DE2131657A1 - Method and device for removing matter particles, in particular dust, from a gas - Google Patents

Description

Dipl. - Ing.Reinhold Kramer 2131 657

Patent attorney

7I / O7OI

Midland-Ross Corporation, Cleveland / USA

Method and device for removing matter particles, especially dust, from a gas.

(Claimed Priority: June 25, 1970 U.S. 49,667)

The invention relates to a method and a device for removing matter particles, in particular dust, from a gas in which a liquid, in particular water, runs through a packing into a liquid sump and that Gas is passed through the packing in countercurrent to this.

There has long been a need to remove exhaust gases To remove matter particles such as dust particles and to cool the gas. This need has in terms of the recent efforts to eliminate air pollution are of great importance attained. The known dedusting and cooling devices have two major disadvantages. First, put the familiar

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Washer and dust extractors one jet higher Speed, nozzle baffles and the like to mix the dust particles with water, which to carry the matter particles out of the gas. The one that occurs in some processes, such as in blast furnace operation Dust, has a high abrasive effect and this causes a high level of wear and tear on the parts of the dust collectors result. The other major disadvantage of known fe facilities is that they are designed for removal smallest dust particles, i.e. particles with a size below a mesh size of 325 (325 openings per 25.4- nim) are not effective. In addition, the Majority of the known methods for treating reusable exhaust gases, in which the gas is both cooled as If cleaning is also to be carried out, the dust is removed first and a separate device is used to cool the gas intended. Of course, it is more desirable to have a single device that cools both the gases as well as removing the particles from the gases, since such a device would be cheaper and more space-saving »

The object of the invention is _s © in method and apparatus provide for cooling of the gas, in which a low wear of parts is ensured by means of the abrasive material particles, and the parts, on the one for removing particles of matter from a gas, and

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Subject to wear and tear are removed. That The method and the device should in particular be suitable for removing matter particles that have a have a higher specific weight than the liquid used, namely usually water.

The method according to the invention is characterized in that the gas is passed through the packing before it is passed through can impact the sump and then guide it essentially horizontally over the surface of the liquid sump.

The inventive device for performing the method is characterized in that in one generally vertically extending housing in the upper area a liquid inlet and in the lower area a collecting space for the liquid with a liquid outlet and a liquid distributor in between, furthermore, the liquid flow can be adjusted by means of a control device in such a way that a liquid is present in the collecting space sump is maintained and that the gas containing the riaterieteilchen is supplied so that it impacts the surface of the liquid sump and after the impact horizontally over the liquid sump flows.

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The refrigerated washing arrangement according to this invention is particularly for removing iron oxide dust, mineral or Metal dust heavier than water from air or exhaust gases is suitable. With the cooling washing device according to the invention becomes both the principle of gas impingement on a liquid, especially water, and the principle of one with a pack of sprinkling provided by the storm. the The advantages achieved in this way are evident from the following description, which explains the invention. The description is based on a drawing which shows a sectional view of a gas washing device according to the invention shows.

The generally cylindrical tower or * washer 10 according to the figure has a cylindrical wall. or a cylindrical housing 11, a substantially conical collecting space 12 and an annular cover plate 13? which is located above the wall. The conical collecting area 12 has at the bottom End of an outlet roller 14. A gas inlet tube 15, which is connected to a source of a dusty gas such as the outlet of a blast furnace extends through the Cover plate 13 and runs downwards in a concentric arrangement borrowed in the v / es within the tower 10. A gas outlet pipe 17 is received through an opening 18 provided in the cover plate 13. love the lower end

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of the inlet pipe 15 there is a holding grid 19 for a pack, which extends annularly from the outer surface of the inlet pipe extends to the inner surface of the wall 11. A bed made of a pack 21 is supported on the grid 19, the substances such as Contains marble, ceramic rings or the like. Lift the inlet pipe 15 and the wall of the tower 11 are wall layers one Pack 23 is provided, the particle size of which is significantly smaller than that of the bed of the pack 21.

A water distribution tray 25 is provided for the distribution of water via the packs 21 and 23. The bowl 25 ″ has a bottom with a perforated surface and is equipped with a plurality of stirrers 27 which allow the gases to flow through the bowl. A grid 29 is provided to hold the bowl 25. The diameter of the bowl is preferably somewhat smaller than the diameter of the wall 11. Through one or more variable water inlet tubes 3I ₁ ä. ± e located in the upper part of the tower 10, pure water is introduced into the bowl.

The collecting space 12 is equipped with a bottom exhaust pipe 33, the size of which is selected in comparison to the water inlet so that that only the smaller part of the water that can be introduced through the pipes 31 is to be drawn off if the bottom drainage pipe is connected to a Water border H is applied. The collecting space 12 also has an overflow outlet pipe 35 »in order to

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wished to maintain water level 37. The overflow flue pipe 35 is dimensioned in such a way that it draws off most of the water introduced through the pipes 31. The overflow flue pipe 35 can, as shown in the drawing, be U-shaped in order to act as a gas seal at the same time to act.

