RU2380322C1 - Device for aerating purified liquid - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: invention can be used for purifying waste water. Air is fed along a pipe 23 into a casing 4 while the air supply valve on line 23 into an additional casing 13 is closed, forcing water out of a floating chamber 7 into an accumulation chamber 8, with subsequent spillover along outlet pipe 25 into a chamber 26 for the floating product. Air is then fed into the additional casing 13, providing formation of an air crater of defined geometrical parametres in the surface layer of the liquid in casing 4. Process liquid is fed along pipe 2 and operational parametres in the device are regulated. An air jet coming out of the lower base of the additional casing 13 forms an air crater on the water surface in casing 4, where the air crater is a paraboloid of revolution whose depth and diametre depend on the speed of the air jet coming out of the base of the additional casing 13. A high speed jet of process fluid is fed into the crater from the nozzle 3 of pipe 2, where the said high speed jet interacts with the curvilinear surface of the bottom of the crater and ejects air at high pressure, thereby carrying out the aeration process and subsequent floatation.

EFFECT: invention increases degree of aeration of volume of purified water.

3 dwg

Description

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

A device for aerating the liquid to be cleaned is known, comprising a sealed reservoir with a pressure distribution pipe installed in it, made with openings facing the surface of the liquid, equipped with nozzles buried in water and installed with a chimney coaxially in the pressure pipe in the form of a box with a nozzle 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.

Also known is a device for aerating the liquid to be cleaned, containing an atmospheric reservoir, in the flotation compartment of which there is a casing, the cavity of which is connected to a source of compressed air and equipped with a supply pipe in communication with the storage of the liquid to be cleaned (see SU No. 1632949, MKI C02F 1/40, B01D 17/035, 1991).

The disadvantage of this solution is also that the degree of saturation of the purified water with air is limited by the air pressure in the aeration zone, i.e. to increase the degree of saturation, it is necessary to increase the pressure in the named zone, which is not always advisable for specific technical and technological conditions at the cleaning site, therefore it is often necessary to confine oneself to the conditions dictated by the operating parameters of the available compressed air sources. This, in turn, does not make it possible to provide a satisfactory degree of purification of oily wastewater from finely dispersed impurities uniformly distributed over their volume, due to the insufficient quality of aeration of their volume (degree of saturation, uniform distribution of air bubbles over the volume of water and their dispersion).

The problem to which the claimed solution is directed is to increase the degree of aeration of the volume of treated water.

The technical result achieved in solving the problem is expressed in the organization of the process of supplying an additional volume of aerated air and increasing the efficiency of the process of saturating water with air, since air under pressure is ejected in the crater of the surface layer of the liquid relative to the pressure in the movable casing, which provides an increase in the degree of aeration and cleaning quality.

The problem is solved in that the device for aeration of the liquid being cleaned, containing an atmospheric reservoir, in the flotation compartment of which there is a casing, the cavity of which is connected to a source of compressed air and equipped with a supply pipe in communication with the storage of the liquid to be cleaned, is characterized in that the casing is made with the possibility of return translational movement along the longitudinal axis, and its end is made confuser, while the inlet pipe is placed in the cavity of the additional casing, its lower section is enclosed in a shaft a skin made in the form of a glass open from below, and the additional casing and shirt are made with the possibility of reciprocating movement along the longitudinal axis, in addition, a section of the additional casing is placed at the edge of the shirt with a gap above the level of the liquid to be cleaned in the cavity of the casing, this edge of the shirt is provided with an annular bend into the cavity of the additional casing, made in the form of an annular groove, and the vertical wall of the shirt is equipped with rows of through holes made around the perimeter of the shirt, Moreover, the upper row of holes is located at the upper end of the shirt, and the lower row of holes is located at its edge at the level of the annular groove, in addition, the cavity of the additional casing is in communication with the source of compressed air.

A comparative analysis of the features of the claimed solution with the features of the prototype and analogues indicates the conformity of the claimed solution to the criterion of "novelty."

Moreover, the features of the characterizing part of the claims provide a solution to a set of functional tasks.

Signs indicating "the possibility of vertical axial movement" of the casing, the additional casing and the supply pipe, allow you to change the air pressure in the casing at operating conditions, as well as the geometric parameters of the jet of working fluid and air crater on the surface of the fluid.

The sign "the end of the casing is made embarrassing ..." allows you to increase the speed of the water-air stream and thereby increase its ejective properties. In addition, the formation of air-water recirculation zones between the axis and the edge of the casing is excluded, since the volume of water introduced by it immediately appears in the "floating" zone.

