DE3438400A1 - Gas scrubber - Google Patents

Abstract

At the gas outlet (14) of the gas conduction channel (10) of a gas scrubber, an annular demister (16) is arranged which surrounds the gas outlet (14). Beneath the demister (16) is located the sump (18) which receives the liquid precipitating from the gas conducting channel. The gas, which exits axially from the gas conducting channel, is radially deflected by a flow baffle (25) and flows radially through the demister (16). The liquid separated by the demister likewise falls into the sump (18). <IMAGE>

Description

Gas scrubber

The invention relates to a gas scrubber with a gas duct, which contains a humidifier, one near the gas outlet of the Gas guide channel arranged liquid sump and with a flow path in the Droplet separator arranged behind the gas guide channel for removing gas Liquid droplets from the gas stream.

In gas washers, a flowing gas comes into contact with liquid brought so that the liquid in the gas flow contained solids, harmful gases and other substances to purify the gas. A significant part of the in Liquid distributed in the gas flow can be collected in a liquid sump will. The remaining liquid is separated with a droplet separator. Such droplet separators consist, for example, of packets bent in a wave-like manner Lamellae between which the gas flows. As a result, they form on the lamellae the diversion of the individual gas flows Drops under the influence sink under the force of gravity and fall into a collecting tray.

Usually a line leads from the gas outlet of the gas scrubber the separately arranged droplet separator. The droplet separation takes place, for example in several separator packages or in a horizontal container. The disadvantage is in In each case, the large space required by the separate arrangement of a droplet separator is required, as well as the corresponding expenditure on pipelines.

The invention is based on the object of a gas scrubber of the initially to create named type, which has a small footprint and space and together forms a compact unit with the droplet separator.

According to the invention, this object is achieved in that the droplet separator ring-shaped and arranged coaxially to the gas duct at its gas outlet is.

In the gas scrubber according to the invention, the droplet separator system is arranged immediately around the gas outlet. The gas must pass the ring-shaped mist eliminator flow through it radially to get into a collecting space and into the outlet pipe. Of the The droplet separator is, so to speak, structurally in the gas washer integrated, although it is not located inside the gas duct, so that the falling of larger droplets into the liquid sump through the droplet separator is not hindered. The droplet separator only absorbs that liquid and separates them, which are not in a direct way from the gas duct into the liquid sump falls into it.

In the case of a direct current washer, the droplet separator is expedient arranged between the lower end of the gas duct and the single sump. Both the gas flow and the liquid supplied by the humidifying device move down in the gas duct. Most of the liquid falls directly into the sump, while the liquid still remaining in the gas stream separated by the droplet separator and then introduced into the same sump will.

The principle of the integrated annular droplet eliminator is not limited to DC washers.

According to a variant of the invention, in a countercurrent washer, in which the gas flow is directed upwards and the liquid transport is directed downwards and in which a first sump is arranged under the gas duct is provided, that the droplet separator is arranged at the upper end of the gas duct and that under the droplet separator a surrounding the end of the gas duct second sump is located in the form of an annular trough. This is where the big ones fall Drops against the gas flow in the first sump arranged below, while the fine droplets are carried away by the gas flow. Because the gas flow the annular droplet separator arranged at the upper end of the gas duct must happen to leave the scrubber can, the droplets of the Gas separated.

According to a preferred embodiment of the invention, in that of the droplet separator enclosed space arranged a flow guide, the the axially incoming flow derives at least approximately radially. The flow guide body serves to maintain a largely turbulence-free flow in the radial Deflection of the gas flow. In this way, the flow resistance of the scrubber kept low.

For the effectiveness of a droplet eliminator, the numerous wave-shaped Having flow channels is compliance with a certain speed range important for the gas flow. Such a mist eliminator becomes ineffective, if it is flown through at too high or too low a speed.

To the droplet separator to the respective Amount of gas to be able to adapt is provided according to a preferred development of the invention, that several annular droplet eliminators are present, of which at least one can be shut off by a locking device. By adjusting the locking device different cross-sections of the separation device can be released, to maintain a certain range of flow velocities.

