RU2665526C1 - Conical jet scrubber - Google Patents

Abstract

FIELD: dust collection equipment.SUBSTANCE: present invention relates to wet dust collection and can be used in chemical, textile, food, light and other industries for purification of gases. Cone nozzle scrubber contains a housing with nozzles for dusty and clean gas, a spray nozzle, support and restrictive plates, between which the nozzle is located, a splatcher made in the form of a nozzle layer located between the supporting and restricting trays, and a device for removing slurry, the support plates being elastic, the nozzle positioned above the lower support plate is made of resilient materials, for example in the form of polyethylene balls, and a vibrator is mounted on the lower support plate, the nozzle is made in the form of hollow balls, on the spherical surface of which a screw groove is cut, or the nozzle is made in the form of a screw line formed on a spherical surface and having a profile like a circle, polygon, "Berl saddle" or "Itallox" saddle in the section perpendicular to the screw line, spraying device is made in the form of vortex nozzles, each of the nozzles comprising a hollow cylindrical body with an external thread for connecting to the connection of a distribution pipeline for supplying liquid and a cap nut fixed to the bottom of the body with a liquid flow divider, wherein in the body a cylindrical opening is made coaxially to it, in the upper part of which a strainer is installed, and in the lower part there is a throttle washer with a nozzle and a divider, the liquid flow divider is attached to the end surface of the union nut and is made of a rod type in the form of a truncated tetrahedron fixed to the end face of the union nut, the edges of which are rods with fixed blades with stops in such a way that they can be rotated from the streams emanating from the throttle washer with the jet of the injector, wherein the edges of the tetrahedron base are also connected by rods with fixed blades and stops, and a diffuser is attached to the surface of the intersection of the end surface of the union nut with its outer surface, covering with its lateral conical surface the divider of the liquid flow, while the outlet of the diffuser is below the base of the truncated tetrahedron, and the outlet itself is connected to an additional divider arranged in the form of a circular perforated plate perpendicular to the axis of the diffuser, a netted dome element is connected to the perforated plate with a vertex directed away from the jet of the nozzle and the cavity of this element is filled with a porous material, for example a wire of the "putanka" type, and the axisymmetric outlet of the diffuser, to the circular perforated plate of the additional dissector, in its central part, a central cylindrical atomizer is formed, which is made in the form of a cylindrical shell, the solid part of which is located in a reticular dome-shaped element, the cavity of which is filled with a porous material, and the perforated part of the cylindrical atomizer extends beyond the mesh dome element.EFFECT: increased efficiency and reliability of the dust collection process by increasing the liquid spraying rate of injectors.1 cl, 5 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. 2322425 (prototype), comprising a housing consisting of a cylindrical part, a conical part, the lower part of which is connected to a cylindrical part and a conical sludge collector, nozzles, respectively, for dusty and purified gas, an irrigation device made in the form of a nozzle installed in the center of the housing.

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 conical nozzle scrubber containing a housing with nozzles for dusty and purified gas, a nozzle irrigation device, support and restriction plates, between which there is a nozzle, a spray trap made in the form of a nozzle layer placed between the support and restriction plates and the device for removal of sludge, and the supporting plates are made elastic, and the nozzle placed above the lower supporting plate is made of elastic materials, for example in the form of plastic balls, but a vibrator is mounted on the lower support plate, the nozzle being made in the form of hollow balls with a helical groove cut through its spherical surface, or the nozzle is made in the form of a helical line formed on a spherical surface and having in cross section perpendicular to the helical profile a circle, polygon type profile, “Berl saddles” or “Itallox” saddles, the irrigation device is made in the form of vortex nozzles, each of which contains a hollow cylindrical body with an external thread for connection to the distributor nozzle pipe for fluid supply, and, mounted in the lower part of the housing, a flare nut with a liquid flow divider, and in the housing, coaxially to it, a cylindrical hole is made, in the upper part of which a strainer is installed, and in the lower part there is a throttle washer with a nozzle and a divider, a liquid flow divider is attached to the end surface of the union nut and is made of the rod type in the form of a truncated tetrahedron fixed to the end surface of the union nut, the ribs of which are the rod and with blades fixed on them with stops in such a way that they can be rotated from flows emanating from the throttle washer with the nozzle nozzle, while the ribs of the tetrahedron base are also connected by rods with blades and stops fixed on them, and on the intersection surface of the butt surface nuts with its outer surface, a diffuser is attached, covering a liquid flow divider with its lateral conical surface, while the outlet of the diffuser is below the base of the truncated tetrahedron and the outlet itself is connected to an additional divider made in the form of a round perforated plate perpendicular to the axis of the diffuser, while a mesh dome-shaped element with a vertex directed away from the nozzle nozzle is attached to the perforated plate, and the cavity of this element is filled with a porous material, for example, wire type of "muddle", and axisymmetrically to the outlet of the diffuser, to the round perforated plate of the additional divider, in its central part, the central a cylindrical atomizer made in the form of a cylindrical shell, the solid part of which is located in a mesh dome-shaped element, the cavity of which is filled with porous material, and the perforated part of the cylindrical atomizer extends beyond the mesh dome-shaped element.

