EP0982389A1 - Process and apparatus for producing combustible gas - Google Patents

Abstract

The process comprises passing the volatile prolyzed product into a free chamber reactor (10), gasifying the prolyzed product in the chamber reactor (10) and using a heat of reaction to gasify the volatile prolyzed product. In the production of fuel gas from industrial waste, tires and plastic waste, waste hermetically sealed is prolyzed in a prolyzing device and the portion of volatile prolyzed from the prolyzed product is gasified by means of air or oxygen-enriched air during formation of fuel gas. An independent claim is included for an assembly to carry out the production.

Description

The invention relates to a method for manufacturing of fuel gas from domestic and industrial waste, used tires, Plastic waste, paint and varnish sludge, car light shredder and the like after that in the preamble of claim 1 defined in more detail. Furthermore The invention relates to a device for performing of the procedure.

A generic method and an associated device are known from DE 24 32 504 C3. Training the method described there and the DE 33 47 554 C2 and EP describe the device 01 26 408 A2.

All of these methods have in common that the Gasification of the volatile pyrolysis products on one Bed made of red hot coke is carried out.

However, the use of coke for gasification has some Disadvantages: So the reaction of the glowing Coke with the oxygen supplied and with the Proportion of water vapor in the volatile pyrolysis products a very large part of the coke itself is unnecessary consumed. This will make the economy of described method greatly reduced.

In addition, the strong endothermic reaction of water vapor and carbon dioxide with the glowing Coke the temperature in that area of the device in which the volatile pyrolysis products are gasified are lowered very quickly, creating a complete Gasification of volatile pyrolysis products, in particular of the oil vapors contained therein becomes. This incomplete gasification of the oil vapors leads to the formation of chemical compounds, such as Aromatics and naphthenes, leading to a later Time of the procedure difficult or at all do not let it convert into harmless substances.

It is therefore an object of the present invention Method and an associated device for production of fuel gas from domestic and industrial waste, used tires, To create plastic waste and the like in which volatile pyrolysis products in economical Way to be gasified without fuel gas that this creates harmful substances.

According to the invention, this task is characterized by Features mentioned in claim 1 solved.

A constructive solution to the problem arises from the characterizing part of claim 6.

By introducing the volatile pyrolysis products into a free space reactor by means of negative pressure, i.e. suction, are the volatile pyrolysis products during passing through the free space reactor of constant movement exposed, causing their very gasification going on much faster.

Due to the gasification of the volatile Share of the pyrolysis products in the free space reactor can be dispensed with the use of coke, what brings significant economic benefits. The free space reactor is also a significant factor larger volume for the gasification of the volatile Given pyrolysis products, whereby the same over a exposed to high temperatures for a significantly longer period of time are. So there are much purer as well Fission gases designated gasification products after passage through the free space reactor. In particular, a Reduction of unwanted hydrocarbons in the combustible fission gases can be reached.

According to the invention, coke can be dispensed with entirely be there for heating and thus for continuing the Gasification reaction after a certain heating phase only the volatile pyrolysis products themselves be used.

Another advantage of the method according to the invention is that the use of pure oxygen is not necessary is.

The device according to the invention is for implementation the method very well, whereby by the the burner device provided in the free space reactor immediate start-up of those necessary for gasification Reactions is guaranteed. The free space reactor can advantageously be made just as large be like this for the course of the gasification reactions necessary is.

Advantageous refinements and developments of Invention result from the dependent claims and from the principle shown below with reference to the drawing Embodiment.

Fig. 1

eine schematische Darstellung einer erfindungsgemäßen Vorrichtung zur Herstellung von Brenngas;

Fig. 2

einen Teil des erfindungsgemäßen Freiraumreaktors mit einer daran angebrachten Brennereinrichtung im Schnitt; und

Fig. 3

die Brennereinrichtung aus Fig. 2 in vergrößerter Darstellung.

It shows:

Fig. 1

a schematic representation of a device according to the invention for producing fuel gas;

Fig. 2

a part of the free space reactor according to the invention with a burner device attached to it in section; and

Fig. 3

2 in an enlarged representation.

Fig. 1 shows a device 1 for the production of Fuel gas from domestic and industrial waste, used tires, Plastic waste, paint and varnish sludge, car light shredder and the same.

