RU2355649C1 - Effluent water treatment device - Google Patents

Abstract

FIELD: treatment facilities. ^ SUBSTANCE: invention is aimed at treatment of effluent water with suspended activated sludge and can be mounted at vehicles. The effluent treatment device comprises casing (1) where there is equalising cell (4) with activated sludge, intake branch pipe (3) and aerators (6), activation cell (8) fitted with fine-bubble aerator (9) and connected to the equalising cell by bypass channel (7) and aerotank (11) fitted with fine-bubble aerator (9) and communicating with the activation cell by main pump (10). A sludge stabilising cell (15) is connected to aerotank (11) by sludge pump (14) and outlet cell (18) - by circulating pump (17). Sludge stabilising cell (15) is connected to equalising cell (4) by return sludge pipe (22). The outlet part of equalizing cell (4) prior to bypass channel (7) is separated from its inlet part by inclined arresting grid (5) with mixing aerators (6) being set on both sides of it. Aerotank (11) is connected to the activation cell by recirculating pump (12) made as an airlift; aerotank (11) is equipped with sensor to detect oxygen in liquid (36) which is connected to control unit (34); valve (38) is fitted at pipe (37) for the air supply to fine-bubble aerator (9); frame ultrafiltration filter (20) is mounted in outlet cell (18). ^ EFFECT: invention allows for decreasing the device dimensions along with upkeeping the effluent treatment degree and providing for the reliable device performance in the wide operation range. ^ 11 cl, 1 dwg

Description

The invention relates to self-regulating systems of biological wastewater treatment with activated sludge in suspension and can be used both for the treatment of domestic wastewater of detached houses and cottages, and for installation on vehicles, for example, on ships or railway cars.

There are known railway passenger cars equipped with sub-car tanks for collecting wastewater from car toilets [1], [2]. They provide convenience and comfort for passengers and do not pollute the environment, but they require the creation of expensive service points for pumping wastewater into the sewer network or for cleaning in stationary complexes, and the pumping process itself is also quite laborious, given the formation of “raw” sediment in the tanks sewage requiring periodic mechanical removal.

A known installation for deep biochemical wastewater treatment, containing a primary sump, aeration tank with an aerator, a secondary sump, sewage supply pipelines, sludge removal, recycled activated sludge, purified water discharge, an ozonation system in the primary sump, an additional sump communicated with the primary sump, a tank for purified water and pipelines for sludge and activated sludge connecting the lower parts of all sumps [3]. This technical solution is complex and not applicable on mobile complexes having a small vertical height with respect to horizontal dimensions.

Also known is the model range of units under the general name "YUBAS", which are fully automated systems of various levels of complexity [4], [5], [6], but applicable only as stationary wastewater treatment plants. In such stationary complexes for biological wastewater treatment, activated sludge containing a mixture of various bacteria and small microorganisms is used, and the activation process occurs with the constant presence of technological interruptions in the operation of the aeration system to create a rhythmic regime of oxygen dissolution with varying degrees of concentration (rhythmic aeration system ARS). This ensures the continuous interaction of wastewater with sludge in suspension and the activation of the full range of biochemical reactions necessary for deep biological wastewater treatment.

The closest analogue of the present invention is the technical solution described in patent RU No. 2305662 [6], including a leveling tank, an activation tank with a tubular well, aeration tank, a settling tank, a sludge stabilization chamber, a piping system and pumps providing fluid overflow or forced transfer thereof, compressor with pneumatic distributors and control unit. The design of this device provides a self-regulating wastewater treatment process and uses only aerobic treatment processes, without the use of primary clarifiers, and also provides for more thorough filtration of water after the clarifier, but it is intended for use in stationary conditions, i.e. in conditions of virtually no external dynamic effects (vibration, overload) and a more stable temperature regime.

The objective of the present invention is to provide a mobile self-regulating system of deep wastewater treatment, capable of functioning reliably when placed on a vehicle, for example in the carriage space of railway passenger cars, and the technical result is to reduce the overall dimensions of the device while maintaining the degree of wastewater treatment by intensifying the flowing biochemical processes, as well as ensuring the reliability of the device in a wide range of conditions ovii its operation.

To achieve the specified technical result in a wastewater treatment device containing a closed housing, in which there is a equalizing compartment with activated sludge, an inlet pipe and fine bubble aerators, an activation compartment connected to it by a bypass channel with a fine bubble aerator installed in its bottom part communicating with the activation compartment by means of the main aeration tank pump, in which a fine bubble aerator is also installed, connected to the aeration tank by means of a sludge pump sludge disposal with an aerator-mixer located in it and a gravity return pipe connected to the equalizing compartment by the return sludge connected to the aeration tank by means of a circulation pump and an overflow pipe, while all aerators and pumps made in the form of airlifts are connected to the compressor via pneumatic distributors connected to the unit control, it is proposed to separate the output part of the equalizing compartment in front of the bypass channel from its input part with an inclined delaying grating, on both sides of which in install aerators in the idon part of the compartment, install a liquid level meter connected to the control unit in the activation compartment, equip the aeration tank with a liquid oxygen sensor and communicate with the activation compartment with a pump in the form of airlift, which is shaped as shown in the drawing (pos. 12), on install a valve connected to the control unit to the air supply duct in the fine-bubble aerator installed in the bottom part of the aeration tank, and install a frame in the output compartment (instead of a bulky conical secondary settler) th filter of ultrafiltrational cleaning.

