DE3814619A1 - Process and apparatus for the combustion of fuel - Google Patents

Abstract

Process and apparatus for the combustion of fuel by means of primary gas containing oxygen and conveyed into a heating space. The primary gas is introduced in a plurality of primary-gas jets into a combustion space of a gas channel, into which combustion space fuel is also introduced. The primary-gas jets generate, in the combustion space of the gas channel, backflows of the gas/fuel mixture undergoing combustion, the said backflows being directed towards an arresting wall.

Description

The invention relates to a method for Burning fuel and a Establishment for carrying out this procedure.

The invention relates to the burning of Fuel in a firebox. This can burn serve different purposes, for example heating of heat transfer medium or the operation of one Gas turbine or other purposes. In the Facility in whose firebox the fuel is burned, it can be a kettle, a Combustion chamber, any heat generator or act like that. Preferably, the combustion can Generation of usable heat, especially of serve industrially usable heat. For example, that Burning the fuel of heat generation in Power plants or to operate turbines or the like, the heating of media of any kind, such as Water, air or the like or other purposes serve. For example, it can also be used to heat buildings or the like. Serve and many other  Have areas of application. It can preferably be used for Serve to generate high heat output, but that is inventive method and the device also at low and medium heat outputs advantageous.

With such procedures and facilities it is desirable that the flue gases as little as possible Contain pollutants to reduce pollutant emissions to keep as low as possible. Also, it is often not satisfactorily solved problem in the firebox to keep the ignited flame stable. To do this it is known to reach into the firebox at a distance so-called flame holder from its wall to arrange, which brought into the flame path form mechanical obstacles such as wires, rods, Discs etc. But such flame holders can Adversely affect the combustion process and the Often increase and satisfy pollutant emissions not for other reasons.

It is therefore an object of the invention to provide a Method of the preamble of claim 1 to create the type mentioned, in which the Flame control while reducing the Successful emission of pollutants.

This object is achieved by the in Claim 1 specified method solved. A Device according to the invention for performing this The method is described in claim 22.  

The invention enables safe flame control the ignited flame in the gas duct combustion chamber on the To reach the catch wall so that there is no additional Flame holder needed. This catch wall forms at the same time the boundary wall of the entrance Combustion chamber and thus does not pose a flow obstacle in the Combustion chamber represents what is favorable to the Combustion process affects. Through through Primary gas jets generated backflows in the Combustion chamber of the gas duct towards the trap wall the flame roots on or near this trap hold and this makes it extremely stable and therefore continuous Combustion causes. Also, there will be reduction at the same time harmful flue gas components reached so that it this procedure also enables the To keep pollutant emissions particularly low.

One can take place that takes place in the method according to the invention Combustion as a continuous burning of fuel denote because the combustion of the fuel in each case as long as desired or required continuously continues until the fuel supply is shut off Burning fuel is stopped again, whereby also the supply of oxygen-containing gas in the Combustion chamber can also be ended. Then it can connect a break of any length during which however at least one pilot light to reignite the flame or flames used to generate heat can burn unless other means of ignition are provided are. Heat generators serving for heat generation, such as boilers, boilers, stoves or the like, but also in other devices according to the invention or must often be provided for control or Regulation of heat generation that of the respective heat generating continuous combustion of the Always last more or less long each time to leave and take breaks in between,  during which the distillery used to generate heat fuel supply - possibly with the exception of the fuel supply for at least one pilot flame - is interrupted, so that no heat or at most only the minor of one or more Flame generated heat is generated. For example it is for boilers of heating systems for buildings or The usual. The supply of fuel and combustion air for power control alternately on and turn off. With the fuel supply switched on the amount of fuel / time supplied is often constant.

In the invention this is of course corresponding also possible, the device according to the invention can also be a boiler, but also one other device for burning fuel. It is alternatively or additionally, if desired, at the inventive method and the inventive Power-modulated operation also possible. Power-modulated operation means that Fuel supply and possibly also the supply of oxygen containing gas - possibly with the exception of fuel and air supply for at least one pilot flame - for Control or regulation of heat generation to vary d. H. to values of different sizes continuously or gradually  to be able to adjust. One can then in the uninterrupted Continuous operation continuous burning of fuel provide with variable fuel quantity / time and, if desired the continuous burning of the fuel for additional power control or regulation with Have break times alternated, where those of warmth generation fuel supply and possibly also the Supply of oxygen-containing gas and thus the heat generation is interrupted, again with exception if necessary the supply of fuel and air for at least one Pilot light.

The trap wall forms a transverse wall in the gas duct. they can also be used as a flame retardant Flame holder wall can be called. It also educates the upstream end wall of the in the gas channel existing combustion chamber in which the flame begins.

The combustion chamber of the gas channel can preferably only form a part of the combustion chamber in which one provides that the combustion chamber of the gas channel is open in opens the rest of the firebox. However, it is also possible the entire combustion in the combustion chamber of the To allow gas channels to take place and, for example, the outlet the gas duct directly to a flue gas outlet to connect.  

However, it is particularly favorable if the combustion chamber of the Gas channels only a partial area, preferably only one forms a relatively small section of the entire firebox. The smoke gases that form in the combustion chamber can escape from it derived from a flue gas outlet or in some other way will.

Although in some cases it is sufficient if only between one of the existing primary gas nozzles and the trap wall at least one passage for flowable medium is available is preferably between at least two primary gas nozzles and the trap, particularly useful between all Primary gas nozzles and the trap openings for flowable Medium should be provided.

