WO2014191160A1 - Separating device for separating carbon dioxide out of a gas stream, and process for separating carbon dioxide out of a gas stream - Google Patents

Abstract

The invention relates to a separating device (1) for carbon dioxide out of a gas stream, especially out of a flue gas stream, comprising an absorber (3) for separating carbon dioxide out of the gas stream by means of a scrubbing medium (9), and a desorber (5), coupled for flow purposes to the absorber (3) via a recycle line (27), for releasing carbon dioxide absorbed in the scrubbing medium (9), wherein a treatment device (25) which is connected for flow purposes to the desorber (5) is set up and designed to remove nitrosamines present in the scrubbing medium (9). The invention further relates to a process for separating carbon dioxide out of a gas stream, especially out of a flue gas stream.

Description

description

Separation device for carbon dioxide from a gas stream, and method for the separation of carbon dioxide from a gas Ström

The invention relates to a separator for carbon dioxide from a gas stream, in particular from a flue gas stream. Furthermore, the invention relates to a method for the separation of carbon dioxide from a gas stream, in particular from a flue gas stream.

Against the background of climatic changes, it is a global goal to reduce the emission of pollutants into the atmo- sphere. This applies in particular to the emission of carbon dioxide (C0 ₂ ), which accumulates in the atmosphere, hindering the heat radiation of the earth and thus as a greenhouse effect leads to an increase in the Earth's surface temperature.

Particularly in fossil-fired power plants for the production of electrical energy, the combustion of a fossil fuel produces a carbon dioxide-containing flue gas. In order to avoid or reduce carbon dioxide emissions into the atmosphere, the carbon dioxide must be separated from the flue gas. Correspondingly, suitable measures are being discussed especially for existing fossil-fueled power plants in order to separate the resulting carbon dioxide from the exhaust gas after combustion (post-combustion capture process).

As a technical realization, the flue gas is brought into contact with a suitable washing medium after combustion, whereby gaseous carbon dioxide contained in the flue gas is dissolved in the washing medium or absorbed in the chemical sense. The exhaust gas freed of carbon dioxide is finally released into the atmosphere. The carbon dioxide-loaded washing medium can be obtained by desorption of the absorbent regenerated carbon dioxide and used again for the absorption of carbon dioxide from the flue gas. Common chemical washing media are based on amines, which react selectively but reversibly with the carbon dioxide contained in the intoxicating gas and thus remove it from the flue gas.

However, a problem in the separation of C0 ₂ from a flue gas in the post-combustion capture process is caused by the acidic components in the flue gas, in addition to carbon dioxide, such as sulfur oxides (S0 _X ) and nitrogen oxides (N0 _X ), via the flue gas be entered in the C0 ₂ -Aschescheideprozess. In this case, for example, by the reaction of the amines from the washing medium with the nitrogen oxides from the flue gas directly, by decomposition products or Nebenreaktio- nen nitrosamines (N-nitroso compounds), which are suspected of being carcinogenic. Since the nitrosamines formed have a low vapor pressure, they are discharged via the purified flue gas into the atmosphere. A minimization of the nitrosamine concentration or, ideally, a complete removal of the nitrosamines in a washing medium used in the CO ₂ deposition is therefore absolutely necessary.

For this purpose, for example, desulfurization units for removing S0 _X and so-called DeNO _x plants can be used to remove N0 _X , which remove the pollutants from the flue gas before entering the separation device. However, even with the use of such devices, the whereabouts of a residual proportion, in particular of nitrogen oxides, in the flue gas can not be ruled out. These are then fed together with the flue gas of C0 ₂ -Abscheidevorrichtung and form there with the wash medium noxious gases and degradation products, in particular the above-described nitrosamines.

One way to remove nitrosamines formed in the wash medium is in the amine wash. Conventional amine washes provide for an evaporator, in which the amine evaporated and the interfering impurities, ie degradation products and so-called "heat-stable salts (HSS)" can be separated as evaporation residue. When using amino acid salts as the active washing substance of the washing medium, however, evaporation for purification is not possible because amino acid salts show no appreciable vapor pressure.

Here, alternatively, a method can be used in which the pure amino acid can be recovered by crystallization. In this method, the nitrosamine is the determining factor for the interpretation of the crystallization process and associated with a correspondingly high cost.

