RU2537611C2 - Apparatus for purifying household waste water - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: apparatus for purifying waste water comprises hydraulically series-connected settling and balancing tank (C1), an anaerobic unit (C2.1), an anoxic unit (C2.2), an oxide unit (C3), a membrane filter unit (C4) and auxiliary equipment. The settling and balancing tank (C1) comprises a device for receiving starting waste water; an anaerobic unit (C2.1) adapted to feed therein activated return sludge together with waste water from the oxide unit (C3); the oxide unit (C3) is adapted to feed therein return sludge from the membrane unit (C4) is provided with an aerating device (C0); and the membrane filter unit (C4) is provided with an aerating device (C0) and a vacuum device for removing purified water (H2.1) for discharge.

EFFECT: high efficiency of purifying waste water, achieving maximum allowable concentration of contaminants on BOD5, COD, ammonium and nitrate nitrogen, phosphate phosphorus, while ensuring small dimensions, mobility and universality of the apparatus, high reliability of the apparatus in conditions of a non-uniform qualitative and quantitative composition of the starting waste water.

12 cl, 1 dwg, 1 tbl

Description

The invention relates to the field of deep treatment of domestic and industrial wastewater in small-sized blocked installations, including those located on oil and gas platforms, terminals and ships. Most well-known small-sized plants treat wastewater only from organic impurities and do not include the removal of nitrogen and phosphorus compounds, which must be removed from wastewater from oil and gas platforms, terminals, and ships.

The prior art known "Installation for wastewater treatment from pollution" (RU 2410335 C2, publ. 24.02.2009). The biological wastewater treatment plant includes an aeration tank, a nitride denitrifier combined with a settling tank, having an anoxic zone and a nitrification zone, pipelines for supplying and discharging waste water, circulating and discharging excess biomass, circulating nitrate-containing wastewater, air ducts and aerators, and airlifts for pumping back activated sludge and intraband recirculation of biomass and nitrate-containing fluid. The installation is equipped with a split gas collection visor located in the nitrification zone below the sludge mixture 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 angles of the gas collection visor. The invention provides an increase in the efficiency of wastewater treatment and an increase in the stability of the system while reducing the cost of wastewater treatment and environmental pollution.

The advantage of the installation is to increase the stability of the biocenosis to changes in the composition of the initial liquid, however, a significant disadvantage of the installation is the lack of the possibility of anaerobic-anoxide-oxide (aerobic) treatment, as a result of which it is impossible to achieve deep purification from phosphorus and nitrogen, and the possibility of using this installation in conditions dynamic loads (pitching and vibration).

A known installation for biological wastewater treatment (RU 101704 U1, publ. 06/18/2010). The biological wastewater treatment plant is characterized in that it contains a rectangular tank divided by longitudinal partitions into four hydraulically connected corridors, each 130 m long, and forming the following sequence of technological zones: the first half of the first corridor is a dephosphation zone (anaerobic); the second half of the first corridor and the second corridor - denitrification zone (anoxide zone); third and fourth corridors - nitrification zone (aerobic zone); at the end of the second corridor, recirculation pumps are installed, which are connected to the pipeline supplying the denitrified sludge mixture from the end of the second corridor to the beginning of the first corridor; recirculation pumps are installed at the end of the fourth corridor, which are connected to the pipeline supplying the nitrate-containing sludge mixture from the end of the fourth corridor to the middle of the first corridor, while returning activated sludge containing nitrates is fed through a separate pipeline to the middle of the first corridor; mixing equipment is installed in the first and second corridors, for example, in the form of mixers for keeping the sludge in suspension, in the third and fourth corridors pneumatic aeration systems are installed, made, for example, in the form of aeration gratings.

The advantage of the installation is the possibility of deep purification of wastewater from nitrogen and phosphorus, however, the disadvantages of the described technical solution include the layout of the installation, in which it cannot be used on offshore structures and ships, because Installation is not small and mobile.

The prior art compact plant for biological treatment and disinfection of wastewater using membrane filtration, taken as a prototype (RU 70512 U1, publ. 09.10.2007).

A compact installation for biological treatment and disinfection of wastewater using membrane filtration includes means for supplying and transporting wastewater to be treated in a treatment unit consisting of an aeration tank having an aerobic and anoxic zone, an aerator installed in the aerobic zone, and a multi-cassette membrane module connected with a treatment unit, a wastewater disinfection unit, means for pumping wastewater, a means for discharging treated wastewater and a means for monitoring the operation of the installation, characterized the fact that the treatment unit is made with a serial connection of the aeration tank and a multi-cassette membrane module with wastewater recirculation by means of a recirculation pump.