The primary gas jets flow at or near Catching wall from the primary gas nozzles into the combustion chamber of the Gas channels, preferably with high to very high Flow velocity. The primary gas jets cause so intense backflows of the combustion Gases towards the trap wall, the primary gas jets at or near the trap wall Flush the trap into the combustion chamber that the trap the flame control of the ignited in the combustion chamber, by the Burning the fuel caused in the Brennram Flame combined with that of the primary gas jets Backflow generated in the combustion chamber causes.

Fuel is also introduced into the combustion chamber. It can affect the entire in the relevant firebox burning fuel or part of it of this fuel. If not all of the fuel is introduced into this combustion chamber, then it can preferably the largest part of the total fuel to be burned in the combustion chamber  can act and the rest of the fuel can then outside the combustion chamber of the gas channel in remaining combustion chamber are burned. For example outside the gas duct at least one gas burner in the Firebox to generate additional heat extreme load operation.

It is particularly advantageous if the Primary gas jets into the combustion chamber of the gas channel to be blown in by the Entrance wall separated from the gas duct combustion chamber Can cause pressure reduction. This pressure reduction in such an anteroom can then be used to any media in this vestibule suck in which medium then from this anteroom also by the effect of the primary gas jets in the combustion chamber of the gas channel can be promoted. This medium can preferably be from the Act the flue gas sucked into the combustion chamber. But come other media alone or in combination with Flue gas in question. For example, the medium can be used as Gas containing coal dust as fuel, preferably be inert gas, so that this Coal dust in the combustion chamber for its combustion is introduced. Other media come for them too Intake into the combustion chamber through the effect of Primary gas jets in question, e.g. combustion favoring or otherwise desired influencing media, etc. It is often also useful this medium to the openings between the primary gas nozzles and the trap wall in a preferably adjustable volume flow by at least one turbomachine, for example a blower or to promote a fan so that the prärgas do not suck it up or its promotion in the Only support the combustion chamber.

The invention makes it possible due to the good flame retention by means of the catching wall that such medium in at quantity / time of the primary gas of a relatively large amount / time from the  Primary gas jets into the combustion chamber of the gas channel sucked in or in any other way through the combustion chamber the passages between the primary gas nozzles and the Catch wall can be initiated in any other way can. This leaves if this medium is concerned recirculated flue gas, especially high dilution of the primary gas through flue gas without the flames affect stability, so extremely low Pollutant emissions can be achieved.

The flame can also be length, thickness, etc. through the combustion chamber of the gas channel, the Flue gas recirculation, the primary gas jets and those of backflows generated by them and the Adjust the combustion chamber optimally or the combustion chamber in design as desired.

The number of in the combustion chamber of the gas channel blown primary gas jets can be two or preferably be more than two, and the same can preferably a plurality of openings in the Catching wall can be arranged by primary gas jets are flowed through or into the primary gas nozzles protrude or penetrate them.

The primary gas nozzles, which the primary gas jets in the Blow in the combustion chamber of the gas duct blowing directions arranged parallel to each other be or have another arrangement. In many In cases it is advisable to arrange them so that the Not blowing directions of at least two primary gas nozzles run parallel to each other, but to each other are inclined. In many cases it is useful if the blowing directions of at least a part of the  Primary gas nozzles diverge from each other or converge. These primary gas nozzles can also do so be arranged so that they are in the combustion chamber of the gas channel one around the longitudinal axes of the preferably straight Generate gas channel circulating vortex flow, by arranging them accordingly inclined.

The peripheral wall of the gas channel can preferably be designed as a tube, preferably as a straight one Pipe. This pipe can be particularly useful approximately be circular cylindrical, but others also come Training in question.

If it is provided that the primary gas jets through Openings in the trap wall into the combustion chamber are blown in, their clear cross-sections are larger, preferably considerably larger than the cross sections of the Primary gas jets are preferably at their height be provided that through each such opening the Trap a single primary gas jet into the combustion chamber is blown in. However, it is also possible to go through such an opening several parallel to each other and / or converging to each other and / or to each other diverging primary gas jets into the combustion chamber to blow in, for example, by means of a single Primary gas nozzle, which is a corresponding plurality of Openings for blowing out primary gas jets has, or by means of several primary gas nozzles he follows.

The gas channel can be used for blowing out the Primary gas jets preferably at least two in  lateral distances from each other Have primary gas nozzles.

In many cases it can be expedient to provide that the openings associated with the primary gas nozzles in the catch wall relative to the primary gas nozzles are arranged that the primary gas nozzles in this Protrude openings or these openings penetrate and beyond them something in the Protrude combustion chamber, being between the edges these openings and the primary gas nozzles as passages clear spaces, preferably annular gaps, are present are, which form flow openings for medium that before preferably from a through the trap wall of the combustion chamber Gas channel separate gas channel anteroom using the Primary gas jets can be sucked into the combustion chamber.

The back flows generated by the primary gas jets in the combustion chamber of the gas channel also have the advantage that the flame length is shortened, which accordingly shorter or smaller design of the firebox with all resulting advantages.

It when the openings of the Catch wall through which primary gas jets flow or in the blowing out of the primary gas jets serving primary gas nozzles at a distance from their walls are used in the downstream direction rejuvenate.

The fuel can be fed into the combustion chamber done in any suitable way. For example  preferably in the middle of the gas channel at least one fuel supply nozzle, preferably an atomizing nozzle for fuel may be arranged, or there can be several such nozzles for fuel be arranged, preferably in the catch wall can be used and atomized liquid Fuel into the combustion chamber in appropriate directions insert, like inject or the like, like light, medium or heavy fuel oil, liquid Hydrocarbons or the like. However, it can also gaseous fuels or gases that Fuel particles such as coal dust or the like included, be provided and in this case it is particularly useful, the trap wall as a double wall or Form cavity wall. The cavity or the cavities, which is or are formed by this double wall, can then be used as a flow channel or channels Introducing the gaseous fuel or the Gas entrained fuel particles in the combustion chamber provide. This introduction can directly into the Openings in the trap for the primary gas jets or the primary gas nozzles and / or away from them Openings through one or more separate openings the catch wall may be provided. All of this is also flow and combustion technology in particular Cheap.

