DE102010002768A1 - Exhaust gas i.e. flue gas, desulfurization device, for fossil-fired power plant utilized for generating electricity, has washing region for purifying exhaust gas and cooling region for cooling gas, where regions are arranged within housing - Google Patents

Abstract

The device (1) has a washing region (3) for purifying exhaust gas i.e. flue gas, and a cooling region (5) for cooling the exhaust gas, where the washing and cooling regions are arranged within a common housing (9). The washing region comprises a liquid distribution device (21) for dosage of absorption liquid. The cooling region comprises a cooling liquid distribution device (27) i.e. spraying unit. The washing region and the cooling region are separated from each other by a chimney base (11). The cooling region is integrated into the washing region.

Description

The invention relates to a device for the desulfurization of exhaust gases, comprising a washing area for cleaning the exhaust gas and a cooling area for cooling the exhaust gas.

Such devices are used in particular for the desulfurization of exhaust gases that arise in fossil-fired power plants for electricity generation. These exhaust gases or flue gases have a large number of harmful substances such as SO _x and CO ₂ . From the viewpoint of environmental protection, it is necessary to reduce the emission of these substances into the atmosphere, and thus separation from the exhaust gas is indispensable.

On an industrial scale, the separation of CO _{2 is} today practically possible only with a combined method of absorption and desorption. For this purpose, a high energy consumption and high investment costs are usually necessary. Due to the fact that power plants and the individual components for an exhaust gas cleaning are still little coordinated, the economy is in question. In this case, it should be considered, for example, that before the removal of CO ₂ from an exhaust gas, it must first be freed of other reactive substances, which requires a plurality of process steps.

In particular, it should be ensured that the flue gas is as far as possible free from SO _x before entering a CO ₂ separation device, since the absorbents used in the absorption of the CO ₂ are generally deactivated by sulfur dioxides. A reaction of SO _x with the absorbents used is usually irreversible. Accordingly, it is necessary that the flue gas is almost completely desulfurized before entering a CO ₂ trap.

For this purpose, the exhaust gas is usually purified in a desulfurization and finally treated in a CO ₂ separation device on. In order to promote the absorption process there, the flue gas purified from SO _{x is} generally cooled in a so-called flue gas cooler before it enters the separation device. The purified during the desulfurization gas is discharged at the outlet from the desulfurization usually directly via a subsequent separate cooling tower. As a result, the conditions for the absorption of CO ₂ in the absorption medium within a separator improved as the solubility of CO _{2 increases} with decreasing temperature For complete desulfurization existing flue gas desulphurisation must be extended or cascaded in series.

According to the current state of the art, the individual steps desulfurization, cooling and CO ₂ separation are successively implemented in separate, separate devices for almost complete purification of flue gases. The space requirement and the associated costs are therefore the economic efficiency of such a complex cleaning at the present time in question.

It is therefore an object of the invention to provide a device for the desulfurization of exhaust gases, which provides sufficient for the absorption of CO ₂ pre-purified gas in a small footprint and low investment costs.

This object is achieved by a device for desulfurization with the feature combination according to claim 1.

Accordingly, the device for desulfurizing exhaust gases comprises a washing area for cleaning the exhaust gas and a cooling area for cooling the exhaust gas. It is provided that the washing area and the cooling area are arranged within a common housing.

The invention thereby dissolves from the existing concept and recognizes the possibility of performing the cleaning of SO _x and the cooling of the purified exhaust gas flow within a common housing, without sacrificing cleaning. The desulfurization so far subsequent cooling of the purified of SO _x flue gas can be stored in a space-saving and within the same housing, as the process of desulfurization itself.

As a result of the combination of the two process steps within a common device, space can thus be saved, in particular in the construction of new power plants, which has an effect on the investment costs and thus has a positive effect on the economically sensible use.

The washing area serves primarily to clean the flue gas introduced into the desulphurisation device. The uncleaned flue gas is preferably rinsed in the wash area with a mixture of water and limestone, whereby the sulfur dioxide is largely absorbed by chemical reactions. The gaseous sulfur dioxide first goes into solution in the absorption liquid. The reaction of sulfur dioxide with limestone finally produces calcium sulphite and CO ₂ . In the lower part of the wash tower, in the absorber sump, it collects with calcium sulphite loaded washing suspension. By blowing in air, a gypsum suspension is formed, which can be suspended in the absorber sump by means of agitators to avoid deposits.

