RU2665399C1 - Scrubber - Google Patents

Abstract

FIELD: dust collection equipment.SUBSTANCE: invention relates to wet dust collecting equipment. Scrubber comprising a body including a conical, cylindrical portion and a slurry tank, a nozzle for introducing a dusty gas, a branch pipe for the outlet of a cleaned, spraying device including an external pipeline with embedded lower and upper nozzles, the ratio of the diameter of the apparatus D to the diameter of the inlet branch pipe Dis in the optimal range of values: D/D=2.2…2.5, and the ratio of the height of the apparatus H to the diameter of the inlet branch pipe Dis in the optimum range of magnitudes: H/D=4.8…5.7, and the nozzles are in the form of vortex nozzles, each of which comprises a body with a swirl chamber and a nozzle, the body is made in the form of the supply fitting with the central opening and is rigidly connected to it and with the coaxial cylindrical sleeve with an internal thread and an expansion chamber, which is coaxial to the body, at that coaxially with the body, a nozzle, in the form of an inverted cup, is connected to the sleeve by means of a thread, in the bottom of which there is a turbulent swirler of the liquid flow with at least two inclusions to the nozzle axis in the form of cylindrical holes located in the end surface of the nozzle, where also a central cylindrical throttle opening is made connected to the nozzle mixing chamber, in series connected to the diffuser outlet chamber, diffuser is installed in the diffuser outlet chamber, the diffuser is made in the form of at least three spokes, each of which is fixed at one end to the outer surface of the diffuser outlet chamber, perpendicular to the surface forming it, and the other to the surface of the body of rotation, for example, a ball whose axis is aligned with that of diffuser outlet chamber. Note also that said ball is located at lower part, behind the diffuser outlet chamber edge, diffuser is attached to the end surface of a cylindrical sleeve coaxial with the body, coaxial to the diffuser chamber. Cut surface of diffuser lies in a plane below the surface of the divider’s body of rotation, divider is made in the form of two spokes, each of which is fixed at one end to the outer surface of the diffuser outlet chamber, perpendicular to the surface forming it, and the other – on an axis on which a rotating body is mounted with the possibility of rotation, made in the form of a ball, the center of which lies on the axis of the diffuser outlet chamber, the surface of the body of rotation made in the form of a ball mounted on the axis with the possibility of rotation is perforated, to the surface of the body of rotation, made in the form of a ball mounted on an axis with the possibility of rotation, elements that rotate it are installed, for example in the form of segments of screw blades, screw grooves are provided on the inner surface of the central cylindrical throttle opening of the vortex nozzle disposed in the end surface of the nozzle for additional twisting of the liquid flow., characterized in that in the rotational body of the vortex nozzle, axis of which coincides with the axis of the diffuser outlet chamber, and the body of rotation itself is located at the bottom, behind the cut of the diffuser outlet chamber, resonant recesses are made in shape in the form of a cylindrical surface of different diameters and length, performing the functions of Helmholtz resonators, their dimensions are determined by the necessary pulsation frequency of the liquid flow to increase the fineness of the sprayed flame.EFFECT: increased efficiency and reliability of the dust collection process by increasing the liquid spraying rate of injectors.1 cl, 4 dwg

Description

The invention relates to techniques for wet dust collection and can be used in chemical, textile, food, light and other industries for the purification of dusty gases.

The closest technical solution to the claimed object is a scrubber according to the patent of the Russian Federation No. 2330713 (prototype), containing a conical, cylindrical part and a sludge collector, a nozzle for introducing dusty gas, a nozzle for exiting a cleaned one, an irrigation device including an external pipeline with lower and upper cuts into the case nozzles

The disadvantage of the prototype is the relatively low efficiency of the dust collection process due to the underdeveloped spray surface of the liquid.

EFFECT: increased efficiency and reliability of the dust collection process by increasing the degree of liquid atomization by nozzles.

