DE19753227A1 - Absorber tower for power station sulfur washers and refuse incinerators - Google Patents

Abstract

An absorber tower has a housing around the washing chamber (2), a sump (3) containing washing fluid, a side gas-inlet (7) immediately over the sump, and a gas exhaustion pipe. The washer chamber (2) has a number of inward-sloping side-baffles (16a, 16b). Washing fluid is pumped from the sump and released over the baffles (16a, 16b) to form curtains (10) which hang in the path of the inflowing gas. One or more jets (9) can be located in positions where they form a fountain directly exposed to the flow of gas.

Description

The invention relates to an absorber tower Wet scrubber, especially for cleaning, in particular Desulphurization of flue gases e.g. B. in coal-fired power plants and Waste incineration plants are used.

A known generic absorber tower is described in KJ Thomé-Kozmiensky: Thermal waste treatment, EE publishing house for energy and environmental technology, Berlin 1994. It has several washing levels, each of which comprises a group of downwardly directed nozzles which spray washing liquid downward, usually a suspension of limestone (CaCO ₃ ) in water, which, together with the sulfur dioxide (SO ₂ ) in the flue gas, forms sulfite (CaSO ₃ ) reacts, which is oxidized to gypsum (CaSO ₄ ) by passing air into the sump and filtered out.

The lowest washing level is slightly above the gas inlet arranged. It is known to design the washing levels in such a way that the nozzles are directed partly downwards, partly upwards are and each widening cone-shaped Form water curtains. At the level of the gas inlet however in known generic absorber towers just one of the higher levels originating, partly due to the reaction of the limestone consumed with the sulfur dioxide of the flue gas Drop mist present, which is not very effective unfolded.

The invention is based, known to improve generic absorber towers by the on the area of the gas inlet for the Flue gas cleaning is better used. This task will solved by the features in the characterizing part of claim 1.  

When examining the sulfur dioxide absorption as Function of the height of the absorber tower was found to be despite the already somewhat weakened effect of the wash liquid originating at higher levels substantial, often even predominant part of the absorption already takes place at the level of the gas inlet.

According to the invention, means are used by which the Current held in this area longer and the Surface of the washing liquid is enlarged there. The Length of stay of the flue gas is extended and over the Cross-section equalized transversely to the flow direction.

The advantages achieved by the invention are above all in that a height section that consists of constructive Reasons is required for flue gas cleaning is used as effectively as possible. This makes it possible to Increase degree of separation or at a certain required degree of separation the height compared to known to reduce generic absorber towers and to achieve significant savings.

In the following the invention with reference to drawings, which are only exemplary embodiments schematically represent, explained in more detail. Show it

Fig. 1 the bottom part of an absorber tower according to the invention according to a first embodiment of the invention,

Fig. 2 shows the lower part of an absorber tower according to a second embodiment of the invention,

Fig. 3 the lower part of an absorber tower according to the invention according to a third embodiment of the invention,

Fig. 4 shows the bottom part of an absorber tower according to the invention according to a fourth embodiment of the invention,

Fig. 5 shows the bottom part of an absorber tower according to the invention according to a fifth embodiment of the invention,

Fig. 6 the bottom part of an absorber tower according to the invention according to a sixth embodiment of the invention,

Fig. 7 shows the lower part of an absorber tower according to the invention according to a seventh embodiment of the invention,

Fig. 8 the bottom part of an absorber tower according to the invention according to an eighth embodiment of the invention,

Fig. 9 shows the bottom part of an absorber tower according to the invention according to a ninth embodiment of the invention,

Fig. 10 shows the lower part of an absorber tower according to the invention according to a tenth embodiment of the invention,

Fig. 11 the bottom part of an absorber tower according to the invention according to an eleventh embodiment of the invention,

Fig. 12 shows the bottom part of an absorber tower according to the invention according to a twelfth embodiment of the invention,

Fig. 13 the bottom part of an absorber tower according to the invention according to a thirteenth embodiment of the invention, and

Fig. 14 the bottom part of an absorber tower according to the invention according to a fourteenth embodiment of the invention.

The absorber tower according to the invention (see FIG. 1, for example) has a circumferential side wall 1 which has a washing volume 2 . B. circular or rectangular cross-section, in the lower part of the washing liquid forms a sump 3 , from which it is continuously withdrawn and a washing level 4 - usually several are arranged one above the other - is supplied, where it is sprayed via nozzles 5 down or up . The nozzles 5 are preferably designed and arranged in a known manner in such a way that they form upwardly and downwardly overlapping cone-shaped water curtains that extend over the entire cross section of the washing volume 2 . The flue gas to be cleaned is fed via a feed line 6 which leads to a gas inlet 7 not far above the sump 3 . At the upper end of the absorber tower is the gas outlet for the cleaned gas. A droplet separator is usually placed in front of it. The sump 3 is aerated from below, so that the sulfite in the washing liquid, which comes from the reaction of the limestone of the washing liquid with the sulfur dioxide of the flue gas, is converted into gypsum. The gypsum is filtered out in a cleaning circuit and limestone is added so that the limestone concentration is always sufficient for the required sulfur dioxide absorption.