The ignition of the flame can be on any suitable Way, for example. By a constantly burning Pilot light.

The primary gas becomes the primary gas nozzles under pressure  promoted. This can preferably be done by means of at least a fan. It is particularly useful if that is due to the action of the primary gas jets medium sucked in an antechamber when flowing through the relevant openings of the catch wall in this Openings is accelerated by what is appropriate Taper these openings in the downstream Direction can take place.

The primary gas jets can preferably be in relative large distances next to each other in the combustion chamber be blown in.

The invention also enables combustion of the Blue flame fuel, which is particularly cheap is.

In the drawing, embodiments of the Invention shown. It shows

FIG. 1A, in a schematic sectional view of a device for combusting fuel in accordance with an embodiment of the invention,

Fig. 1B is an enlarged detail of the invention according to Fig. 1A,

Fig. 2 is a partial sectional view of Fig. 1A, taken along the section line 2-2 in enlarged representation,

Fig. 3 shows a detail of a device for combusting fuel in longitudinal section according to a further Ausführungsbei game of the invention,

Fig. 4 is a plan view of the outlet opening a primary gas according to one embodiment,

Fig. 5 shows a detail of a gas passage in longitudinal section according to a further embodiment of the invention,

Fig. 6 is a fragmentary plan view of a hollow trap wall according to another embodiment of the invention,

FIG. 7 shows a section through the catching wall according to FIG. 6, seen along the section line 7-7.

The device 10 for combusting fuel shown in FIG. 1A can be a boiler, a combustion chamber or the like. It has a housing 11 in which there is a large combustion chamber 12 , to which a flue gas outlet 13 ' connects at the top, which can, for example, continue to a chimney, chimney or the like.

The combustion chamber 12 is penetrated near its upper end by a tube 13 or a plurality of tubes through which a preferably liquid heat transfer fluid is passed for heating it. This heat transfer fluid can be, for example, water, oil, steam or the like.

In the lower half of the combustion chamber 12 projects at a distance above its bottom 14, a horizontal gas channel 15 , the peripheral wall of which is formed by a straight, preferably circular cylindrical tube 17 . This tube 17 is divided within the firebox 12 by two spaced vertical partition walls 16 and 25 into a pressure chamber 19 , an intermediate space 30 and a combustion chamber 20 . The intermediate wall 16 forms a catch wall which separates the intermediate space 30 which forms an antechamber in front of the combustion chamber 20 from this combustion chamber 20 . The combustion chamber 20 is a partial area of the combustion chamber 12 and the area outside the combustion chamber 20 is designated by 36 .

A fan 21 is connected to the upstream end of the pressure chamber 19 and serves to suck in primary gas containing oxygen, which may preferably be air, and conveys it into the pressure chamber 19 .

From this pressure chamber 19 , this primary gas can flow into the combustion chamber 20 through a plurality of primary gas nozzles 22 which are fixedly arranged in the preferably flat intermediate wall 25 at lateral distances from one another. In this exemplary embodiment, a ring of a total of six primary gas nozzles 22 is provided, which are arranged around the longitudinal axis of the straight gas channel 15 at the same central angle distances from one another and at the same radial distances from this longitudinal axis as shown in FIG. 2.

The catching wall 16 is solid here with an approximately constant thickness - for example it can be formed by a sheet metal - and runs perpendicular to the longitudinal axis of the gas channel 15 and is essentially flat, but can also have a different shape, for example completely flat, slightly curved be or have other suitable training, for example often also be a hollow wall.

The pressure chamber 19 is connected to the antechamber 25 and the combustion chamber 20 in a gas-conducting manner through the primary gas nozzles 22 . The peripheral wall of the gas channel 15 formed by the tube 17 is closed in this exemplary embodiment against the region 36 of the combustion chamber 12 surrounding it and outside of the housing 11 against the ambient atmosphere 38 , that is to say that the tube 17 has no openings on its periphery through which the area 36 of the combustion chamber or from the ambient atmosphere 38 of the Ge housing 11 gas could flow into the gas channel 15 .

In the pressure chamber 19 of the gas duct 15 , a fuel line 28 leads through the wall of the tube 17 , which is connected to a fuel atomizing nozzle 23 which is fixed in the middle in the intermediate wall 25 and in the collecting wall 16 and coaxially with them. This nozzle 23 protrudes with its head a little bit into the combustion chamber 20 of the gas channel 15 beyond the collecting wall 16 and the nozzle 23 projects with its head a little bit into the combustion chamber 20 of the gas channel 15 beyond the collecting wall 16 and this Nozzle 23 has atomizing means for atomizing the liquid fuel introduced into it at high pressure. As indicated by the dashed jets, the atomizing fuel is sprayed in jets directed obliquely to the longitudinal axis of the straight gas channel 15 in the direction of the primary gas jets blown into the combustion chamber 20 from the primary gas nozzles 22 . An ignition or pilot flame, not shown, can ignite the fuel-primary gas mixture in the combustion chamber and the fuel introduced through the nozzle 23 into the space 20 is then continuously burned until the fuel supply to the nozzle 23, for example for regulating or controlling the Thermal output of the device 10 temporarily, or to switch it off completely, is interrupted again, wherein the fan 21 can also be switched off if necessary. If the flame which can be generated by supplying fuel by means of the nozzle 23 is ignited by means of at least one pilot flame, this pilot flame can of course continue to burn during the interruption of the supply of fuel to the nozzle 23 or, if the boiler 10 is to be put completely out of operation, the at least one pilot flame can also be used be switched off. The fuel supply to the nozzle 23 , when it is switched on, can be constant, or variable fuel supply can also be provided.