Alternatively, a method can be used which makes use of the low thermal stability of nitrosamines. In such a process, after the absorption of carbon dioxide, the washing medium is taken from an absorber of a separator and fed to a nitrosamine reduction process. The nitrosamines are decomposed at temperatures above 200 ° C, so that the nitrosamine content in the washing medium can be regulated and significantly reduced.

However, the high temperatures in the destruction of the nitrosamines also lead to a loss of the washing medium itself, as this reacts irreversibly at high temperatures and with a corresponding C0 ₂ -Beladung by so-called carbamate polymerization, ie degraded. Thus, such methods are also limited.

It is therefore a first object of the invention to provide a carbon dioxide separation device which, while retaining the capacity of the washing medium, enables effective separation of nitrosamines contained in the washing medium. A second object of the invention is to specify a method for the deposition of carbon dioxide which allows the purification of a nitroso-contaminated washing medium.

The first object of the invention is achieved by a separator for carbon dioxide from a gas stream, in particular from a flue gas stream, comprising an absorber for separating carbon dioxide from the gas stream by means of a washing medium, and a via a return line fluidly coupled to the absorber desorber for releasing Carbon dioxide absorbed in the washing medium, the desorber being fluidly connected to a treatment device which is set up and designed to remove nitrosamines contained in the washing medium.

The invention is based on the fact that nitrosamines must necessarily be removed from a washing medium due to their harmful effects in order to prevent discharge into the atmosphere. However, the methods used to date for this purpose are only conditionally suitable for removing the nitrosamines in order to obtain the washing medium or while ensuring the concentration of the active components in a washing medium. In particular, in the thermal decomposition of nitrosamines, by which they can be removed very effectively from a washing medium, the temperature-induced degradation and thus the loss of the washing medium proves to be problematic.

Taking into account the above, the invention recognizes that, despite the above-described problem with respect to the degradation of the washing medium on the removal of nitrosamines can be accessed by thermal decomposition, if the washing medium to be purified from nitrosamines not removed at the absorber, but instead at the desorber and thermal accordingly is treated. For this purpose, the desorber is a treatment device fluidically connected, which is set up and designed to remove contained in the washing medium nitrosamines.

The scrubbing medium to be cleaned is hereby removed at one point of the separating device, namely at the outlet of the desorber, and fed to the processing device. At this point, the CO ₂ loading of the washing medium, which promotes undesired degradation and in particular the carbamate polymerization of the washing medium, is particularly low. Thus, removal from the desorber can effectively remove nitrosamines from the wash medium without degrading the active component of the wash medium due to excessive CO ₂ loading. In this way, on the one hand, the amount to be used

Washing medium for maintaining the concentration of the active component in the deposition process compared to common cleanup possibilities significantly reduced and thus reduces the operating costs of the separation device. At the same time, the temperature at the outlet of the desorber is higher than at an absorber outlet, so that less heating of the washing medium requires less energy than is the case when the washing medium is removed from the absorber. This lower energy requirement also has a positive effect on the operating costs.

The treatment device thus fulfills the requirements for effective separation of nitrosamines contained in the washing medium and at the same time makes it possible to maintain the concentration of the active washing component in the washing medium.

For this purpose, the treatment device may additionally comprise, in particular, those device components which serve to further reduce the CO ₂ loading of the detergent. Thus, the thermal degradation due to carbamate polymerization can be significantly reduced and at the same time a destruction of the nitrosamines in the washing medium can be implemented. In order to supply the washing medium from the desorber to the treatment device, the return line of the desorber advantageously comprises a branch line, which is fluidically coupled to a supply line of the treatment device. Thus, the largely freed from carbon dioxide washing medium can be removed from the desorber via the return line and fed via the branch line of the treatment device. In principle, the washing medium can also be fed into the treatment device via a line which is connected to the outlet of the desorber and which is not fluidically coupled to the return line of the desorber. To purify the washing medium by a thermal

Decomposition of the nitrosamines contained in the washing medium, it is particularly advantageous if the treatment device comprises a flash vessel, which is set to remove a carbon dioxide contained in the washing medium. A flash tank is an evaporator that uses the

Principle of flash evaporation uses. In this case, steam is produced by a pressure difference between a liquid flowing into a flash container and the pressure prevailing in the flash container itself.