According to the first embodiment ( FIG. 1), a pipe 8 opens out somewhat upstream of the gas inlet 7 - there may also be several - into the feed line 6 , with a downwardly directed nozzle 9 , through which washing liquid is introduced into the upper part of the feed line 6 . The nozzle 9 can be designed as a slot nozzle and produce a curtain-like flow structure from washing liquid or also have a rather round cross section, so that it produces a fountain-like structure 10 of this type . It can be slightly inclined in the direction of flow, so that the structure 10 spreads parallel to the direction of flow in the gas stream. This effect can also be achieved or enhanced by introducing the washing liquid at a relatively low pressure. In any case, the introduced washing liquid is carried along by the gas stream and spreads in it. Already at the level of the gas inlet 7 , it is well distributed in the gas flow and remains in close contact with it for a relatively long time. It mixes particularly strongly in the upper part of the gas stream, which has the tendency to bend upwards immediately behind the gas inlet 7 and to flow along the side wall 1 in a relatively direct way upwards. Due to the early and particularly close mixing with washing liquid, the otherwise often insufficient cleaning of this gas portion, the length of which is particularly short in the washing volume 2 , is significantly improved. In addition, the tendency mentioned is weakened by the action of structure 10 on the flue gas flow.

In the absorber tower according to the second embodiment ( FIG. 2), two or more pipes 8 with nozzles 9 are provided, which in this case do not open into the feed line 6 , but rather just behind the gas inlet 7 into the washing volume 2 . The effect is similar to that of the absorber tower according to the first embodiment. Here, too, curtain-like or fountain-like structures 10 of washing liquid form at the level of the gas inlet 7 , in particular in the vicinity thereof, which mix closely with the gas flow. Here, too, the mixing in the vicinity of the gas inlet is particularly strong and has a particularly favorable effect on the cleaning of the upper layers of the gas stream emerging from the gas inlet 7 . This effect is improved by a canopy 11 mounted above the gas inlet, which prevents the uppermost layer of the gas flow from being bent directly upwards while avoiding the structures 10 .

The basic structure of the absorber tower according to the third embodiment ( FIG. 3) corresponds to that of the first embodiment. Essentially the same effects are achieved. However, with some distance in front of the nozzle 9 as a z. B. triangular, inclined plate trained baffle 12 , which meets the wash liquid jet emerging from it. It is thereby deflected and, even if it is a strong jet with a high exit velocity, dissolves into a structure 10 which is designed as a liquid curtain passing over the edges of the plate. It is directed essentially parallel to the gas flow, so that it is carried along by it and is distributed in it. The structure 10 has a large contact area due to the formation as a liquid curtain, which increases its influence on the gas flow.

The absorber tower according to the fourth embodiment ( FIG. 4) is constructed in a very similar manner. The only difference is that again a canopy 11 is attached above the gas inlet 7 and the tube 8 is passed through the same, so that the downward-directed nozzle 9 is just below the canopy 11 .

Again, the absorber tower according to the fifth embodiment ( FIG. 5) is constructed similarly, according to which the baffle plate 12 is attached directly above the gas inlet 7 and thus also acts as a canopy. The nozzle 9 is immediately above the same and is directed towards its top. Of course, several nozzles can also be provided. The resulting curtain-like structure 10 is drawn into and distributed by the suction of the gas stream penetrating from the gas inlet 7 into the washing volume 2 . A bending of the gas flow upwards immediately behind the gas inlet 7 is suppressed particularly effectively.

The absorber tower corresponds according to the sixth embodiment (Fig. 6) in its basic structure of the second embodiment, with the difference that here below the nozzles 9 in turn each z. B. triangular, inclined baffles 12 are attached.

Similar to the embodiment described above, the absorber tower is constructed in accordance with the seventh embodiment ( FIG. 7). The difference is on the one hand that the nozzles 9 are not compressed in the vicinity of the gas inlet 7 , but are distributed more evenly over the cross section of the volume 2 , on the other hand the plate-shaped impact bodies 12 are preferably circular and horizontally attached. They are hit in the middle by the liquid jets that appear perpendicularly on their upper sides, which are thereby broken down into approximately disk-shaped curtain-like structures 10 . The structures 10 preferably extend essentially over the entire cross-section of the washing volume 2 , so that the gas stream must pass through them and thereby mix closely with them.

