SU967520A1 - Apparatus for wet cleaning of gases from solid particles - Google Patents

Description

The invention relates to chemical engineering and can be used for wet cleaning of gases, for example gaseous olefins, from solid particles.

A known apparatus for wet cleaning of gases from solid particles, including a cylindrical body with bubbled plates [1].

The disadvantage of such devices is the low quality of cleaning due to the presence of built-in gas detectors made in the form of plates with local openings for the distribution of gases over the cross section.

Closest to the invention in technical essence is an apparatus for wet cleaning of gases from solid particles, including a vertical cylindrical body, inlet and outlet nozzles for gas and liquid, a liquid distributor, while gas distributors made in the form of truncated conical plates of different sizes are installed over the entire height of the case diameter placed to each other with large bases [2]. However, the flare spray and liquid. the bone curtain does not provide complete contact of all solid particles in the gas stream with the liquid.

The purpose of the invention is to increase the intensity and quality of cleaning by ⁵ by the formation of a continuous and continuous liquid film and bubble layers of a given height.

To achieve the goal, a device for wet cleaning of gases from solid particles, including a vertical cylindrical body, inlet and outlet nozzles for gas and liquid, a liquid distributor, with 15 gas distributors made in the form of truncated cone-shaped plates of different diameters each other with large bases, while plates of a larger diameter 2θ are attached to the case with a large base, and plates of a smaller diameter are installed along the axis of the case, the dispenser is made in in the form of an annular collector and is located above the 25 upper plate, the apparatus is equipped with a support column mounted along the axis, while plates of a smaller diameter are attached to the rack, the larger base of which is located 30 at a distance from the walls of the casing, which is evenly reduced by 3 to the gas inlet pipe, the smaller plate base a larger diameter is placed at a distance from the support column, uniformly decreasing to the gas inlet, and the plates are made with triangular openings directed downward. .

The drawing shows a structural diagram of the apparatus.

The apparatus includes a housing 1, consisting of shells interconnected by flange connections.

Inside the housing 1 is placed a rack 2, consisting of separate parts interconnected. The support column 2 is rigidly connected in the upper part with the shell of the housing 1 using ribs 3, and in the lower part with the gas inlet 4 using ribs 5.

In the lower part of the housing 1 are located the outlet pipe 6 of the liquid and the inner shells 7 and 8, which with the pipe 4 form a chamber for collecting liquid.

in the upper part of the housing, there is a gas outlet pipe 9 and a liquid inlet pipe 10 connected to a distribution chamber, a cup 11, a support column 2 and a conical plate 12 fixed to the support column 2.

The plate 12 with the glass 11 form an annular gap for passing a predetermined amount of liquid into the apparatus, and with a shell of the housing 1 with a conical plate 13 form a pocket with a gap in the lower part, while the plate 13 is rigidly connected with the shell of the housing 1, and forms a support column 2 pocket with a gap at the bottom.

The gaps between the conical plates 12 and 13, the housing 1 and the support column 2. are uniformly reduced in height of the housing, starting from the upper bubble pocket. Plates 12 and 13 have holes 14 for liquid overflow, located at one fixed level and having the shape of a triangle located with the apex down.

The overflow openings on the conical plates record the ultimate fluid levels in the bubble layer.

The triangular shape of the overflow holes located with the top of the triangle downward helps stabilize the operation of the apparatus when the flow rate changes, since an increase in the liquid level requires a smooth flow through the sections of the overflow holes. This requirement is more fully met by the triangular shape of the holes with the top down. At the same time, reliable protection against gas leakage through the free section of the holes due to the contact of the gas with the liquid flowing down from the conical surface is provided.

The gas flow passing through the bubbling layer, due to the increase in the cross section of the layer along the gas, decreases its speed, which leads to a reduction in the entrainment of particles of the solid phase. In this case, the velocity of the film flow of the liquid exceeds the velocity of the solid particles, and the gas flow rate in the bubbling layer decreases uniformly.

The device operates as follows.

The fluid flow through the inlet pipe 10 enters the distribution chamber and through the annular gap between the plate 12 and the glass 11, flowing down the plates 12 and 13, forms a continuous and continuous liquid film, fills the bubble pockets sequentially, starting from above, and meeting with the gas entering into the apparatus through the inlet pipe 4, forms a bubble zone in the pockets? variable, expanding upward volume. In this case, the upper level of the bubble zone is maintained by means of triangular holes 14 and plates 12 and 13 ..

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Thus, the invention can significantly improve the efficiency and quality of dusty gas purification due to the formation of a continuous and continuous liquid film, which promotes better contact ^{4 of the} dusty gas with the liquid.

Claims (1)

1. The patent of the Federal Republic of Germany 2019333, cl. 12 e 2/01, 1977. . U.S. Patent 3,533,608, cl. 261-109, 1970. Purified gas and Liquid Polluted gas