RU91888U1 - BARBOTAGE ABSORBER FOR GAS CLEANING - Google Patents

Abstract

1. A bubbler absorber for cleaning gases from mechanical and chemical components, including a vertical cylindrical body with nozzles for supplying and discharging gas, loading and unloading nozzles for the absorbing reagent, a reservoir for accumulating absorption products, an absorption chamber with tubes for supplying the gas to be cleaned, placed in its upper part, characterized in that the housing is integral with the absorption chamber, the pipes for supplying the gas to be cleaned are installed with the possibility of movement in a vertical plane STI for immersion in the absorbing agent and have a diameter less than the diameter of the tube for supplying gas. ! 2. The absorber according to claim 1, characterized in that the ratio of the diameter of the pipes (S1) for supplying the gas to be cleaned to the diameter of the pipe (S) for supplying the gas S1: S is 0.1-0.2. ! 3. The absorber according to claim 1, characterized in that the cylindrical body is made of corrosion-resistant steel or of organic material resistant in dilute solutions of sulfuric acid.

Description

The utility model relates to devices for cleaning gases from harmful mechanical and chemical components by absorption, can be used in the metallurgical and chemical industries for carrying out processes in the gas-liquid, gas-liquid-solid, and solid-liquid systems with the absorption of mechanical or gaseous components of the gas stream by a liquid phase or suspension.

A known absorber for cleaning gas from acidic components, comprising a housing with gas inlet and outlet fittings, absorbent inlet and outlet fittings, a dividing plate with blank vertical partitions mounted at a distance from the housing wall, forming segmented channels between which the lower mass transfer section is located (Patent RF №1353484, IPC V01D 53/18, publ. 1987.11.23).

In the specified absorber, countercurrent contacting of acid gas is carried out with a partially saturated, finely generated absorbent, and then with a coarse-generated absorbent on mass transfer plates, which allows to achieve a high degree of gas purification.

The disadvantages of the absorber are not high enough performance, increased metal consumption and the complexity of the design of the apparatus.

A known absorber for carrying out the process of absorption of a gas agent by a liquid phase or suspension, containing a cylindrical body with a bottom and nozzles for the input and output of gas, liquid and heat or coolant, the upper and lower tube sheets are placed inside the case, with vertical bubblers and circulation pipes fixed in them while the bubbler pipes consist of sections and are made with perforation for supplying gas inside them, decreasing from bottom to top along the height of the apparatus (AS USSR No. 1386257, IPC MPK V01D 53/18, publ. 1985.10.28). Gas is supplied through the pores of the bubble tubes to the section with the largest pore size and, rising up through the pipes, is absorbed by the liquid phase, and the absorbed amount of gas is made up sequentially from the lower sections. The circulation of the liquid occurs as a result of the difference in the densities of the pure liquid in the circulation pipe and the gas-liquid mixture in the bubble tubes. The absorber provides an increase in productivity by increasing the contact surface of the phases.

The disadvantage of the absorber is the design complexity and the insufficiently high degree of gas purification from impurities.

A known absorber (apparatus APT-prototype), comprising a vertical cylindrical body with a reservoir for accumulating absorbing liquid, equipped with a pipe for removing purified gas located in the side of the body and a discharge pipe for liquid located in the lower part of the body; a vertical absorption chamber placed in the housing, in the upper part of which there are nozzles for supplying gas and loading liquids, as well as a battery of venturi tubes for spraying the absorbing liquid (G.M. Gordon, I.L. Peysakhov. Dust collection and purification of gases in non-ferrous metallurgy, Moscow, M, 1977, p.203-204).

Gas is supplied to the upper part of the absorption chamber, where it is brought into contact with the absorbing liquid sprayed from the venturi, as a result of which the gas is purified, the purified gas is discharged from the housing through the outlet pipe, the liquid with absorbed impurities is accumulated in the tank and then discharged from it.

The disadvantage of the absorber is the low degree of purification of gases from impurities, due to insufficient surface and the duration of contact of the sprayed liquid with gas flowing in the vertical direction. To increase the surface and duration of gas contact with the reagent, it is necessary to increase the height of the absorption chamber or to complicate the design of the apparatus. When using suspensions, for example slaked lime, as an absorber, difficulties arise in operation due to clogging of the sprayers with solid particles in suspension.

The technical result of the proposed utility model is the implementation of effective contact of the gas to be cleaned with the absorbent reagent (liquid or suspension), which allows to increase the degree of gas purification from mechanical, gaseous components while ensuring the reliability of the absorber.

The specified technical result is achieved in that in a bubbler absorber for cleaning gases from mechanical and chemical components, including a vertical cylindrical body with nozzles for supplying and discharging gas, loading and unloading nozzles for an absorbing reagent, a reservoir for accumulating absorption products, an absorption chamber with pipes for of the gas to be purified, placed in its upper part, according to the utility model, the housing is made integral with the absorption chamber, pipes for supplying the gas to be cleaned They are mounted with the possibility of moving in a vertical plane for immersion in an absorbing reagent and have a diameter smaller than the diameter of the pipe for supplying gas.

The ratio of the diameter of the pipes (S ₁ ) for supplying the gas to be cleaned to the diameter of the pipe (S) for supplying gas S ₁ : S is 0.1-0.2, and the cylindrical body is made of corrosion-resistant steel or organic material that is resistant to diluted sulfuric acid solutions.