In a flash tank used in the processing apparatus, the washing medium taken from the return line of the desorber is introduced into the flash tank at atmospheric pressure. Here it comes with the flash evaporation overheating of the washing medium. A residual amount of carbon dioxide dissolved in the desorber in the desorber still disappears in the scrubbing medium and can thus be removed from the scrubbing medium. The flash container is thus used for degassing of the washing medium prior to the thermal decomposition of the nitrosamines. Thus, the C0 ₂ loading of the washing medium before the thermal destruction of the nitrosamines can be further reduced. The degradation of the washing medium as a result of carbamate polymerization is thus significantly reduced. Expediently, the carbon dioxide separated off from the washing medium in the flash container is fed via a discharge line connected to the flash container to a utilization device which serves for processing and transferring the carbon dioxide into further products. For example, the carbon dioxide can be compressed to allow for transport to a storage location where it can be finally stored.

Preferably, the flash tank is preceded by a preheater fluidly, so that the washing medium has the desired temperature for the flash evaporation on entering the flash tank. Due to the already increased temperature of the washing medium after removal from the desorber in this case only a small preheating is necessary in particular, so that the preheater can be made small. In a particularly advantageous embodiment of the invention, the flash container is followed by a reaction chamber for the decomposition of nitrosamines contained in the washing medium downstream of the fluid. The reaction chamber is in this case designed, in particular, as a tubular reactor, it being understood that the use of other reaction vessels is also possible. During the process, the washing medium flowing out of the flash container and largely freed of carbon dioxide flows into the reaction chamber. Within the reaction chamber is the

Washed medium, so that the nitrosamines contained in the washing medium are thermally destroyed. Since unwanted carbon dioxide has already been removed in the flash vessel upstream of the reaction chamber, thermal degradation of the washing medium as a result of carbamate polymerization can be prevented.

Conveniently, the reaction chamber downstream of the cooling of the treated washing medium, a heat exchanger downstream. So the washing medium on the for the Separation process and the subsequent absorption of carbon dioxide required temperatures are cooled down.

For recycling the washing medium, the treatment device comprises a return line, which is fluidically coupled to the return line of the desorber. By means of these two flow-coupled lines, a simple recycling of the washing medium into the separation process or the separating device for carbon dioxide takes place.

Conveniently, the desorber is fluidly coupled via its return line to a supply line of the absorber. Thus, the scrubbing medium purified in the desorber of carbon dioxide can be supplied to the absorber. Within the absorber, the washing medium is then again available for the absorption of carbon dioxide and, depending on the configuration of the absorber for cooling, expediently flows through one or more cooling units. Preferably, a discharge line is connected to the desorber, which opens into a utilization device. The recycling facility serves to prepare and transfer the desorbed carbon dioxide into further products. For example, the remaining C0 ₂ -rich gas stream can be compressed in order to enable transport to a storage location where the C0 _{2 can} finally be stored.

Conveniently, an amino acid salt solution is used as the washing medium. An aqueous amino acid salt solution is useful here. In the use of an amino acid salt as the absorption medium, it has been found advantageous to use an amino acid salt having a carbon substituent selected from the group consisting of hydrogen, an alkyl, a hydroxyalkyl and an aminoalkyl. More preferably, an amino acid salt is used which has a nitrogen substituent from the group which contains hydrogen, an alkyl, a hydroxyalkyl and a haloalkyl. Again, a single amino acid salt such as a potassium salt of glycine or other amino acids may be used. Also, mixtures of different amino acid salts can be used as the absorbent. More preferably, the amino acid salt is a salt of a metal, especially an alkali metal.

The desorber is preferably connected to a reboiler. As a so-called bottom evaporator, the reboiler supplies the necessary heat of regeneration for the separation of absorbed CO ₂ from the washing medium. The loaded washing medium is in this case regenerated by steam, which is generated in the reboiler. To generate the steam within the reboiler this is usually heated with imported steam, for example from a connected steam power plant.