A round perforated plate is attached to the perforated part of the shell of the nozzle cylinder. A diffuser is attached to the round perforated plate of the nozzle cylinder. In the nozzle diffuser, made in the form of a truncated conical surface, perpendicular to its axis, to the inner surface, an axis is fixed located in the middle between the perforated plate and the outlet cross section of the diffuser, while rotating nozzles are mounted on the axis, located symmetrically relative to the axis of the body, and made in the form cylinders with helical grooves on the surface, and the helical grooves of the rotating nozzles have the opposite direction.

In FIG. 1 shows a conical nozzle scrubber with a movable nozzle; FIG. 2 - nozzle in the form of hollow balls, on a spherical surface of which a helical groove is cut, in FIG. 3 - nozzle in the form of cylindrical rings, on the side surface of which a helical groove is cut, in FIG. 4 - a nozzle in the form of cylindrical rings, on the lateral surface of which a helical groove is cut, having in cross section perpendicular to the helical line a profile of the Berl saddle or Itallox saddle, in FIG. 5 is a nozzle diagram.

A conical nozzle scrubber with a movable nozzle comprises a housing consisting of a cylindrical part 1, a conical part 2, the lower part of which is connected to a cylindrical part 3 and a conical sludge collector 4, with nozzles for dusty and purified gas, respectively. The irrigation device 7 is made in the form of a nozzle mounted in the center of the housing. The spray catcher is made in the form of a nozzle layer 9 located between the support 5 and restrictive 6 plates (Fig. 1). A nozzle layer is also located on the lower support plate 8. The lower 5 and 8 support plates and nozzle 9 are made of elastic materials. The nozzle placed above the lower support plate is made of elastic materials, for example in the form of plastic balls. In FIG. 2 shows a variant of the nozzle 10 in the form of hollow balls, on the spherical surface of which a helical groove is cut, in FIG. 3 is a variant of a nozzle in the form of cylindrical rings, on the side surface of which a helical groove is cut, in FIG. 4 is a variant of a nozzle in the form of cylindrical rings, on the lateral surface of which a helical groove is cut, having in cross section perpendicular to the helical line a profile of the Berl saddle or Itallox saddle. A vibrator can be installed on the lower support plate 8 (not shown in the drawing). The nozzle can be made of elastic polymeric materials, composite materials, and obtained by molding or sintering.

The vortex nozzle (Fig. 5) contains a hollow body 11, consisting of a cylindrical part with an external thread for connecting to the fitting (not shown) of a distribution pipe for supplying fluid, and, secured in the lower part of the body, a union nut 16 with a flow divider 17 liquids. In the housing 11, coaxially to it, a cylindrical hole 12 is made, in the upper part of which a strainer 14 is installed, and in the lower part there is a throttle washer 13 with a nozzle 15.

The fluid flow divider 17 is attached to the end surface of the union nut 16 and is made of the rod type in the form of a truncated tetrahedron fixed to the end surface of the union nut 16, whose ribs 18 are rods with blades 19 fixed to them with stops 20 so that they can rotate from flows emanating from the throttle washer 13 with the nozzle nozzle 15, while the ribs of the base of the tetrahedron are also connected by rods with blades and stops fixed to them.

To the surface of intersection of the end surface of the union nut 16 with its outer surface, a diffuser 21 is attached, covering a liquid flow divider 17 with its lateral conical surface, the outlet of the diffuser 17 being below the base of the truncated tetrahedron, and the outlet itself is connected to an additional divider 22 made in the form of a round perforated plate perpendicular to the axis of the diffuser 21, while a mesh dome-shaped element 23 with a vertex attached to the perforated plate 22 a systematic way in the direction of the jet nozzle 15 and the cavity 24 of the element is filled with a porous material, such as wire type "thread waste."

The nozzle with the active divider is as follows.

When the fluid is supplied to the housing 11 under the action of a pressure drop of 0.4 ... 0.8 MPa, it rushes into the cylindrical hole 12 through the strainer 14, and then into the throttle washer 13 with the nozzle 15. From the nozzle 15, the fluid flows into the divider 17, in the form of a truncated tetrahedron fixed to the end surface of the union nut 16, the ribs 18 of which are rods with blades 19 fixed to them with stops 20 so that they can be rotated from the flows coming from the throttle washer 13 with the nozzle nozzle 15, which allows stole chit fine dispersion phase liquid spray.

A variant is possible when the axisymmetric outlet of the diffuser 21, to the round perforated plate 22 of the additional divider, in its central part, is attached a central cylindrical atomizer 25, made in the form of a cylindrical shell, the solid part of which is located in the mesh dome-shaped element 13, the cavity of which is filled with porous material 24, and the perforated portion 26 of the cylindrical atomizer 25 extends beyond the mesh dome-shaped element 23.