It is also possible, inter alia, to design the fuel nozzle 23 as a two-substance nozzle, ie, to initiate through it the atomizing of the liquid fuel secondary gas in relation to the primary gas, but normally only in relatively small amounts. This secondary gas can preferably also be air and, in addition to the oxygen introduced into the combustion chamber by the primary gas, also enter oxygen into it, which then also participates in the combustion.

The fuel atomizing nozzle 23 is only schematically Darge and can have any suitable type, for example. Be a swirl atomizing nozzle or have other suitable training. Instead of such an atomizing nozzle, several atomizing nozzles may also be arranged on the collecting wall 16 at higher outputs.

A supply line 18 is connected to an opening in the peripheral wall of the antechamber 30 and serves to introduce flowable medium into this antechamber 30 , from which this medium can flow into the combustion chamber 20 together with the primary gas jets flowing out of the primary gas nozzles 22 . For this purpose, openings 29 are provided in the catch wall 16, which taper in a trumpet shape from their outlet openings 32 in the upstream direction to their upstream inlet openings 33 , as shown. These openings 29 can be rotationally symmetrical or also have another suitable shape or, in a manner not shown, can also be formed only by holes in a flat catch wall. In low stromaufwärtigem distance in front of each inlet port 33, the exit mouth 31 of the respective opening 29 is associated with primary gas 22nd However, these primary gas nozzles 22 may also protrude into the openings 29 or penetrate them.

Each primary gas nozzle 22 is arranged coaxially with the opening 29 assigned to it. The clear cross sections of the inlet mouth 32 and outlet mouth 33 of each opening 29 are larger than the clear cross section of the outlet mouth 35 of the associated primary gas nozzle 22nd Between each primary gas nozzle 22 and its associated opening 29 there is an annular annular gap which is a passage 29 into the combustion chamber 20 for the flowable medium which can be introduced into the antechamber 30 by means of the line 18 , so that this medium from this antechamber 30 into the combustion chamber 20 can flow. This medium can be, for example, gas containing coal dust, for example air containing coal dust, which coal dust is burned in the combustion chamber 12 , this coal dust already at least partially burning in the combustion chamber 20 of the gas channel 15 forming a region of the combustion chamber 12 . This medium can also be another medium, for example only air, post-combustion exhaust gas from the combustion chamber 12 or other flowable medium, preferably combustible or non-combustible gaseous medium or carrier gas which carries with it solid and / or liquid particles which cause combustion in the combustion chamber support or should be burned.

In this exemplary embodiment, a throttle and shut-off valve 44 is interposed in line 18 , which can be adjusted continuously or gradually between its maximum open position and its shut-off state by means of a motorized actuator 50 . The delivery of the medium is a valve 44 upstream flow machine 45, such as a pump, blower, or the like., But the support can also be supported from the primary gas jets or with omission of the flow machine 45 by the action of the primary gas jets carried out alone. In this exemplary embodiment, the line 8 opens into the ambient atmosphere 38 of the device 10 . However, it can also be connected to any supply line, for example to a return line branching off from the combustion chamber 12 or the smoke exhaust 13 ' for supplying flue gas into the combustion chamber 20 for post-combustion, or it can be connected to a supply line for other medium which is in the Combustion chamber is initiated.

In general, it is expedient to shut off or restrict or severely restrict the line by means of the valve 44 during the starting process of the device 10 , which can be provided automatically depending on the time and / or depending on the condition or manually.

It is also possible to provide manual or automatic adjustment of the valve 44 at operating temperatures of the device 10 , for example depending on fluctuations in air pressure, the power output of the device 10 or the like.

The starting process means starting up the device 11 from its cold state and starting it up until the operating temperature is reached. For this purpose, the actuator 50 can be adjusted by means of a control device 46 via the line of action 49 in this embodiment. A temperature sensor 47 arranged in the combustion chamber 12 is connected to this control device 46 and senses the respective internal temperature of the combustion chamber 12 at one point in its area 36 , ie outside the combustion chamber 20 . Since it is particularly expedient to facilitate the starting process, at least in an initial phase of the starting process, to shut off the valve 44 or throttle strongly, it can now be preferably provided for the starting process that the valve 44 depending on the temperature felt by the temperature sensor 47 during the described starting process is adjusted. For example, it can be provided that it is shut off when the device 10 is cold and remains shut off until its predetermined temperature, which it feels during an initial phase of the starting process, has risen to, for example, 100 to 200 ° C. and then can be provided be that with a further rise in temperature of the shut-off valve 44 is gradually and steadily opened more and more and is opened to a maximum at a pre-determined, felt combustion chamber temperature, which, for example, may be somewhat below normal operating temperatures or may also be in the operating temperature range. This makes the starting process better and easier. Automatic or manual adjustment of the valve 44 can serve to influence the operation of the device 10 at operating temperatures, for example to minimize the emission of pollutants, to control the power or the like.

Instead of controlling the valve 44 as a function of the combustion chamber temperature sensed by the sensor 47, it can also be provided that a timer 48 is switched on at the start of the starting process, which measures a predetermined period of time and then resets to zero by the beginning of the next starting process. As long as this time period runs from the start of the starting process, the control device 46 causes the valve 44 to be shut off in a predetermined manner or to be throttled constantly or variably as a function of time during this time period or to be shut off for a range of this time period and during the remaining range of this period is throttled constant or variable. When this period has elapsed, the shut-off valve 44 can then be opened further, preferably set to the maximum open position or to a predetermined constant throttle position or, for example, depending on the temperature of the fire sensor 47 felt, the room temperature can be adjusted automatically.

