EP2470759A1

EP2470759A1 - Device for cleaning exhaust gases containing nox

Info

Publication number: EP2470759A1
Application number: EP10725158A
Authority: EP
Inventors: Sebastian Hirschberg
Original assignee: Sulzer Chemtech AG
Current assignee: Sulzer Chemtech AG
Priority date: 2009-07-01
Filing date: 2010-06-11
Publication date: 2012-07-04
Also published as: CN102472142A; WO2011000685A1; US20120087840A1; CN102472142B

Abstract

The invention relates to a device (1) for cleaning an exhaust gas stream (2) containing NOx, comprising a channel (3) through which a reactant (4) containing NH₃can flow, wherein the channel (3) comprises a shell element (5), which surrounds the channel (3) and has an inlet opening (6) for feeding the reactant (4) containing NH₃and an outlet opening (7). The exhaust gas stream (2) containing the NOx can flow around the shell element (5). A distribution element (8) for distributing the reactant (4) containing the NH₃ can be connected to the shell element (5) such that, by means of the distribution element (8), the reactant (4) containing the NH₃ can be introduced into the exhaust gas stream (2) and mixed with the exhaust gas stream (2). The distribution element (8) comprises an opening (9), through which the reactant (4) containing the NH₃ can be introduced into the exhaust gas stream (2) as a gas phase, wherein the reactant (4) containing the NH₃ can be evaporated inside the shell element (5). The shell element (5) comprises a heat transmitting element (10), so that the shell element (5) can be heated by means of the exhaust gas stream (2).

Description

Device for purifying exhaust gases containing NOx

The invention relates to a device for purifying a NOx exhaust gas stream.

A DeNoX system is a system for denitrating exhaust gases, ie for the removal of nitrous gases, ie gases with the molecular formula NOx. In this case, x can in particular assume the values 1 or 2, that is to say NO, mean NO ₂ , non-integer values for x are also possible, for example in a combination as N ₂ Os. In the case of DeNoX systems with SCR (selective catalytic reaction) catalysts, as used or planned, for example, in fossil fuel power plants or even diesel engines, incinerators or cement plants, ammonia (NH ₃ ) must be metered into the exhaust gas upstream of the catalytic converter. In the catalyst, one

so-called reduction catalyst, NOx and NH _{3 are converted} to nitrogen (N ₂ ) and water (H ₂ O).

To provide the ammonia, currently the two following principles are mainly used.

After a first known operating principle, the evaporation of the ammonia takes place outside the exhaust gas duct. This requires a separate evaporation system or a system for the supply of gaseous ammonia and has safety disadvantages, since this requires the storage of large amounts of liquid ammonia at very low temperature and / or high pressure, which represents a considerable hazard. For this reason, this solution is increasingly questioned today. Alternatively, ammonia can be stored as a water-ammonia mixture or water-urea mixture, which is much safer from a safety point of view. But with this solution is the necessary Apparalive installation and the energy required to evaporate the water-ammonia mixture respectively for evaporation of the water-urea mixture and the subsequent hydrolysis of the urea in ammonia very large. That makes this solution less economically interesting

Alternatively, a reaction agent can also be distributed in an exhaust pipe by means of a diaphragm or throttle installed in the interior of a spray pipe, which is shown in DE19946901. This orifice or throttle is to avoid a non-uniform Wandfiim, which forms on the inside of the spray tube. This solution is disadvantageous as a

Heat transfer to the reagent is not provided. The

Reactant therefore does not evaporate in the spray tube, but the

Evaporation takes place, as described below, by the direct contact of the droplets of the reaction medium with the hot exhaust gas. Document US6449947 describes a solution in which the reaction medium emerging from a feed line! is evaporated in the exhaust stream. The reactant is injected into the exhaust stream where it is vaporized and thoroughly mixed with the exhaust stream through a turbulence screen. That is, the evaporation of the reeaküonsmittels carried out by contact with the exhaust gas after exiting the supply line, so that liquid reactant enters the exhaust gas stream, so the reagent can not be vaporized already in the supply line. The document US2006 / 0191254 also describes a solution for mixing liquid ammonia, which may be mixed with compressed gas, into an exhaust gas stream. The patent US 7 ^* Ö9Ö'81Ö B2 describes a method for exhaust gas purification in power plants, in which a part of the exhaust gas flow is diverted. A urea-water solution is added to the branched exhaust gas stream in a separate chamber, evaporated and converted by hydrolysis into ammonia and CÖ2. This partial flow of exhaust gas is then returned by a blower and a static mixer with the main flow mixed. Due to the storage of ammonia in the form of the much less problematic urea and the conversion to ammonia until shortly before use, the risk potential can be considerably reduced, but the Druckveriust increases, which precludes an application of this solution, especially for exhaust gas flows with large volume, because the energy needs an essential one for overcoming pressure ulceration

Factor that leads to a cost penalty for this solution.

