DE102005061298B4 - Fluidized bed furnace - Google Patents

Abstract

Fluidized bed furnace (10) comprising mixing and incinerating a fluidized medium and combustible matter containing incombustible matter having a density higher than that of the fluidized medium, comprising:
- an air distribution device (14, 15, 15a, 15b) disposed on a furnace bed (12) for introducing fluidizing air for fluidizing the fluidized medium;
An incombustible discharge port trench (20) disposed in the center of the furnace bed and having an inclined portion (16) and an exhaust chute (17) for discharging the incombustible matter, the inclined portion (16) being from an end of the exhaust port trench (20) for incombustible materials extending obliquely to the center or to a side and wherein the outlet chute (17) at the lower end of the inclined portion (16) on the lower side of the Auslassöffnungsgrabens (20) and connected to an exit for incombustible materials ;
- A plurality of auxiliary nozzles (18, 18 a, 18 b) disposed on inner sides (15 a) of the Auslassöffnungsgrabens and facing each other, ...

Description

(1) Field of the invention

The Invention relates to fluidized bed furnaces. In doing so Mixed waste and a brought into the fluid state medium and burned, especially in fluidized bed furnaces with a mechanism for removing combustible waste incombustible substances.

(2) Description of the Related Art

traditionally, Waste becomes like urban Waste, liquid waste & sludge as well Industrial waste burned by a fluidized bed furnace. A fluidized bed furnace burns the waste by the heat energy of the fluidized medium when the highly heated, medium displaced by air into the fluid state from the bottom of the bed body is introduced, wherein the medium is in the fluid state and contact with the waste is made. A fluidized bed furnace shows an advantage in that it hardly causes functional failures in the device comes because no local high temperature, resulting in a uniform and stable burning process is relieved.

however becomes even and Stable burning due to incombustible substances such as pipes, tiles as well as pebbles, stones and glasses in the waste that has accumulated in the waste facility, causing failures and malfunctions occur in the oven.

hereupon In order to solve the above problem, various fluid bed ovens with non-combustible outlets were used Substances disclosed in a part of the fluid bed and in practical Brought use.

For example, this reveals JP 51-109669 U (1976) oblique rectification plates at the bottom of the waste incinerator body. The incombustible matter is blown out of outlet pipes existing at the lower edges of the rectification plates. More specifically, the incombustible matters are sifted by a wind sifter produced by a wind blown from the lower parts of the exhaust pipes, and they are discharged by a screw conveyor to the outside of the refuse incinerator.

However, that shows JP 51-109669 U (1976) has the disadvantage that the fluidized medium (sand) is separated from the incombustible materials by the injected air and collects in the outlet tubes, causing them to become clogged. Further, there is another disadvantage in that the rectifying means are complicated in construction and they may be closed by the incombustible matter.

Further, the JP 4-208 304 A (1992) an incombustible discharge device disposed in the central recess of the continuously sloping bed, the non-incinerable discharge device being defined by its width and area. However, there is a drawback that a massive fluid-state medium (sand) should be ejected when the bed is large in size, thereby increasing the heat loss.

Further, the JP 63-271016 A several wind boxes in the lower part of the bed. More specifically, an outlet for incombustible substances is present at the bottom of the bed. The amount of air to fluidize the sand gradually decreases toward the center of the valley.

Further, the JP 4-217 708 A Air supply ducts in three or more windboxes with flow control valves in a bed with an air distribution panel sloping downwardly and an incombustible outlet in the slanted center of the bed.

However, it persists JP 63-271016 A and JP 4-217 708 A a disadvantage in that the movement of the incombustible materials may possibly be prevented when the sand flow at the outlet is low and an area without flow is created between it and the wind boxes. On the other hand, if the area is to be taken away without river, massive sand should be expelled, whereby the heat loss increases greatly.

Furthermore, this discloses JP 4-122926 U (1992) Air nozzles on the wall near the inlet of the outlet, thereby destroying or suppressing the area without flow at the inlet of the outlet. Although it is possible to expel the incombustible substances that always sink to the bottom of the bed, that shows JP 4-122926 U (1992) have the disadvantage that incombustible materials such as conduits and meshes, which begin to sink at a certain density in the fluidized layer, may remain if the flow direction and the velocity of the sand are not adjusted to those of the incombustible materials.

Further, the JP 9-236227 A (1997) Air distribution devices for circulating the air so that the incombustible materials flow around the outlet to expel them. However, the shows JP 9-236227 A (1997) an after Part in that massive non-combustible substances fall down into the outlet when the air circulation is too strong. As a result, the outlet may be closed. Further, there is another disadvantage in that the construction and control mechanism of the waste incinerator are complicated because the air circulation should be generated under optimum conditions of the air velocity, the air ratio and the combustion temperature in order to maintain the optimum combustion and suppress the generation of harmful materials ,

The explained above different conventional fluidized bed furnaces should solve the following problems if incombustible substances evenly with minimal heat loss are to be expelled.

The Problems lie in the following: (1) The movement of the incombustible Substances are prevented when near the outlet the area forms without flow; (2) the heat loss increases when a solid fluidized medium increases is ejected to the formation of the area without flow too prevent; (3) the outlet is closed if uneven and aggregated incombustible substances are expelled; (4) the air circulation becomes Hardly controlled by a construction in which forcibly recirculated air is generated to expel incombustible matter, and further massive incombustible substances fall into the outlet when the air circulation is excessive; (5) non-combustible materials such as wires and meshes that fluidize at a certain density in the Begin to sink layer, are difficult to eject, if not the flow direction and the speed of the sand on those of the incombustible Substances are adjusted.

