RU2438996C1 - Aerotank - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: invention relates to treatment of industrial and household effluents with the help of air dispersers and may be used in sewage treatment plant aerotanks in bioscrubbing of effluents. Prepared mix of effluents and active sludge is fed into reservoir 1 via water duct 2. After filling said reservoir, air is into hollow ceramic body of disperser 7 from air duct 4 via flow restricting device 6. Dispersed air is fed from said hollow body via its gas-permeable walls into water-sludge medium wherein active biological oxidation of contaminants occurs due to bubbling and convective flows. Purified water is fed from aerotank via water duct 3 into filtration units.

EFFECT: higher intensity and efficiency, reduced consumption of air, metal, capital and operating costs.

7 cl, 2 dwg

Description

The invention relates to the treatment of industrial and domestic wastewater using air dispersants and can be used in aeration tanks of wastewater treatment plants for biological wastewater treatment.

Aeration systems perform two main functions: saturate the water with oxygen and mix it, providing contact between the oxygen introduced, contaminants and activated sludge. The aeration is based on the laws of gas-liquid mass transfer, consisting in the formation of a developed liquid-gas interface and implemented by supplying dispersed air into the volume of water.

In world and domestic practice, at least one assembly is used for wastewater aeration, having an air supply pipe made of polyethylene, a distribution manifold, an air distribution pipe with aerators fixed to it.

The system also has inlet and outlet conduits for the liquid to be cleaned and activated sludge. Air dispersion is carried out using dispersing devices in the form of perforated pipes with various dispersing nozzles made of porous powder and fibrous materials in the form of pipes, ceramic plates and diffusers (L.A. Kulsky. Theoretical foundations and technology for water conditioning. Kiev, Naukova Dumka, 1980 , p. 382-384; RU 2061662, 10/06/1996; RU 2324660, 05/20/2008; Catalog of the company "Pall Corporation)), wwwpall.corri; Advertising brochure of the company "NOPON OY" TURKVEKIA FiN-00700 Helsinki, Finland, 1994; RU 2152362, 10.07.2000, RU 2118298, 08.27.1998; RU 2226182, 03/27/2004).

The disadvantages of the known aeration tanks include the low efficiency of oxygen dissolution due to the significant size of the air bubbles (1-6 mm), which leads to a mismatch of the state of the contacting phases “water-air” or “silt mixture-air”, metal consumption and design complexity with significant capital and energy costs.

Of the variety of designs of aeration tanks, the closest analogue is a device containing a tank, on the bottom of which an air distribution system is mounted, consisting of an air supply riser, an air manifold, a drain pipe, air distribution pipes with placed ceramic disk dispersers, including an aerator body, o-rings, a retaining shell, air inlet, ceramic dispersant, made in the form of a plate of sintered powder oks and aluminum (V.Bozhenov «FLYGT company equipment for biological treatment of waste water" Water Treatment №10, 2005 s.31-36).

A disadvantage of the known design of the aeration tank is the bottom placement of the air-distributing system, which, in cases of an unusual situation, does not allow to eliminate local disturbances in the operation of the units without releasing the tank from the water-sludge mixture. The implementation of the air dispersant from a polycrystalline sintered alumina powder with an indeterminate distribution of fine and coarse porosity and hydraulic resistance of the plate wall does not allow organizing their optimal ratios for organizing maximum mass transfer and convection flows into distant volumes of the water-silt mixture, which leads to a decrease in the intensity and efficiency of the process aeration.

The objective of the proposed technical solution is to develop an aeration tank with increased intensity and efficiency of the aeration process, reducing air energy consumption, metal consumption, capital and operating costs.

To solve this problem, an aeration tank has been developed, which, in contrast to the known design, contains an air supply system located above the working level of the aerated water-sludge mixture, the air supply system is connected by a flexible pipe to ceramic dispersants, made in the form of a whole-ceramic hollow body, the walls of which are formed by fine-grained or coarse-grained monofractions ceramic materials, a screw hole was made in the housing for attaching the inlet fitting a connected to a flexible conduit.

As a result of experimental testing of the device, it was found that, using throttling devices, it is possible, if necessary, to change the pressure and air flow in each dispersant, which together with small (average size 5-12 microns) and large pores (average size 400-800 microns) in dispersants allows to obtain vertical and horizontal flows of air bubbles uniformly distributed throughout the volume of water-silt loading.