In WO2 / 06/122581 a heating element is provided to evaporate a reactive liquid coming from an injection nozzle. Oxidation reactions are the source of the reactive behavior of the reactive fluid. In addition, the chamber of the

Regenerating device heated by flowing exhaust gases. In principle, this solution is a partial flow as in US Pat. No. 7,090,881 B2. If the oxidizable liquid were heated solely by the exhaust gas flow, a very large partial flow would be required to provide the required energy for their evaporation. In addition, a blower would be required, which would increase the Plaizbedarf for the system and the pressure loss of this solution. It is also not excluded that droplets get into the main flow of the exhaust gas. According to another previously known functional principle, the atomization and then evaporation of a water-ammonia mixture takes place directly in the exhaust gas duct. This solution is less problematic in terms of safety, since such a mixture can be stored relatively easily, but requires an investment in very expensive atomizing nozzles. An example of such a solution is given in EP 1956208 A. The atomizing nozzle can be designed as a single-substance nozzle or as a two-component nozzle. The term single-fluid nozzle is used specifically for atomizing nozzles, in which only the liquid to be atomized is conveyed through the nozzle. In the case of two-substance nozzles, in addition to the liquid to be atomized, a propellant gas is also conveyed into the nozzle, as a result of which the atomization can be improved, ie in particular the production of very fine drops with a narrow

Drop size distribution and low dependence of

Liquid flow is possible. However, one is

Compression device for the compression of the propellant gas required. This compression device has a high demand for energy, which is especially for large exhaust streams, such as in

Industrial plants and power plants occur too economically

realizable solutions.

In addition, problems with dust-laden exhaust gases can arise when the dust is wetted by not yet vaporized droplets and accumulates as an impurity on walls of a film evaporator or catalyst or on a static mixer disposed in the exhaust stream upstream of the catalyst. At a gas pressure of, for example, 8-8 bar, such two-fluid nozzles typically produce

Drop size distributions with a Sauter diameter of 20 - 50 μm, but single large drops of up to 120 μm. Because of the contamination previously described by the accumulating on the walls dust must be taken to ensure that no drops can get into the catalyst or on the mixer. The time of flight of the droplets before the catalyst or a mixing device must be sufficient so that a complete evaporation of these droplets is ensured and requires correspondingly large length of the exhaust ducts. In small channels, such as exhaust pipes of motor vehicles, the time of flight of the drops to the catalyst is only a few milliseconds, which is not sufficient to evaporate larger drops during the flight phase. For this reason, at least the larger drops must be separated from the exhaust gas and vaporized in a liquid. For this purpose EP 1956206 A provides a film evaporator. In the case of motor vehicles, this is often permissible since a particle filler removes the dust from the exhaust gas in advance and thus there is no longer the risk of contamination. In the patent application WO 2004/079171 A1 is a combined

Evaporator and distributor made up of porous ribs

described. Urea-water solution should be distributed inside the porous structure and evaporated. According to this application, the evaporation energy is extracted from the flow of hot exhaust gas via heat conduction through the fins. Through openings in the ribs then the gaseous ammonia can escape. A large number of such ribs is necessary to remove the heat necessary for the evaporation of the flow of the flow. The proper distribution of the liquid urea water solution to these many fins is technically difficult to realize because of the complex 2-phase flow inside the fins. It's tough

ensure that no liquid can escape from the openings.

From the located at different positions openings in these ribs, depending on the position of the opening, very different

Volumes of vaporized solution or only partially vaporized vapor-liquid mixtures emerge. As a result, the required uniform pre-distribution of the ammonia over the cross section of the channel in which the evaporator is arranged, can not be guaranteed.

It is therefore an object of the invention to provide a device for safe and complete evaporation of ammonia and its uniform distribution over the cross section of the channel, which has a reduced energy consumption, short length, or little space and a low pressure drop in the exhaust duct. At the same time, the solution should be at least as safe in terms of safety as the use of a two-fluid nozzle.

