RU72965U1 - SEWAGE TREATMENT DEVICE - Google Patents

Abstract

The utility model is aimed at increasing the degree of aeration of wastewater while increasing the uniformity of aeration of the volume of oily wastewater with fine air bubbles. The specified technical result is achieved by the fact that the device comprises a reservoir, nozzle nozzles for supplying them in the form of a freely flowing jet, placed coaxially in the cavity of the casing, made in the form of a glass open from below, the edge of which is placed below the edge of the chipper, made in the form of a glass of larger diameter, open from above, in the cavity of which the casing is located, moreover, the upper part of the casing, free of water, is configured to increase the pressure in it of air. It is equipped with a sealed additional tank located above the tank, while the lower part of the gap between the walls of the chipper and the tank is connected by a pipe to a distributor located at the bottom of the floatation compartment of the additional tank, formed by a vertical chipper separating the additional tank into the float and storage compartments. The upper edge of the baffle plate is located below the minimum water level in an additional tank, the upper part of the volume of which is free of water, is made with the possibility of lowering the air pressure in it. The additional tank is configured to discharge a flotated volume of impurities from it, and the lower part of the storage compartment of the additional tank is configured to drain purified water from it. The lower part of the casing is made confuser, while at its edge, at equal distances from each other, confuser nozzles are placed, the longitudinal axes of which are directed to its longitudinal axis, tilted to the bottom, while the nozzles are connected by channels to the upper part of the casing cavity, free from water The distributor is configured to heat water to a temperature close to the boiling point. 1 ill.

Description

The utility model relates to wastewater treatment and can be used to isolate various impurities from them, for example, petroleum products.

A device for wastewater treatment is known, comprising a sealed tank with a pressure distribution pipe installed in it, made with holes facing the surface of the liquid, equipped with nozzles buried in the water and installed with a chimney coaxially in the pressure pipe in the form of a box with a pipe placed under the nozzles, and two peripheral pockets installed one above the other, the lower of which is connected by a pipeline to the chipper (SU No. 996332, MKI C02F 1/00, 1981).

The disadvantage of this solution is the unsatisfactory degree of purification of oily wastewater due to the low degree of aeration.

It is also known a device for wastewater treatment, containing a reservoir, nozzle nozzles for supplying them in the form of a freely flowing jet, placed coaxially in the cavity of the casing, made in the form of a glass open from below, the edge of which is placed below the edge of the chipper, made in the form of a glass, a larger diameter open at the top, in the cavity of which the casing is located, and the upper part of the casing, free of water, is configured to increase air pressure in it (SU No. 1632949, MKI C02F 1/40, B01D 17/035, 1991).

The disadvantage of this solution is the unsatisfactory degree of purification of oily wastewater from fine impurities uniformly distributed over their volume due to the insufficiently uniform distribution of air bubbles over the volume of water and their dispersion.

The problem to which the claimed solution is directed is to provide the possibility of purification of oily waste

waters from fine impurities uniformly distributed over their volume.

The technical result achieved in solving this problem is expressed in the fact that the degree of aeration of wastewater is increased while the uniformity of aeration of the volume of oil-containing wastewater with finely dispersed air bubbles is increased, which makes it possible to float finely dispersed particles of impurities and, due to this, allows to increase the degree of purification of oil-containing water from free (undissolved) impurities to a level of at least 99% of their initial content.

The problem is solved in that the device for wastewater treatment, containing a reservoir, nozzle nozzles for supplying them in the form of a freely flowing jet, placed coaxially in the cavity of the casing, made in the form of a glass open from below, the edge of which is placed below the edge of the chipper, made in the form glass, a larger diameter, open on top, in the cavity of which the casing is placed, and the upper part of the casing, free of water, is configured to increase the pressure in it of air, characterized in that it is sealed an additional tank located above the tank, while the lower part of the gap between the walls of the chipper and the tank is connected by a pipeline to a distributor located at the bottom of the floatation compartment of the additional tank, formed by a vertical chipper separating the additional tank into the float and storage compartments, while the upper edge a baffle plate, located below the minimum water level in an additional tank, the upper part of the volume of which, free of water, is made with the possibility of lowering the pressure in it of air, while the additional tank is configured to drain the flotated volume of impurities from it, and the lower part of the storage compartment of the additional

the tank is made with the possibility of removing purified water from it, in addition, the lower part of the casing is made confuser, while at its edge, at equal distances from each other, confuser nozzles are placed, the longitudinal axis of which is directed to its longitudinal axis, with an inclination to the bottom, this, the nozzles are connected by channels with the upper part of the cavity of the casing, free of water, while the dispenser is configured to heat water to a temperature close to the boiling point.