In order to stabilize the level of wastewater in the equalizing compartment, the bypass channel between the equalizing and activation compartments can be made vertical with an entrance located in the bottom part of the equalizing compartment and an outlet at the top of the activation compartment.

To ensure reliable functioning of the frame filter of ultrafiltration cleaning, a fine-bubble aerator can be located underneath in the bottom part of the outlet compartment, and a vacuum pump can be installed on the outlet pipe.

A disinfection chamber with an ultrasonic cavitator and an ultraviolet irradiator can also be installed on the exhaust pipe.

To stabilize the wastewater treatment process and increase the reliability of the device, regardless of environmental conditions, the housing can be made thermostatically controlled and equipped with a heat exchanger located in it.

Inside the activation compartment and the aeration tank, bulkhead dampers of fluid vibrations can be installed.

Aerotank, activation and equalizing compartments can be equipped with drainage pipes for exhaust air.

The housing of the device can be made in shape and overall dimensions, providing the possibility of its installation in the undercarriage of a passenger car.

To reduce the mass of the device, improve thermal insulation properties and increase the life of the housing can be made of plastic, such as polypropylene.

A possible implementation of the invention is illustrated in the drawing.

The drawing shows a diagram of a device for wastewater treatment.

The wastewater treatment device comprises a closed housing 1, in which a series of compartments for treating wastewater in the process of their successive movement are formed by means of partitions 2.

Initially, wastewater flows through the inlet pipe 3 into the equalizing compartment 4, divided into two parts by an inclined delaying grate 5, on both sides of which aerators 6 are installed in the bottom part of the compartment.

When the level increases, the effluent from the equalizing compartment 4 flows through the bypass channel 7 into the activation compartment 8, in which a fine-bubble aerator 9 is installed in the bottom part of it.

By means of a main pump 10 made in the form of an airlift, the effluent enters the next compartment - aeration tank 11, in which a fine-bubble aerator 9 is also installed. Several aerators 9 can be installed in each compartment depending on their size and capacity of the compartment.

The aeration tank 11 also has a recirculation pump 12 in the form of an airlift, which is shaped as shown in the drawing (pos. 12), which ensures that part of the liquid returns to the activation compartment 8 when it exceeds the level of the inlet elbow 13 of the pump 12.

The aeration tank 11 is connected by a sludge pump 14 made in the form of an airlift with a sludge stabilization compartment 15 with an aerator-mixer 16 located in it and through a circulation pump 17 also made in the form of an airlift with an outlet compartment 18.

In the outlet compartment 18 in front of the outlet pipe 19, a frame filter for ultrafiltration cleaning 20 is installed, under which a fine bubble aerator 9 is located.

The outlet compartment 18 communicates with the aeration tank 11 by an overflow pipe 21 from the upper level of the outlet compartment into the surface space of the aeration tank, and the sludge stabilization compartment 15 is connected to the equalizing compartment 4 by the return sludge pipe 22, to which the drain pipes 23 of the exhaust air are connected, and at its outlet is installed protective grill 24.

A vacuum pump 25 can be installed on the outlet pipe 19, and behind it a disinfection chamber with an ultrasonic cavitator 26 and an ultraviolet irradiator 27.

In the activation compartment 8 and in the aeration tank 11 can be installed bulkhead-vibration dampers 28 and heat exchangers 29 for heating (cooling) the liquid, associated, for example, with the climate system of the car on which the wastewater treatment device is mounted.

All the aerators installed in the compartments of the housing 1 and the airlift pumps are connected by a duct 30 to a compressor 31. A turbofase air distributor 32 and a pneumatic distributor 33 are connected to the control unit 34 and ensure the operation of the device in the first and second phase on the air duct 30.

The control unit 34 is connected to a level gauge 35 installed in the activation compartment 8 and to an oxygen sensor in the liquid 36 located in the aeration tank 11, while a controlled valve 38 is installed on the air supply pipe 37 to the fine bubble aerator 9.

The proposed device for wastewater treatment operates as follows.

Wastewater through the inlet pipe 3 enters the equalizing compartment 4, in which the process of their treatment with activated sludge begins, as well as grinding and destruction of solid fractions by intensive circulation of effluents by aerators 6 operating in the turbine phase, mounted on both sides of the inclined delay grid 5.