The flue gas cleaned of SO _x then flows inside the housing into the cooling area. Here, on the one hand, a cooling area is conceivable, which is separated from the washing area in terms of process technology and space. In this case, the two areas may be connected to each other, for example via an opening. Likewise, a combined embodiment in which the washing area and the cooling area are arranged without separation from each other within the common housing is possible. The cooling area cools the exhaust gas to such an extent that it can be introduced into a separation device for the absorption of CO ₂ , without having to be fed to a separate cooling stage in between.

In an advantageous embodiment of the invention, the washing area comprises a liquid distribution device. This liquid distribution device can be designed, for example, as a spray unit and serves, in particular, for the metering of absorption liquid. The uncleaned flue gas is sprayed by means of the liquid distribution device with absorption liquid, in particular a mixture of water and limestone. For this purpose, in particular absorption liquid is removed from the absorber sump and fed via a circulation of the liquid distribution device. The liquid distribution device distributes the liquid in countercurrent to the upwardly rising within the housing exhaust, whereby the SO _x is largely absorbed by chemical reactions. In principle, it is also possible that the absorption medium is cooled in circulation before it is fed to a liquid distribution device.

The cooling region preferably comprises a further liquid distribution device for distributing cooling liquid. This liquid distribution device can also be configured in the form of a spray unit and serves primarily to cool the already cleaned exhaust gas flow. In this case, a liquid distribution device is provided in particular in procedurally separate washing and cooling areas within a housing, which wets the already purified from SO _x exhaust gas with a cooled liquid, such as water. For example, a desulfurization can take place by means of a first liquid distribution device and the cooling of the exhaust gas by a second liquid distribution device. Alternatively, of course, it is also conceivable that the second Flüssigkeitsverteil device cooled cooling liquid, for example, from the absorber sump, sprayed and therefore serves in addition to the cooling of the absorption of SO _x .

Conveniently, the washing area and the cooling area are separated by a chimney tray. The washing area is in this case arranged in particular in the lower part of the device. Since it comes only there due to the absorption of SO _x to solid precipitates, a use of known standard equipment is possible. Depending on the design of the desulfurization device, it is furthermore possible to arrange one or more liquid distribution devices or spray units within the housing in the wash area and / or in the cooling area.

Advantageously, the cooling area is alternatively integrated in the washing area. Here, no separation of the two areas is provided. In particular, both areas are combined. In order to purify the flue gas and to cool it before it emerges, it is then in particular possible to cool the absorption liquid out of the absorber sump and to disperse it via a liquid distribution device.

In a further advantageous embodiment of the invention, a circulation is included, which is connected to at least one liquid distribution device. About the circulation liquid is pumped into the liquid distribution device and distributed from there inside the housing finely. In principle, the circulation can also be connected to a plurality of liquid distribution devices. For this purpose, for example, a branch point may be provided within the circulation, which supplies only a partial flow of the absorption liquid for cleaning the exhaust gas of a first Flüssigkeitsverteil device, whereas the remaining absorption liquid is pumped to a second Flüssigkeitsverteil means.

In particular, the cooling of the circulating liquid, that is to say the absorption liquid or circulated liquid taken from the absorber sump, also lends itself. Accordingly, the circulation advantageously comprises a cooler which serves to cool at least part of the absorption liquid. By a reduced temperature of the circulating liquid, the solubility of SO _x improved, so that the cleaning effect is improved thereby. In this case, it is in particular possible to cool the entire liquid withdrawn from the absorber sump and then to meter it, as already described above, via different liquid distribution devices or spray units within the desulphurisation device.

Furthermore, an agitator is included within the wash area. This is useful because it can be prevented by a suitably arranged agitator that formed solid on the Bottom of the wash area settles and possibly cords, for example, clogged to the pump within the circulation.

In a particularly advantageous embodiment of the invention, a pack is included within the housing. Packings are internals that can be used in absorbers or columns. They generally serve to increase the mass transfer area and the residence time of various substances. If, for example, gas flows through a packing which is wetted with absorption liquid, the structure of the packing can increase the residence time of both fluids. As a result, the heat of the gas can be transferred particularly well to the liquid.

One usually differentiates between structured and disordered packs. A structured packing usually consists of thin, corrugated metal plates or wire nets to ensure an optimal exchange between the different phases or components with minimal pressure resistance. Disordered packs or beds, in particular of fillers are used in chemical processes to increase the surface of action at the same time low flow resistance. They are used for example in columns and made of different materials depending on the purpose. Overall, the additional heat exchange surface provided by the package further enhances the separation efficiency of SO _x or cooling by the cooling fluid.