The execution of the housing at the same time with the absorption chamber ensures the tightness of the apparatus and eliminates leakage of the gas to be cleaned, and the installation of pipes for supplying the gas to be cleaned with the ability to move in a vertical plane allows you to adjust the depth of immersion of the pipes in the absorbing reagent, which provides the necessary surface and duration of gas contact with the absorber reagent (for example , a solution of ammonia or a slurry of slaked lime, limestone), and adjust the height of the non-sparged layer of the suspension in the absorber (h ₁ -h ₂ ), h This eliminates the delamination of both the initial and the suspension formed during gas purification and leads to an increase in the degree of gas purification from mechanical and chemical components. The manufacture of pipes for supplying the gas to be cleaned with a diameter (S ₁ ) equal to 0.1-0.2 of the diameter (S) of the gas supply pipe allows maintaining the gas velocity at the level of 0.5-0.8 m / s, which also provides the necessary the duration of contact of the gases with the absorber and effective gas purification, this eliminates clogging of the pipes with a suspension, which increases the reliability of operation of the absorber.

The figure shows a bubbler absorber for cleaning gases from mechanical and chemical components. The absorber consists of a vertical cylindrical body 1 with a nozzle 3 for supplying purified gas and a nozzle 2 for removing purified gas, a loading 4 and unloading 7 nozzles for an absorbing reagent, a reservoir 6 for accumulating absorption products, in the upper part of the housing there are bubblers 5 for supplying a cleaned gas gas mounted vertically

The operation of the device.

The housing 1 of a bubbler absorber made of corrosion-resistant steel or organic material that is resistant in dilute sulfuric acid solutions is filled through the inlet pipe 4 with an absorbing reagent, which can be used as water, an aqueous suspension of hydrated lime, or another absorber (e.g. ammonia) of gas. Pipes 5 for supplying the gas to be cleaned are immersed to a depth of h ₂ , depending on the required duration of contact of the gas bubbles with the absorbent reagent. Through the pipe 3, the gas to be cleaned is supplied to the bubbler pipe system 5, maintaining the gas velocity in the pipes at a level of 0.5-0.8 m / s, with the ratio of the diameter of the gas supply pipes (S ₁ ) to the diameter of the pipe (S) for supplying the gas to be cleaned gas, S ₁ : S is equal to 01, -0.2. When cleaning a gas containing, for example, sulfur dioxide, and using an aqueous lime suspension as an absorbent, the SO ₂ contained in the gas reacts with the suspension and, in the form of calcium sulfite or calcium sulfate, accumulates with the lime suspension in the tank 6 and is discharged through the discharge pipe 7 from the absorber. The purified gas is discharged from the absorber through the pipe 2, the degree of gas purification from sulfur dioxide reaches 97.5-98.6%.

Examples of using the utility model.

Example 1. As an absorbing reagent used 10% aqueous pulp of limestone, or burnt lime, pre-crushed to a particle size of 90% - 74 microns. A sulfur-containing gas with a SO ₂ content _of 5% (vol.) Was passed through the absorber at a linear velocity of 0.5 m / s. The experiments were carried out at room temperature; the immersion depth of the bubble tubes in the suspension was varied. The results are shown in table 1. From table 1 it is seen that the installation of bubblers with the ability to move in a vertical plane allows for the adopted suspension density to determine the optimal value of immersion of the pipes in the absorbent suspension (15-20 mm), which provides a high degree of absorption, a large amount of immersion to increase the hydraulic resistance of the absorber and energy costs for the cleaning process.

Example 2. A bubbler absorber was used as a dust collector. The apparatus was filled with water, the process was conducted at a temperature of 25 ° C. A known amount of dust in the form of crushed sulfide copper concentrate with an average particle size of ≤40 μm (dust concentration at the inlet 500 g / m ³ , gas flow rate 0.5 m / s) was supplied to the gas stream at the inlet to the absorber. After the experiment, the contents of the tank were filtered, and the cake was dried. Dust collection efficiency was determined as the ratio of the amount of captured dust in the absorber to the mass of dust blown into the apparatus. The obtained data confirmed the high efficiency of using a bubbler absorber as a dust collecting apparatus.

Table 1.
The results of the absorption of sulfur dioxide in a bubbler absorber No. p / p Absorbent The value of the immersion of the bubble tubes, mm The degree of absorption,% one. 1. Limestone suspension 10.0 97.5 20,0 98.6 40,0 98.5 2. Lime suspension 10.0 96.8 20,0 98.5 40,0 98.6

Table 2.
Indicators of wet dust collection in a bubble absorber No. p / p Absorbent The value of the immersion of the bubble tubes, mm Dust collection efficiency,% one. Water 10.0 86.4 2. Water 30,0 97.8 3. Water 50,0 97.9

Claims (3)

1. A bubbler absorber for cleaning gases from mechanical and chemical components, including a vertical cylindrical body with nozzles for supplying and discharging gas, loading and unloading nozzles for the absorbing reagent, a reservoir for accumulating absorption products, an absorption chamber with tubes for supplying the gas to be cleaned, placed in its upper part, characterized in that the housing is integral with the absorption chamber, the pipes for supplying the gas to be cleaned are installed with the possibility of movement in a vertical plane STI for immersion in the absorbing agent and have a diameter less than the diameter of the tube for supplying gas. 2. The absorber according to claim 1, characterized in that the ratio of the diameter of the pipes (S ₁ ) for supplying the gas to be cleaned to the diameter of the pipe (S) for supplying the gas S ₁ : S is 0.1-0.2. 3. The absorber according to claim 1, characterized in that the cylindrical body is made of corrosion-resistant steel or organic material that is resistant in dilute sulfuric acid solutions.