This is achieved by the fact that in a scrubber containing a housing, a housing comprising a conical, cylindrical part and a sludge collector, a nozzle for introducing dusty gas, a nozzle for exiting a cleaned one, an irrigation device including an external pipeline with lower and upper nozzles embedded in the housing, the ratio of the diameter of the apparatus D to the diameter of the inlet pipe D _o is in the optimal range of values: D / D _o = 2.2 ... 2.5, and the ratio of the height of the apparatus N to the diameter of the inlet pipe D _o is in the optimal range of values: N / D _o = 4, 8 ... 5.7, and the nozzle made in the form of vortex nozzles, each of which contains a housing with a swirl chamber and a nozzle, the housing is made in the form of a supply fitting with a central hole, and rigidly connected to it and a coaxial cylindrical sleeve with an internal thread and an expansion chamber, coaxial to the housing, while being aligned with the housing , in its lower part a nozzle made in the form of an inverted glass is connected to the sleeve by means of a thread, in the bottom of which a turbulent swirl of a fluid flow is made with at least two inclined to the axis of the nozzle with inlets in the form of cylindrical holes located in the end surface of the nozzle, where a central cylindrical throttle hole is also made, connected to the nozzle mixing chamber connected in series with the diffuser outlet chamber, a divider made in the form of at least three spokes is installed in the diffuser outlet chamber , each of which is fixed at one end on the outer surface of the diffuser outlet chamber, perpendicular to its surface, and the other at the surface of the body of revolution, n an example of a ball whose axis coincides with the axis of the diffuser output chamber, and the rotation body itself is located in the lower part behind the slice of the diffuser output chamber, a diffuser is attached to the end surface of the cylindrical sleeve coaxial with the body, coaxial to the diffuser chamber, the cut surface of which lies in the plane, located below the surface of the body of rotation of the divider, and the divider is made in the form of two spokes, each of which is attached at one end to the outer surface of the diffuser output chamber, perpendicular to forming it surface, and the other on the axis on which, with the possibility of rotation, is installed a body of revolution made in the form of a ball, the center of which lies on the axis of the diffuser output chamber, while the surface of the body of revolution, made in the form of a ball mounted on the axis, can rotation, made perforated, and to the surface of the body of rotation, made in the form of a ball mounted on the axis, with the possibility of rotation, elements are installed that carry out its rotation, for example in the form of segments of screw blades.

In FIG. 1 shows a general view of the scrubber; FIG. 2 is a plan view thereof, in FIG. 3 is a diagram of a vortex nozzle for spraying liquids; FIG. 4 is an embodiment of a nozzle rotation body with resonant recesses.

The scrubber contains a housing including a conical 1, cylindrical 2 parts and a sludge collector 3, a pipe 4 for introducing dusty gas, a pipe 5 for exiting purified gas with a spiral flow straightener. The irrigation device is made in the form of at least two external water supply pipelines 6 and 7 connected to a common fluid supply 10, each of which has lower 8 and upper 9 vortex nozzles embedded in the housing 1, having the opposite direction of rotation of the sprayed liquid from the irrigation devices. In the lower part of the housing there is a sludge collector 3 with a L-shaped plate. The ratio of the diameter of the apparatus D to the diameter of the inlet pipe D _o is in the optimal range of values: D / D _o = 2.2 ... 2.5. The ratio of the height of the apparatus N to the diameter of the inlet pipe D _o is in the optimal range of values: N / D _o = 4.8 ... 5.7.

The vortex nozzle (Fig. 3-4) includes a housing 11, which is made in the form of a supply fitting with a central hole 13, and rigidly connected to it and a coaxial cylindrical sleeve 12 with an internal thread 15. An expansion chamber 14 is located in the cylindrical sleeve 12 coaxial to the housing. In this case, coaxially to the housing, in its lower part it is connected to the sleeve 12 by means of a thread 15 a nozzle 16 made in the form of an inverted cup, in the bottom 17 of which a turbulent swirl of a fluid flow is made with at least two cylinder-shaped openings inclined to the axis of the nozzle 19 and 20 located in the end surface of the nozzle 16 formed by its bottom 17. In the end surface of the nozzle 16 also has a Central cylindrical throttle hole 18 connected to the mixing chamber 21 of the nozzle, sequentially connected ennoy diffuser with outlet chamber 22. Moreover, the effective area of flow sections of inclined cylindrical holes 19 and 20, taken in combination, and the center hole 18 are equal.

