UA113559U - METHOD OF AEROBIC BIOLOGICAL WASTE WATER TREATMENT - Google Patents

Abstract

The method of aerobic biological wastewater treatment includes a container in which the wastewater is saturated with dissolved oxygen under aerobic conditions, immobilized microorganisms on a fibrous carrier, the root system of higher aquatic plants attached to the carrier element. Carbon fibers are used as the fibrous carrier, which is subjected, together with the root system of higher aquatic plants, to an ejection aeration with a water-oxygen mixture, which is placed near a vessel consisting of a nozzle, a vortex chamber, and an air supply source. The inlet of the nozzle is connected to the pipeline of water supply, which is sprayed by its confuser, diffuser sections, and the outlet is connected to the vortex chamber, the inlet tangential channel of which is connected by a hose to the source of supply of ambient air, and the outlet of the vortex chamber with a collector of water-oxygen mixture, placed in a container, the outlet fittings of which are connected with perforated nozzles, vertically placed under a fibrous carrier, the root system of higher aquatic plants of the carrier element.

Description

The utility model belongs to water treatment, namely aerobic biological wastewater treatment and can be used to treat industrial, domestic and agricultural wastewater and stormwater.

The majority of industrial wastewater is contaminated with one or another oil product that forms a film of floating pollution on the surface of the water. This is due to the wide use of these substances, for example, in mechanical engineering (production of various parts on machines using lubricating and cooling fluids containing petroleum products).

The concentration of dissolved petroleum products in the wastewater of galvanic production reaches 30 mg/dm.

A known method of cleaning the gas mixture from harmful impurities (Patent Mo 71620 of Ukraine,

IPC (2006.01) VO10 53/34, "Method of cleaning the gas mixture from harmful impurities", 28.11.2012,

Bul. Mo 14). The method includes passing a gas mixture through an aqueous medium with a biologically active material with immobilized microorganisms located in it.

Biologically active material is a fibrous synthetic material made of polyamide or polyethylene terephthalate fibers with a diameter of 1-3 mm. The fibrous material is stretched over the frame and installed perpendicular to the flow of the gas mixture.

The disadvantage of the method is that it does not provide purification of industrial wastewater from petroleum products and heavy metal ions.

Fibrous material (carrier) made of polyamide fibers has an insufficiently high specific surface - 26.1 m/g, which significantly affects the concentration of active biomass of microorganisms, thereby reducing the rate of oxidation of contaminated substances during wastewater treatment.

Features common to the analogue are: containers; cleaning mixture (water): immobilized microorganisms; fibrous material (fibrous carrier) made of polyamide or polyethylene terephthalate fibers; supporting element (frame).

The closest in terms of technical essence and the achieved technical result is known

Ko) method of biological wastewater treatment. There is a known method of deep purification of wastewater (Patent No. 54808 of Ukraine, IPC 7 СО2Р 3/32, 17.03.2003, Bul. Mo 3), which is accepted as the closest analogue.

The method includes feeding wastewater to a filtration basin with a waterproof bottom covered with a thermally insulating fibrous material, and filtering it through a gravel fill, a bacterial preparation and the root system of higher aquatic plants. The waste water is saturated with oxygen before being fed into the filtration basin, and the gravel filling is partially replaced with zeolite, which is from 10 to 50 95 gravel.

The disadvantage of the method is the insufficient quality of purification of industrial wastewater, such as galvanic production, from oil products and heavy metal ions.

Wastewater is saturated with oxygen to a concentration above b mg/l, which is insufficient for intensive aerobic oxidation of organic substances by microorganisms, especially at a water temperature of 17-20 "C. Water saturation with oxygen to the specified value is achieved by known pneumatic aeration systems, which are presented in the form of perforated pipelines, filter-bearing plates, etc. The operation of such systems requires significant energy costs associated with maintaining the necessary pressure (air, water) in pneumatic mains. In addition, the degree of air oxygen utilization in such systems rarely approaches the value of 10 95.

Signs shared with the closest analogue are: tank-basin; fibrous material (fibrous carrier); root system of higher aquatic plants; oxygen; waterproof bottom (bearing element).