The second object of the invention is achieved according to the invention by a method for separating carbon dioxide from a gas stream, in particular from a flue gas stream, in which a gas stream is brought into contact with the washing medium in an absorber of a separating device while separating carbon dioxide contained in the gas stream. and the laden washing medium for releasing the carbon dioxide is fed to a desorber of the separating device, wherein the washing medium after the separation of the carbon dioxide in the desorber is supplied to a recycling device coupled to a return line of the desorber, in which nitrosamines contained in the washing medium are removed.

The method is used to purify a contaminated with nitrosamines washing medium in a deposition process for carbon dioxide. By means of such a method, the washing medium can be effectively cleaned of unwanted and interfering nitrosamines before it is returned to the absorption process while maintaining the concentration of the active washing component. The washing medium is expediently fed to the treatment device via a branch line connected to the return line of the desorber. In order to further remove carbon dioxide dissolved in the washing medium, the washing medium is fed to a flash tank in the treatment device. Here, the C0 ₂ load of the washing medium is further reduced, thus creating optimal conditions for the thermal decomposition of the nitrosamines.

Preferably, the scrubbing medium is fed to a reaction chamber for the decomposition of nitrosamines after it leaves the flash vessel. The largely freed of carbon dioxide washing medium can be purified here and finally returned to the deposition process.

In order to achieve the necessary for the absorption in the absorber temperature of the washing medium, the liberated from nitrosamines wash medium is expediently cooled after exiting the reaction chamber.

To return to the deposition process, the washing medium preferably flows via a return line of the treatment device into the return line of the desorber.

In order to return the purified washing medium to the absorption process, this is expediently returned to the absorber via a supply line coupled to the return line of the desorber.

For storage or further use, separated carbon dioxide is fed to a utilization device in the desorber. Preferably, the carbon dioxide separated in the flash container is also supplied to this utilization device, so that the utilization device can be used in common for both C0 ₂ gas streams. In order to provide the necessary regeneration heat in the desorber for the separation of absorbed C0 ₂ from the washing medium, effluent washing medium is fed to a reboiler. It is advantageous if an amino acid salt solution is used as the washing medium, the amino acid salt can react selectively but reversibly with carbon dioxide contained in the flue gas and can thus remove it from the flue gas. Further advantageous embodiments of the method for

Purification of a contaminated with nitrosamines washing medium resulting from the directed to the deposition device dependent claims. The advantages mentioned for this purpose can be correspondingly transferred to the process.

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

1 shows a separation device for carbon dioxide with a schematic treatment device for the removal of nitrosamines from a washing medium, and

2 shows a detailed representation of the treatment device according to FIG. 1

1 shows a separation device 1 for carbon dioxide from a flue gas stream. The separation device 1 comprises an absorber 3 and a desorber 5 fluidically coupled thereto.

For the separation of carbon dioxide from the flue gas of a

Combustion system, the flue gas is introduced into the C0 ₂ - separator 1. For this purpose, the flue gas is supplied to the absorber 3 via a flue gas line 7. In the absorber 3 is located as a washing medium 9, an aqueous amino acid salt solution, which is used to separate the carbon dioxide contained in the flue gas. For this purpose, the flue gas in the absorber 3 is brought into contact with the washing medium 9 and the Carbon dioxide contained in the flue gas absorbed in the washing medium 9. The cleaned of carbon dioxide gas stream is discharged from the absorber 3 at the absorber head 11. Via a discharge line 13, the absorber 3 is fluidly coupled to a feed line 15 of the desorber 5, so that the loaded with carbon dioxide washing medium 9 can be pumped via these two lines 13, 15 with temperature increase by means of a pump 17 in the desorber 5.

In this case, the loaded washing medium 9 passes through a heat exchanger 19, in which the heat of the regenerated scrubbing medium 9 flowing from the desorber 5 to the absorber 3 is transferred to the laden scrubbing medium 9 supplied to the desorber 5 by the absorber 3. The heat exchanger 19 thus uses the waste heat of the desorber 5 to preheat the washing medium 9 from the absorber 3 before entering the desorber 5.

Within the desorber 5, the carbon dioxide absorbed in the washing medium 9 is thermally desorbed. For the treatment and transfer of carbon dioxide the desorber 5 is connected to a discharge line 21, which opens into a utilization device 23. In the utilization device 23, the desorbed C0 ₂ -rich gas stream can be compressed in order, for example, to enable transport to a storage site.

