DD296619A5 - METHOD AND DEVICE FOR REDUCING THE CO CONTENT IN EXHAUST GASES FROM COMBUSTION ENGINES - Google Patents

Abstract

The invention relates to a method and a device for reducing the CO content in exhaust gases of incinerators, in particular for domestic and special waste. For example, the waste is burned in a rotary kiln and the exhaust gases are routed to a waste heat boiler downstream of the kiln. There, using the combustion gas jets of burners, the exhaust gases coming from the rotary kiln are vigorously mixed, thus intensifying the reaction between CO and O2. To further improve the combustion of CO to CO2, an oxidant and / or a catalytic agent may be introduced into the combustion gas stream. Fig. 1 {method; Device; exhaust gases; CO; Domestic and special waste; Incinerators; Burner; waste heat boiler; Rotary kiln; Oxidant; catalytic agent}

Description

For this 3 pages drawings

Field of application of the invention

The invention relates to a method and a device for reducing the CO content in exhaust gases of incinerators, in particular in the combustion of household and hazardous waste, wherein the waste burned for example in a rotary kiln and the exhaust gases are passed through a boiler downstream of the furnace.

Characteristic of the known state of the art

The waste gases from waste incineration plants, as well as the exhaust gases of power plant boilers that work with coal firing, contain, among other things, carbon monoxide, whose proportion should be kept as small as possible.

In waste incineration plants, for example, the waste is introduced into DC-driven rotary kilns and burned there.

These ovens end in waste heat boilers, from which the slag is pulled down, while the exhaust gases or flue gases flow through the first boiler train practically vertically from bottom to top. After a deflection, another heat exchange takes place in a convection part. The waste heat boilers are followed by an exhaust gas purification process.

The aim of the invention is to reduce the CO content in the exhaust gases of incinerators.

Presentation of the veson of the invention

The invention has for its object to improve the management of the exhaust gases from incinerators in conjunction with the arrangement of suitable burner.

According to the invention the object is achieved in that the combustion gases of burners, in particular high-speed burners, are blown into the boiler together with an oxidizing agent and / or a catalytically active agent.

It has proved to be advantageous to blow the combustion gases at a speed of at least 100m / s transversely to the flow direction of the exhaust gases in the Kessol and indeed so, they are directed towards each other from opposite sides of the boiler. It is expedient to inject the combustion gases in one or several different levels or heights into the boiler.

According to the invention, the flue gases are mixed by means of burners, in particular high-speed burners.

High-speed burners are burners in which combustion takes place in a burner chamber mounted on the burner and the combustion gases flow through a nozzle with speeds of about 100m / s and more in the boiler.

Due to the high exit pulse of the combustion gases emerging from the burners, the exhaust gases or flue gases flowing through the boiler are sucked in and vigorously mixed in order to achieve the greatest possible reaction of CO with O ₂ .

In addition to this mixing of the flue gases, as already mentioned, it is proposed according to the invention to introduce an oxidizing agent and / or a catalytically active agent into the combustion gases of the burners.

These means may preferably be injected into the exhaust nozzles of the burners or into the combustion gas stream of the burners in the boiler.

Suitable oxidizing agents are, for example, oxygen O ₂ , ozone Oj, hydrogen peroxide H ₂ O, nitrous oxide N ₂ O, sodium peroxide Na ₂ O ₂ and manganese oxide MnO ₂ . The catalyst used is in particular copper oxide as copper (I) oxide Cu ₂ O and as copper (II) oxide

The additional introduction of an oxidizing agent and / or a catalyst considerably improves the combustion of CO to CO ₂ and thus greatly reduces the CO content in the exhaust gases.

embodiments

An exemplary embodiment of the invention will be described below with reference to the drawing, in which

Fig. 1: schematically shows the projecting into the first boiler train of a waste heat boiler end of a rotary kiln.

2 shows a section along the line H-II of Figure 1.

Fig. 3: shows schematically in section a boiler with a coal furnace.

4a and 4b show schematically in section a combustion chamber.

The temperatures in the first radiation train of the boiler are currently above the Drehrohrofenendes currently about 100O ⁰ C to 1500 ⁰ C, in the middle of the train about 750 to 850 ° C and at the upper end in the deflection of the train about 600 to 700 ⁰ C. These temperatures vary depending on the waste composition, the oven mode and the degree of soiling of the boiler.

At these temperatures mechanical Umwälzeinrichtungen are unsuitable.