The basis of a useful model is the task of developing a method of aerobic biological wastewater treatment, which would allow to increase the efficiency of cleaning industrial, domestic, agricultural wastewater and stormwater from oil products, heavy metal ions by using a fibrous carrier that has the largest specific surface area for immobilization of microorganisms and jet vortex method of saturating water with dissolved oxygen. 60 The essential features of the method are:

containers with treated wastewater; aerobic conditions; fibrous carrier; microorganisms placed on a fibrous carrier; higher aquatic plants and their root system; a supporting element to which a fibrous carrier is attached, higher aquatic plants; dissolved oxygen; production of a fibrous carrier from carbon fiber, which, together with the root system of higher aquatic plants, is subjected to ejector aeration with a water-oxygen mixture; hydraulic activator, which is placed near a container consisting of a nozzle, a vortex chamber, a source of ambient air supply, the inlet of the nozzle is connected to the water supply pipeline, which is sprayed by its confusor, diffuser sections, and the outlet of the nozzle is connected to the vortex chamber, and to the outlet the tangential channel of the vortex chamber is connected to the ambient air supply source with a hose, and the outlet of the vortex chamber is connected to the collector by tubes; the collector of the water-oxygen mixture, which is placed in a container, and its outlet fittings are connected to perforated nozzles, which are vertically placed under the fibrous carrier, the root system of higher aquatic plants of the supporting element.

Features of the method that differ from the closest analogue are the presence of: a fibrous carrier made of carbon fiber, which, together with the root system of higher aquatic plants, is subjected to ejector aeration with a water-oxygen mixture; hydraulic activator, which is placed near a container consisting of a nozzle, a vortex chamber, a source of ambient air supply, the inlet of the nozzle is connected to the water supply pipeline, which is sprayed by its confusor, diffuser sections, and the outlet of the nozzle is connected to the vortex chamber, and to the outlet the tangential channel of the vortex chamber is connected to the ambient air supply source with a hose, and the outlet of the vortex chamber is connected to the collector by tubes; the collector of the water-oxygen mixture, which is placed in the container, and its outlet fittings are connected to perforated nozzles, which are placed vertically under the fibrous carrier,

With the root system of higher aquatic plants of the supporting element.

The essence of the proposed method of aerobic biological wastewater treatment is as follows. Wastewater treatment is carried out under aerobic conditions in artificial pools (channels) with immobilized microorganisms on a fibrous carrier, the root system of higher aquatic plants, which are attached to the supporting element.

Carbon fibers, which have a significant porous surface, are used as a fibrous carrier. (The porous surface of 1 gram of carbon fiber is at least 2380 m32). The carrier together with the root system of higher aquatic plants is subjected to ejector aeration with a water-oxygen mixture. Water saturation with oxygen is carried out by a jet-vortex method (using ejector aeration. Ejector aeration is carried out by the proposed generator, which is placed near a container consisting of a nozzle, a vortex chamber, a source of ambient air supply. The nozzle sprays the water supplied to its entrance into small particles in the form of an aerosol torch with their confusing, diffusive sections, and the outlet of the nozzle is connected to the vortex chamber. The vortex chamber has an inlet tangential channel, which is connected to the ambient air supply source with a hose. The vortex chamber mixes and swirls small particles of water with air, the flow becomes turbulent and a water-oxygen mixture is obtained at its exit. The exit of the vortex chamber is connected to the distribution collector of the water-oxygen mixture, which is placed in a container, the corresponding fittings of the collector are connected to perforated nozzles, which are vertically installed under the fibrous carrier, the root by the system of higher aquatic plants of the supporting element.

The proposed method of aerobic biological wastewater treatment is explained by the drawing. In fig. 1 shows a general view of an artificial pool from above with a hydraulic activator; in fig. 2 - section along A-A in fig. 1; in fig. C - a nozzle with a vortex chamber in fig. 1; in fig. 4 - a view along arrow B of the vortex chamber in fig. WITH; in fig. 5 - view along the arrow B of the collector in fig. 1; in fig. 6 - air supply source in fig. 1.

The device consists of a container 1, which has side walls 2 and transverse rails 3. Waste water to be cleaned enters zone 4, where there is a beginning of the flow of waste water from galvanic production. The carrier element 5, the fibrous carrier b with immobilized microorganisms is placed in zone 4 of container 1 at the beginning of the wastewater flow.