A comparative analysis of the features of the claimed solutions with the features of the prototype and analogues indicates the compliance of the claimed solutions with the criterion of "novelty."

The search results showed that the claimed utility model does not follow explicitly from the prior art for the specialist, since the influence of the transformations provided for by the essential features of the claimed solution is not revealed from the prior art determined by the applicant, which provides a positive reaction to achieve a technical result - to increase the degree of aeration of waste water water, while increasing the uniformity of aeration of the volume of oily wastewater with fine air bubbles and provide the ability to separate petroleum products dissolved in water.

Figure 1 schematically shows a cross section of a device. The drawing shows the tank 1, nozzle nozzles 2, the casing 3 with the edge 4, the bump 5 with the edge 6, the gap 7, between the walls of the bump 5 and the tank 1, an additional tank 8 with a vertical baffle 9, dividing it into a floating 10 and accumulating 11 compartments. In addition, the branch pipes 12 and 13 of the tank 1, the branch pipes 14 and 15 of the additional tank 8, the drain pipes 16 of the tank 1, the additional tank 8 and the chipper 5, the supply pipe 17 of the tank 1, the air pipes 18 and 19 are shown

respectively, of tank 1 and additional tank 8, distributor-heater 20, pipe 21, confuser nozzles 22 with channels 23. In addition, the surface of the liquid 24, the water-air stream 25, the foam layer 26 containing the flotated impurities are shown. The additional tank 8 is made in the form of a separate tank installed above the tank 1. The distributor-heater 20 is made in the form of a heat exchanger, the input of the heat-receiving circuit of which is connected to the pipe 21, and the output is made in the form of perforated holes in the upper wall of the distributor-heater, open into the cavity of the floating compartment 10 of the additional tank 8. In this case, the heat transfer circuit of the distributor-heater 20 is made in the form of a tubular heat exchanger connected to a heat source (in the drawing dough is not shown) with a working agent having the appropriate thermal parameters, for example, to the cooling system of power plants (taking into account operation under reduced pressure, the thermal parameters of the working agent will not be high). The edge 4 of the casing 3 is located below the edge 6 of the bump 5. The drainage pipes 16 of the tank 1 and the additional tank 8 are placed below the inlet holes of the pipes providing water drainage from the gap 7 (pipe 12) and the storage compartment 11 (pipe 15) and should preferably be placed in different points of the perimeter of the bottom. In addition, the confuser portion 27 of the casing 3 is shown.

The listed elements and parts do not differ in design and materials from known elements and parts used for similar purposes, with similar requirements for strength, performance, etc. The upper part of the volume of the casing 3, through the air pipe 18, is connected to a source of compressed air - compressor (not shown in the drawings). Top of the volume

additional tank 8, through the air pipe 19, is connected to a vacuum pump (not shown in the drawings). The branch pipes 13 of the tank 1 and 14 of the additional tank 8, providing the removal of flotated impurities (foam), are placed on the walls of the tanks at a level corresponding to the liquid level in them.

The claimed device operates as follows. The operating parameters in the installation are brought to the nominal, namely: the tank is filled with water (it is advisable to use purified water at the start-up phase), create a pressure above atmospheric pressure up to 0.1 MPa in the cavity of the casing 3 (in the zone of water saturation with air), by turning on the compressor, connected to the pipe 18, in addition, in the air cavity of the additional tank 8 create a vacuum up to 0.03-0.05 MPa by turning on the vacuum pump connected to the pipe 19. In addition, turn on the heat to the distributor-heater 20. Then start water supply subject boiling cleaning. The purified water is poured out of the nozzle nozzle 2 at a high speed, in the form of a jet under a pressure of 0.8-1.0 MPa, down through an air layer (located in the casing 3 above the surface of the liquid 24 already in the tank 1). In the process of its movement through the air layer, the purified water captures a large amount of air, which, under the influence of the medium, disperses into small bubbles and partially dissolves in the volume of the jet and the volume of water under the surface of the liquid 24. As a result, water is formed in the volume of the purified water an air stream 25 extending deep into the liquid from its surface. The depth of penetration of the jet 25 and the dimensions of its cross section are determined by the flow parameters of the treated water. Interacting with the outlet openings of the confuser nozzles 22, the air-water jet 25, due to the ejection effect, “draws” into itself an additional volume of compressed air (through channels 23) from the zone of water saturation with air. The confuser lower part 27 of the casing 3 provides