It is a further object of the invention to avoid that

Fesisloffparükβl, like dust, in contact with the NH3-containing

Reaction center! come. An inventive apparatus for purifying an NOx containing exhaust gas stream comprises a closed channel which NH ₃ containing from one Reaktionsrnittel can flow, the channel being a

SVianteletement, which surrounds the Karzai and an inlet opening for the supply of liquid, NH _3- containing reactant and a

Exhaust opening includes. The jacket element can be flowed around by the exhaust gas flow containing NO x, wherein a distributor element for distributing the NH ₃ -containing reaction medium can be connected to the jacket element so that the NH ₃ -containing reaction medium can be introduced into the exhaust gas flow and mixed with the exhaust gas flow by means of the distributor element. The upgrading element has one or more openings through which the Nhh-containing reactant can be introduced as a gas phase into the exhaust gas stream. The NH ₃ -containing reactant is vaporizable within the Manteielements. For this purpose, the jacket element comprises a heat-transmitting element, so that the jacket element can be heated by means of the exhaust gas flow.

In particular, the heat-transmitting element may be formed as a rib or a tube. When the heat-transferring element as a pipe

is formed, it can simultaneously take over the function of the jacket element. Is the heat-transmitting element formed as a tube, which

at the same time forms the jacket egg, a very compact device is available.

Downstream of the distributor element may be arranged a mixer, in particular a static mixer, in order to mix the exhaust gas stream with the NH ₃ -containing reactant. The conversion of NOx with NH ₃ to N ₂ and H ₂ O takes place in a catalyst arranged downstream of the mixer. Preferably, the catalyst extends over the entire cross-sectional area of an exhaust gas channel leading to the exhaust gas stream, so that the conversion described above along a path as short as possible of the catalyst can take place, thus the length of the catalyst seen in the flow direction of the exhaust gas flow can be as small as possible.

According to a variant, the Manteieiement a reactor element for

Conversion of urea into MH ₃ include, in particular, the

Urea be supplied to the reactor element in the liquid phase.

The NH 3 -containing reactant according to one of the preceding variants remains in the interior of the jacket element and can only occur in the interior in the liquid state. This ensures that no liquid enters the exhaust gas flow and deposits on the inner surface of the exhaust duct or the heat transfer elements located in the exhaust duct. For this reason, dust particles are not on the inner surface of the

Exhaust gas ducts, deposited on the jacket element or on the heat-transferring elements. Thus, contamination of the inner surface of the exhaust passage, the jacket member, the heat-transferring elements as well as any downstream mounting elements, such as

for example, the distribution element or a static mixer

be excluded. The NHs-containing reactant emerges from the

Distributor over at least one opening. Since the NH ₃ -containing

Reactant is present in the distribution element in the gas phase, it comes downstream of the distribution element to a mixing of NHs-containing reactant with the exhaust gas stream without formation of a liquid

Phase. Thus, any dust particles entrained in the exhaust gas stream can not adhere to a surface wetted with a liquid because no liquid can enter the exhaust gas stream. The jacket element may contain flow-deflecting internals, in particular, the jacket element may be a metal foam or

Ceramic foam included. The heat that has been removed from the exhaust gas flow is distributed by heat conduction throughout the foam. The

Flow deflecting internals are used for rearrangement or deflection of the flow of Nhh-containing reactant. Through the rearrangement or Umienkung it comes to the formation of detachments and / or vortices, which results in an increase in the heat transfer resulting in an efficient heating of the NH ₃ -haltigen reaction center! becomes possible. The combination of heat transfer and heat conduction is for a metal or

Ceramic foam surprisingly much higher than for

flow deflecting internals, as for example for static

Mixers are in use.

In particular, the metal or ceramic foam is open-pored, so that the entire volume, which is occupied by the metal or Kzmramikaum, for the heat transfer and the deflection or rearrangement of

The jacket element as well as the metal or ceramic foam advantageously have a thermal conductivity of at least 15 W / m K, preferably at least 30 W / m K, particularly preferably at least 60 W / m K, so that the heat transfer from the exhaust gas stream to the NH ₃ - containing reaction center! additionally improved.

The jacket element and / or the metal foam may have a catalytically active surface, in particular if a variant

is provided, in which a decomposition of urea to produce a NH ₃ -containing reactant is provided.