There is the possibility of determining the effective cross-sectional area of a to change a single droplet eliminator or in addition to a droplet eliminator, which is always effective to provide further lockable droplet separators.

The droplet separator can be made of wave-shaped radial in front view There are lamellas. Such a mist eliminator has the advantage of being small Pressure loss.

In the following, with reference to the drawings, exemplary embodiments the invention explained in more detail.

1 shows a partial side view of a direct current washer section, Fig. 2 is a section along the line II-II of Fig. 1, Fig. 3 a direct current washer with several droplet separators, some of which can be shut off Fig. 4 is a co-current scrubber with slow gas flow; and Fig. 5 is a Countercurrent washer.

The gas scrubber shown in Fig. 1 operates on the direct current principle, d. H. the tubular gas duct 10 is of the gas to be cleaned in the same Direction flows through as from the liquid coming from the humidifier 11 is sprayed into the gas duct 10. Gas and liquid flow in it Gas duct 10, which is designed as a washing tower, in the vertical direction of up down. The gas guide channel 10 is with a holding device 12 on one Support structure 13 attached hanging. It consists of a tube of essentially constant cross-section and is empty with the exception of the humidifier, i. H. otherwise it does not contain any internal fittings.

The lower outlet 14 of the gas duct 10 is located in a Chamber 15, which contains several droplet separator systems 16 and 17. The Chamber 15 is open at the lower end and it opens there into the liquid sump 18, which the absorbs liquid falling from the gas duct 10. From Chamber 15 A pipe 20 connected to the outlet 19 leads out laterally.

The droplet separator 16 is an annular lamellar droplet separator, whose lamellae 21 are on a Tnnenflansch 22, which is attached to the peripheral wall of the Swamp 18 is attached. The upright lamellae 21 are - in plan view - Curved in a wave shape and there are wave-shaped flow paths between the lamellae 23 formed (Fig. 2). The slats 21 have drainage channels 24, which in the individual Flow paths 23 protrude into it and act as a drip catcher. Collect drops in addition, behind every bend in a flow path. The slats 21 are made made of plastic or sheet metal profiles.

They have constant cross-sectional dimensions over their height. Since the Lamellae 21 are aligned radially, their outer distances are greater than theirs inner clearances. The waveform is so pronounced that the flow paths are also in near the outer periphery of the droplet separator between the lamellae undulating run, d. H. the wave crests and troughs interlock, so that none there is a straight passage for the gas.

The space enclosed by the droplet separators 16 and 17 can be of the gas can only be left through this mist eliminator. The droplet eliminator 17 closes off the upper end wall of this room. The through this mist eliminator 17 liquid separated from the gas also falls into the sump 18.

In the collecting channel 22 on which the lamellae 21 of the droplet separator 16 are a number Diving bells provided by the the liquid can fall through a bD # eriauf (siphon system) in c ### ### - pf ^, °. The droplet separator 16 is flowed through in the horizontal direction while the liquid on the lamellae 21 drops in the vertical direction.

The risk of liquid being carried away by the gas flow, is small due to the special design of the drainage channel 24.

In the space enclosed by the droplet separator 16 is located a flow guide body 25 in the form of a cone. The axis of the flow guide body 25 lies on the extension of the axis of the gas guide channel 10 and the tip points to the gas duct.

The flow guide body 25 serves to control the axially impinging gas flow redirect radially and reduce pressure build-up and turbulence.

The embodiment of Fig. 3 differs from that 2 only in that a third droplet separator 27 is additionally provided is, which is the upper end of the space containing the liquid sump 18 with the Inside the chamber 15 connects, and that the two mist eliminators 17 and 27 can be shut off by a locking device 28 and 29, respectively. The locking devices 28 and 29 consist in the illustrated embodiment of flaps that against the passage of the respective droplet separator can be folded. With big ones Gas quantities are all three mist eliminators 16, 17 and 27 in operation, while at low gas quantities, the droplet separators 17 and 27 blocked individually or together can be so that the Gas velocity through the mist eliminator 16 is sufficiently large to achieve effective droplet separation. Even the mist eliminators 17 and 27 are annular and they delimit together with the Droplet separator 16 that space into which the gas outlet 14 leads and the down through the sump 18 is completed.