As mentioned, the turbomachine 45 can also be omitted, if necessary, since the primary gas jets in the antechamber 30 generate underpressure, which causes the medium to be sucked in through the line 18 into the antechamber 30 of this medium from the antechamber 30 , from where this medium also flows through the passages 43 through the action of the primary gas jets into the combustion chamber 20 .

The primary gas jets preferably flow out of the primary gas nozzles 22 at high speed. These primary gas nozzles 22 each have a trumpet-shaped inflow mouth and then run cylindrically up to the vicinity of the front end region, which tapers conically in the direction of flow.

These primary gas nozzles 22 can preferably be designed such that the cross sections of the primary gas jets flowing out of them are not circular, but rather have a non-circular, preferably wave-like or gear-like outline, in that the clear cross section of the primary gas nozzle 22 has a corresponding outline at its outlet opening. An embodiment of such a primary gas nozzle is shown in FIG. 4 in a top view of its gas outlet end face 31 having the outlet mouth 35 . The outline of the clear cross section at the outlet opening 35 has a serpentine corrugation here. The axial grooves of the peripheral wall of the clear interior of the nozzle 22 caused by this undulating course of the outline can extend over the axial length of the nozzle 22 or only begin inside the nozzle 22, for example, approximately in its middle and then continue to the outlet mouth 35 . As a result, the outer surface of the primary gas jet flowing out of the nozzle 22 is considerably enlarged, which has a favorable effect on the generation of strong backflows in the combustion chamber 20 and relatively short flame lengths. Specifically, the primary gas jets, due to their high velocities when flowing out of the primary gas nozzles 22, generate considerable pressure reductions which, in the combustion chamber 20 of the gas channel 15 , generate backflows, as indicated by the arrows, of the medium in it in the direction of the collecting wall 16 . These backflows practically lead to the trap wall 16 , since the pressure reduction generated by the primary gas jets in the combustion chamber 20 has a full effect on the trap wall 16 . As a result, the catching wall 16 acts as a flame holder, so that it can also be referred to as a flame holder wall and no other flame holders are required apart from it. It is also possible to have the outlet openings of the primary gas nozzles 22 flush with the catch wall or to have them open into depressions in the catch wall 16 .

Due to the backflows of the mixture burning in the combustion chamber 20 towards the trap wall 16 , which thus practically or can run as far as the trap wall, the combustion of the fuel is also improved, inter alia a higher degree of burnout is achieved and the pollutant emission is reduced. This device 10 is characterized by the structural simplicity of the gas channel 15 with primary gas nozzles 22 and catch wall 16 . The gas duct 15 can also be relatively short, as can the rest of the combustion chamber 36 , because the backflows also reduce the flame length.

FIG. 3 shows a longitudinal section of a gas duct 15 , which in the details not shown can correspond to the gas duct 15 according to FIG. 1.

The other details of the device 10 , not shown in FIG. 3, can also correspond to those of the device 10 according to FIG. 1.

The pressure chamber 19 of the gas channel 15 , in which the blower (not shown), which preferably feeds primary gas consisting of air, is likewise separated from an antechamber 30 upstream of the combustion chamber 20 by a preferably flat intermediate wall 25 . The primary gas nozzles 22 inserted into the partition wall 25 forming an end wall of the pressure chamber 19 protrude into this antechamber 30 until close to the trap wall 16 delimiting this antechamber 30 , which forms an intermediate wall between it and the combustion chamber 20 . Openings 29 tapering in a trumpet shape in the flow direction are arranged in this catch wall 16 and lead from the antechamber 30 into the combustion chamber 20 , so that the antechamber 30 is connected to the combustion chamber 20 in a fluid-conducting manner via these openings 29 . Each such opening 29 is arranged coaxially with a primary gas nozzle 22 located upstream from it. The smallest clear diameter of the opening 29 is larger than the cross section of the primary gas jet blown out of the relevant nozzle 22 through this opening 29 at the level of this opening 29 , so that this primary gas jet by induction from the anteroom 30 medium through the annular-shaped passages 43 between the primary gas nozzles 22 and the trap wall 16 and through the openings 29 into the combustion chamber 20 . In this medium is, in this particularly advantageous embodiment to the surrounding from the gas channel 15 part of the region 36 of the furnace 12 is sucked into the antechamber 30 through the effect of the primary gas jets flue gas. There is therefore a return of flue gas generated in the combustion chamber 12 from the area 36 of the combustion chamber 12 through the antechamber 30 into the combustion chamber 20 of the gas channel 15 , namely by the action of the primary gas jets and not by means of a flow machine 45 as in the exemplary embodiment according to FIG Fig. 1A.

As in the device according to FIG. 1A, the combustion chamber 20 of the gas channel 15 opens out into the region 36 of the combustion chamber 12 . This area 36 of the combustion chamber 12 is preferably larger, in particular substantially larger than the combustion chamber 20 of the gas channel 15, which also forms an area of the combustion chamber 12 . So that can be sucked in by the primary gas jets under pressure from the area 36 of the combustion chamber 12 in the antechamber 30, 30 openings 26 are arranged in the circumferential wall of the gas channel 15 , ie in the tube 17 of the gas channel at the level of the antechamber, which from the combustion chamber area 36 lead into the anteroom 30 . These openings 26 may be pushed in size than the gas passage 15 which is pushed short length of pipe to be over adjusted 27 to the circular tube 17 27 trained shift by one, said slider 27 to shut off these openings 25 through them manually or by an actuator or the like. can be. By axially moving the slide 27 , the return of flue gas can thus be shut off and optionally throttled variably, and the volume flow of the recirculated exhaust gas can thus be adjusted relative to the volume flow of the primary gas. The invention enables very strong dilution of the primary gas by recirculated flue gas, which allows extremely low pollutant emissions to be achieved. The flue gas recirculation means that further reductions in pollutant emissions can be achieved, and even extremely low pollutant emissions can be achieved.