The metal foam may contain aluminum, especially as one

Aiuminiumiegierung be formed. A metal foam made of aluminum can be easily manufactured and is therefore relatively inexpensive to procure. The ceramic foam can be embodied, for example, as a silicon carbide ceramic. Silicon carbide has a very high thermal conductivity, high wear resistance and good strength and can be processed into open-pored foam structures. The NH ₃ spherical reaction mixture may comprise an aqueous ammonia solution. The aqueous ammonia solution is introduced into the jacket element in the region of the inlet opening. Due to the heat transfer, the water evaporates, so that both the resulting NH ₃ , as well as the remaining water in the gaseous phase.

The exhaust gas stream may be at least 12 m ³ / h, preferably at least 1000 SiT ³ Zh, more preferably at least 10000 Hi ³ Zh. The

Inlet temperature of the exhaust gas into the channel is at least 150 ^of v ^N >.

The channel in which the exhaust gas stream flows may have a cross-sectional area which is at least 0.0007 m ² , preferably at least 0.05 m ^z , particularly preferably at least 1 m ² .

The device according to one of the preceding embodiments can be used to purify a NOx-containing exhaust gas stream from a

Industrial plant, in particular a power plant can be used. Other possible uses include denitrification plants for exhaust gases from power plants, for exhaust gases from diesel engines or exhaust gases

Calling refuse incineration plants.

The invention will be explained with reference to the drawings. 1 shows a schematic view of the device according to the invention. FIG. 2 shows a schematic view of a second embodiment variant of FIG

inventive device

An inventive apparatus 1 for purifying a NOx

1 comprises a closed channel 3, which can be flowed through by a NH3-containing reagent 4. The channel is partially cut in Fig. 1 to make the internals visible. The channel has a jacket element 5. which the channel 3 surrounds and an inlet opening 8 for supplying NH _3- containing

Reaction center! and an exit opening 7. The outlet opening 7 opens into a distributing element 8. The holding element 5 can be moved in the direction of the exhaust gas flow 2 containing NOx. To the mantle element 5 is a distributing element 8 for distributing the NH ₃ -containing reactant 4

connectable, so that by means of the distribution element containing the NHb

Reaktionsmittef 4 can be introduced into the exhaust stream 2 and mixed with the exhaust stream 2. The distribution element 8 has a hollow interior and one or more openings 9 through which the NH ₃ halves

Reaction center! 4 as a gas phase in the exhaust stream 2 can be introduced. The NH ₃ -containing reactant 4 is vaporizable within the shell element, that is, the NH ₃ -containing reactant 4 evaporates in the interior of the

Sheath element 5. For this purpose, the sheath element 5 comprises a

heat-transferring element 10, so that the jacket element 5 can be heated by means of the exhaust gas stream 2

Fig. 2 shows a schematic view of a second embodiment of the inventive device. The individual elements of the same function receive the same reference numerals as in FIG. 1. FIG. 2 shows an exhaust gas canister. 14, which includes a device 1 for purifying a NOx-containing

Exhaust gas stream 2 contains. A closed channel 3, is traversed by a NH _3- containing reagent 4. This channel 3 is as

serpentine running pipe shown. Of course, the course of the closed channel 3 does not have to be serpentine, it could, for example, also run helically, which is not shown here. The course of the tube in the exhaust duct 14 is such that the entire

Cross-sectional area of the exhaust passage 14 is usable for heat exchange.

The exhaust passage 14 is partially cut in Fig. 2 to make the internals visible. Furthermore, the channel 3 is shown cut at two parts to show its internals. In the interior of the channel 3 which is formed as a surrounded by a jacket member 5 cavity can a wärmeϋberiragendes element be attached, which is formed for example as a metal or ceramic foam, but the heat-transferring element may also comprise packing or a combination of different internals. The internals can also be provided only on some sections of the channel.

The channel has an inlet opening 6 for the supply of NH _3- containing

Reaction means and an outlet opening 7. The outlet opening 7 opens into a Verteilelemenl 8. In the present presentation gehl formed as a tube jacket element directly into a pipe over, soft to

Distribution element 8 leads. The distributor 8 is used for distribution of the NH ₃ containing reaction means 4, so that the NH ₃ containing reactant 4 is introduced into and be mixed with the exhaust gas stream 2 by means of the distributing element in the exhaust gas stream. 2 The distribution element 8 branches into at least two oil elements 15, 16, 17, 18, which have a hollow interior and one or more openings 9, through which the NH ₃ -containing

Reactant 4 is introduced as a gas phase in the exhaust stream 2.