To remove nitrosamines contained in the washing medium 9, the desorber 5 is connected to a treatment device 25 in terms of flow technology. The fluidic coupling in this case takes place via a return line 27 connected to the desorber 5. The return line 27 comprises a branch line 29, which in turn is fluidically coupled to a supply line 31 of the treatment device 25.

Thus, in the desorber 5 largely freed from carbon dioxide washing medium 9 removed from the desorber 5 and the Aufbe- be supplied 25 riding device. The preparation device 25 comprises a preheater 33, a flash tank 35 downstream of the preheater, and a reaction chamber 37. By means of these device components 33, 35, 37, the C0 ₂ charge of the scrubbing medium 9 supplied to the treatment device 25 can be further developed in a first step be reduced. Subsequently, nitrosamines contained in the washing medium 9 can be removed by thermal decomposition.

With regard to the detailed description of the processing device 25, reference is made at this point to the description of the subsequent FIG 2. After the removal of the nitrosamines in the treatment device 25, the washing medium 9 is returned to the separation process in the separation device 1. For this purpose, the treatment device 25 comprises a return line 39, which is fluidically coupled to the return line 27 of the desorber 5. The return line 27 of the desorber 5 in turn is fluidically coupled to a feed line 41 of the absorber 3.

The regenerated in the desorber 5 washing medium 9 is returned via the fluidic connection between the return line 27 and the feed line 41 by means of a pump 43 in the absorber 3 and is there to re-absorption of C0 ₂ from the flue gas available. To provide the necessary heat of regeneration for the separation of the carbon dioxide from the washing medium 9, the desorber 5 is connected to a reboiler 45. The loaded washing medium 9 is in this case regenerated by steam, which is generated in the reboiler 45. The reboiler 45 is heated with imported steam, for example from a connected steam power plant, which is not shown here. FIG. 2 shows a detailed illustration of the processing device 25. The treatment device 25 serves to remove nitrosamines contained in the washing medium. For this purpose, the treatment device 25, as already designated in the description of FIG. 1, comprises a flash container 35. The flash container 35 is a flash evaporator, to which the washing medium 9 withdrawn from the desorber 5 is supplied via a supply line 47. The washing medium 9 in this case passes through a filter 49 and a pump 51. In addition, the washing medium 9 is preheated before entering the flash tank 35 in the preheater 33, so that the washing medium 9 has the desired temperature for the flash evaporation. In the flash tank 35 9 is still contained in the washing medium

Carbon dioxide removed in order to reduce the C0 ₂ loading of the washing medium 9 as much as possible and so significantly reduce the degradation of the washing medium 9 due to carbamate polymerization. For this purpose, the desorber 5 removed washing medium 9 is introduced into the flash tank 35 at atmospheric pressure. In the flash evaporation, superheating of the washing medium 9 occurs here. A residual fraction of carbon dioxide dissolved in the desorber 5 during desorption in the washing medium 9 evaporates and can thus be removed from the washing medium 9. The flash container 35 is thus used to degas the washing medium 9 prior to the thermal decomposition of the nitrosamines.

The carbon dioxide separated off from the washing medium 9 in the flash container 35 is connected via a flash container 35

Outlet line 53 of the utilization device 23 is supplied, in which also the carbon dioxide-rich gas stream is discharged from the desorber 5. Here, both gas streams can be combined and compacted and transported to a storage site.

The thermal decomposition itself then takes place in the reactor chamber 37 designed as a tubular reactor Flash tank 35 flowing, largely freed from carbon dioxide washing medium 9 flows into the tube reactor 37 and is heated there. By heating, the nitrosamines contained in the washing medium 9 can be thermally destroyed. Since unwanted carbon dioxide has already been removed in the flash tank 35 upstream of the reaction chamber 37, thermal degradation of the washing medium 9 as a result of carbamate polymerization can be prevented. To cool the tube reactor 37 leaving the washing medium 9, the tube reactor 37, a heat exchanger 55 downstream of flow. Thus, the washing medium 9 can be cooled down to the temperatures required for the deposition process and the subsequent absorption of carbon dioxide in the absorber 3.