The advantage of the installation is the use of membrane filtration, which reduces the volume occupied by treatment plants, and also contributes to an increase in the concentration of activated sludge, which in turn allows a higher and more stable quality of wastewater treatment compared to the traditionally known method of precipitation of activated sludge (active microorganisms) in secondary clarifiers.

The disadvantage of the installation is the lack of the possibility of anaerobic-anoxide-oxide (aerobic) treatment, as a result of which it is impossible to achieve deep purification from phosphorus and nitrogen.

The disadvantages of the described technical solution include the two-story layout of the installation, in which it cannot be used on offshore structures and ships.

The objective of the invention is to increase the efficiency of wastewater treatment (achieving the maximum permissible concentration of pollution by BOD5, COD, ammonium and nitrate nitrogen, by phosphorus phosphates) while ensuring the small size, mobility and versatility of the installation, as well as the possibility of its use on offshore structures and ships.

The technical result consists in improving the removal of nitrogen, phosphorus and suspended solids and increasing the reliability of the installation in conditions of uneven qualitative and quantitative composition of the source (waste) water.

The claimed installation of household wastewater treatment contains hydraulically serially connected sump-averager (C1), anaerobic block (C2.1), anoxide block (C2.2), oxide (aerobic) block (C3), membrane filtration block (C4) as well as auxiliary equipment. The settling tank-averager (C1) contains a device for receiving the source (waste) water, which then subsequently enters the anaerobic block (C2.1), the anoxide block (C2.2), the oxide (aerobic) block (C3) and the membrane filtration block (C4 ), which contains a vacuum device for removing purified water (permeate) for discharge and / or for reuse, while it is equipped with an aeration device to prevent contamination of the pores of the membranes. The anaerobic block (C2.1) is configured to feed back activated sludge into it along with wastewater from the oxide (aerobic) block (C3), the oxide (aerobic) block (C3) (C0) is configured to feed back sludge from it membrane block (C4.) and is equipped with an aeration device. Ancillary equipment includes pumping equipment (H1-H3), pipelines, valves (K1-K15), air supply system.

The return of activated sludge between the blocks can be carried out either by airlift or by means of a peristaltic pump. The use of a peristaltic pump for pumping activated sludge into the anaerobic block (C2.1) from the oxide (aerobic) block (C3) is preferred, because when using airlifts, the return sludge will inevitably be enriched with oxygen, which will adversely affect the anaerobic process.

Air lifts and aeration devices are connected to the air supply system. The air supply system may use an air supply compressor and / or a centralized air line. In order to activate aerobic processes, oxygen enriched air can be used.

An embodiment of the installation is preferred in which the averaging sump is equipped with a mechanical cleaning device, for example, a mechanical grill, or a macerator, or a drum filter, or a hydrocyclone mud filter, which will remove mechanical impurities such as threads or hair.

An embodiment of the apparatus is preferred in which the anaerobic unit is equipped with a mixing pump to prevent air oxygen from entering the anaerobic unit and to maintain activated sludge in suspension.

Preferred is an implementation of the installation in which the pumping equipment includes a reagent metering pump, a vacuum pump for the membrane unit, a membrane backwash pump, a wastewater treatment and circulation pump, an excess sludge removal pump and a tank emptying pump

Preferred is such an implementation of the installation, in which the installation of domestic wastewater treatment, further comprises a container for collecting purified water (permeate).

Preferred is such an implementation of the installation, in which the installation of domestic wastewater treatment further comprises a reagent tank for storing the membrane flushing reagent

Preferred is such an implementation of the installation, in which the installation of treatment of domestic wastewater further comprises an automatic control unit.

Preferred is such an implementation of the installation, in which the installation of domestic wastewater treatment further comprises a tank for collecting sludge.

Preferred is such an implementation of the installation, in which the installation of the treatment of domestic wastewater further comprises a disinfection unit for purified water (permeate).