In the output diffuser chamber, a divider is installed, made in the form of at least three spokes 23, each of which is fixed at one end on the outer surface of the diffuser output chamber 22, perpendicular to its surface, and the other in the surface of the body of revolution 24, for example, a ball, whose axis coincides with the axis of the diffuser outlet chamber 22, and the body of revolution 24 is located in the lower part, behind a slice of the diffuser outlet chamber.

It is possible that the surface of the body of revolution 24, whose axis coincides with the axis of the diffuser outlet chamber 22, and the body of revolution 24 is located in the lower part, behind a slice of the diffuser outlet chamber, is made in the form of an ellipsoid, the small axis of which is axisymmetric to the axis of the diffuser outlet chamber 22 ( not shown in the drawing).

A variant is possible when a diffuser 25 is attached to the end surface of the cylindrical sleeve 12, coaxial with the housing 11, coaxially with the diffuser chamber 22, the cut surface of which lies in a plane below the surface of the divider rotation body 24.

A variant is possible when the divider is made in the form of two spokes 23, each of which is fixed at one end on the outer surface of the diffuser outlet chamber 22, perpendicular to its surface, and the other on the axis 26, on which, with rotation, a rotation body 24 is mounted, made in the form of a ball, the center of which lies on the axis of the diffuser output chamber 22.

A variant is possible when the surface of the body of revolution 24, made in the form of a ball mounted on an axis 26, is rotatable perforated.

A variant is possible when, to the surface of the body of rotation 24, made in the form of a ball mounted on the axis 26, with the possibility of rotation, elements are installed that rotate it, for example, in the form of segments of screw blades (not shown).

A variant is possible when on the inner surface of the central cylindrical throttle hole 18 located in the end surface of the nozzle 16, helical grooves are made for additional twisting of the fluid flow (not shown).

Vortex nozzle operates as follows.

The sprayed liquid enters the casing 11 through the central opening 13, then into the expansion chamber 14, coaxial to the casing 11. After the chamber 14, the liquid is directed to the nozzle 16, where it is distributed in several directions: the first through the central cylindrical throttle hole 18 into the mixing chamber 21, and the second - into a turbulent swirl of a fluid flow with inlets inclined to the nozzle axis in the form of cylindrical holes 19 and 20, also connected to the mixing chamber 12 of the nozzle, where during the interaction of these encountered flows Odita crushing them to form a turbulent flow heading to the diffuser outlet chamber 22, where the additional fragmentation of liquid droplets when they collide with each other due to the expanding of the turbulent fluid flow.

In the output diffuser chamber 22, the output vortex stream collides with the divider, its spokes 23, and the surface of the body of revolution 24, which leads to additional crushing of liquid droplets and the formation of finely sprayed jets.

It is possible that in the body of revolution 24, the axis of which coincides with the axis of the diffuser outlet chamber 22, and the body of revolution 24 is located in the lower part, behind the slice of the diffuser outlet chamber, resonance recesses 27 are made in shape in the form of a cylindrical surface of different diameters and lengths, performing the functions of Helmholtz resonators, the dimensions of which are determined by the necessary frequency of pulsation of the fluid flow (Fig. 2) to increase the fineness of the sprayed flame.

Scrubber works as follows.

The dusty gas stream enters the housing 1 through the tangential inlet 4 of the dusty gas stream, and encounters a swirling atomized liquid stream in its way, having a twist direction, both opposite to the direction of twist of the gas stream, and in passing. As a result of this interaction, a gas-liquid suspension is formed, which enters through the spreader into the pipe 5 and is released into the atmosphere. Sludge is discharged through a sludge collector 3.

A centrifugal nozzle for spraying liquids works as follows.