After cooling, the scrubbing medium purified by nitrosamines is returned via the return line 39 to the treatment device 25 to the deposition process in the separating device 1, where it is again available for absorbing carbon dioxide from a flue gas stream.

Claims

claims

1. Separating device (1) for carbon dioxide from a gas stream, in particular from a flue gas stream, comprising an absorber (3) for separating carbon dioxide from the gas stream by means of a washing medium (9), and via a return line (27) fluidly with the Absorber (3) coupled to desorber (5) for releasing carbon dioxide absorbed in the washing medium (9), the desorber (5) being fluidly connected to a treatment device (25) arranged to remove nitrosamines contained in the washing medium (9) and is trained.

2. Separating device (1) according to claim 1, wherein the return line (27) of the desorber (5) has a branch line

(29), which is fluidically coupled to a supply line (31) of the treatment device (25).

3. Separator (1) according to claim 1 or 2, wherein the treatment device (25) comprises a flash container (35) for removing carbon dioxide contained in the washing medium (9).

4. Separating device (1) according to claim 3, wherein the flash container (35) is preceded by a preheater (33) fluidly.

5. Separating device (1) according to claim 3 or 4, wherein the flash container (35) is a reaction chamber (37) downstream of the decomposition of nitrosamines contained in the washing medium (9) fluidly connected downstream.

6. Separating device (1) according to claim 5, wherein the reaction chamber (37) for cooling the treated washing medium (9), a heat exchanger (55) is downstream of flow.

7. Separator (1) according to one of the preceding claims, wherein the treatment device (25) comprises a return line (39), which is fluidly coupled to the return line (27) of the desorber (5).

8. Separating device (1) according to one of the preceding claims, wherein the desorber (5) via its return line (27) fluidly coupled to a feed line (41) of the absorber (3).

9. Separating device (1) according to one of the preceding claims, wherein the desorber (5) has a discharge line (21) is connected, which opens into a utilization device (23).

10. Separator (1) according to one of the preceding claims, wherein the desorber (5) is connected to a reboiler (45).

11. Separating device (1), wherein as the washing medium (9) an amino acid salt solution is used.

12. A method for the separation of carbon dioxide from a gas stream, in particular from a flue gas stream, in which

- A gas stream in an absorber (3) of a separating device (1) is brought under deposition of carbon dioxide contained in the gas stream with the washing medium (9) in contact, and

 the loaded washing medium (9) is fed to a desorber (5) of the separating device (3) for releasing the carbon dioxide,

wherein after the removal of the carbon dioxide in the desorber (5), the washing medium (9) is fed to a treatment device (25) fluidically coupled to a return line (27) of the desorber (5), in which nitrosamines contained in the washing medium (9) are removed ,

13. The method according to claim 12, wherein the washing medium (9) of the treatment device (25) via a return line (27) of the desorber (5) connected branch line (29) is supplied.

14. The method according to claim 12 or 13, wherein the washing medium (9) for removing in the washing medium (9) contained carbon dioxide in the treatment device (25) is fed to a flash tank (35).

15. The method of claim 14, wherein the washing medium (9) is preheated before entering the flash tank (35).

16. The method according to any one of claims 14 or 15, wherein the washing medium (9) for the decomposition of nitrosamines after the

Outlet from the flash tank (35) is fed to a reaction chamber (37).

17. The method of claim 16, wherein the liberated from nitrosamines washing medium (9) after exiting the reaction chamber (37) is cooled.

18. The method according to any one of claims 12 to 17, wherein the washing medium (9) via a return line (39) of the processing device (25) in the return line (27) of the desorber (5) flows.

19. The method according to any one of claims 12 to 18, wherein the washing medium (9) via a with the return line (27) of the desorber (5) coupled feed line (41) is returned to the absorber (3).

20. The method according to any one of claims 12 to 19, wherein in the desorber (5) separated carbon dioxide a recycling device (23) is supplied.

21. The method according to any one of claims 12 to 20, wherein from the desorber (5) effluent washing medium (9) is fed to a reboiler (45).

22. The method according to any one of claims 12 to 21, wherein as the washing medium (9) an amino acid salt solution is used.