Instead of forming the tube 17 of the gas channel 15 as cylindrical in the area of the combustion chamber 20, as shown, in many cases it can also have a different design, preferably over the entire length of the combustion chamber 20 or over at least a partial area of the combustion chamber 20 in the direction of its outlet opening, diverging into area 36 .

In this exemplary embodiment, the primary gas nozzles 22 arranged axially parallel to one another can be arranged, for example, in a ring as in FIG. 2, wherein they are also held in the intermediate wall 25 . For example, six primary gas nozzles can also be provided here, but their number can also be smaller or larger. Instead of a single ring, a plurality of rings of such smaller primary gas nozzles can also be provided, or else they can have any desired arrangement and distribution by means of which the desired effects of the primary gas jets are achieved.

It is also possible, in a manner not shown, to arrange these straight primary gas nozzles 22 in such a way that their blowing directions, ie the longitudinal axes of their primary gas channels, are inclined obliquely to the longitudinal axis of the combustion chamber 20 , in which case it is then expedient to also close the assigned openings 29 of the catching wall 16 tend that the respective primary gas nozzle 22 and the associated opening 29 of the catch wall 16 are arranged coaxially with each other. With such inclinations, all primary gas nozzles 22 can preferably be arranged with their jet directions diverging or converging and / or all can be inclined in the circumferential direction of the combustion chamber 20 in the same sense that a flow circulating about its longitudinal axis results in the combustion chamber.

A fuel atomizing nozzle 23 is in turn arranged in the middle of the collecting wall 16 , which preferably introduces liquid fuel into the combustion chamber 20 in the atomized state as jets 24 in directions inclined to the primary gas jets.

The primary gas conveyed by the blower (not shown) during operation flows out of the pressure ram 19 into the primary gas nozzles 22 and through them as primary gas jets at high speeds into the antechamber 30 at a short distance in front of the associated openings 29 of the collecting wall 16 and as free primary gas jets through these openings 29 into the combustion chamber 20 at high speed.

The cross sections of these primary gas jets in the openings 29 of the collecting wall 16 are smaller than the clear cross sections of these openings 29 , so that these primary gas jets suck in flue gas from the area 36 of the combustion chamber 12 through the openings 26 and the antechamber 30 into the combustion chamber 20 of the gas channel 15 which flows from the vestibule 30 through the passages 43 and the openings 29 into the combustion chamber 20 and is therefore only conveyed by the primary gas as in a jet pump. As a result, the primary gas is diluted by this flue gas flowing into the combustion chamber, wherein, as mentioned, very high dilutions, that is to say very high volume flows of the sucked-in flue gas, are possible and permissible and are also very advantageous because of the strong pollutant reduction that can be achieved thereby.

As a result of the strong backflows generated in the combustion chamber 20 of the gas channel 15 by the plurality of primary gas jets, which lead up to approximately the trap wall 16 , the flame roots of the flame can practically stick to the trap wall 16 and no separate flame holders are necessary, since the trap wall 16 causes the flame to be ignited in the combustion chamber 20 of the gas channel.

The combustion chamber 20 of the gas channel 15 is each so long that the backflows are reliably generated in it. However, the flame beginning in it can extend from this combustion chamber 20 into the remaining, larger area 36 of the combustion chamber 12 , preferably even quite far.

The primary gas nozzles 22 in the gas channel 15 according to FIG. 3 can also preferably be designed to generate primary gas jets with a non-circular cross section at the level of the outlet opening of the primary gas nozzles, since this further optimizes the combustion process and further reduces the pollutant emissions. For example, the outlet openings 35 of these nozzles 22 can also be designed the same or similar as shown in FIG. 4. This non-circular design of the outlet opening of the nozzle 22 allows, inter alia, the amount of smoke gas drawn in through the antechamber 30 to be increased and the backflow in the combustion chamber 20 to be influenced even more favorably. The length of the flame can also be shortened as a result.

In the exemplary embodiment according to FIG. 5, a short section from a gas channel 15 is shown, which is designed similar to that according to FIG. 3 and is part of a device for the continuous combustion of fuel, for example a device similar to that according to FIG. 1A. This gas channel 15 differs from that of FIG. 3 essentially in that the trap wall 16 , the anteroom 30 , in the flue gas from the area 36 of the combustion chamber 12 surrounding the gas channel 15 through the primary gas jets through openings 26 in the peripheral wall 17 of the Gas channel 15 can also be sucked in, separates from the combustion chamber 20 of the gas channel 15 , here is designed as a hollow wall or double wall. This design can be used to introduce gaseous fuel or fuel particles carried by gas, in particular coal dust, into the combustion chamber 20 of the gas channel 15 in a particularly simple manner. For this purpose, a fuel feed line 28 ' for flowable fuel, which is introduced under pressure and through openings 39 provided in the openings 29 for the primary gas jets of the collecting wall 16 and / or through or at or near these openings 20 , opens into the cavity 37 of the collecting wall 16 other outlet openings in the collecting wall 16 flow from it into the combustion chamber 20 together with the primary gas jets and the recirculated flue gas. In the middle of this catch wall 16 there is also a further outlet opening 41 leading into the combustion chamber 20 for the fuel. A plurality of such fuel outflow openings 41 can also be provided at a distance from the openings 29 for the primary gas jets or only such outlet openings for the fuel can be provided at a distance from the openings 29 of the collecting wall 16 for the primary gas jets. An embodiment of FIGS. 6 and 7 where the partial shown hollow trap wall 16 immediately adjacent has the downstream edge of each of its openings 29, only one of which is shown here only in the combustion chamber 20 adjacent surface 40 of outlet openings 39 'for fuel which are formed as small holes arranged in a ring, which enclose the opening 29 at a short distance.