The sign "... the inlet pipe is placed in the cavity of the additional casing ..." ensures the movement of the fluid flow at the outlet of the nozzle of the inlet pipe in the "shell of compressed air", thereby solving the problems of alignment of the fluid flow and the air crater.

Signs indicating that "the lower section of the additional casing is enclosed in a jacket made in the form of a glass open from below ... in addition, a slice of the additional casing is placed at the level of the edge of the shirt, with a gap above the level of the liquid to be cleaned in the cavity of the casing", provides an increase in pressure in the air flow upon impact with the surface of the liquid being cleaned and the formation of an air crater, and also the intensity of the interaction of the surface layers of the jet of working fluid with the air flow is increased, which caused Intensive introduction of air into the volume of the cleaned liquid ejected by the water jet takes place.

Signs "the edge of the shirt is provided with an annular bend into the cavity of the additional casing, made in the form of an annular groove, and the vertical wall of the shirt is equipped with rows of through holes made around the perimeter of the shirt, in addition, the upper row of holes is located at the upper end of the shirt, and the bottom row of holes is located at its edges at the level of the annular groove ... "provide air passage from the cavity of the additional casing into the cavity of the shirt and exclude the evacuation of the cylindrical cavity between the inner surface of the shaft flanges and the outer surface of the supply pipe.

The sign "... the cavity of the additional casing is in communication with the source of compressed air ..." provides compressed air to the additional casing and the formation of an air crater with excess air pressure in the surface layer of the liquid being cleaned.

Figure 1 schematically shows a cross section of the device, figure 2 and figure 3 shows the nodes a and b of this device.

The drawings show an atmospheric tank 1, a supply pipe 2 with a nozzle nozzle 3, a casing 4, the end 5 of which is made confuser, a chipper 6, a floating compartment 7 with open upper edges, a gap 8 between the walls of the chipper 6 and the outer walls of the tank 1, which is a storage compartment reservoir 1. The casing 4 is made with the possibility of reciprocating along the longitudinal axis in the chipper 6 and is mounted in the working position in height by threaded clamps 9 mounted on the cover 10 of the atmospheric tank 1. Inside the casing 4, centering radial kerchiefs 11 with centering rings 12 are placed, in which an additional casing 13 is mounted with the possibility of vertical axial movement relative to the casing 4. It is fastened in the working position by a sealing collar 14 mounted on the top cover 15 of the casing 4. An air pipe with throttle shutoff valve 16, regulating the air pressure, respectively, in the casing 4 and the additional casing 13 in operating modes. Inside the additional casing 13 is placed the inlet pipe 2 of the working fluid with the possibility of vertical axial movement. Her fastening in the working position is carried out by a sealing assembly 17 on the upper bottom of the additional casing 13. The lower section of the supply pipe 2 is enclosed in a jacket 18, the end of which is made in the form of a confuser nozzle 19. The shirt 18 has the possibility of axial movement along the pipe of the working fluid 2 and is mounted on it a threaded assembly 20. An annular groove 21 is installed between the cylindrical part of the jacket 18 and the confuser nozzle 19. Above the upper plane of the annular groove 21 and under the threaded assembly 20 in the vertical wall of the jacket 18 around the perimeter through holes 22 are made. Through holes 22 located above the upper plane of the annular groove 21 provide air inlet from the cavity of the additional casing 13 into the cavity of the jacket 18, and through holes 22, under the threaded assembly 20, allow air to escape from the cavity of the jacket 18 into the cavity additional casing 13, which causes the oncoming movement of the annular layer of air and the pressure of the working fluid stream. The axial movement of the jacket 18 relative to the pipe 2 of the working fluid and the additional casing 13 allows you to change the length of the stabilized flow of fluid flowing from the nozzle nozzle 3. Centering the shirt 18 relative to the additional casing 13 and the pipe of the working fluid 2 is made by installing centering rings and scarves inside the casing 13, similarly the casing 4. The slice of the additional casing 13 is placed at the level of the confuser nozzle 19 of the shirt 18 of the supply pipe 2, the edge of which is placed at a distance from the edge of the outlet holes on the casing 4. Furthermore, the additional housing cavity 13 communicates with a source 23 of compressed air. The possibility of vertical axial movement of the casing 4, the additional casing 13 and the supply pipe 2 allows you to change the air pressure in the casing 4 at operating conditions, as well as the geometric parameters of the jet of working fluid and air crater on the surface of the liquid.