The garbage is in a bunker 2, from where he through a line 3 through a connected to it Transport screw 4 into a pyrolysis drum 5 Pyrolysis device is introduced. In the Pyrolysis drum 5, the garbage is known per se Indirect heating in a temperature range pyrolyzed from 300 ° C to 650 ° C. The heating the double-walled pyrolysis drum 5 takes place via a Line 6 with a combustible gas, whereupon one will be discussed in more detail later.

During pyrolysis in the pyrolysis drum 5 are formed on the one hand pyrolysis coke and on the other hand volatile Pyrolysis products, such as long-chain and cyclic hydrocarbons, Steam, pyrolysis oils and mineralized Solids in the form of dust and ash. The Pyrolysis coke is made via a discharge device 7 the pyrolysis drum 5 and another use fed. The volatile pyrolysis products are over a line 8 discharged from the pyrolysis drum 5.

The volatile pyrolysis products arrive from line 8 via a burner device 9 into a free space reactor 10. In the at the top of the Sidewall of the free space reactor 10 arranged burner device 9, which is very detailed in FIG. 3 is shown, a line 11 also opens out what air or air mixed with oxygen in the Free space reactor 10 is passed. The volatile pyrolysis products are vacuumed, so sucking, in initiated the free space reactor 10. To do this in an area in the process direction behind the Free space reactor 10 on a particularly suitable one Place a device, not shown, for generation of negative pressure, such as a fan.

The burner device 9 is tangential to the inner wall the first individual free space reactor 10a, thereby creating a cyclonic flow in it and thus a good utilization of the volume of the Free space reactor 10 is formed. Another arrangement the burner device 9, e.g. vertically on the free space reactor 10, is also possible. However, has the tangential arrangement proved to be favorable.

The free space reactor 10 is in the present embodiment consisting of two individual, cylindrical free space reactors 10a and 10b, which at their Bottom connected via a passage 12 are. Is located below the passage 12 a discharge device 13, which over the entire Length of the free space reactor 10 or over the two Diameter of the individual free space reactors 10a and 10b and through the passage 12. Instead of the Formation of the free space reactor 10 from two individual Clearance reactors 10a and 10b can of course be used even a single free space reactor 10 or one Larger number of free space reactors 10 are provided his. The cylindrical shape of the two individual free space reactors 10a and 10b can by any other geometric shape can be replaced, whereby however, the cylindrical shape for the following described reactions proved to be the most suitable Has.

In the free space reactor 10, the are via the line 8 introduced volatile pyrolysis products with feed of air or oxygenated Air gasified via line 11. For this it is necessary by introducing natural gas through the burner device 9 initially sufficient temperatures in the To create a range between 1000 ° C and 1200 ° C. To Reaching these temperatures can initiate Natural gas can be stopped in the burner device 9 because the heat of reaction of the volatile pyrolysis products sufficient to control the temperature in the free space reactor 10 maintain and thus the gasification reaction to keep going. In the gasification reaction the cyclic and long chain hydrocarbons of the volatile pyrolysis products (pyrolysis oil, tars, pyrolysis water cracked or split into permanent gases, so to gases that are not further split like carbon monoxide, hydrogen, Carbon dioxide, methane or water vapor. When cracking become pollutants such as nitrogen oxides destroyed, some also dehydration takes place. The solids that separate out in the form of dust or partially melted slag are from the discharge device 13 from the Free space reactor 10 removed and a further use fed. Of course, for everyone individual free space reactor 10a or 10b and for the Passage 12 individual discharge devices 13 conceivable.

By regulating the supply of air or oxygen enriched air via line 11 in the Free space reactor 10 can be ensured that with the volatile pyrolysis products in the form mineral substance supplied by dust and ash only in this way is melted far to the end of the gasification process together with soot in the form of solid or at most doughy particles. Hereby can be associated with the appearance of liquid slag Problems, such as the formation of solid ones Slag approaches can be prevented. Mostly a sub-stoichiometric proportion of air in the free space reactor 10 set.