In the drawing, the general flow of the gas is shown by flow lines with a large arrowhead and the general Flow of water indicated by flow lines with a smaller arrowhead.

The scrubber 10 operates in the following manner to remove the dust from the gases. Primary cleaning takes place directly in the ifeastr of the Bsuamel room through direct impact of the dust contained in the gases emerging from the pipe 15 on the water sump. When the gases enter the water touch, the dust particles get wet and removed from the gas. The impact speed from the tube 15 exposed / Emerging gases should preferably be above 40 m / s% so that a high degree of movement occurs and complete mixing of gas and water. It has been found that using this high gas velocity, the prospects that the particles come into contact with the water and are thereby removed instead of being with the gas flow

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be taken along, be significantly enlarged. After the impact, the gases flow horizontally along the surface of the water sump, radially in all directions outward towards the wall 11 of the tower. During the radial outward flow, the gases lose speed and the dust particles, which have not been removed by the impact on the water sump, fall from the gases into the water sump due to their gravity. The cooling of the gases takes place in the packing 21, where water and gases flow in opposite directions to one another. The wall layer of the packing 23 should preferably be made of a particle size that is no larger than half the particle size of the bed of the packing 21, so that the gases are prevented from being drawn off the walls, as is the case with packs that only a single uniform particle size or «tJm1 \; en.

It has been shown experimentally that when gases containing iron oxide dust are scrubbed, in fact all of the Dust is excreted in the water sump, which is drained via the exhaust pipe 33 and that the water, which runs through the overflow discharge pipe 35, essentially is clean. The overflow drain pipe 35 is preferably in attached near the wall 11 of the tower, so that the dust particles falling into the water sump settle in the sump before they reach the overflow outlet pipe. With the unit shown in the drawing, almost 90% of the

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Water can be removed through the overflow drain pipe 35. There the water is relatively clean, it can be cooled and recycled. The water coming out of the outlet pipe 14 is heavily laden with dust particles and can be directed to an enrichment apparatus so that, if desired, the particles can be removed.

10 claims
1 figure

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Claims (10)

Expectations .} A method for removing matter particles, in particular dust, from a gas, in which a liquid, in particular water, runs through a packing into a liquid sump and the gas is passed through the packing in countercurrent thereto, characterized in that the gas is forwarded the passage through the packing allows it to hit the sump and then guide it essentially horizontally over the surface of the liquid sump. 2. The method according to claim 1, characterized in that the liquid flow downwards is directed and the water is distributed as it flows down that at least part of the liquid in one Collection space for the liquid is collected to a liquid sump and that the gas from above against the Liquid sump passed and after the horizontal outflow over the surface of the liquid sump is passed through the trickling water at the top. 109853/1759 3. Procedure according to. Claim 1 or 2, characterized that the impact velocity on the surface of the liquid sump at least 40 m / s. 4. The method according to any one of claims 1 to 3 »characterized in that the gas is approximately in the center of the liquid sump and most of the liquid that has accumulated in the liquid sump is removed at the circumference. 5 «Device for carrying out the method according to one of the Claims 1 to 4, characterized in that that in a generally perpendicularly extending housing (11, 12) in the upper area there is a liquid inlet (31) and in the lower area a collecting space (12) for the liquid with a liquid outlet (14) and a liquid distributor (25) between them, furthermore The liquid flow can be adjusted by means of a sail device in such a way that a liquid sump is maintained in the collecting space (12) and that the matter particles are removed containing gas is supplied so that it impinges on the surface of the liquid sump and after Impact flows horizontally over the liquid sump. 109853/1759 6. Apparatus according to claim 5 »characterized that the supply line (15) for the gas is essentially perpendicular within the Housing runs and ends immediately above the liquid sump, 7. Apparatus according to claim 5 or 6, characterized in that within the housing a holding device (19) for a pack (21) extending from the gas inlet (15) to the housing wall, 23) it is provided that on the holding device the Substance of the packing is stored and a liquid distributor is located between the liquid inlet (31) and the packing (21, 23) (25) is provided, above which the gas outlet (17) is located. 8. Device according to one of claims 5 to 7 »characterized in that in upper area of the liquid sump adjacent to Periphery of the housing an overflow device (35) for the liquid is located. 9. Device according to one of claims 5 to 8, characterized in that the Housing is closed by an annular cover plate (13) and the liquid sump in the lower 109853/1759 Area of the housing is located that at least one liquid pipe (Jl) received from the upper part of the housing that the gas pipe (15) from the opening of the cover plate (15) is recorded and this immediately above of the liquid sump ends and that the holding device for the pack consists of a grid (19), that between the packing and the liquid pipe a shell with a large number of openings is provided ^ and above this shell the gas outlet pipe (17) is received by the housing. 10. Device according to one of claims 5 to 9 »characterized in that the adjacent to the periphery of the housing arranged particles of the packing (23) smaller than the Eest of the particles the rest of the pack (21). 109853/1 759