SU1667907A1 - Scrubber - Google Patents

Abstract

The invention relates to a technique for the wet cleaning of gases from particles suspended in them and can be used in the chemical, pharmaceutical and food industries, primarily to trap highly dispersed, poorly wettable dusts with a high flotation coefficient. The aim of the invention is to increase the degree of gas cleaning from poorly wettable highly dispersed dusts. For this, in a scrubber containing a housing, a gas inlet nozzle 3 communicated with a duct 4 made with a confuser 5, a neck 6, a diffuser 7, a neck 6 are made with a cross-sectional area equal to 1:10 - 15 of the gas inlet nozzle 3. Box 4 is made with slotted gaps 9, the axes of which are oriented at an angle α equal to 12-20 ° to the vertical axis. Bubble plates 10 are equipped with overflow devices 11 located on the side of the body and stabilizers of the foam layer 13 in the form of honeycomb lattices of vertical plates, the height of which decreases evenly from the body to the duct 4, while the angle β between the upper plane of the plate 10 is 15-30 ° The housing also has fittings 15 for removing foam, located at a distance of 1.5-2.0 heights of the overflow device. 3 ill., 1 tab.

Description

The invention relates to a technique for the wet cleaning of gases from particles suspended in them and can be used in the chemical, pharmaceutical and food industries, primarily for trapping highly dispersed, poorly wettable dusts with a high flotation coefficient.

The aim of the invention is to increase the degree of gas purification from poorly wettable highly dispersed dusts.

FIG. 1 shows the scrubber, general view, section; in fig. 2 shows section A-A in FIG. one; in fig. 3 - foam stabilizer.

The scrubber includes a housing 1, a hopper 2 for deposition of sludge, a nozzle 3 for introducing dusty gas, communicated with a duct 4 made with a confuser 5, a neck 6, a diffuser 7, an irrigator 8 located in the duct 4. The neck 6 is made with a cross-sectional area equal to 1 : 10-15 cross-sectional area of the gas inlet nozzle 3. Box 4 is made with slotted gaps 9, the axes of which are oriented at an angle a equal to 12-20 ° to the vertical axis. Bubble plates 10 with overflow devices 11 located on the side of case 1 are placed between case 1 and duct 4 and equipped with sprinklers 12. On plates 10 there are foam stabilizers 13 in the form of honeycomb lattices of vertical plates 14, the height of which evenly decreases from case 1 to the duct 4. with this, the angle / between the top plane of the stabilizers and the plane of the plates is 15-30 °, and the equivalent cell diameter of the stabilizers is 1: 10-20 of the height of the foam layer.

The housing 1 is also provided with fittings 15 for removing foam located at a distance of 1.5-2.0 heights of the overflow device 11. The fitting 16 is provided for the output of the cleaned gas in the housing.

Scrubber works as follows.

The gas containing highly dispersed, poorly wettable dust flows through the gas inlet port 3 into the rectangular duct 4, where it is irrigated with liquid entering through the irrigator 8. The passage through the confuser 5, the throat 6 and the diffuser 7, the gas-liquid flow gains high speed, resulting in intensive wetting of the surface of the particles

and coaguli. The ratio of the cross-sectional area of the neck and the duct should be 1: 10-15, since it is precisely at these ratios that the most intensive mode of wetting is provided. With respect

the throat and duct sections are less than 1:10 and the relative speeds of movement of fine dust particles and liquid droplets are insufficient and a considerable part of the particles remain unwetted. With an area ratio of more than 1:15, the hydraulic resistance of the scrubber increases dramatically and the energy consumption increases. Next, the gas-liquid stream enters the gap gaps 9 and hits the free surface of the liquid, as a result of a sudden change in the direction of flow of the particles the particles are separated from the gas and absorbed by the liquid. Slotted gaps 9 should be located at an angle

Of 12-20 ° to the vertical axis, since it is precisely this range that provides a good degree of absorption of particles by the liquid and the appearance of a wave that overwhelms the bubble plate 10.

In the event that the angle between the slit gaps and the vertical axis is less than 12 °, then a stable wave will not occur, and the liquid level on the pressure plate will either not be significant or

absent altogether, which leads to the absence of a foam layer and the passage of the finest dust fractions through a scrubber. At an angle of more than 20 °, the hydrodynamic structure of the fluid movement in the scrubber is disturbed.

in addition, the rebound of particles from the liquid mirror increases, which leads to poor cleaning.