The technical result is achieved by increasing the number of biological treatment units in comparison with analogues (the use of biological wastewater treatment according to the three-zone anaerobic-anoxide-oxide treatment scheme, which was previously used only for large volume aeration tanks) in order to provide deeper removal of nitrogen and phosphorus while using membrane filtration, which allows to increase the concentration of activated sludge (2.5-8 times) and, accordingly, reduce the overall dimensions of the installation, Obtain a high and stable quality of wastewater, as compared with a conventionally known method of deposition of the activated sludge (active microorganisms) in the secondary settling tanks.

A diagram of the claimed invention is shown in FIG. one.

The proposed installation contains biological treatment units (C1-C4) and is equipped with at least a device for supplying initial wastewater to it and a device for removing purified water — water for discharge and / or water for reuse (permeate water), as well as in FIG. . 1 shows auxiliary equipment, including pumping equipment (H1-H3), pipelines, valves (K1-K9), aerators (C0), air supply compressors (2.1 and 2.2), the collection tank for purified water (permeate) (C6), reagent a container for storing the membrane flushing reagent (C5), an automatic control unit, a container for collecting sludge.

In FIG. 1 marked:

C1 — averaging sump with a mechanical cleaning device (not shown in FIG. 1);

C2.1 - anaerobic block equipped with a mixing pump (not shown in Fig. 1);

C2.2 - anoxide block denitrifier;

C3 - oxide (aerobic) block nitrifier;

C4 - membrane filtration unit with ultrafiltration membrane modules;

H1 - reagent metering pump;

H2.1 - a vacuum pump for the membrane unit;

H2.2 - backwash pump of the membrane unit;

Н3.1 - feed pump for wastewater treatment and circulation mixing;

Н3.2 - pump for removal of excess sludge and emptying of tanks.

The operation of the claimed installation of wastewater treatment is as follows.

Wastewater enters the averaging sump (C1), where the wastewater is clarified by separation of mechanical impurities, floating impurities and fat. Then the clarified water through a mechanical cleaning device, for example, a mechanical grill, macerator or drum filter enters the biological treatment.

From the clarification tank (C1), water is pumped (H3.1) to the anaerobic block (C2.1), where phosphorus is removed. Here, for example, with a peristaltic pump (not shown in Fig. 1) or airlift, returning activated sludge is supplied from the compressor (2.1) together with waste water enriched in phosphates and nitrates from the oxide block (C3). To exclude air oxygen entering the anaerobic block and to maintain activated sludge in suspension, circulating mixing is carried out with a screw pump (H3.1).

From the anaerobic block (C2.1), the wastewater together with the sludge by gravity, for example, through an overflow device located under water, is fed into the anoxide block denitrifier (C2.2). In the anoxide block, nitrates are converted to molecular nitrogen. From the anoxide block (C2.2), wastewater by gravity, for example through the upper funnel, enters the lower part of the oxide (or aerobic) nitrification block (C3), where ammonium nitrogen is converted to nitrates. This unit is equipped with a fine bubble aerator (C0) for continuous aeration of activated sludge from the compressor (2.2). Returned activated sludge from the oxide block by airlift together with waste water from the compressor (2.1) is supplied to the anaerobic block (C2.1).

In order to maintain the necessary concentration of activated sludge, the return sludge is supplied to the oxide block, for example, by airlift from the compressor (2.1) from the membrane filtration block (C4).

From the oxide (aerobic) block (C3), the activated sludge mixture is supplied to the membrane filtration block (C4). The membrane filtration unit includes ultrafiltration membrane modules with a pore size of the membranes of 0.03-0.2 microns. Membrane modules can consist, for example, of sets of hollow fiber polymer membranes or plate membranes or ceramic tubular membranes and the like. Membrane filtration is carried out using a vacuum pump (H2.1). Permeate after passing through the membrane modules through a vacuum line enters the tank of purified water (C6) or is sent to the discharge.

The vacuum line is equipped with a vacuum gauge, an electromagnetic valve and a rotameter (not shown in Fig. 1). To prevent contamination of the pores of the membranes and continuous operation of the membrane unit with the help of the compressor (2.2), air is supplied to the lower part of the membrane unit through a fine bubble aerator (C0). Additional cleaning of the pores of the membranes is carried out by periodic backwashing using a backwash pump (H2.2), included in the vacuum line. Rinsing is carried out from the tank of purified water (C6). Periodically (depending on the membranes used, from 1 to 4 times a month), the pores of the membranes are washed with a chemical reagent, for example sodium hypochlorite. The membrane unit operates in automatic mode.