By the contact of the exhaust gas with the absorber liquid, there is the possibility that part of the absorption liquid is entrained by the exhaust gas flow. Appropriately, therefore, at least one droplet separator is included within the housing. The mist eliminator removes liquid mist from the flue gas before it is further treated. The moist air is passed through a container such as a random bed or sieve of various mesh sizes. Due to these installations, the gas is forced to change its flow direction abruptly. However, due to their higher density, the drops can not do so quickly and bounce off the fixtures. There they run down and can be drained or returned to the process. Depending on the respective configuration of the desulfurization device, only one droplet separator or a plurality of droplet separators can be provided.

In the following, embodiments of the invention will be explained with reference to a drawing. Showing:

1 a device for desulphurising flue gases with a washing area and a cooling area separated from this washing area by a chimney tray inside a housing,

2 a device having a washing area and a cooling area, wherein the cooling is arranged in the upper region of the device, and

3 a device having a washing area and a cooling area, wherein the cooling is arranged in the lower region of the device.

In 1 is a device 1 to see the desulfurization of flue gases. The device 1 has a washing area 3 for cleaning the flue gas and a cooling area 5 on. The washing area 3 has an inlet 7 for flue gas. The washing area 3 and the cooling area 5 are within a common housing 9 arranged and only by a first fireplace ground 11 procedurally separated. As a result of this separation, the two process stages have minimal influence.

The flue gas gets over the inlet 7 in the wash area 3 let in. In the lower part of the wash area 3 is the absorber sump 13 with the absorbent, a limestone solution. In the absorber sump 13 is formed by the reaction of the limestone solution with the SO _x and oxygen gypsum, which collects. To avoid deposits in the absorber sump 13 the suspension is by means of a stirrer 15 suspended. The resulting plaster is peeled off and can then be further processed. The spent in the formation of gypsum suspension is replenished continuously. The inflows and outflows required for this purpose are not explicitly shown in the figures.

The washing area 3 has a circulation 17 with a pump 19 on top of the absorbent from the bottom of the wash area 3 that is, from the absorber sump 13 to a first Flüssigkeitsverteil device 21 inflated. The liquid distribution device 21 distributes the pumped absorbent, so that this in countercurrent to the rising gas back towards the absorber sump 13 falls.

The gas, which is now cleansed of SO _x , rises from the wash area 3 further up. Here it happens a first drop separator 23 , In the mist eliminator 23 be the ones from the washroom 3 separated from the gas entrained drops and returned to the process. The gas is dehumidified accordingly.

The gas flows through an opening in the bottom of the fireplace 11 in the cooling area 5 , Within the cool area 5 The purified gas is then cooled before it is ready for further treatment from the desulfurization 1 is dismissed. In the cooling area 5 is a pack 25 introduced, through which the gas flows through. The package 25 For example, it is made of folded stainless steel. As a result, the surface and the residence time for the heat transfer between the gas and the cooling liquid are increased compared to a direct drop of the liquid. The residence time of the liquid in the package 25 is so large that the heat transfer between the gas and the liquid is particularly good.

This is above the pack 25 another, designed as a spray unit Flüssigkeitsverteil device 27 arranged. To this liquid distribution device 27 is on the floor of the fireplace water by means of another pump 29 over a second cycle 30 through a cooler 31 pumped. The liquid distribution device 27 finally distributes the cooled water inside the cooling area 5 , whereby the purified gas is cooled.

Above the liquid distribution device 27 is a second mist eliminator 33 arranged according to the first droplet 23 the liquid entrained by the gas separates and the purified gas passes through an outlet 35 omits. After leaving the gas, the gas can then be supplied to a CO ₂ separation device, where it is finally purified to the outlet to the atmosphere.

In 2 is a device 41 shown for desulfurization in the washing area 43 and the cooling area 45 combined, so they are not separated. Both process stages 43 . 45 are inside a housing 47 arranged.

It should be noted that due to the combined device an explicit separation of wash area 43 and cooling area 45 not possible. Accordingly, the handle of a wash area 43 below for the lower area within the device 41 used, whereas the concept of a cooling area 45 is used for the upper area.

As in 1 the flue gas flows through an inlet 49 in the lower area 43 into it. Also here is located in the lower part of the wash area 43 the absorber sump 51 with the absorbent, which by a stirrer 53 is suspended.

In contrast to the embodiment according to 1 the cooling of the gas in the present case is achieved in that the absorption liquid is not only available to react with SO _x available, but that it also acts as a cooling liquid. She gets out of the absorber sump 51 by means of a pump 55 over a round 57 pumped. The circulation 57 has a cooler 59 that transfers the liquid all the way to a liquid distribution facility 61 inflated. The liquid distribution device 61 Accordingly, a cooled absorption liquid is sprayed, which serves to absorb SO _x and likewise to cool the gas. Due to the low temperature of the circulating or absorption liquid, the solubility of the SO _{x is} improved at the same time.