All of the mentioned cracking or cracking reactions can be found in the two individual free space reactors 10a and 10b instead, with the redirection over the Passage 12 swirling the flow of volatile Pyrolysis products is achieved. Because of this turbulence becomes the total volume of the free space reactor 10 exploited. This will make the required Residence time of the volatile pyrolysis products in the Free space reactor 10 ensured. In the free space reactor 10b are the volatile pyrolysis products implemented close to the thermodynamic equilibrium.

At the top of the second single free space reactor 10b leave the resulting from the reaction Permanent gases the same via a line 14 and get to a cooling stage 15, in which a cooling takes place below the slag softening point. A line 16 is connected to the cooling stage 15, about which the fission gases, which at a later date the process arise and the low temperatures have to be returned. This will a cooling of the gasified components of the volatile Pyrolysis products below the softening point of the realized mineral components and the doughy ones Particles are converted into the solid state.

A heat recovery boiler 17 connects to the cooling stage 15 in which the heat of the gasification gas is used becomes. The gasification gas leaves the waste heat boiler 17 via a line 18. After the waste heat boiler 17 and line 18 follow in a not shown, however a gas scrubber, a clean gas blower as well as various cleaning facilities. Furthermore, the line 18 also follows Above mentioned device for generating negative pressure. After this setup, line 6 becomes the pyrolysis drum 5 and line 16 to the Cooling stage 15 removed. Thus, part of the of the gasification reaction described above Fission gas used to heat the pyrolysis drum 5 and another part for cooling in the cooling stage 15, with the heating of the pyrolysis drum 5 fission gas used for this purpose was not used with the pyrolyzed gas Rubbish comes into contact. The two mentioned However, gas quantities represent only a small proportion of the emerging permanent gases. The largest part is used as fuel gas.

2 shows the first individual free space reactor 10a in a sectional view, here a refractory Lining 19 within the same outer wall is recognizable. The liner 19 is also in the Free space reactor 10b and present in the passage 12 and ensures good insulation of the entire free space reactor 10, thereby maintaining steady high temperatures is guaranteed.

2 also shows the burner device 9 a pilot burner provided for ignition and monitoring 20. The burner device 9 consists of the Pyrolysis gas burner through which the carbonization gas is fed is as well as from a necessary for the initial heating Heating burner. The pilot burner 20 and the heating burner are operated with natural gas. The heating burner can also be used when the calorific value the volatile pyrolysis products is too low. At the The bottom of the free space reactor 10 is the discharge device 13 shown in the form of a screw conveyor, that in a trough 21 of the free space reactor 10 arranged and made of heat-resistant steel.

Fig. 3 shows the burner device 9 in section. This points from the inside to the outside through the line 8 formed inner tube element to initiate the volatile pyrolysis products in the free space reactor 10 on. Outside of line 8 there is a first one Ring slot 22, through which through the line 11 air or oxygen-enriched air into the free space reactor 10 is initiated. The first ring slot 22 is coaxial with the inner ring member or Line 8 arranged outside the same.

Outside the first ring slot 22 and coaxially the same has the burner device 9 a second Ring slot 23, which on its outer circumference is connected to a supply line 24. About the second Ring slot 23 becomes natural gas in the free space reactor 10 initiated, which for heating the gasification process is used.

A third ring slot 25 is located outside of the second ring slot 23 is coaxial with the same and is like the first ring slot 22 with the line 11 intended for air or air mixed with oxygen. At the end facing the free space reactor 10 is the first ring slot 22 with the third ring slot 25 connected.

To cool the burner device 9 is outside the third ring slot 25 an annular slot element 26 arranged, which consists of a fourth ring slot 27th and a fifth ring slot 28. The fifth Ring slot 28 is with a feed line 29 for Cooling water connected and the fourth ring slot 27, which is arranged within the fifth ring slot 28 is with a drain 30 for the cooling water Mistake. All ring slots 22, 23, 25, 27 and 28 are thus arranged coaxially to one another. On that is the end facing the free space reactor 10 Ring slot element 26 is provided with a gap 31 which the fourth ring slot 27 with the fifth ring slot 28 connects. The gap 31 has a smaller one Cross section as the ring slots 27 and 28 on and thus contributes to an increase in flow velocity of the cooling water in this area. Consequently is achieved that the cooling water is constantly at the Outside wall of the ring slots 27 and 28 is what too a good cooling of the free space reactor 10 facing End of the burner device 9 leads.