Provision can also be made for the mixture of the combustion chamber 20 to be recirculated through the or at least one cavity of the hollow collecting wall 16 through the primary gas jets. For example, in Fig. 5 the fuel feed line 28 'can be omitted and the relevant opening of the cavity 37 can be closed for this purpose. The primary gas jets then suck in mixture from the combustion chamber 20 through the cavity 37 of the trap wall 16 , which flows into the cavity 37 through the central opening 41 and flows out again through the annular gaps 39 and flows back into the combustion chamber. It can also be provided here that the cavity 37 of the trap wall 16 is divided into areas which are sealed off from one another in a fluid-tight manner, from which at least one area of the recirculating mixture flows through the combustion chamber and at least one other area of fuel flows through it to introduce it into the combustion chamber.

Instead of arranging the primary gas nozzles 22 upstream of the openings 29 of the collecting wall 16 , as in FIGS . 2, 3 and 5, provision can also be made for them to protrude into these openings 29 or for them to protrude through these openings 29 , in which the latter case can then reach a short distance into the combustion chamber, as indicated by two-dotted lines in FIGS. 3 and 5 at 22 ' and 22'' , these nozzles 22', 22 '' from the walls of the Openings 29 are spaced apart so that here the passages 43 are present for medium sucked in from the antechamber 30 into the combustion chamber 20 by the primary gas jets.

It is also conceivable to provide that flue gas sucked in by the primary gas jets from the environment 36 of the gas channel 15 flows directly into the combustion chamber 20 , for example in the device according to FIG. 1A for this purpose in the pipe 17 near the combustion chamber 20 the catch wall 16 or adjacent to it at least one inlet opening for flue gas is provided. Or in some cases it can also be provided that the flue gas drawn in from the anteroom 30 by the primary gas jets into the combustion chamber 20 from the area 36 of the combustion chamber 12 flows through at least in part at least one opening in the collecting wall 16 which is not flowed through by primary gas.

Usually it is sufficient for the invention Facilities if they have a single one Have combustion chamber. For very large facilities However, the facility may also have several fireboxes have in which, if desired, independent fuel from each other or simultaneously or in parallel can be burned to generate heat.

It is also possible to provide that the passages 43 can be variably throttled and / or shut off, for example by means of sleeves arranged on the primary gas nozzles 22 so as to be slidable coaxially and firmly connected to one another, the flanges of which form annular disks which are spaced from a maximum open position in front of the catch wall 16, preferably up to the abutment against the catch wall 16, manually or by means of an actuator, it can be moved axially and back again and adjusted in any axial position.

It is also conceivable in some cases that at least one passage for medium flowing from the antechamber 30 into the combustion chamber 20 is present only between a primary gas nozzle or a partial number of the total primary gas nozzles and the trap wall and accordingly the at least one other primary gas nozzle is spaced in the catch wall 16 is inserted so that there is no passage for medium between it and the catch wall.

Claims (31)