The supporting element 5 is made in the form of a raft made of hollow pipes 7 and has additional buoyancy. The roach 5 has a perforated bottom 8, the holes 9 are made of a certain size for placing planted plants 10 in them, which are higher aquatic plants, for example, water hyacinth (Eichhornia beautiful). The roach 5 has elongated halyards 11, with the help of which it is attached to the side walls 2 and transverse rails 3.

Hollow pipes 7, roach 5, perforated bottom 8 are made of plastic, for example, polypropylene. The fibrous carrier b is attached to the hollow pipes 7 and the perforated bottom 8 of the roach 5. This makes it possible, when the roach 5 is placed in water, for the fibrous carrier 6, together with the root system of higher aquatic plants, to be completely immersed in the column of wastewater.

Fibrous carrier b is segments of carbon fibers of a certain length. The fibers have a porous surface that reaches (in one gram) at least 2380 m. The fibrous carrier, together with the root system of higher aquatic plants, is subjected to ejector aeration with a water-oxygen mixture using hydroactivator 12.

The hydraulic activator 12 is placed near the container 1, which consists of a nozzle 13, a vortex chamber 14, a source 15 of supply (suction) of ambient air. The inlet 16 of the nozzle 13 is connected to the water supply pipeline, which is sprayed into small drops by its confusor 17, 18, diffuser 19 sections and other elements. (Other elements are not marked on the drawing).

On the surface of the diffuser section 19, longitudinal recesses 20 are made, which break the supplied water stream into fine water dust. The outlet 21 of the nozzle 13 is connected to the vortex chamber 14.

The vortex chamber 14 has an input tangential channel 22, to which the source 15 of the supply of ambient air is connected with a hose 23, with a nozzle 24 for accelerating the flow. The intake part 25 of the air source 15 is made in the form of cones, the upper 26, the lower 27, which are installed and fixed one above the other in such a way that they form a circular cavity 28 for air supply (suction). The cone 27 in the lower part has a more gentle surface, which ends with an opening 29. The opening 29 is connected to the hose 23. The air supply source 15 is placed on the tower 30, which is fixed near the container 1.

The water that is sprayed by the diffuser 19 with its longitudinal depressions 20 turns into a rotary-progressive movement. As a result, at the outlet 21 of the nozzle 13 and in the vortex chamber 14 (on its axis), the pressure decreases sharply, a discharge is formed and air is intensively sucked in from the air supply source 15. The vortex chamber 14 mixes and

Zo swirls small particles of water with air (the flow becomes turbulent), and at its outlet 31 we get a water-oxygen mixture.

The outlet 31 of the vortex chamber 14 is connected by a hose 32 to the collector 33 of the water-oxygen mixture, which is placed in the container 1 between the roaches 5. The collector 33 has outlet fittings 34 with electromagnetic valves 35. The fittings 34 are connected to the perforated pipes 37 with tubes 36. which are vertically placed under fibrous carriers 6, the root system of higher aquatic plants 10 roaches 5.

Pipes 37 have elongated holes, which are covered with aeration membranes along the perimeter. (Holes, aeration membranes are not marked on the drawing).

Electromagnetic valves 35 are connected (by electrical connection) with a power source (low-voltage battery) and a software tool (computer), which ensure the sequence of supplying the water-oxygen mixture under each plank 5. (The electrical system and its elements on drawings are not marked).

The proposed method of aerobic biological treatment of polluted wastewater, in comparison with the known basic methods, allows to improve the quality and efficiency of wastewater treatment from oil products, heavy metals through the combined use of both an artificial fibrous carrier and a natural one - in the form of the root system of higher aquatic plants, which subjected to saturation with a water-oxygen mixture obtained by the jet-vortex method using ejector aeration with a concentration of dissolved oxygen in water up to 8-40 mg/l. The natural filamentous carrier of higher aquatic plants, together with the artificial fibrous carrier, form and form a dense biocenosis of destructive microorganisms and other hydrobionts, which ensure high-quality and effective cleaning of industrial and domestic, agricultural, stormwater wastewater from oil products, heavy metals and other pollutants.

Production of the product using the jet-vortex method of oxygen saturation of water does not require relatively large material costs, because widely known materials and components are used. The effectiveness of biological purification of industrial and domestic wastewater from petroleum products and heavy metal ions was tested at real stormwater treatment plants of the galvanic production plant of JSC "Motor Sich" in Zaporizhzhia. (510)

Claims (1)

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