RU2410335C2 - Waste water treatment apparatus - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: apparatus for biological treatment of waste water has a nitrifier-denitrifier aerotank (2) merged with a settling tank (4), having an anoxic zone and a nitrification zone, pipes for inlet and outlet of waste water, circulation and outlet of excess biomass, circulation of nitrate-containing waste water, air ducts and aerators (3), as well as air lifts for pumping returned active sludge (6) and intra-zone recirculation of biomass and nitrate-containing liquid (5). The apparatus is fitted with a split gas-collecting cap (7) lying in the nitrification zone below the level of the sludge mixture outside the perimetre of the settling tank (4) at a rising angle to the air lifts for intra-zone recirculation of biomass and nitrate-containing liquid (5), mounted at the point of intersection of the rising angles of the gas-collection cap.

EFFECT: high efficiency of treating waste water and high stability of operation of the system while lowering cost of treating waste water and environmental pollution at the same time.

2 cl, 4 dwg, 1 tbl

Description

Installation for wastewater treatment from pollution can be used for complete biological wastewater treatment of populated areas and separately located objects (rest houses, sanatoriums, cottage and shift villages, etc.).

Known structures for biological wastewater treatment, including aeration tanks-mixers and aeration tanks-displacers (see N.I. Likhachev, I.I. Larin, S.A. Khaskin and others. Sewerage of populated places and industrial enterprises / Designer Handbook. - M .: Stroyizdat, 1981. - P.227, 228).

Aeration tanks mixers are characterized by a uniform supply along the length of the structure of the source fluid and activated sludge. Complete mixing of wastewater with a sludge mixture in them ensures equalization of sludge concentrations and the biochemical oxidation process, therefore aeration tanks mixers are more suitable for the treatment of concentrated wastewater with sharp fluctuations in their flow rate, composition and amount of pollution. Propellant aeration tanks have a concentrated inlet of the starting fluid and circulating sludge at the beginning of the construction. The increased concentration of contaminants at the beginning of the facilities provides an increase in the rate of their oxidation, which slightly reduces the overall period of aeration, but changing the composition of wastewater along the length of the aeration tank makes it difficult to adapt the sludge and reduces its activity, i.e. reduces the efficiency of wastewater treatment. In addition, the need to separate the sludge mixture requires secondary settling tanks, devices for circulation and removal of excess biomass, which ultimately increases the cost of wastewater treatment.

It increases the efficiency and reduces the cost of wastewater treatment by blocking the aeration tank with a secondary settling tank in one tank, while the circulation of return sludge is ensured by airlifts (installations of Reited Air (USA), Bayogest, Rapid-Block (England), as well as blocks treatment plants with a capacity of 50-200 m ³ / day, developed by TsNIIEP of engineering equipment (see Goncharuk E.I., Davidenko A.I. and others. Small-sized sewage treatment plants. - K .: Budivelnik, 1974. - P.153, 165).

However, the air supply to the airlifts in these installations causes increased energy costs, which ultimately increases the cost of wastewater treatment.

Closest to the technical nature of the claimed invention is the "Installation of biological wastewater treatment" according to the patent of the Russian Federation No. 2152907, class. C02F 3/00, dated July 20, 2000, which contains an aeration tank of a nitri-denitrifier combined with a sump, having an anoxide zone and a nitrification zone, pipelines for supplying and discharging waste water, circulating and discharging excess biomass, circulation of nitrate-containing wastewater, air ducts and aerators, airlifts for pumping return activated sludge and intraband recirculation of biomass and nitrate-containing liquid.

However, this installation has several disadvantages, the main of which are:

- increased time spent in the nitrification zone;

- the need for additional energy consumption when it is necessary to pump a recirculation nitrate-containing sludge mixture into the denitrification zone;

- environmental pollution by wastewater and solid phase products (carbon dioxide and methane);

- the sensitivity of the biocenosis to the negative effect of the original fluid with sharp changes in its composition.

As a result, this reduces the efficiency of treatment and increases the cost of wastewater treatment, and also leads to an additional charge for environmental pollution.

The objective of the invention is to increase the efficiency of wastewater treatment from pollution and increase the stability of the system while reducing the cost of wastewater treatment and environmental pollution.

The objective of the invention is achieved in that the known biological wastewater treatment plant, including a nitri-denitrification aeration tank combined with a sump, having an anoxic zone and a nitrification zone, sewage supply and discharge pipelines, excess biomass circulation and drainage, nitrate-containing wastewater circulation, air ducts and aerators, airlifts for pumping return activated sludge and intraband recirculation of biomass and nitrate-containing liquid, equipped with a split gas collection visor located in the zone itrifikatsii below the level of the mixed liquor from the outside perimeter of the settler at an upward angle to the air lift recycling of biomass and the intraband nitratosoderzhaschey liquid mounted at the intersection angles of the ascending gas-collection hood. At the same time, the gas-collecting visor is cut into at least two equal parts. The design of the split gas collection visor is shown in Fig.1.

The invention is illustrated by drawings, which presents its plan (figure 2), section 1-1 (figure 3) and section 2-2 (figure 4).

