration tank.

From the aeration zone, wastewater through overflow windows 12 enters the degassing zone, then to block 3 of the secondary sump 2, where it is clarified by gravity settling and filtering through a suspended layer of activated sludge.

The purified water enters the drainage tray 4 and then through the pipeline 5 is discharged from the installation (indicated by the arrow) through the pipeline 5.

Active sludge accumulates in the storage hopper 7 of the secondary sump 2 and the airlift 16 is fed for recycling to the aeration zone. Excess activated sludge is removed using airlift 17.

The emptying of the capacities of the installation is carried out using the pipe 15 with the valve 19 open.

As a result of using the proposed installation, a degree of purification is achieved that meets the standards for fishery reservoirs.

Moreover, in relation to the closest analogue, a positive effect is achieved, consisting in reducing the amount of equipment and simplifying the design of the installation.

The installation is made in the form of a metal container, has small dimensions and light weight, which facilitates its installation, and allows transportation by road, rail and sea.

Information sources:

1. RF patent No. 785225, M.C. C02F 3/12, published. 1980.

2. RF patent No. 1710525, M. Cl. C02F 3/30, published 1992.

3. RF patent No. 58117, M. Cl. C02F 3/30, published 2006.

Claims (1)

A wastewater treatment plant containing series-connected containers made in the form of an aeration tank, a secondary sump, a thin-layer sump block and a drainage channel connected to a treated water drain pipe, a sewage supply pipe connected to an aeration tank in which biofeedback cassettes are installed, inter-capacity partitions, aeration system, including air duct and aerators located in the lower part of the aeration tank, discharge pipe for the accumulating hopper located the lower part of the installation, the airlift of the supply of activated sludge for recirculation, made in the form of a pipeline connecting the accumulating hopper and the aeration tank, and the airlift of removal of excess sludge, made in the form of a pipe connected to the aeration tank, with overflow in the upper part of the aeration tank with a thin-layer cleaning unit window.