The NH ₃ -containing Reaktionsmittei 4 is vaporizable within the Manteleiements, that is, the NH ₃ -containing reactant 4 evaporates in the interior of the Manteleiements 5. For this, the jacket member 5 comprises a heat-transmitting member 10, so that the jacket member 5 is heated by the exhaust stream 3, in particular the heat-transmitting element 10 according to FIG. 1 or FIG. 2 may be formed as a rib 11 or as a tube 12. In general, a plurality of ribs 11 is provided, which are formed as plate-shaped elements. Preferably, the plates extend in the flow direction of the exhaust gas stream 2, so that the exhaust gas stream 2 passes along the plate-shaped elements.

Of course, the plate-shaped elements are only a preferred embodiment of a heat-transmitting element. Alternatively or in addition, tubular elements, thickenings, disk-shaped elements, rod-like elements, schaufeiförmige elements, lattice structures, Metal foams and the like may be provided. Of course, these elements can be arranged in any combination.

The exhaust gas flow has a higher temperature than the heat-transferring member 10, so that heat transfer from the heat-transferring member 10 to the NH? containing reactant 4 takes place. If the heat-transferring element 10 is formed as a tube 12, it simultaneously assumes the function of the jacket element 5. The heat transfer takes place in this case from the exhaust gas flow through the tube wall to the NH3-containing reaction center! 4, This heat transfer may be sufficient if the required temperature difference between the exhaust stream 2 and the NH ₃ -containing reactant 4 is large enough, or the volume flow 2 at NH _3- containing reaction center! 4 is so small that the available heat transfer surface is sufficient in each case.

In addition, the jacket element 5 according to FIG. 1 or FIG. 2 is preferably made of good heat-conducting material. manufactured, so that the heat transfer

can be improved. The sheath element 5 has a thermal

Conductivity of at least 15 W / m K, preferably at least 30 W / m K, more preferably at least 60 W / m K on.

If the temperature difference between exhaust stream 2 and NH ₃ containing reaction center! 4 is low and / or a larger proportion of NH3-containing reactant is required. because the concentration of NOx in the exhaust stream is high, that provided by the shell member 5 alone

Heat transfer surface be insufficient, so that the

heat-transferring elements at least one of the above

Can accept embodiments.

Downstream of the distributor 8 may be shown after each of

Embodiments be arranged a mixer, in particular a static mixer to mix the exhaust gas stream with the NH3-containing reactant. This mixer is not shown in the drawing. According to a variant of the method, the NH ₃ -high reactant 4 can be obtained by conversion of urea. This reaction could also take place inside the jacket element 5. For this purpose, the jacket element can comprise a non-illustrated reactor element for converting urea into NH ₃ ; in particular, the urea can be supplied to the reactor element in the liquid phase. The supply of urea can be carried out, for example, by means of a device as shown in EP 1956208 A.

The Manteielement according to FIG. 1 or 2 may contain Strömungsumienkende and good heat conducting internals, which, as metal foam or

Ceramic foam 13 may be formed. The metal or

Ceramic foam 13 is preferably open-pore, thus the NH _3- containing reactant 4 can flow through the metal foam evenly. The metal or ceramic foam 13 may in particular be in heat-conducting connection with the manure element, so that the heat of the exhaust gas stream can be transferred to the NH 3 -containing reactant 4 via heat conduction through the jacket element 5 as well as through the metal or ceramic foam 13.

The exhaust gas flow 2 has a higher temperature than the heat-transmitting element 10, so that a heat transfer from the heat-transferring

Element 10 to the NH3-containing reactant 4 takes place. According to FIG. 2, the heat-transferring element 10 is formed as a tube 12 with ribs 11 arranged thereon and at the same time assumes the function of the jacket element 5. The heat transfer takes place in this case from

Exhaust gas flow over the ribs and the pipe wall to the NH ₃ -containing

Reactant 4. This heat transfer may be sufficient if the required temperature difference between the exhaust stream 2 and the NH ₃ -containing reactant 4 is large enough, or the volume flow 2 of NH ₃ containing reactant 4 is so small that the available heat transfer surface in each Case is sufficient. In a small exhaust gas can! with 1 m ^{2 of} cross-sectional area, one

