DE937486C - Process and gas generator for gasifying dust-like or fine-grain fuels - Google Patents

Description

Process and gas generator for the gasification of dusty or fine-grained Fuels The heat demand for the gasification of solid fuels, which is essentially in the reduction of carbon dioxide: and water vapor to carbon dioxide and hydrogen by means of carbon, is by combustion of by known methods Carbon covered with the free oxygen contained in the gasification agent. the Gases generated by this combustion get granular or granular during the gasification lumpy fuels from the combustion zone, into the gasification zone, in which the Gasification of the fuel is going on. This process is strongly heat-binding. The heat required for the gasification of fuels can be known according to others Process can also be fed to the gas generator from the outside, e.g. B. by expedient circulated gases which, together with the gasification agent, are stored in a regenerator be heated to high temperatures of, for example, about 130o to 150o ° C. Of the the actual gas generator then only contains one gasification zone.

The gasification of coal dust, in suspension, one has similar as in the gasification of granular fuels, the combustion zone and the reduction or gasification zone arranged one behind the other in the same shaft. The one for you Gasification of the coal dust required heat is produced by partial combustion of imported fuel is generated. As a result of the high. Temperatures that are in the Prevail combustion zone, becomes the portion not burned here of coal dust in biscuit. converted. This portion of the fuel is of the. Gases evolved in the combustion zone, aaso. not in the form of easily burn similar coal dust, rather than hard-to-burn coke in the gasification zone guided. This reduction in the combustibility of the coal dust is the main reason for the fact that in this process the gases formed in the gasification zone the gas generator left at a high temperature and that the ashes are badly burned out.

According to another known method for the gasification of. Coal dust the gasifying agent, consisting of oxygen and water vapor, becomes before entry in the gas generator in. a regenerator heated to about 120o ° C and the other heat required for the gasification zone by burning coal dust, with obtained from the free oxygen of the gasification agent. So this is going to be a big one Part of the heat required for the gasification zone is supplied to the gas generator from the outside and accordingly. less heat in the gas generator itself through the combustion of coal dust generated.

An end to this dust gasification consists in d: ate - like that is known for the gasification of granular or lumpy fuels - the gas generator all the heat required for gasification is supplied by gases heated together with the gasification agent in a Regeneratod to about 1q.00 ° C will. Here, too, the gas generator contains only one gasification zone. The good verb dissociation of the imported coal dust. is retained in this way of working. The quantities of the tumble gas that must be used are, however, considerably large. Since the coal dust @ is gassed in suspension, d. H. to continue with the gas flow must be large Gassing chambers are made available i. These procedures are because - they are regenerators only use b, a, r and are suitable for carrying out under normal pressure not for that. Gasification under higher pressure of e.g. B. 2 to 2o at and more.

Also known is a method for. Gasifying dusty or fine-grain fuels by means of oxygen, mixed with water vapor, according to the u.mlau @ fen, the useful gas with the gasifying agent introduced into the gas generator in this way is that it burns with part of the oxygen, even before the gasifier acts on the coal to be gasified. You can go to. an execution form dieseln process also so much gas. trace back that the entire im. Gasifying agents contained free consumed by combustion of the recirculated gas. is before the gasification of the solid fuel begins. The recycled useful gas is under complete consumption of the free oxygen contained in the gasification agent burned in the rooms in front of the actual gasification zone. From the combustion chambers the hot combustion gases enter the gasification shaft into which, the coal dust, is introduced. The generator consists of a cylindrical outer shaft, in which the gassing room is designed as a concentrated inner shaft, see above. d: ate between: the two shafts an annular space is created, in which z. B. for the purpose The outer cohesion. and inner walls of the annulus advantageously stone fixtures can be located at the same time to guide the gas. to serve. The ashes can solid or liquid can be withdrawn from the gasification shaft. In this procedure the good combustibility of the coal dust is retained, but there are special somewhat intricate gas generator designs required.

According to the invention, with the simplest construction of the pulverized coal gas generator a high throughput while achieving a high thermal efficiency as well as an extensive variability in the composition of the gas produced possible. That. Process is for the gasification of fine or dusty fuels, in particular coal statlb, at all practically possible pressures. and with basel suitable gasification agents.

According to the invention, the -for the gasification taking place in suspension heat required by dusty or fine-grain fuels that flammable gas approximately with the theoretically required amount of oxygen or with less oxygen at the periphery of the space used for gasifying the fuel introduced and burned in this room, expediently with a short flame, and that the fuel is gasified with the gases generated by the combustion. Care is taken to ensure that the fuel is as possible during the gasification cannot come into contact with free oxygen. The flammable gas and that the gas containing free oxygen on the one hand and the fuel on the other are accordingly soi introduced into the gas generator that the combustion of the gas in a combustion zone and the gasification of the fuel, with those in the combustion: nungs.zone resulting hot gases take place in a gasification zone in such a way that does not get into this free oxygen.