acceleration of the movement of the water-air stream 25 and, thereby, enhances the ejection of air from the upper part of the casing 3, free of water. Further, the purified water, saturated with bubbles of dispersed air and the air dissolved in them, is forced out through the zone between the bottom of the tank 1 and the edge 4 of the casing 3, where the jet energy is extinguished, into the gap between the walls of the casing 3 and the chipper 5. In this case, the rest of the device the flow of water takes a calm character, convective currents are absent. Under these conditions, an intensive unhindered separation of impurity particles occurs in the entire volume of the liquid being cleaned (particles of oil products flotate with air bubbles, i.e. the formation of particle-bubble aggregates that float to the surface due to their low specific gravity). The result is a foam layer 26 containing flotted impurities, which is removed in a known manner through the outlet pipe 13. The purified water, as a denser medium, is entrained down to the bottom of the tank, while the chipper 5 prevents the entry of impurities into the purified water during its downward movement , to the nozzle 12 of the tank 1. Next, the liquid after the first stage of purification is supplied through a pipe 21 to the atomizer - heater 20 of the additional tank 8. Here, the treated water passes through a heat-absorbing circuit and is heated heat tolerable working agent passing through the heat-transfer circuit. Boiling water is achieved at a temperature of less than 100 ° C, which is lower, the higher the vacuum level maintained in the additional tank 8, for example, at a pressure of 0.03 MPa, the boiling point will be 67 ° C, and at a pressure of 0.05 MPa will be 80 ° C. This, in turn, ensures heating and bubbling (by the generated vapor bubbles) of the volume of water in the cavity of the distributor-heater 20. At the same time, substances with a boiling point below 100 ° C, dissolved in water, also evaporate. Further heat treated water

released into the cavity of the floating compartment 10.

Since the pressure in the volume of its floating compartment 10 turns out to be lower, the pressure of the air contained in the feed water (which is at least 0.1 MPa) causes a rapid aeration of the feed water with a large number of small air bubbles (namely, air dissolved in water) , the average sizes of which are many times smaller than the average sizes of air bubbles released at the first stage of purification, the number of which in a unit volume is much larger and which are distributed uniformly. In addition, there is intensive mixing of the volume of water due to bubbling with steam bubbles. Under these conditions, intensive flotation of particles of oil products remaining after the first stage of purification occurs, with the formation of particle-bubble aggregates that float to the surface due to their low specific gravity. As a result, on the surface of the additional tank 8 a foam layer 26 is formed containing the flotted impurities, which is periodically removed in a known manner through the branch pipes 14. Vapors of oil products and water are removed through the air pipe 19 of the additional tank 8, during the operation of the vacuum pump, after which they in a known manner, they are separated from the air and separated from each other (or discharged into oily waters to be treated). Purified water, as a denser medium, drags down to the bottom of the additional tank 8, while the vertical baffle 9 prevents the ingress of impurities into the purified water during its movement down to the pipe 15 of the tank 8. For periodic cleaning of the bottom of the tanks 1, 8 and bump 5 from accumulating sludge use drainage pipes 16.

The aeration coefficient in the proposed device as a result of creating favorable conditions for saturation of the cleaned liquid with air is 10-12. Final degree of water purification,

processed in the proposed device, reaches 99%, which indicates the advisability of using the proposed device.

The application of the proposed design will entail a sharp reduction in the cost of purification of oily water due to low material consumption, low cost and ease of implementation of the method, a high degree of purification.

Claims (1)

A device for wastewater treatment, containing a reservoir, nozzle nozzles for supplying them in the form of a freely flowing jet, placed coaxially in the cavity of the casing, made in the form of a glass open from below, the edge of which is placed below the edge of the chipper, made in the form of a glass, a larger diameter, open from above, in the cavity of which the casing is located, the upper part of the casing, free of water, is configured to increase air pressure in it, characterized in that it is equipped with a sealed additional tank above the tank, while the lower part of the gap between the walls of the chipper and the tank is connected by a pipe to a distributor located at the bottom of the floatation compartment of the additional tank, formed by a vertical chipper separating the additional tank into the float and storage compartments, while the upper edge of the chipper partition is located below the minimum the water level in the additional tank, the upper part of the volume of which, free of water, is made with the possibility of lowering the pressure in air, while the additional tank is configured to drain the flotated volume of impurities from it, and the lower part of the storage compartment of the additional tank is configured to drain purified water from it, in addition, the lower part of the casing is made confuser, while at its edges at equal distances confusor nozzles are placed from each other, the longitudinal axis of which is directed to its longitudinal axis, with an inclination towards the bottom, while the nozzles are connected by channels to the upper part of the casing cavity, free of water, when this distributor is configured to heat water to a temperature close to the boiling point.