At the end facing the free space reactor 10 the ring slots 22, 23 and 25 inwards to the line 8 inclined to increase the mixing intensity of volatile pyrolysis products with the supplied air or oxygen to reach. The second ring slot 23 is opposite to that first ring slot 22 and third ring slot 25 somewhat reset and points to the free space reactor 10 facing end bores 32 through which the natural gas can escape.

Other structural designs of the burner device 9 are of course also possible However, the present embodiment as has proven favorable.

Claims (14)

Process for the production of fuel gas from domestic and industrial waste, used tires, plastic waste, paint and varnish sludges, light car shredders and the like, the waste being pyrolyzed in a pyrolysis device with the exclusion of air, and the volatile fraction of the pyrolysis products resulting from the pyrolysis being added with the addition of air or gasified by oxygen-enriched air to form the fuel gas,
characterized in that 1.1 the volatile pyrolysis products are introduced into a free space reactor (10) by means of negative pressure, 1.2 the gasification of the volatile pyrolysis products is carried out in the free space reactor (10), and 1.3 for gasification of the volatile pyrolysis products whose own heat of reaction is used. Method according to claim 1,
characterized in that
the supply of air or air mixed with oxygen into the free space reactor (10) is such that the mineral substance introduced into the free space reactor (10) is only melted with the volatile pyrolysis products to such an extent that it is present in the form of solid or pasty particles after the gasification has ended . The method of claim 1 or 2,
characterized in that
the volatile pyrolysis products are broken down during their gasification. The method of claim 1, 2 or 3,
characterized in that
the volatile pyrolysis products and the air or the air mixed with oxygen are introduced into the free space reactor (10) via a burner device (9). Method according to claim 4,
characterized in that the burner device (9) is ignited by introducing natural gas. Method according to one of claims 1 to 5,
characterized in that the pyrolysis device (5) is heated by fission gas formed during the gasification of the volatile pyrolysis products. Device for carrying out the method according to one of claims 1 to 6 with a pyrolysis device,
marked by 7.1 a free space reactor (10) for gasifying the volatile pyrolysis products, which is connected to the pyrolysis device (5), 7.2 a device for generating negative pressure in the free space reactor (10), and 7.3 a burner device (9) for introducing the volatile pyrolysis products into the free space reactor (10) and for heating the volatile pyrolysis products. Device according to claim 7,
characterized in that
the burner device (9) is arranged in the upper region of the free space reactor (10) tangential to the inner wall thereof. Device according to claim 7 or 8,
characterized in that two substantially cylindrical free space reactors (10a, 10b) are provided which are connected to one another via a passage (12). Device according to one of claims 7 to 9, characterized in that a discharge device (13) is arranged on the underside of the free space reactor (10). Device according to one of claims 7 to 10, characterized in that the free space reactor (10) is provided with a refractory lining (19). Device according to one of claims 7 to 11, characterized in that the free space reactor (10) is followed by a cooling stage (15). Device according to one of claims 7 to 12, characterized in that the burner device (9) has the following elements: 13.1 an inner tube element (8) for feeding the volatile pyrolysis products into the free space reactor (10), 13.2 a first ring slot (22) for supplying air or oxygen-enriched air into the free space reactor (10), which is arranged at least approximately coaxially to the inner ring element (8) outside the same and connected to a feed line (11), 13.3 a second ring slot (23) for supplying natural gas to the free space reactor (10), which is arranged at least approximately coaxially to the inner ring element (8) and the first ring slot (22) outside the same and connected to a feed line (24), 13.4 a third ring slot (25) for supplying air or oxygen-enriched air into the free space reactor (10), which is at least approximately coaxial with the inner tubular element (8), the first ring slot (22) and the second ring slot (23) outside the same arranged and connected to a feed line (11), and 13.5 an annular slot device (26) for supplying and removing cooling water, which is arranged at least approximately coaxially with the inner tubular element (8), the first annular slot (22), the second annular slot (23) and the third annular slot (25) and is connected to a feed line (29) and a discharge line (30) for cooling water. Device according to claim 13,
characterized in that the ring slot device (26) for the cooling water is provided at the end of the burner device (9) facing the free space reactor (10) with a gap (31) for increasing the flow rate of the cooling water.

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