1. Method for burning fuel using oxygen-containing primary gas which is conveyed in a combustion chamber, the primary gas being introduced into a combustion chamber of a gas duct, into which fuel is also introduced and in which combustion chamber the combustion of the fuel begins and takes place at least partially, characterized in that the primary gas is blown into this combustion chamber by means of a plurality of primary gas nozzles in a plurality of primary gas jets in a direction leading away from a trap wall delimiting it on the input side in such a way that the primary gas jets in the combustion chamber of the gas channel are directed backflows of the gas-fuel mixture which is in combustion towards the trap wall generate, and that between at least one primary gas nozzle and the trap wall there is at least one passage through which medium can flow into the combustion chamber. 2. The method according to claim 1, characterized in that that between at least two primary gas nozzles and the Trap, preferably between all Primary gas nozzles and the trap wall openings for Medium are present in the combustion chamber  this can flow through. 3. The method according to claim 1 or 2, characterized characterized in that a plurality in the trap wall of openings are provided through which the primary gas jets are blown into the combustion chamber be, the cross sections of the Primary gas jets smaller in these openings, preferably considerably smaller than the smallest are clear cross sections of these openings. 4. The method according to claim 1 or 2, characterized characterized in that the primary gas jets in height the trap wall or downstream of it Primary gas nozzles are blown out. 5. The method according to any one of the preceding claims, characterized in that the volume flow of the Medium that passes through the passage or passages between the primary gas nozzle (s) and the trap wall can flow into the combustion chamber, variable can be throttled and / or shut off, preferably automatically depending on the time and / or the temperature of the furnace. 6. The method according to any one of the preceding claims, characterized in that during the respective Starting process of the volume flow through the Passages between the primary gas nozzles and the Catch wall in the medium flowing into the combustion chamber relative to the size of this volume flow  Operating temperatures at least in one Initial phase of the starting process reduced, preferably the supply of this medium is shut off being, under the start-up process the startup of the firebox from its cold state Operating temperature is understood. 7. The method according to any one of the preceding claims, characterized in that the combustion chamber through the entrance wall separated from the vestibule is in which vestibule flowable medium sucked in by the action of the primary gas jets and from it by the action of Primary gas jets conveyed into the combustion chamber which medium it is preferably from the firebox Flue gas can act. 8. The method according to any one of the preceding claims, characterized in that at least one Primary gas jet, preferably each primary gas jet into the combustion chamber by one assigned to it flows in separate opening of the trap, through which so no other primary gas jet flows. 9. The method according to any one of the preceding claims, characterized in that by at least one Opening the trap wall at least two Primary gas jets into the combustion chamber of the gas channel flow in.   10. The method according to any one of the preceding claims, characterized in that at least two Primary gas jets, preferably all Primary gas jets in the combustion chamber to each other are blown in parallel, preferably parallel to the longitudinal axis of the combustion chamber. 11. The method according to any one of the preceding claims, characterized in that at least two Primary gas jets into the combustion chamber with its Blown in along the longitudinal axis are, preferably at least two, preferably all of the inclined blowing directions of the Primary gas nozzles diverge from each other or converge. 12. The method according to any one of the preceding claims, characterized in that between at least a primary gas nozzle and the trap wall at least an annular gap-shaped passage for medium is present, preferably between all Primary gas nozzles and the collecting wall annular gap Passages are available. 13. The method according to any one of the preceding claims, characterized in that from at least one for blowing out primary gas Primary gas nozzle several primary gas jets in the Combustion chamber are blown.   14. The method according to any one of the preceding claims, characterized in that from at least one for blowing out primary gas Primary gas nozzle, preferably from all of these Nozzles, one single jet of primary gas each Combustion chamber is blown in. 15. The method according to any one of the preceding claims, characterized in that the openings of the Catch wall, through the primary gas jets and / or out flow medium into the combustion chamber can taper in the downstream direction. 16. The method according to any one of the preceding claims, characterized in that the cross sections of the blown out of the primary gas nozzles Primary gas jets at the level of the outlet openings the primary gas nozzles are out of round, preferably roughly gear or wavy outlines exhibit. 17. The method according to any one of the preceding claims, characterized in that all the fuel is introduced into the combustion chamber of the gas channel or that except in the combustion chamber of the gas channel still fuel in the rest of the firebox can be initiated. 18. The method according to any one of the preceding claims, characterized in that at least two Primary gas jets, preferably all Primary gas jets through separate openings in the  Catch wall through and / or by means of the distance primary gas nozzles arranged in the Combustion chamber are blown. 19. The method according to any one of the preceding claims, characterized in that in the combustion chamber of the Gas channel liquid fuel, preferably in atomized state is initiated. 20. The method according to any one of claims 1-8, characterized characterized in that in the combustion chamber of the Gas channel gaseous fuel initiated is preferably by at least one Cavity of the trap wall into the combustion chamber is initiated. 21. The method according to any one of claims 1-19, characterized in that in the combustion chamber of the Gas channel solid contained in a gas Fuel particles, preferably coal dust, can be initiated, preferably by at least one cavity in the trap wall through. 22. Device for performing the method according to one of the preceding claims, characterized in that it has a combustion chamber ( 12 ) which is at least partially formed by a combustion chamber ( 20 ) of a gas channel ( 15 ), which combustion chamber ( 20 ) of the gas channel on the input side is limited by a flame retaining wall ( 16 ) that in this combustion chamber ( 20 ) from a blower ( 21 ) or the like. Primary gas conveyed by means of primary gas nozzles ( 22 ) can be introduced in several jets, the primary gas nozzles ( 22 ) relative to the collecting wall ( 16 ) are arranged so that there are backflows in the combustion chamber of the gas channel caused by the primary gas jets in the direction of the trap wall and that at least one passage ( 43 ) for flowable medium between the trap wall ( 16 ) and at least one primary gas nozzle ( 22 ) can flow into the combustion chamber, is present, preferably between all primary gas nozzles and the trap openings for Med are available. 23. The device according to claim 22, characterized in that the collecting wall ( 16 ) is an intermediate wall of the combustion chamber ( 20 ) and an upstream anteroom ( 30 ), in which anteroom flowable medium, preferably from the combustion chamber, flue gas, can be introduced and through the Openings ( 29 ) between the primary gas nozzles ( 22 ) and the collecting wall ( 16 ) can be passed through into the combustion chamber. 24. Device according to claim 22 or 23, characterized characterized in that the fluid medium sucked in by the primary gas jets and into the Combustion chamber is promoted. 25. Device according to one of claims 22 to 24, characterized in that the primary gas nozzles ( 22 ) are arranged at a distance from one another preferably forming at least one ring. 26. Device according to one of claims 22 to 25, characterized in that the outlet openings ( 35 ) of the primary gas nozzles ( 22 ) are arranged at a short downstream distance in front of the openings ( 29 ) of the collecting wall ( 16 ) assigned to them, and that these openings ( 29 ) of the catch wall preferably have clear cross sections which are considerably larger than the clear cross sections of the outlet openings ( 35 ) of the primary gas nozzles ( 22 ). 27. Device according to one of claims 22 to 25, characterized in that the primary gas nozzles ( 22 ) protrude into or penetrate into the openings ( 29 ) of the catch wall ( 16 ) assigned to them. 28. Device according to one of claims 22 to 27, characterized in that in the catch wall ( 16 ) at least one fuel nozzle ( 23 ) for introducing fuel into the combustion chamber ( 20 ) of the gas channel ( 15 ) is arranged. 29. Device according to one of claims 22 to 28, characterized in that the catch wall ( 16 ) is a cavity wall or double wall, the at least one cavity as a fuel feed line for introducing fuel into the combustion chamber ( 20 ) of the gas channel and / or as a flow-through space for at least one recirculating flow, which, caused by at least one primary gas jet, flows from the combustion chamber into a cavity of the trap wall and flows out of it back into the combustion chamber. 30. Device according to one of claims 22 to 29, characterized in that it comprises throttling means and / or shut-off means ( 27; 44 ) for throttling and / or shutting off the passages ( 43 ) between the primary gas nozzles ( 22 ) and the catching wall ( 16 ) inflowing medium and / or these passages. 31. Device according to one of claims 22 to 30, characterized in that it is a heat generator, preferably a boiler ( 10 ).