The use of fine-grained fractions of ceramic powders in the formation of a dispersant wall in the range of 10-150 μm allows you to form an interaction surface in the "liquid-gas" system 10 ² -10 ⁶ times more than that achieved in analog dispersion systems. The use of monofraction powders within 1000 μm eliminates the formation of foam on the surface of the water-sludge loading, and when the dispersant wall porosity is 40-50%, the hydraulic resistance in the dispersant wall is 2-4 times less than with the identical thickness of the ceramic plate in analog devices.

The ability to change the distance of the dispersants from each other and the bottom of the tank allows you to adjust the distribution of vertical and horizontal flows of bubbles of different sizes in the volume of water-silt loading.

Depending on the acidity and alkalinity (pH) of the water-sludge medium, it is possible to use monofraction ceramic materials from a number of oxide compounds Al ₂ O ₃ , SiO ₂ , ZrO ₂ , Cr ₂ O ₃ , mullite, clay, or oxygen-free ceramic based on SiC.

The technical essence of the claimed object is as follows:

- the location of the air supply system above the working level of the aerated water-sludge mixture provides ease of maintenance, the possibility of local repair of individual components, including the replacement of dispersants, without stopping the operating mode in the aeration tank;

- flexible connection of dispersants with an air-supply system provides a predetermined distribution pattern of dispersants in the volume of the aeration tank and the organization of bubble-convection flows intensifying mass transfer processes;

- the implementation of the air dispersant in the form of a hollow body made of monofraction ceramic materials allows, with identical geometrical dimensions with the prototype, to increase the dispersion surface by 2-2.5 times, while simplifying the design, to realize dispersion in optimal hydrodynamic conditions, to provide increased mass transfer and favorable development conditions microorganisms actively involved in the biological oxidation of contaminants;

- the implementation of the dispersant of ceramic materials that are resistant to the pH of the aerated medium, increases the warranty period of its performance, and the provision of technological parameters of the aeration process without the formation of foam leads to improved environmental conditions.

Figure 1 presents the functional diagram of the aeration tank, figure 2 is a vertical section of a ceramic dispersant.

The aeration tank includes a tank (1), inlet (2) and outlet (3) water ducts, an air duct (4), a flexible pipe (5), a throttle (6), a ceramic hollow dispersant (7) containing an all-ceramic hollow body (8), walls (9), threaded hole (10), fitting (11).

The device operates as follows.

The pre-obtained mixture of wastewater and activated sludge is fed into the tank (1) through a water conduit (2). After filling the tank (1) from the duct (4), the throttle (6) and flexible conduit (5) supply air through the nozzle (11) and the hole (10) into the hollow ceramic disperser body (8) (7). From the hollow body (8), through air-permeable walls (9) dispersed into small or large bubbles, the air enters the water-silt medium, where active biological oxidation of contaminants occurs under the influence of bubbling and convection flows. The purified water through a water conduit (3) is discharged from the aeration tank to the filtration units.

An experimental check of the operability of the proposed device for aeration of industrial wastewater can increase the throughput of the aeration tank in wastewater by 30-40%, reduce air consumption by 60-70%, increase the degree of oxygen production by 8-10 times, and reduce the specific energy consumption per transfer of one kilogram oxygen by 5-6 times.

Claims (7)

1. The aeration tank includes a reservoir supplying and discharging water to the cleaned liquid and activated sludge, a duct for supplying aeration air and a ceramic flat disperser connected to it, characterized in that the duct for supplying aeration air is located above the working level of the aerated water-sludge mixture and is connected by a flexible a pipeline with a ceramic dispersant made in the form of an all-ceramic hollow body, the walls of which are formed by fine-grained or coarse-grained monofractions of ceramic FIR powders manufactured in the housing bore with a screw thread for fastening the inlet socket connected with a flexible conduit. 2. The aeration tank according to claim 1, characterized in that the flexible pipe is connected to the duct through a throttle device with the possibility of changing the air flow for each dispersant. 3. Aeration tank according to claim 1, characterized in that the dispersants are installed with the possibility of changing the distance between each dispersant and the bottom of the aeration tank reservoir. 4. Aeration tank according to claim 1, characterized in that the walls of the all-ceramic hollow body of the dispersant are made with a permeable porosity of 40-50%. 5. Aeration tank according to claims 1 and 4, characterized in that the permeable fine-porous wall of the dispersant is formed by fine-grained monofractions of ceramic powders with a particle size of 10 to 150 microns. 6. Aeration tank according to claims 1 and 4, characterized in that the permeable coarse-grained wall of the dispersant is formed by coarse-grained monofractions of ceramic powders with a particle size of from 500 to 1000 microns. 7. Aeration tank according to claim 1, characterized in that the monofraction ceramic materials are resistant to pH of the aerated medium.

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