As the equalization compartment 4 is filled, the effluent flows through the bypass channel 7 into the activation compartment 8, where it is exposed to fine bubble aeration in the second phase created by the fine bubble aerator 9. Due to the placement of the aerator 9 in the bottom zone, the air bubbles generated by it penetrate the entire column of liquid located in the compartment 8 and their small size (fine bubble) provides reliable and thorough dissolution of oxygen in the air for use by its biomass in the oxidation of decaying organic pollutants x water, and during periods of oxygen deficiency during pauses of aeration, the development of denitrification processes.

Partially treated wastewater is pumped in the form of airlift by the main pump 10 to the aeration tank 11, where they are further processed, supported by their almost constant level, also placed in the bottom zone with a fine-bubble aerator 9 in the first phase, the operation of which is regulated by the indications located in aeration tank 11 of the oxygen sensor in the liquid 36. If the level of effluents in the aeration tank 11 is exceeded, their excess is pumped out by the pump 12 operating in the turbo phase into the activation compartment 8.

The sludge pump 14 operating in the second phase is supplied with excess sludge from the sludge pump 14 from the aeration tank 11 to the sludge stabilization compartment 15, where the aerator-mixer 16 is located in the first phase. When the liquid level in the compartment rises, the surplus returns through the return sludge pipe 22 into the equalizing compartment 4, and the circulation pump 17 operating in the turbo phase, the liquid from the aeration tank 11 is pumped to the output compartment 18, where, passing through the frame filter ultrafiltration cleaning 20, the vacuum pump 25 is fed to the outlet mu conduit 19 in the decontamination chamber in which ultrasound is processed cavitator ultraviolet irradiator 26 and 27.

After that, completely purified and disinfected water without suspended particles can be supplied to the circulating water supply system.

Information sources

[1] RU, PM No. 20918, E03F 7/10, 2001

[2] FR, No. 2683495, V61D 35 / 00.1991

[3] RU, No. 2060967, C02F 3 / 02.1995,

[4] RU, No. 2220112, C02F 3 / 02.2003,

[5] RU, No. 2228915, C02F 3/02, 2003

[6] RU, No. 2305662, C02F 3/12, 2006 (prototype).

Claims (11)

1. A device for wastewater treatment, comprising a closed housing in which a leveling compartment with activated sludge, an inlet pipe and aerators is located, an activation compartment connected to it by a bypass channel with a fine-bubble aerator installed in its bottom part, communicating with the activation compartment through the aeration tank main pump , which also has a fine bubble aerator connected to the aeration tank by means of a sludge pump, a compartment for stabilizing sludge with an aerator-mixer located in it and connected to a by means of a circulation pump, the outlet compartment with a filter located in front of the outlet pipe, the sludge stabilization compartment is connected to the equalizing compartment by an overflow pipe, and all aerators and pumps made in the form of airlifts are connected to the compressor through pneumatic distributors connected to the control unit, characterized in that the output part of the equalizing compartment in front of the bypass channel is separated from its input part by an inclined delaying grating, on both sides of which in the bottom part of the compartment agitators-aerators are installed, the aeration tank is in communication with the activation compartment by a recirculation pump made in the form of an airlift, while the oxygen sensor in the liquid is connected to the control unit in the aeration tank, and a valve is installed on the air supply pipe to the fine-bubble aerator located in the bottom part of the aeration tank, also associated with the control unit, while the filter located in the output compartment is made in the form of a frame filter for ultrafiltration cleaning. 2. The device according to claim 1, characterized in that the bypass channel between the equalizing and activation compartments is made vertical with an entrance located in the bottom part of the equalizing compartment and an exit at the top of the activation. 3. The device according to claim 1, characterized in that in the bottom part of the output compartment under the frame filter of ultrafiltration cleaning installed finely bubble aerator. 4. The device according to claim 1, characterized in that a discharge pump is installed on the exhaust pipe. 5. The device according to claim 1, characterized in that a disinfection chamber with an ultrasonic cavitator and an ultraviolet liquid irradiator is installed on the outlet pipe behind the discharge pump. 6. The device according to claim 1, characterized in that the housing is thermostatically controlled and equipped with a heat exchanger located therein. 7. The device according to claim 1, characterized in that inside the activation compartment and aeration tank are installed vertical bulkheads-dampers of fluid vibrations. 8. The device according to claim 1, characterized in that the aeration tank, activation and equalizing compartments are equipped with drainage pipes for exhaust air. 9. The device according to claim 1, characterized in that the casing is made in shape and overall dimensions, providing the possibility of its installation in the car space of the passenger car. 10. The device according to claim 1, characterized in that the housing is made of plastic, for example polypropylene. 11. The device according to claim 1, characterized in that between the outlet compartment and the aeration tank there is an overflow pipe from the upper level of the outlet compartment to the surface space of the aeration tank.