To achieve a large gasification capacity it will be advantageous SEVERAL COMBINATION ZONES AND GASIFICATION ZONES: Successive in the gas generator provided, - which - expediently lie close together. For the same reason and recommends to achieve as complete a gasification of the fuel as possible it is the fuel introduced into the gas generator with the reacting gases to mix intimately, e.g. B. to swirl strongly.

The temperatures in the combustion zone can be used in the process according to the invention can be regulated easily and with simple means, in particular by adjusting the amounts of flammable, gas used, this way leaves also influence the composition of the gas generated.

The combustible gas produced in the process according to the invention can be used Gases or other flammable gases of any origin can be used.

The method according to the invention has the further advantage that it can be carried out in a gas generator of a particularly simple design. For example internals and constrictions in the gas generator shaft are not required.

The new method can, for example, in a vertical cylindrical Manhole. At the bottom of the shaft are useful in one to the shaft level vertical plane arranged gas burners with which fuel gas and the gasification agent are advantageously introduced into the shaft that they with Burn as short a flame as possible. In this way it becomes a uniform horizontal Burning zone formed. Immediately above this will also be useful in a horizontal plane coal dust feeds arranged through which with in the process generated gas or another gas is blown coal dust. In the one created in this way Gasification zone, the hot combustion gases rise from the combustion zone below and cause the gasification of the coal dust. Above the gasification zone can again a combustion zone, then again a gasification zone, and it is possible to provide a larger number of these zone pairs in the same gas generator.

In the combustion zones, the combustion is directed so that the all free oxygen contained in the gasification agent is consumed; it should so as possible to avoid that free oxygen with the in the gasification shaft imported carbon comes into contact and this thereby wholly or partially is burned. This ensures that the coal dust never has higher temperatures as they are responsible for the heat-binding reduction of carbon dioxide and water vapor are required, d. H. the high reactivity of the coal dust remains fully obtained by the method according to the invention. The carbon contained in coal dust is practically only consumed by the reaction with carbonic acid and water vapor. Since this reaction is heat-binding, the coal dust grains cannot reach high temperatures assume their temperature remains well below the temperature produced by the combustion arises in the combustion zone. Even if this combustion temperature is significant is above the melting temperature of the ash, the ash cannot melt will; for ashes still containing carbon cannot melt because the ashes contained in them Carbon is gasified with heat consumption. But also ash particles that have become carbon-free do not come to melting temperature. You take out the hot combustion gases Heat through contact, but are, in particular thanks to the invention applied strong turbulence, surrounded by coal dust particles, which as a result of the the gasification reaction taking place at them has a significantly lower temperature have than the ash particles. But these carry the heat they have absorbed by radiation to them. This will keep the ash particles from getting too high temperatures preserved, .and the coal particles are added by the heat radiating ash particles Heat supplied, which accelerates the gasification reaction.

Serve as fuel gases z. B. self-generated gases in the gas generator, see above can this, if necessary after z. B. in multiclones od. Like. Gas purifiers have been treated for the purpose of dust removal, hot to the gas burners in the combustion zone be guided. Are as fuel gas z. B. methane-containing gases used, so can methane is converted into carbon monoxide and hydrogen in the gas generator.

The gasification agent, consisting of air, oxygen-enriched air, or practically pure oxygen on the one hand and water vapor or carbon dioxide or a mixture of both on the other hand or the like, is expediently fed to the gas burners at a high temperature.

It also appears particularly expedient for carrying out the invention an embodiment in which the gas burners and pulverized coal feeds are not how described above, in two separate levels, but alternately, are arranged in the same plane. The combustion and gasification zones are located so then in the same plane.

This embodiment is shown schematically in the drawing: Fig. I in elevation, Fig. 2 in cross section.

i is the sheet metal jacket of the upright cylindrical gas generator, 2 its refractory lining, 3 the nozzle for the sinking ash, q. the gas outlet nozzle; A, B, C and D are four planes, perpendicular to the cylinder axis of the gas generator. In each of these levels, for example, four gas burners 5 and coal dust feeds 6 are arranged alternately on the gas generator jacket, in such a way that the gas and coal dust flows emerging from them at an expediently selected speed form tangents to an imaginary circle in a known manner. The imaginary circle can also be different for the gas flows coming from the gas burners 5 than for the gas flows laden with coal dust emerging from the feeds 6. In this way, the strong turbulence between the supplied coal dust and the hot combustion gases, which is aimed at according to the invention, is achieved. Different amounts of gasifying agents and coal dust can be fed to the individual zones; The composition of the gasification agent can also be different for the individual levels.