The cavity of the casing 4 and the additional casing 13 are connected to a source of compressed air to the compressor (not shown in figure 1). In addition, the drawings show the outlet pipes 24 and 25 of the atmospheric tank 1. The outlet pipe 24 of the atmospheric tank 1 provides the outlet of the swallowed product (foam), is placed on the walls of the tank 1 at a level corresponding to the liquid level in it, and the outlet pipe 25 carries out the outlet of the swallowed product into chamber 26.

The device operates as follows.

The operating parameters in the device are brought to face value, namely: the floatation compartment 7 and the atmospheric tank 1 are filled with water to the upper edges of the walls of the chipper 6 (it is advisable to use purified water at the start-up phase).

The movable casing 4 is immersed in the liquid to a depth corresponding to the working air pressure in the casing 4 during aeration. At the same time, the movable additional casing 13 assembled in the casing 4 with the pipe 2 and the jacket 18 is installed in height with a gap between the lower cut of the casing 13 and the confuser 5 of the casing 4, determined by the process parameters. The jacket 18 is pre-installed on the inlet pipe 2 with a corresponding clearance of the nozzle 3 cut-off and the cut-off nozzle 19 to ensure the length of the stabilized section of the outflowing jet from the nozzle 3 corresponding to the operating mode.

Air is supplied through a pipe 23 to the casing 4 with the air supply valve on line 23 closed to the additional casing 13, displacing water from the flotation compartment 7 into the storage 8, followed by overflow through the outlet pipe 25 into the flotated chamber 26 with its subsequent drainage. In this case, the working liquid level in the casing 4 is set above the confuser 5 of the casing 4, providing a layer height between the lower base of the confuser and the free surface of the liquid of the order of 50-80 mm, depending on the process parameters. Then, air is supplied to the additional casing 13, ensuring the formation of an air crater of certain geometric parameters in the surface liquid layer in the casing 4, and the working pressure in the casing 4 is regulated by throttling the air through the throttle shut-off valve 16 with the working pressure controlled by a manometer in the upper part of the casing.

They supply the working fluid through the pipe 2 and adjust the operating parameters in the device, bringing them to the nominal value, at the corresponding working air pressures (within 1-2 ata) in the casing 4.

An air stream leaving the lower base of the additional casing 13 forms an air crater on the water surface in the casing 4, which is a rotation paraboloid, the depth and diameter of which depend on the speed of the air stream flowing from the base of the additional casing 13. Into the crater with a high speed from the nozzle 3 pipes 2 a jet of working fluid is supplied, interacting with the curved surface of the bottom of the crater and ejecting air with high pressure, carrying out the process of aeration and subsequent flotation.

The possibility of axial vertical movement of the casing 4, the supply pipe 2 and the additional casing 13 allows you to change the geometric parameters of the flowing stream, crater and change the degree of aeration of the liquid in operating modes.

Excessive air pressure in the crater in the surface liquid layer, due to the additional air stream of the casing 13, provides increased ejective ability of the water stream flowing from the nozzle nozzle 3.

The aeration coefficient in the proposed device as a result of creating favorable conditions for saturation of the cleaned liquid with air is 15-17. The final degree of purification of water processed in the proposed device reaches 99%, which indicates the advisability of using the proposed device.

Claims (1)

A device for aerating the liquid to be cleaned, containing an atmospheric reservoir, in the flotation compartment of which there is a casing, the cavity of which is connected to a source of compressed air and provided with a supply pipe in communication with the storage of the liquid to be cleaned, characterized in that the casing is made with the possibility of reciprocating movement along the longitudinal axis and its end is made confuser, while the inlet pipe is placed in the cavity of the additional casing, its lower section is enclosed in a shirt made in the form of a glass, open from the bottom, and the additional casing and shirt are made with the possibility of reciprocating movement along the longitudinal axis, in addition, a slice of the additional casing is placed at the edge of the shirt with a gap above the level of the liquid being cleaned in the cavity of the casing, while the edge of the shirt is provided with an annular bend into the cavity additional casing, made in the form of an annular groove, and the vertical wall of the shirt is equipped with rows of through holes made around the perimeter of the shirt, in addition, the upper row of holes ra is located at the upper end of the shirt, and the bottom row of holes is located at its edge at the level of the annular groove, in addition, the cavity of the additional casing is in communication with a source of compressed air.

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