SU1632476A1 - Gas cleaning apparatus - Google Patents

Abstract

The invention relates to heat and mass transfer equipment, can be used in the process of cleaning and cooling gases, absorption, wet dust collection and eliminates sprinkling and reduce material consumption. The gas cleaning apparatus includes a housing, cylindrical shells of spraying cones interconnected along the height of the apparatus, while the cylindrical shell of the first spray cone along the gas flow is connected to the gas inlet. In the gap between the housing and the cylindrical shells, an axial multi-blade swirl is installed with the direction of flow swirling opposite to the direction of twisting the flow with slotted notches of the spraying cones, and the gas outlet nozzle is directed tangentially to the body in the direction of twisting the flow with an axial multi-blade swirl. 2 з.п, ф-л, 4 Il.

Description

The invention relates to heat and mass transfer equipment and can be used to carry out gas cleaning and cooling processes, absorption, and wet dust collection.

The aim of the invention is the elimination of the splash hole and the reduction of the material intensity of the apparatus.

Figure 1 schematically shows the apparatus; figure 2 is the same, top view; on fig.Z - section aa in figure 1; figure 4 - element spray cone with slit notches.

The gas cleaning apparatus includes a housing 1 with a gas supply nozzle 2, a tangential gas exhaust nozzle 3, a nozzle 4 for draining the liquid, spraying a cone 5 with slotted notches 6, a fluid supply pipe 7 provided with axial conical swirlers 8 and fender elements 9. The cone 5 is connected to the height of the apparatus by cylindrical shells 10, while the cylindrical shell of the first along the gas flow of the spraying cone is connected to the nozzle 2 of the gas supply. In the gap between the cylindrical shells 10 and the body 1 of the apparatus, an axial multi-blade swirler 11c is installed with a direction of flow swirl opposite to the direction of flow swirl with slotted notches 6 spray cones 5. The tangential nozzle 3 is located in the direction of the flow twist with an axial multi-blade swirl 11.

The gas cleaning apparatus operates as follows.

The gas stream enters the apparatus through the pipe 2, connected to the cylindrical shell 10 of the first along the gas

a stream of spraying cone 5 with slotted notches 6. Irrigating liquid flows into the upper part of the apparatus, enters the tube 7 and is distributed over the height of the apparatus, flowing out through the slots formed by the ends of the tubes 7 and the fender elements 9 with a cascade of liquid curtains. The irrigating fluid is picked up by the gas flow, directed to the spray cone, crushed, pass through the slotted notches 6, the smaller base of the cone 5 and the axial conical swirl blade 8, and at the same time it is in intensive contact with the gas flow. Such interaction of gas and liquid provides very favorable conditions for heat and mass transfer due to the creation of a highly developed and continuously renewed contact surface of phases.

The passage of the slotted notches 6 and the swirler 8, the gas-liquid flow is twisted. In the swirling gas-liquid flow coming out of the first phase contact phase, the interaction between the gas and the liquid on the surface of the droplets carrying along with the gas continues; down and in the form of a film, they are again picked up by the gas stream and are crushed by it when they pass through the slit together. 6, and the gas stream is also in intensive contact with the fresh portions. This means that the gas stream is consistently and repeatedly encountered with the torches of the liquid, the unsaturated absorbed components, intensively contacts with it on the spray cones 5 and during the passage of the conical swirlers 8. Pass through several stages of spraying and contact , the swirling gas-liquid flow exits through the slotted notches of the lower sawing cone 5 and through the blades of the conical swirler 8, while under the action of centrifugal forces large droplets liquids are thrown to the walls of housing 1, collected in its lower part, and the contact liquid is withdrawn from the apparatus through fitting 4. The gas flow continues to move upwards in the annular gap between the shells 10 and housing 1, while on the approach to the multi-blade axial swirler 11 it changes direction of twist on the opposite. By changing the swiveling direction to the opposite, the gas flow is completely free from liquid droplets, which, being thrown against the walls of the housing 1, form a downwardly flowing film of liquid. , which eliminates the formation of stagnant zones in it.

Thus, the connection of the cylindrical shells of spraying cones between each other along the height of the apparatus and the fastening of the cylindrical shell of the first gas stream of the sawing cone to the gas inlet pipe forms an area of intense downward contact of gas and liquid, while the annular gap between the shells and the housing in which a multi-blade axial swirler is installed, virtually eliminating the liquid carried away from the apparatus by the gas flow by changing the direction of the swirling flow, which ensures The liquid drops are almost completely separated from the gas stream. At the same time, the dimensions of the apparatus, i.e. decreases its consumption of materials. The advantage of this device is the location of the gas inlet and outlet nozzles at the same level, which facilitates the installation of the device in technological communications that ensure the purification of gases.

Claims (3)

1.A gas cleaning device, including a housing with gas inlet and outlet nozzles, a fitting for draining liquid, spraying cones with slotted notches, equipped with cylindrical shells attached to their large bases, a pipe for liquid bore and fitted with axial conical swirlers and fender elements, characterized in that, in order to eliminate the splash guards and reduce the material capacity of the apparatus, the cylindrical shells of the spraying cones are interconnected along the height of the apparatus, while the cylindrical The gull of the first along the gas flow of the spraying cone is connected to the gas inlet. 2. An apparatus according to claim 1, characterized in that it is provided with a connected multi-blade swirler installed in the gap between the casing and the cylindrical shells, with the direction of flow swirling opposite to the direction of flow swirling of the spray cones. 3. The apparatus according to claims 1 and 2, characterized in that the gas inlet fitting is installed tangentially to the body and in the direction of swirling of the flow with an axial multi-blade swirl. FIG. one Gas FIG. 2 Fig.Z / Phage. four