Figure 1 shows schematically the end of a rotary kiln 10, which is approximately in the first beam train or boiler train 14 of a

generally protruding with 12 designated boiler. Between the outer periphery of the rotary kiln 10 and the opening in the boiler train 14 is an annular gap of z. B. 10 to 40mm width, but not shown in Figure 1 and enters through the so-called secondary air into the boiler 12.

The exhaust gases from the rotary kiln 10 flow in the boiler train 14 vertically from bottom to top and they are vigorously mixed in the boiler train 14 according to the invention under itself and with the secondary air.

Above the entry end of the rotary kiln 10 in the boiler train 14, advantageously immediately above, therefore, burners 16,18,20,22,24,26 in particular so-called high-speed burners, arranged in the two opposite side walls 36,38 of the boiler train 14 and mounted are installed.

In the example shown, four burners are installed in each side wall of the boiler train 14, such. B. the burner 16,18,20 in the side wall 38 and the burner 22,24,26 in the side wall 36 of the boiler train 14th

The burners 16, 18, 20 thus face the burners 22, 24, 26 and the combustion gas jets emerging from their nozzles 30 are directed towards one another.

In the vertical direction, the individual burners are arranged offset in height with respect to one another, for example, the burners 16, 18, 20 can lie in one plane, while the burners 22, 24, 26 can lie in another, higher plane.

It has also been shown that it is expedient to arrange the burners, which are installed on one of the two walls 36 and 38, offset in height from each other, as Figure 1 shows.

Thus, the burners 16 and 20 installed in the wall 38 are in a horizontal plane that is between the burners 16

and 20 arranged burners 18, however, lies in a higher level. The same applies to the burner 22,24,26, which in the

Wall 36 of the boiler train 14 are installed, in which case the burners 22 and 26, as shown in FIG. 1, lie in the upper level,

while the burner 24, which is installed between the two burners 22,26 in the wall 36, arranged in the lower level

Both air vertical and the horizontal section of the burner from each other depending on the beam cones 32 of the

the burner nozzles 30 exiting combustion gases can be selected.

Measurements have shown that the opening angle of the beam cone 32 is about 20 °. The horizontal distance of the burner from each other can now be suitably chosen so that the beam cone 32nd

just in the middle plane 40 of the boiler train 14 just meet or overlap.

The same applies to the vertical distance A of the two burner groups from each other. The central axis of the burner nozzles 30 (and thus the central axes of the beam cone 32) preferably extend horizontally and

perpendicular to the respective side wall 36 and 38, respectively.

It is stressed, however, that this need not be the case; H. These center axes of the burner nozzles 30 and the beam cone 32,

can also be inclined at an acute angle to the horizontal upwards or downwards, and they can also form a 90 ° deviating angle to the respective side wall 36 and 38, respectively. (The term "horizontal" refers to the boiler train 14 being vertically arranged and the exhaust gases flowing out of the rotary kiln 10 vertically upward from below.)

With this arrangement, the burner 16 to 26, whose horizontal and vertical spacing practically the beam diameter

in the middle of the boiler train 14 corresponds to a very good mixing of the boiler train 14 from bottom to top flowing exhaust gas is already achieved, since this arrangement already a very large part of the cross-sectional area of the boiler train is detected. Due to the mutual Verse of the individual burner, a frequent deflection of the exhaust gas flowing in the boiler train 14 is achieved and thus intensifies the mixing and reaction. Preferably, the burners are as close as possible, d. H. arranged directly above the outlet of the rotary kiln 10, whereby it is achieved that the secondary air is sucked in the highest possible temperature of the burner jets and the time for the reaction of the oxygen with the

Carbon monoxide is as long as possible. In addition, it can be provided above burner 16 to 26 further burners 28, e.g. two burners in two more Layers to provide, which are installed in the same manner as the burner 16 to 26. The burner 28 are expediently

but offset in the horizontal direction relative to the burners 22,18,26 by half their center distance.

By this additional burner 28 exhaust strands that have not yet been detected by the lower burner groups

are mixed, whereby the reaction of CO with O _{2 is} further improved.