After turning, the gas stream is bubbled through the foam layer on the plate 10. In the foam mode, the dust removal process occurs due to the turbulent transfer of dust particles from the gas to a very developed surface of the liquid. The dust particles entering the gas bubbles due to the strong rubbing of the gas with the liquid hit the walls of the liquid and are trapped by them. In order to provide the required height of the foam layer, stabilizers of foam layer 13 in the form of cellular arrays of vertical plates 14 are installed on the bubble plate. The height of the plates decreases uniformly from the body to the duct, and the angle ft between the upper plane of the stabilizers and the plate surface is 15-30 °. This makes it possible to maintain a constant height of the foam layer over the entire plane of the plates.

At an angle of 3-15 °, due to the intensive flow of foam into the overflow device and the low mobility of the foam layer, the height of the foam layer of the body is less than that of the duct, which leads to disruption of the hydrodynamics of the bubble plate and deterioration of the degree of gas cleaning near the duct. At an angle of 30 °, on the contrary, the height of the foam layer at the body is greater than that of the duct, which also impairs the operation of the scrubber.

The vertical plates of the foam layer stabilizer may be made inclined towards the box, with the inclination angle to the vertical axis being 15-20 °. The equivalent cell diameter of stabilizers is 1: 10-20 of the height of the foam layer, which provides a fine cellular foam structure, a developed surface of the liquid and provides a high degree of dust collection. With larger cell sizes, the foam layer consists of larger bubbles and dust starts to flow into the bubbles without contacting it with a film of liquid. With smaller cell sizes, the free cross-sectional area of the plate is reduced and the hydraulic resistance of the scrubber increases.

After passing through the foam layer, the purified gas is discharged from the scrubber through fitting 16.

The foam containing the trapped dust particles enters the overflow device where it is irrigated with liquid from the sprinklers 12. Irrigation contributes to a more rapid quenching of the foam and the deposition of dust in the bunker

2. from which dust together with the liquid is discharged from the scrubber.

The finely dispersed, poorly wetted dust, which has a high flotation rate, accumulates on the surface of the foam layer to form a dense layer and does not flow well into the overflow device, since in this case the underlying layers of foam enter. This leads to

as the dust accumulates on the surface of the foam layer, its removal from the scrubber begins. To avoid this, the body is equipped with fittings 15 for removal of the top layer of foam saturated with dust particles, the Fitting

are located at a distance of 2-2.0 from the height of the overflow device above the level of the bubble plate. This allows you to directly remove only the top layer of foam, without capturing the underlying layers,

which are less saturated with dust and enter the overflow device. Indirectly, this also allows you to adjust the height of the foam layer on the plate and exclude it from exceeding more than 0 the height of the overflow device, which is a violation of the normal operation of the scrubber. In laboratory conditions, scrubber was used to purify air containing sebacic dust.

acid, when the concentration of dust at the entrance to

scrubber 160 mg / m, air temperature at

scrubber inlet 160 ° C. average diameter

particles of sebacic acid dust 18 microns.

The table shows the dependence of the efficiency of air purification on the ratio of the areas of the cross section of the neck and the gas inlet nozzle on the angle of inclination of the axes of the gap gaps to the vertical axis, on the angle of inclination / 3 between the top plane of the stabilizer

and the plate surface, from the nozzle to the plate.

Claims (1)

Claims of invention Scrubber including body, silo for sludge sedimentation, sprinklers, branch pipe the introduction of dusty gas, communicated with a duct made with a confuser, neck, diffuser, bubbling plates, characterized in that, in order to increase the degree of gas purification from bad wettable highly dispersed dusts, the neck is made with a cross-sectional area equal to 1: 10-15 of the cross-sectional area of the gas inlet, the box is made in the lower part with slit gaps, the axes of which are oriented at an angle of 12-20 to the vertical axis; located on the hull side, and foam foam stabilizers in the form of cellular arrays i of s GGMK plates, the height of which is equal to 1 Y ir diminishes from the body to the duct the angle between the top plane  - 1p aps and a plate surface is 15-30 °, and the housing is equipped with fittings for foam removal, located at a distance of 1.5-2.0 heights of the overflow device | I I, g (| f {I g: m iif1, and I & chRCHTs i-i n 1 0) g InI tj t f 3 i 10 1 IS 1 5 b 1 fn f 1f h tm A - A (lobernu / lo) L FIG. 2 / 15 15