In the case of the otherwise similarly constructed absorber tower according to the eighth embodiment ( FIG. 8), the nozzles 9 are directed upwards and the baffle bodies 12, which are preferably circular plates, are attached approximately at half the height of the gas inlet 7 or higher. They are again hit in the middle by the liquid jets hitting their undersides, so that again approximately disc-shaped structures 10 are formed which, of course, are partially dissolved and carried away by the gas stream passing through them. The washing liquid is pumped directly from the sump 3 into the pipes 8 . Since the liquid does not have to be pumped to a higher level, the design has the advantage of lower energy consumption.

In the absorber tower according to the ninth embodiment ( FIG. 9), cones placed upside down instead of plates are provided as impact bodies 12 , each of which dissolves the liquid jet directed against its tip into a structure 10 which corresponds to a conical shell that diverges upwards. The structures 10 can again extend over the entire cross section of the washing volume 2 .

In the tenth embodiment ( FIG. 10), a horizontal perforated plate 13 extending over the entire cross section of the washing volume 2 and having holes 14 which are evenly or unevenly distributed and whose diameter is preferably between 20 cm and 80 cm is installed above the gas inlet 7 . By means of a pump device 15 , washing liquid is constantly pumped up out of the sump 3 and passed onto the top of the perforated plate 13 , so that it flows down again over the edges of the holes 14 , forming cylindrical curtain-like structures 10 . Again, the perforated plate 13 forms, together with the structures 10, an obstacle which extends across the entire cross section transversely to the gas flow and which must penetrate it, and then intimately mixes with the washing liquid.

A similar basic idea is assumed in the eleventh embodiment ( FIG. 11). Here are two guide plates 16 a, b - there can of course also be more - which each protrude from the side wall 1 to slightly above the center of the washing volume 2 , where they overlap one another with a height offset. By means of a pump device 15 , washing liquid is pumped from the sump 3 onto the upper guide plate 16 a, over the edge of which it then flows off to form a curtain-like structure 10 onto the lower guide plate 16 b, over the edge of which it then in turn forms a curtain-like structure 10 in the swamp 3 falls behind. The lower guide plate 16 b starts immediately above the gas inlet 7 and forms a type of extended canopy. Immediately behind the gas inlet 7 , but otherwise similar to the first embodiment, a pipe 8 with a nozzle 9 is passed through it, through which additional washing liquid is introduced into the gas stream, which forms a fountain-like structure 10 which is carried along by the gas stream and distributed in the same. The guide plates 16 a, b and the structures 10 produced by them form here a double obstacle, each of which extends across the entire cross-section transversely to the gas flow, through which the same must pass twice. A particularly intimate mixture of flue gas and washing liquid is thereby achieved. This effect can be further enhanced by additional guide plates. On the other hand, only a single guide plate arranged above the gas inlet can also be provided. In any case, the first of the said obstacles is already at the level of the gas inlet 7.

In the absorber tower according to the twelfth embodiment ( FIG. 12), a centrally arranged tube 8 is provided with an upwardly directed nozzle 9 which is only slightly above the sump 3 . A ring plate 17 is attached further up, the outer edge of which abuts the side wall 1 all around and above the gas inlet 7 and which has a lower-lying central opening 18 which lies just above the nozzle 9 . It is designed in this way and the pressure of the liquid jet emerging from it is set such that the structure 10 formed by it represents a fountain which just fills the opening 18 . It is supplemented by a liquid curtain which is formed by the washing liquid which is collected by the ring plate 17 and flows over the edge of the opening 18 . The ring plate 17 , together with the structure 10, in turn extends over the entire cross section of the washing volume 2 , so that the gas flow must again pass through the structure 10 , whereby it mixes intimately with it.

The absorber tower according to the thirteenth embodiment ( FIG. 13) corresponds fundamentally to that according to the twelfth embodiment, with the difference that here a fountain-like structure 10 by an agitator attached below the surface of the washing liquid in the middle of the sump 3 , one by an approximately horizontal one Axis rotatable screw 19 is thrown directly from the same, similar to a propeller. In addition, waves can be generated on the surface of the sump 3 . Contrary to the illustration in FIG. 13, the screw 19 may also be rotatable about a vertical axis.

In the absorber tower according to the fourteenth embodiment ( FIG. 14), below the surface of the washing liquid in the sump 3 there is also a screw 19 which can be rotated by a suitable drive about an approximately horizontal axis. It creates a strong flow in the sump 3 , which is preferably directed towards the inlet-side part of the side wall 1 . The flow there leads to the formation of an ascending curtain-like structure 10 , which pushes itself at least in front of most of the gas inlet 7 , so that inevitably a strong mixing of the latter with washing liquid occurs. This effect is supported by a canopy 11 directly above the gas inlet 7 . Waves also form in the remaining part of the surface of the sump 3 . T. open high and thus form structures 10 which, for. T. are curtain-like and in any case essentially show surfaces directed transversely to the gas flow. It is of course also possible to place the emphasis on this wave formation and z. B. by intermittent drive of the screw 19 to produce a reciprocating flow, which especially causes a strong swell in the swamp 3 .