The fluid is fed through the inlet 11 into the annular gap 16, from where to the swirl 15 through the throttling holes 17 tangentially located to the inner surface of the swirl 15. The rotating fluid flow from the swirl 15 exits through a calibrated conical hole 19 of the nozzle insert 18, resulting in a spray of liquid whose root angle is determined by the angle of inclination of the conical surface of the hole 19.

With an average diameter of the hole 19, which is in the range of 2.5 ... 3.5 mm and the pressure supplied through the inlet 11 of the liquid under a pressure of 6 ... 9 MPa, atomization of 400 to 1000 kg / h of liquid is provided. The nozzle is easy to manufacture and maintain.

The proposed device can be used to clean fine dust and humidify air in ventilation units and air conditioning units, as well as in trapping mists, readily soluble dust, as well as in joint processes of dust collection, gas cooling and absorption. The effectiveness of the proposed apparatus design increases due to the larger surface of the gas-liquid suspension, by using counter-swirling flows of liquid and gas, and in the above processes and when collecting dust particles larger than 5 microns in size is about 95% ... 97%.

Claims (1)

A scrubber containing a housing including a conical, cylindrical part and a sludge collector, a nozzle for introducing dusty gas, a nozzle for exiting a cleaned one, an irrigation device including an external pipeline with lower and upper nozzles embedded in the housing, the ratio of the diameter of the apparatus D to the diameter of the inlet nozzle D _o is in the optimal range of values: D / D _o = 2.2 ... 2.5, and the ratio of the height of the apparatus N to the diameter of the inlet pipe D _o is in the optimal range of values: N / D _o = 4.8 ... 5.7, and nozzles made in the form of vortex nozzles k, each of which contains a housing with a swirl chamber and a nozzle, the housing is made in the form of a supply fitting with a central hole and rigidly connected to it and a coaxial cylindrical sleeve with an internal thread and an expansion chamber, coaxial to the housing, while being aligned with the housing in its lower part a nozzle made in the form of an inverted cup connected to the sleeve by means of a thread, in the bottom of which a turbulent swirl of a fluid flow is made with at least two inlet in the form of cylindrical holes of holes located in the end surface of the nozzle, where a central cylindrical throttle aperture is also made, connected to the mixing chamber of the nozzle connected in series with the diffuser outlet chamber, in the diffuser outlet chamber there is a divider made in the form of at least three spokes, each of which one end is fixed on the outer surface of the diffuser outlet chamber, perpendicular to forming its surface, and the other - on the surface of the body of revolution, for example a ball whose axis coincides with the axis of the diffuser outlet chamber, and the rotation body itself is located in the lower part behind the slice of the diffuser outlet chamber, a diffuser is attached to the end surface of the cylindrical sleeve coaxial with the housing coaxially to the diffuser chamber, the cutoff surface of which lies in a plane below the surface of the divider rotation body and the divider is made in the form of two knitting needles, each of which is fixed at one end on the outer surface of the diffuser output chamber, perpendicular to its surface, and the other on the axis, on With the possibility of rotation, a rotation body is installed, made in the form of a ball, the center of which lies on the axis of the diffuser output chamber, while the surface of the body of rotation, made in the form of a ball mounted on the axis, can be rotated, is perforated, to the surface of the body of rotation made in the form of a ball mounted on the axis, with the possibility of rotation, elements are installed that rotate it, for example, in the form of segments of screw blades, while on the inner surface of the central cylindrical core a spiral hole of the vortex nozzle located at the end surface of the nozzle has helical grooves for additional twisting of the fluid flow, characterized in that in the body of rotation of the vortex nozzle, the axis of which coincides with the axis of the diffuser outlet chamber, and the rotation body itself is located in the lower part, a slice of the diffuser output chamber, resonant recesses are made in shape in the form of a cylindrical surface of different diameters and lengths, performing the functions of Helmholtz resonators, the dimensions of which are determined by the required frequency of pulsation of the fluid flow to increase the fineness of the spray torch.

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