The gas burners 5 are expediently chosen so that the combustion with as short as possible Flame takes place in which all im through the pipe 8 supplied gasification agent containing free oxygen by combustion with the incoming gas through line 7 is consumed. So that with certainty happens, this combustion can be carried out with excess gas.

Become the combustible gas and the gasifying agent containing oxygen - preheated to temperatures above the ignition point of the flammable gas, so both media are expediently fed separately from one another to the gas burner. As shown in the drawing, the one containing the free oxygen is expedient Gasifying agent introduced in the middle of the burner, the combustible gas on the circumference of the burner, in such a way that there is the jet of gasifying agent emerging from the burner surrounds on all sides. So it can be easily prevented that coal dust particles with come into contact with oxygen and burn completely or partially.

The invention has the advantage that in the combustion zone very high Temperatures are permissible because in the gasification zone as a result of the strong turbulence the ash particles. the heat absorbed by them to the colder coal particles can submit; so the ash particles do not reach melting temperatures. The temperature the greater their reactivity, the smaller the coal particle. at Particularly sensitive ashes can reduce the temperature in the combustion zone Supply of suitable amounts of excess gases can be reduced.

This can be done by coordinating the composition of the gasification agent with the supplied amount of the combustible gas also with one only made of oxygen and water vapor existing gasifying agents without added carbon dioxide the ratio Change H2: C O in the generated gas to a large extent, at least within the limits 2: i to i: i, possibly even i :: 2. Used in the method according to the invention the oxygen pressure gasification of coal dust or the like. The gas outlet temperature lowered to about 700 to 750 ° C, then when using an expediently chosen Synthetically formed gasification agent methane.

By arranging the combustion and gasification zones in several successive planes perpendicular to the generator axis can change the temperature within the space containing these levels with appropriate coordination of the Composition of the gasification agent can be kept very high.

As a result, through the strong turbulence and through the maintenance of the The reactivity of the coal dust can result in a high throughput at low gas outlet temperatures and the best ash burnout can be achieved.

Claims (13)

PATENT CLAIMS: i. Process for the gasification of pulverulent or fine-grain fuels, especially coal dust, in which the heat required for gasification is generated by burning fuel gas with the free oxygen of the gasification agent and the amount of fuel gas supplied is such that all of the free oxygen contained in the gasification agent is Combustion of the fuel gas is consumed before the gasifying agent acts on the fuel to be gasified, characterized in that the fuel gas is introduced together with the gasifying agent at the periphery of the space used for gasifying the fuel and in this', expediently, is burned with a short flame. 2. The method according to claim r, characterized in that the introduction of fine or dusty fuels takes place on the perimeter of the gassing room. 3. The method according to claim i and 2, characterized characterized in that the gases formed during the combustion with the gas to be gasified Fuel are swirled. 4. The method according to claim i to 3, characterized in that that fuel gas and gasifying agent are introduced into the gasification shaft, heated to a high temperature will. 5. The method according to claim i to 4, characterized in that the gases and the fuel to be gasified in the gas generator tangentially to imaginary circles to be introduced. 6. The method according to claim i to 5, characterized in that in the direction of the axis of the gas generator, two or more pairs of combustion zones and gasification zones follow one another. 7. The method according to claim i to 5, characterized characterized in that the gas burner and fuel supply zones are in the same planes lie, of which several can be arranged one above the other. B. Procedure according to Claim i to 7, characterized in that excess combustible gas in the Combustion zone is introduced, its amount and composition and the Amount and composition of the gasification agent are coordinated in such a way can, that especially in the gasification with oxygen and water vapor a desired Ratio of hydrogen to carbon monoxide in the generated gas is obtained. 9. Procedure according to claims i to 8, characterized in that as the combustible gas in the process self-generated gas, if necessary after cleaning, or other, z. B. inethane-containing Gases are used. ok Gas generator for carrying out the method according to claim i to 6 and 8 and 9, characterized by an elongated space with several Gas burners (5), which are located in an expediently perpendicular to the longitudinal axis of the room Level are arranged, and fuel supply lines arranged in the same way (6), with several gas burner zones with fuel supply zones in the longitudinal axis of the room alternate. i i. Gas generator for carrying out the method according to claims r to 5 and 7 to 9, characterized by an elongated space with several gas burners (5) and fuel supply elements (6), which alternate with one another on the gas generator jacket arranged in the same, expediently lying planes perpendicular to the longitudinal axis of the room are. 12. Gas generator according to claim ro and 1z, characterized in that the elongated The space is free of built-in components and constrictions. 13. Gas generator according to claim ro to 12, characterized in that the gas burners and coal dust feeds on the 'shaft circumference are arranged so that the gas and coal dust flows emerging from them are tangents to form imaginary circles. Attached publications: German patent specifications No. 569 2ir, 571 r68.