In order to increase the effect surface with low flow resistance, is a pack 63 inside the case 47 arranged. This pack 63 consists for example of a disordered bed of packing, which provide a particularly large surface for the heat exchange between absorption and cooling liquid and exhaust gas available.

The cleaned and cooled gas is then passed through one above the liquid distribution device 61 arranged droplet separator 65 passed and leaves the desulfurizer 1 via an outlet 67 ,

3 shows how 2 a device 71 for desulfurization in the the washing area 73 and the cooling area 75 combined within a common housing 77 are arranged.

Also in this embodiment is a separation due to the combination of washing area 73 and cooling area 75 inside the case 77 not possible, so as in 2 the wash area 73 the lower and the cooling area 75 referred to the upper area.

The flue gas is via an inlet 79 the washing area 73 fed. The desulphurisation device 71 includes one within the absorber sump 81 existing agitator 83 which shows the mixing of the absorbent or the solids, which are at the bottom of the washing area 73 settle, serves.

In contrast to the previously described 1 and 2 The absorption fluid is circulated over two cycles 85 . 87 directed. For this purpose, the absorbent from the absorber sump 81 over the pump 89 and a cooler 91 within the first round 85 pumped. The liquid is sent to a first liquid distribution device 95 directed and used from there for cleaning and cooling of the exhaust gas. Below the first liquid distribution device 95 is a pack designed as a bed of packing 97 intended.

The second partial flow is via a pump 99 in the direction of a second Flüssigkeitsverteil device 101 from where it enters the desulfurization device 71 is returned. By such a configuration can be left after the first cleaning still remaining in the exhaust gas SO _x after the first liquid distribution device 95 Absorb in the absorption liquid and thus increase the cleaning performance. Furthermore, only a part of the liquid needs to be in the cooler 91 be cooled, leaving the cooler 91 compared to the cooler 59 in 2 is smaller. In this way, investment costs can be saved.

Finally, the purified exhaust leaves the device 71 after passing through a mist eliminator 103 via an outlet 105 ,

The combined arrangement of a washing and a cooling area in a housing, the separation efficiency of SO _x can be improved with simultaneous cooling of the flue gas with reduced space requirements.

Claims (10)

Contraption ( 1 . 41 . 71 ) for purifying exhaust gases, comprising a washing area ( 3 . 43 . 73 ) for cleaning the exhaust gas and a cooling area ( 5 . 45 . 75 ) for cooling the exhaust gas, wherein the washing area ( 3 . 43 . 73 ) and the cooling area ( 5 . 45 . 75 ) within a common housing ( 9 . 47 . 77 ) are arranged. Contraption ( 1 . 41 . 71 ) according to claim 1, wherein the washing area ( 3 . 43 . 73 ) a liquid distribution device ( 21 . 61 . 95 . 101 ) for metering an absorption fluid. Contraption ( 1 . 41 . 71 ) according to claim 1 or 2, wherein the cooling area ( 5 . 45 . 75 ) a liquid distributor ( 27 . 61 . 95 . 101 ) for distribution of a cooling liquid. Contraption ( 1 . 41 . 71 ) according to one of the preceding claims, wherein the washing area ( 3 . 43 . 73 ) and the cooling area ( 5 . 45 . 75 ) through a chimney tray ( 11 ) are separated from each other. Contraption ( 1 . 41 . 71 ) according to one of the preceding claims, wherein the cooling area ( 5 . 45 . 75 ) in the washing area ( 3 . 43 . 73 ) is integrated. Contraption ( 1 . 41 . 71 ) according to one of the preceding claims, wherein a circulation ( 17 . 30 . 57 . 85 . 87 ) associated with at least one liquid distribution device ( 21 . 27 . 61 . 95 . 101 ) connected is. Contraption ( 1 . 41 . 71 ) according to claim 6, wherein the circulation ( 5 . 45 . 75 ) a cooler ( 31 . 59 . 91 ) which serves to cool at least part of the absorption liquid. Contraption ( 1 . 41 . 71 ) according to one of the preceding claims, wherein within the washing area ( 3 . 43 . 73 ) an agitator ( 15 . 53 . 83 ) is included. Contraption ( 1 . 41 . 71 ) according to any one of the preceding claims, wherein a package ( 25 . 63 . 97 ) to increase the heat exchange surface within the housing ( 9 . 47 . 77 ) is included. Contraption ( 1 . 41 . 71 ) according to one of the preceding claims, wherein at least one droplet separator ( 23 . 33 . 65 . 103 ) within the housing ( 9 . 47 . 77 ) is included.

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