The wastewater treatment plant from pollution has a housing 1 and consists of an aeration tank of a nitrifying denitrifier 2 with air ducts and aerators 3, a secondary settling tank for separating the sludge mixture 4, airlifts of intraband recirculation of biomass and nitrate-containing liquid 5, and airlifts of return activated sludge 6. From the outside along the perimeter of the sump at an ascending angle to the airlifts of intraband recirculation of biomass and nitrate-containing liquid 5, there is a split gas collection visor 7. The installation has discharge pipelines and biogas biomass 8, a wastewater supply 9, a sludge mixture collection tray 10 and a sludge mixture transportation pipe 11, a treated sewage collection tray 12, as well as an anoxic zone 13 and a nitrification zone 14.

Installation for wastewater treatment from pollution works as follows.

The wastewater freed from debris and sand flows through pipeline 9 to the anoxic zone 13 of the aeration tank of the nitrification-denitrifier 2, where recirculation nitrate-containing liquid and return activated sludge also enter with the help of airlifts 5 and 6. In the volume of the denitrifier with mechanical stirring under anoxic conditions (stirrer not shown), nitrates and nitrites are reduced to gaseous nitrogen and organic substances are oxidized to water and carbon dioxide. Nitrogen and carbon dioxide are released into the atmosphere. The waste fluid enters the nitrification zone 14 of the aeration tank of the nitrification-denitrifier 2, aeration of which is carried out through the aerators 3 located at the bottom. The exhaust air enriched in carbon dioxide, which enters the gas collection hood 7, located in the nitrification zone below the silt mixture around the perimeter of settler 4, carries away nitrate-containing liquid, providing intraband recirculation and its return to the anoxide zone 13 using airlifts 5. The sludge mixture is collected in the tray 10 and flows through the pipe 11 to the secondary toynik 4, wherein separated into purified liquid and biomass. Active sludge settling on the bottom of the sump, with the help of airlift 6 returns to the anoxide zone, and the treated water is collected by trays 12 located in the upper inner part of the sump, and is discharged outside the installation.

Excess sludge from the secondary sump is periodically removed from the system through line 8 under hydrostatic pressure.

In the installation compared with the prototype achieved the following advantages:

- reduced residence time of wastewater in capacities by 25-30%, which adequately reduces the cost of treatment;

- the concentration of carbon dioxide in gas emissions into the environment is reduced by 30-35%;

- part of the energy spent on transportation of the recirculation nitrate-containing liquid to the anoxide zone is saved;

- increased efficiency of wastewater treatment from nutrients without adding an additional amount of organic substances;

- increased stability of the biocenosis of the system to the negative effects of wastewater with possible salvo emissions of pollution.

Comparative technical and economic indicators of the base and proposed installation No. p / p The name of indicators unit of measurement Basic setting Suggested installation one Capital construction costs conventional unit one 0.8 2 Operating costs conventional unit one 0.8 3 The time required to change the process parameters: hour - oxidation of organic substances four 3 - nitrification 8 5 four Content of ingredients in treated wastewater mg / l As for facilities for the full biological treatment of domestic wastewater As for facilities for the full biological treatment of domestic wastewater

A decrease in the residence time of wastewater in the treatment bioreactors was achieved by providing microorganisms of autotrophs with an additional amount of mineral carbon in the form of carbon dioxide introduced together with a recirculating nitrate-containing liquid during the destruction of organic substances to final forms (Н ₂ О + СО ₂ ).

The energy savings are due to the use of a nitrate-containing liquid as an energy carrier in the anoxic zone of the exhaust air collected by the gas collection visor located in the nitrification zone.

The decrease in the concentration of carbon dioxide in gas emissions into the environment is explained by its partial use by microorganisms as a substrate.

The increase in the efficiency of wastewater treatment from nutrients is due to the use of microorganisms as a substrate of carbon dioxide, supplied together with a recirculating sludge mixture.

The increased stability of the biocenosis to changes in the composition of the initial fluid is explained by the presence of intrazonal biomass recirculation. The aeration tank is divided into conditional zones formed by the areas of airlift operation, in which biomass circulates, adapted to the chemical composition of pollution in this part of the aeration tank, which creates a stable trophic food chain at each stage of biodegradation of wastewater ingredients. The proposed model of the bioreactor retains the advantages of the aeration tank-mixer and aeration tank-displacer, smoothing out their disadvantages.

Claims (2)

1. Installation of biological wastewater treatment, including aeration tank nitri-denitrifier combined with a sump, having an anoxic zone and a nitrification zone, pipelines for supplying and discharging wastewater, circulation and removal of excess biomass, circulation of nitrate-containing wastewater, air ducts and aerators, airlifts for pumping return activated sludge and intraband recirculation of biomass and nitrate-containing liquid, while the installation is equipped with a split gas collection visor located in the nitrification zone below the sludge level mixtures from the outside along the perimeter of the sump at an ascending angle to the airlifts of intraband recirculation of biomass and nitrate-containing liquid mounted at the intersection of the ascending corners of the gas-collecting peak. 2. The biological wastewater treatment plant according to claim 1, characterized in that the gas collecting hood is cut into at least two equal parts.

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