The burners, which are commercially available, can be operated, for example, with propane gas. Figure 3 shows schematically a boiler, z. B. a power plant boiler, which is operated with coal firing. The boiler 42 is formed and constructed in a conventional manner, so that it need not be described in detail. Below the boiler 42 is a traveling grate 44, on which the furnace is located, and the hot exhaust gases or Flue gases rise, as also known, through the boiler 42 therethrough upwards. Above the traveling grate 44 are in the lower part of the boiler 42 burners 46, in particular high-speed burner,

installed in at least one wall of the boiler 42 so that their combustion gases transversely to the flow direction of the

Firing of the boiler coming flue gases are blown into the boiler, the inflow speed of this Combustion gases at about 100m / s or above. Preferably, the high speed burners 46 are installed in two opposite walls of the boiler 42

and their combustion gases flow toward each other into the boiler 42. The high speed burners 46 may lie in one plane, but advantageously they are superimposed on and offset from one another in at least two or more planes, as shown in FIG.

Figures 4a and 4b respectively show the combustion chamber 52 of one of the burners, e.g. of the burner 16. Into the combustion chamber 52 protrudes

a burner lance 50 in at the outflow end of a flame 54 burns.

The resulting combustion gases are injected via the respective burner nozzle 30 in the boiler 12, wherein

a combustion gas jet cone 60 is formed.

To improve the combustion of CO ₂ CO ₂ , an oxidizing agent and / or a catalyst is now passed through a line 56

(Figure 4a) or by a line 58 (Figure 4 b) introduced into the effluent from the combustion chamber 52 combustion gases.

In the embodiment of FIG. 4a, the oxidant and / or the catalytic agent are introduced into the burner nozzle 30

fed into which the line 56, while in the embodiment of Figure 4 b, the oxidizing agent and / or

Jer catalyst be blown through the line 58 directly into the boiler 12, in particular directly into the jet cone 60. The combustion gas stream enriched with the oxidizing agent and / or the catalytic agent mixes with the Oven exhaust gases, which is achieved by these means with the furnace exhaust gases mix fine and the desired reaction

bring about or promote.

The combustion gas flow is thus both pulse medium for mixing the furnace exhaust gases and carrier medium for

the oxidizing agent (s) and the catalytic agent (s).

The inventive method is also suitable for household waste incineration plants, for example, with Schrägrostfeuerung

work. Here are the high-speed burners also above the firing in the lower part of the boiler or

Boiler train arranged, as described above in connection with a power plant boiler.

Claims (10)

1. A method for reducing the CO content in waste gases from incinerators, in particular in the incineration of household and hazardous waste, the refuse ζ. B. burned in a rotary kiln and the exhaust gases are passed through a Dom furnace downstream waste heat boiler and then through a cleaning system, characterized in that in the boiler Verbrennungsgasö of Erennern, especially high-speed burners, are blown together with an oxidizing agent and / ocle / a catalyst , 2. The method according to claim 1, characterized in that the injection velocity of the combustion gases is at least about 100m / s and that they are injected transversely to the flow direction of the exhaust gases in the boiler. 3. The method according to claim 1 and 2, characterized in that the combustion gases with the oxidizing agent and / or the catalyst from opposite sides of the boiler from each other trimmed and injected in one or more different levels or heights in the boiler. 4. The method according to claim 1, characterized in that the (or) the oxidizing agent and / or the (or) catalytic agent (s) are introduced or injected into the discharge nozzles of the high-speed burners or in the combustion gas stream in the boiler. 5. The method according to claim 1, characterized in that are used as the oxidant oxygen, ozone, hydrogen peroxide, nitrous oxide, sodium peroxide and / or manganese oxide and copper oxide catalyst. 6. A device for carrying out the method according to claim 1 to 4, characterized in that in the boiler (12; 14) above the output of the rotary kiln (10) or in the boiler (42) above the firing a plurality of high-speed burners (16 to 26 46) is installed, the discharge nozzles (30) are directed into the interior of the boiler (12; 14; 42). 7. Apparatus according to claim 5, characterized in that the burners (16 to 26) in two opposite side walls (36; 38) of the boiler (12; 14) zugrichtet built on each other and in particular in a plurality of vertically superimposed planes are arranged. 8. Apparatus according to claim 5 and 6, characterized in that in the two side walls (36; 38) of the boiler built-in opposite burners are arranged offset in height to each other. 9. Apparatus according to claim 5 to 7, characterized in that the horizontal and the vertical distance of the burners from each other approximately to the diameter of the jet cone (32) of the combustion gases of the burner in the middle of the boiler (12, 14). 10. Apparatus according to claim 5 to 8, characterized in that in the boiler (12; 14) above the burner (16 to 26) further burners (28) are installed, which are horizontal to the burners (16 to 26) by half their center distance are arranged offset.