In the exemplary embodiment in FIG. 4, the gas guide channel 10 slowly flows through the gas. The gas duct 10 also opens into the here circumferentially enclosed by the droplet separator 16 into it, the downward is drained to the sump 18. The droplet separator 16 has a smaller diameter than the gas guide channel 10, um.higher gas velocities in the droplet separation to reach. The space 15 surrounding the outlet of the droplet separator 16 has no direct connection to the interior of the gas duct 10, but only Via a siphon system to the sump 18. The droplets fall from the droplet separator 16 in the sump 15 arranged below.

In Fig. 5, a countercurrent gas scrubber is shown in which the gas flow introduced into the inlet 30 at the lower end of the vertical gas duct 10 will. The humidifying device 11 sprays liquid inside the gas duct 10 downwards, i.e. in the opposite direction to the gas flow. At the bottom is the sump 18 into which most of the liquid falls.

The liquid parts carried away by the gas flow are removed by the droplet separator 16, which is located above the gas outlet 14 at the upper end of the gas guide channel 10, deposited. Under the annular droplet separator 16, which is coaxial with the gas duct is arranged, there is a second sump 31 in the form of an annular trough. This sump 31 forms the lower boundary of the space 15, which is the droplet separator 16 encloses. The penetrating into the space enclosed by the droplet separator 16 The gas flow is deflected by the flow guide body 25 in the radial direction in order to to flow through the annular droplet separator 16 radially. The droplet eliminator 16 is attached directly to the upper wall 32 of the room 15.

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Claims (9)

Claims 1. Gas scrubber with a gas duct (10) which has a Contains humidification device (11), one in the vicinity of the gas outlet (14) of the Gas guide channel arranged liquid sump (18; 31) and with one in the flow path of the gas behind the gas guide channel (10) arranged droplet separator (16) for Removal of liquid droplets from the gas flow, which is not possible e i c h n e t that the droplet separator (16) is annular and coaxial to the gas duct (10) is arranged at its gas outlet (14). 2. Gas scrubber according to claim 1, characterized in that at one DC scrubber of the droplet separator (16) between the lower end of the gas duct (10) and the sump (18) is arranged. 3. Gas scrubber according to claim 1, characterized in that at one Countercurrent scrubber with gas flow upwards and liquid output downwards is directed and in which under the gas duct (10) a first sump (18) is arranged, the droplet separator (16) at the upper end of the gas duct (10) is arranged and that under the mist eliminator (16) is the end of the The second sump (31) surrounding the gas duct (10) is in the form of an annular Tub is located. 4. Gas scrubber according to one of claims 1 to 2, characterized in that that in the space enclosed by the droplet separator (16) there is a flow guide body (25) is arranged, which the axially emerging flow at least approximately radially derives. 5. Gas scrubber according to one of claims 1 to 4, characterized in that that several annular droplet eliminators (16, 17, 27) are provided, of which at least one can be blocked by a blocking device (28, 29). 6. Gas scrubber according to one of claims 1 to 5, characterized in that that the droplet separator (16,17,27) from undulating radial in front view Lamellae (21) exist. 7. Gas scrubber according to one of claims 1 to 5, characterized in that that the droplet separator (16) consists of radial lamellae which are undulating in the front view and the droplet separators (17, 27) consist of demister packs. 8. Gas scrubber according to one of claims 1 to 6, characterized in that that in the case of a gas duct (10) which has essentially no internal fittings has, the inner diameter of the droplet separator (16) is larger than that of the gas duct (10). 9. Gas washer according to one of claims 1 to 6, characterized in that that in a gas duct (10) with internal fixtures, the inner diameter of the Droplet separator (16) is smaller than that of the gas guide channel (10).