It is possible that a round perforated plate 27 is attached to the perforated portion 26 of the shell of the cylindrical atomizer 25.

It is possible that a diffuser 28 is attached to the round perforated plate 27 of the cylindrical atomizer 25.

It is possible that in the diffuser 28, made in the form of a truncated conical surface, perpendicular to its axis, to the inner surface, an axis 29 is fixed located in the middle between the perforated plate 27 and the output section of the diffuser 28, while the rotary nozzles 30 are mounted on the axis 29 symmetrically about the axis of the housing 11, and made in the form of cylinders with helical grooves on the surface, and the helical grooves of the rotating nozzles 30 have the opposite direction.

Conical nozzle scrubber with a movable nozzle operates as follows.

The dusty gas stream enters the housing 1, through the inlet of the dusty gas stream, and meets a curtain from the nozzle 9, which is wetted with water or other absorbent from the irrigation device 7. To remove sludge, a device 4 is used to remove sludge in the form of a channel in the bottom of the housing or a separate mechanism. To ensure free movement of the nozzle 9 in the gas-liquid mixture, its density should not exceed the density of the liquid. The process of dust collection takes place in the optimal hydrodynamic mode of the gas scrubber, characterized by the regime of full developed fluidization. To intensify the hydrodynamic regime, a vibrator is installed on the lower support plate 8 (not shown in the drawing). This will allow the scrubber to switch to the vibro-fluidized bed mode, in which the interaction efficiency of the nozzle 9, irrigated by the liquid, with the gas phase will increase, and, consequently, will increase the overall efficiency of the apparatus. The implementation of the nozzle 9, the bottom 8 of the support plate of elastic material will allow under certain conditions to create a mode of oscillation or self-oscillation, which will also increase the efficiency of interaction of the nozzle 9 with the irrigated liquid.

The scrubber 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 the process of dust collection, gas cooling and absorption of packed gas washers.

Claims (1)

A conical nozzle scrubber comprising a housing with nozzles for dusty and purified gas, a nozzle irrigation device, support and restriction plates, between which a nozzle is located, a spray catcher made in the form of a nozzle layer located between the support and restriction plates, and a device for removing sludge, the supporting plates are made elastic, and the nozzle placed above the lower supporting plate is made of elastic materials, for example in the form of plastic balls, and on the lower supporting plate a vibrator is installed, and the nozzle is made in the form of hollow balls, on the spherical surface of which a helical groove is cut, or the nozzle is made in the form of a helix formed on a spherical surface and having in cross section perpendicular to the helical line, a profile such as a circle, polygon, “Berl saddle” or Itallox saddles, the irrigation device is made in the form of vortex nozzles, each of which contains a hollow cylindrical body with an external thread for connection to the nozzle of the distribution pipe for a liquid ode and a union nut fixed in the lower part of the housing with a fluid flow divider, and a cylindrical hole is made in the housing, coaxial to it, a strainer is installed in the upper part, and a throttle washer with a nozzle and a divider is installed in the lower part, the fluid flow divider is attached to the end surface of the union nut and is made of the rod type in the form of a truncated tetrahedron, fixed to the end surface of the union nut, the ribs of which are rods with a fixed blade with stops in such a way that they can be rotated from the flows emanating from the throttle washer with the nozzle nozzle, while the ribs of the base of the tetrahedron are also connected by rods with blades and stops fixed to them, and to the intersection surface of the end surface of the union nut with its outer surface a diffuser is attached, covering with its lateral conical surface a liquid flow divider, while the outlet of the diffuser is below the base of the truncated tetrahedron, and the outlet itself with it is integrated with an additional divider made in the form of a round perforated plate perpendicular to the axis of the diffuser, while a mesh dome-shaped element with a vertex directed away from the nozzle nozzle is attached to the perforated plate, and the cavity of this element is filled with porous material, for example, a wire of the “tangle” type, and axisymmetric to the diffuser outlet, to the round perforated plate of the additional divider, in its central part, a central cylindrical spray is attached spruce made in the form of a cylindrical shell, the solid part of which is located in the mesh dome-shaped element, the cavity of which is filled with porous material, and the perforated part of the cylindrical atomizer extends beyond the mesh dome-shaped element, characterized in that a round perforated plate is attached to the perforated part of the shell of the cylindrical atomizer to which a diffuser is attached, made in the form of a truncated conical surface, perpendicular to its axis, to the inside on the surface, an axis is fixed, located in the middle between the perforated plate and the outlet cross section of the diffuser, while rotary nozzles are mounted on the axis, located symmetrically relative to the axis of the body and made in the form of cylinders with screw grooves on the surface, and the spiral grooves of the rotary nozzles have the opposite direction.

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