If additional disinfection is necessary from the collection tank for purified water (C6), permeate can be supplied to the disinfection unit, which, for example, consists of an ultraviolet disinfection unit (not shown in Fig. 1). The unit turns on automatically depending on the water level in the tank (C6). The disinfection unit can be installed by agreement with the consumer.

Thus, controlled biomembrane wastewater treatment systems increase the efficiency of wastewater treatment and plant design reliability. As a result, the proposed design of the installation ensures the achievement of quality indicators of treated water, approaching the maximum permissible for discharge according to sanitary-hygienic and fishery standards.

As confirmation of the possibility of obtaining the technical result indicated by the applicant, the results of an experimental verification of an experimental model of the OSV-5.0 wastewater treatment plant, developed on the basis of application materials that were carried out on real municipal wastewater from June to September 2013 at the Northern Station, are presented Aeration (SSA) of the St. Petersburg Vodokanal and the Chemical and Bacteriological Laboratory of Wastewater of the St. Petersburg Sewerage Branch of the State Unitary Enterprise "St. Petersburg Vodokanal" accredited in the Accreditation System of Analytical Laboratories (Centers) of the Gosstandart of Russia (State Register Number - ROSS RU. 0001.510962) (Table 1).

The average cleaning performance of the experimental setup: suspended solids - 6.3 mg / l, COD - 21 mg / l, BOD ₅ - 2.5 mg / l, N-NH ₄ - 2.9 mg / l, N-NO ₃ - 7.5 mg / l, P-PO ₄ - 0.56 mg / l, the average cleaning efficiency of the installation according to the indicators is: suspended solids - 97%, COD - 94.7%, BOD ₅ - 98.3%, N- NH ₄ - 86.7%, P-RS ₄ - 80.6%. Small deviations from the MPC norms are observed for ammonium nitrogen, which is explained in this period by heavily contaminated incoming water, as well as by the short period of the experimental verification of the installation.

The best results achieved in wastewater treatment (by BOD5, COD, ammonium and nitrate nitrogen, by phosphate phosphates) were obtained using hollow fiber ultrafiltration membranes simultaneously with anaerobic-anoxide-oxide (aerobic) wastewater treatment.

Claims (12)

1. Installation of domestic wastewater treatment, containing hydraulically in series connected sump-averager, anaerobic block, anoxide block, oxide block, membrane filtration block, as well as auxiliary equipment, including pumping equipment, pipelines, valves, air supply system, at least one aerating device, characterized in that the settling tank-averager comprises a device for receiving source, waste water; and the anaerobic block is configured to feed back activated sludge into it along with wastewater from the oxide block; the oxide block is configured to feed into it return sludge from the membrane block and is equipped with an aeration device; the membrane filtration unit is equipped with an aeration device and a vacuum device for discharging purified water to a discharge. 2. Installation according to claim 1, characterized in that a peristaltic pump is used to supply return activated sludge. 3. Installation according to claim 1, characterized in that the air supply system includes a compressor. 4. Installation according to claim 3, characterized in that in order to activate aerobic processes, the air supply system is configured to supply oxygen enriched air. 5. Installation according to claim 1, characterized in that the settling tank is equipped with a mechanical cleaning device, which is a mechanical grill, or a macerator, or a drum filter, or a mud filter of a hydrocyclone principle of operation. 6. Installation according to claim 1, characterized in that the anaerobic block is equipped with a mixing pump to prevent air from entering the anaerobic block and to maintain activated sludge in suspension. 7. Installation according to claim 1, characterized in that the pumping equipment includes a reagent metering pump, a vacuum pump for the membrane unit, a backwash pump for the membrane unit, a wastewater treatment pump and circulating mixing, an excess sludge removal and emptying pump capacities. 8. Installation according to claim 1, characterized in that the installation of domestic wastewater treatment further comprises a container for collecting purified water. 9. Installation according to claim 1, characterized in that the household wastewater treatment plant further comprises a reagent tank for storing the membrane flushing reagent. 10. Installation according to claim 1, characterized in that the domestic wastewater treatment plant further comprises an automatic control unit for the installation. 11. Installation according to claim 1, characterized in that the installation of domestic wastewater treatment further comprises a tank for collecting sludge. 12. Installation according to claim 1, characterized in that the installation of domestic wastewater treatment further comprises a disinfection unit for purified water.