Exhaust gas temperature of 200 ⁰ C at a velocity of the exhaust stream of 8.2 m / s, an evaporator system according to the invention was tested and compared with an evaporator tube, which was equipped with internals according to the prior art (EP 0 655 275 B1). The mass flow ratio of the water-ammonia mixture to be metered relative to the exhaust gas was 0.3%. The water-ammonia mixture had an ammonia content of 20%. In this case, an inventive evaporator having an inner diameter of 30 mm and a length of the evaporator of 6 m could be realized. In contrast, the prior art evaporator had an inner diameter of 20 mm and a length of 86 m. Of the

Pressure loss in the NH ₃ -ha¬ term reactant is significantly lower than in the previously known evaporator in the inventive evaporator. In the last part of the evaporator, where the reaction medium has already largely evaporated, pressure losses of about 1 bar / m are achieved in the inventive evaporator, while 3 bar / m are formed in the evaporator according to the prior art. The erfϊndungsgemäße evaporator generates a pressure drop of 0.22 mbar in the exhaust stream while the previously known evaporator with 2.4 mbar causes a more than an order of magnitude higher pressure drop in the exhaust gas. With the device according to one of the inventive

Embodiments thus a comparable pressure loss is generated as in the downstream of the device optionally arranged static mixer.

The length of the channel 3 is significantly lower than for a solution according to the prior art. In addition, the pressure loss generated by the channel 3 in Abgaskana! 14 surprisingly significantly lower than in the previously known solution due to the shorter length of the device according to the invention.

Claims

claims

1. Device (1) for purifying a NOx-containing exhaust stream (2), comprising a channel (3), which of a NH _3- containing reaction center! {4} is flowed through, wherein the channel (3) a

Sheath element (5), which surrounds the channel (3) and an inlet opening (6) for supplying the NH ₃ -containing reactant (4) and a Austrittsöffnυng (7) υmfasst, wherein the jacket member (5) of the NOx-containing exhaust gas stream (2 ) can flow around, wherein (to the casing element 5) is connected a Verieilelement (8) the distribution of the NH ₃ containing reaction means (4) so that the NH ₃ containing reagent (by means of the distributing element (8) 4) into the

Exhaust gas stream (2) can be introduced and mixed with the exhaust stream (2), wherein the Vβrteilelement (8) has an opening (9) through which the NH ₃ -containing reactant (4) as a gas phase in the

Exhaust gas stream (2) can be introduced, wherein the NH _3- containing reactant (4) within the jacket element (5) is evaporated, characterized

in that the jacket element (5) comprises a heat-transmitting element (10). so that the jacket element (5) can be heated by means of the exhaust gas flow (2).

2. Device according to claim 1, wherein the heat-transmitting element (10) is designed as a rib (11),

3. Apparatus according to claim 1, wherein the heat-transmitting element (10) is designed as a tube (12).

4. Device according to one of the preceding claims, wherein

downstream of the distributor element (8) a mixer is arranged, in particular a static mixer.

5. Device according to one of the preceding claims, wherein the manure element (5) comprises a reactor element for the conversion of urea into NH ₃ ,

6. Apparatus according to claim 5, wherein the urea the

Reactor element can be supplied in the liquid phase.

7. Device according to one of the preceding claims, wherein the jacket element (5) contains flow-deflecting internals.

8. Device according to one of the preceding claims, wherein the jacket element (5) contains an open-cell foam (13).

9. Apparatus according to claim 8, wherein the foam (13) is a metal or

Ceramic foam is.

10. Device according to one of the preceding claims wherein the jacket element (5) and / or the metal or ceramic foam (13) has a thermal conductivity of at least 15 W / m K ₁ preferably at least 30 W / m K, particularly preferably at least 80 W / m K has.

11. Device according to one of the preceding claims wherein the Manteielement (5) and / or the metal or ceramic foam (13) have a kataiytisch effective surface.

12. Device according to one of the preceding claims, wherein the

NH3-containing reactants (4) comprises an aqueous ammonia solution.

13. Device according to one of the preceding claims, wherein the

Exhaust gas stream (2) is at least 12 m ³ / h, preferably at least 1000 m ³ / h, more preferably at least 10000 m ³ / h.

14. Device according to one of the preceding claims, wherein the channel (3) has a Guerschnittsfiäche which is at least Ö0Ö07 m ² , preferably at least 0.05 m ² , more preferably at least 1 m ² .

15. Use of the device (1) according to one of the preceding

Claims for purifying a NOx-containing exhaust stream from an industrial plant, in particular a power plant.