There are numerous modifications to those described Embodiments possible, especially by combination of the various specified means. It is always essential that in the area at the level of the gas inlet structures of washing liquid with the washing volume relatively extensive surfaces are formed. They can be created from the outset so that they can easily be carried away by the gas flow and become in distribute it well. You can also as more or less well-formed barriers oriented transversely to the gas flow be through which the gas flow must pass, so that he at least z. T. dissolves and also takes away, whereby the washing liquid is again distributed in it or from whom he is distracted, so that he can touch them strokes along and also with the Washing liquid comes into close contact. Thereby the Current in the area of the Wash volume slows down and the Cleaning effect is strengthened. Of course it is possible to combine both approaches, as z. B. at Absorber tower according to the eleventh embodiment is the case.

Claims (20)

1. Absorber tower for a wet scrubber, with, in a housing, a washing volume ( 2 ) with a sump ( 3 ) of washing liquid and a gas inlet ( 7 ) arranged immediately above it, and at its upper end a gas vent, characterized in that it Means are included which are suitable for producing structures ( 10 ) of washing liquid at the level of the gas inlet ( 7 ). 2. Absorber tower according to claim 1, characterized in that the means are designed such that the structures ( 10 ) of washing liquid produced by them are formed at least in part substantially parallel to the direction of flow of the gas to be cleaned. 3. Absorber tower according to claim 1 or 2, characterized in that the means are designed such that the structures ( 10 ) of washing liquid produced by them are oriented at least in part substantially transversely to the direction of flow of the gas to be cleaned. 4. Absorber tower according to claim 3, characterized in that the means and the structures ( 10 ) of washing liquid produced by them together extend over the entire cross section of the washing volume ( 2 ) transversely to the flow direction of the gas to be cleaned. 5. Absorber tower according to one of claims 1 to 4, characterized in that the means are at least predominantly effective in the gas inlet ( 7 ) or in the vicinity thereof. 6. absorber tower according to one of claims 1 to 5, characterized characterized that the funds are suitable curtains or to produce fountains of washing liquid. 7. Absorber tower claims 5 and 6, characterized in that the means are suitable to produce a curtain or a fountain of washing liquid immediately above the gas inlet ( 7 ) or in the upper region thereof. 8. absorber tower according to one of claims 1 to 7, characterized in that the means comprise at least one nozzle ( 9 ). 9. absorber tower according to claim 8, characterized in that at least one nozzle ( 9 ) is arranged immediately above the inlet region and directed downwards. 10. Absorber tower according to claim 8 or 9, characterized in that at least one nozzle ( 9 ) in the sump ( 3 ) or immediately above the same and is directed upwards. 11. Absorber tower according to one of claims 8 to 10, characterized in that the means comprise at least one at least one nozzle ( 9 ) opposite at the level of the gas inlet or immediately above the same baffle body ( 12 ) for distributing the beam emanating therefrom. 12. Absorber tower according to claim 11, characterized in that the impact body ( 12 ) is plate-shaped or conical. 13. absorber tower according to one of claims 1 to 12, characterized characterized in that the means at least one edge form over which to form a water curtain Washer fluid can be passed. 14. Absorber tower according to claim 13, characterized in that the means comprise a perforated plate ( 13 ) onto which washing liquid can be directed to form water curtains falling over the edges of holes ( 14 ). 15. Absorber tower according to claim 14, characterized in that the perforated plate ( 13 ) extends over the entire cross section of the washing volume ( 2 ). 16. Absorber tower according to claim 14 or 15, characterized in that the holes ( 14 ) in the perforated plate have diameters between 20 cm and 80 cm. 17. Absorber tower according to one of claims 1 to 16, characterized in that the means comprise at least one over the gas inlet ( 7 ) attached from the side in the middle protruding guide plate ( 16 b), through which washing liquid are passed to form a water curtain can, with several guide plates ( 16 a, 16 b) overlapping one another at different heights. 18. Absorber tower according to one of claims 1 to 17, characterized in that the means comprise a plate with at least one opening ( 18 ) and a device for generating a fountain which fills the at least one opening ( 18 ). 19. Absorber tower according to one of claims 1 to 18, characterized characterized in that the means at least one Mixer for generating one from the swamp ascending fountain, a liquid curtain or of waves. 20. Absorber tower according to claim 19, characterized in that the mixer is designed as a rotatable screw ( 19 ).