SU814417A1 - Apparatus for cleaning gases - Google Patents

Description

one

The invention relates to the purification of ventilation emissions containing ammonia from the photocopiers used in the printing industry and can be used to clean up similar emissions from other industries.

Apparatuses for cleaning vent emissions are known, consisting of an adsorption part and a drift catcher, where various failed-type gratings are installed in the adsorption part, and the drop catcher is an inertial louver-type device, I:

A gas cleaning apparatus is known, comprising a housing, an adsorption chamber with a nozzle located therein, and a droplet separator.

In the known apparatus, the adsorption process is carried out in the reaction layer, which is a nasak, made of needle-punched material with a thickness of 4-5 mm, with subsequent trapping of condensed vapors and splashes in the droplet separator 2.

However, at gas velocities of 2.53, 5 m / s, there is a violation of the foam regime with the formation of long gas flares that emerge on the surface of the foam layer and transform it into a system of relatively large jets and liquid splashes emitted by the gas, which leads to a sharp increase in ash spray and condensed fog. This reduces the contact surface.

0 gas with a liquid and the uniformity of the adsorption process is disturbed, which leads to a decrease in the efficiency of gas cleaning.

The purpose of the invention is to increase the efficiency of the process of trapping ammonia from the ventilation air.

The goal is achieved by the fact that the drip catcher is equipped with a distribution chamber with windows,

0 installed coaxially it is a package of grids with alternating cell sizes in the ratio of 1/2, and the distance between the distribution chamber and the grid package

5 is 0.9-1.1 window widths.

In addition, the nozzle is made in the form of mesh layers, having a living cross section of 55-60%, and the ratio of the diameter of the filament of the mesh to the distance between the grids is, 8.

The drawing shows a gas cleaning apparatus.

Appa5) am contains two working stages: an adsorption chamber and a drip catcher. The adsorption chamber is complete in two detachable sections: bottom 1 and intermediate 2. In the bottom section 1 there is an inlet 3 for introducing contaminated ventilation air into the apparatus and a nozzle 4 for draining the spent solution. In the intermediate section 2, a nozzle 5 is installed and a pipeline with a nozzle device b for supplying the absorption solution.

Inertial drift catcher 7 contains a distribution chamber 8 with windows (openings) 9 placed in the cylindrical part of the drift catcher body above the intermediate section 2 of the adsorption chamber. On the wall of the cylindrical part of the drip pan 7 opposite the windows (openings) 9 of the distribution chamber 8, a package of mesh 10 is installed. The distance between the distribution chamber and the package surface adjacent to it is 0.9-1.1 of the window width (hole diameter). The cross-sectional area of the windows (or holes) is calculated based on the productivity of the apparatus and the diameter of the droplets to be captured. In the lower part, the casing of the drop absorber 7 has a drain fitting I, and its conical part - the outlet 12 for the removal of purified air.

The device works as follows.

The contaminated air enters through the inlet 3 to the bottom section 1 of the adsorption chamber.

The air passes with its further movement through the nozzle 5, which is colored by the absorption solution (technical or weakly acidified water is used as the latter), creating a gas-liquid layer in the nozzle in which ammonia is adsorbed. When using nozzles from grids, the operation of the apparatus is characterized by the formation of a cellular film foam in which separate gas bubbles are connected to each other by liquid films separating them.

The particles of the absorption pacTBOpav that are carried away from the reaction layer by the purified air enter the distribution chamber 8 of the drip pan and pass through its windows 9

acquire a given speed. With a sharp change in the direction of air movement and a drop in the velocity of the particle due to inertial properties, the length of the straight motion and get into the cells of the package, combined into large drops, flow down the grids to the lower part of the drift catcher 7 and through the drain fitting 11 and the hydraulic seal the output from the apparatus . Using nozzles from the nets

o intensify the absorption process by reducing the digeter of gas bubbles and the development of the area wetted by the absorption surface of the contacting surface, leads

5 to an increase in the contact surface of the phases, and consequently, to the intensification of the processes of heat and mass transfer. At the same time, uniform foam mode is maintained, the formation of long gas flares is eliminated, the splash of the absorption solution is reduced. The use of these elements allows to intensify the process of adsorption, and, consequently, the efficiency of gas cleaning, as well as

5 to improve the hydrodynamic characteristics of the apparatus and its durability.

Claims (2)

1. A gas cleaning apparatus, comprising a housing, an adsorption chamber with a nozzle and a drip catcher located in it, characterized in that, in order to increase the efficiency of ammonia trapping, the drip tray is equipped with a distribution chamber with windows, installed in a coaxially alternating-size mesh package cells with respect to 1/2, and the distance between the distribution chamber and the grid packet is 0.9-1.1 window widths. 2. The apparatus according to claim 1, characterized in that the nozzle is made in the form of mesh layers with a living cross section of 55-60%, and the ratio of the diameter of the mesh thread to the distance between the meshes is 0.4-0.8. Sources of information taken into account in the examination 1. Author's certificate of the USSR 434969, cl. On 01 D 47/04, 1971. 2. Industrial and sanitary cleaning of gases. 1967, 4, p. 22