OBJECT OF THE INVENTION

It It is an object of the invention to provide fluid bed furnaces that are combustible Eject waste materials evenly with minimal heat loss can.

solution the task

These Task is solved by those in the independent claims defined fluid bed ovens.

Further preferred features are described in the dependent claims.

More accurate said to be the fluidized bed furnace according to the first Example of the invention, a fluidized state medium and combustible substances that are non-combustible substances with a density above that contained in the fluid state medium, mixed and burned.

Of the Fluidized bed furnace according to the first Example is provided with: an air distribution device, which is arranged on a furnace bed, to introduce fluidizing air; an outlet opening trench for incombustible Substances, which is placed in the center of the furnace bed to the incombustible Expel substances; an outlet chute for incombustible substances which are connected to the outlet opening trench via a bevel Section of the trench is connected, by at least one end of the ditch at an angle goes down; one or more auxiliary nozzles, facing each other are arranged on insides of the trench to two ways of auxiliary air to initiate in the oblique Section and the slide are initiated; and flow rate controls for controlling the flow rates of the two paths of auxiliary air.

At the Fluidized bed furnace In the first example, the airspeed is above that Oven bed larger than the above the oblique Section that is larger than the above Chute is what by controlling the flow rates of fluidizing air and the two ways of auxiliary air takes place, hence the incombustible Substances are collected in the chute, which is based on the density difference between the fluidized medium and the incombustible materials he follows.

According to the first Example, where the air velocity above the fluidized bed is greater than the above bevel Section is larger than the above Slide is, the incombustible substances are based on the Air speed difference and a density difference between the fluidized medium and the incombustible materials safely in collected the slide.

Further be, according to the first Example, the incombustible substances in the non-flammable chute collected without the furnace bed is beveled, or without training (as with the conventional Technique) of any solid air circulation that controls the movement of the fluidized medium dominates. Accordingly, the furnace construction and the associated one Control mechanism simplified. Furthermore, the education of the prevents unfluidized area, causing the incombustible substances be ejected evenly. Furthermore, the heat loss minimal, since it is not necessary, a massive fluidized Eject medium.

Further, according to the first example, the air velocities corresponding to the area in the furnace are made different, that is, the downward flow is formed above the outlet port while the fluidized medium is above the inclined portion and fluidized around the furnace bed around the two sides of the opening trench. Therefore, the incombustible matters are properly mixed with the fluidized medium, the combustion state is properly maintained, and the incombustible materials are uniformly ejected by the downward flow from above the discharge port.

At the Fluidized bed furnace of the second example of the invention is the fluidized bed to both sides ditch flat. According to the second For example, it is not necessary to bevel the fluidized bed (as in the conventional one Technology), which simplifies the furnace construction.

At the Fluidized bed furnace In the third example, the auxiliary nozzles blow the auxiliary air down with respect to the horizontal direction, thereby ejecting the to promote incombustible substances.

According to the third Example is the above-mentioned down-stream design encouraged whereby the formation of the non-fluidized area around the outlet opening around is prevented and the incombustible substances are ejected evenly.

At the Fluidized bed furnace of the third example of the invention become a fluidized Medium and combustible substances containing non-combustible substances with a density above the of the fluidized medium, mixed and burned. Of the Fliessbettofen the fourth example is provided with the following: an air distribution device, which is arranged on a furnace bed, fluidizing air for fluidizing the fluidized medium initiate; an outlet for incombustible Substances, which is placed in the center of the furnace bed to the incombustible To eject substances, wherein the furnace bed surrounding the outlet opening flat is; an outlet chute for Incombustible substances that are connected to the outlet for incombustible substances is; one or more auxiliary nozzles, facing each other on insides of the opening are arranged to introduce auxiliary air, which is introduced into the chute; and flow rate controls for controlling the flow rates of the auxiliary air. In the fluidized bed furnace of the fourth example, the auxiliary air surge of the auxiliary nozzles the expulsion of the incombustible substances.

It It should be noted that the auxiliary nozzles are symmetrical or asymmetrical are arranged. According to In the fourth example, the auxiliary nozzles blow the auxiliary air down in terms of horizontal direction to the formation of the downward flow to promote, around the formation of the non-fluidized area around the outlet opening to prevent. Thus, the incombustible substances are ejected uniformly.

At the invention Fluid bed furnace is the air velocity above the opening surrounding it Oven bed bigger as the over the chute, which by controlling the flow rates of fluidizing air and the auxiliary air takes place, whereby the incombustible substances in the chute will be collected, indicating the density difference between the fluidized medium and the incombustible substances takes place. According to The invention is the combustion state of the combustible materials suitably maintained, and become the incombustible substances evenly pushed out.

Further it is preferred that the jet lengths of the auxiliary air flow of the auxiliary nozzles be adjusted in such a way that the beam is not the center the opening reached. According to In the sixth example, the incombustible substances are compared with safely ejected into small densities without being disturbed by the auxiliary air.

It is also preferred that the auxiliary nozzles along the vertical Direction to be attached to the inside of the trench and the Auxiliary air from exhaust holes blown out, which is attached to the front ends of the auxiliary nozzles are, with a suitable nozzle design is available.

According to the invention is the uniform ejection the incombustible substances thereby facilitated that a small Amount of auxiliary air is introduced and the incombustible substances and the fluidized medium are mixed. Furthermore, the heat loss minimized, and there is a minimal expulsion of the fluidized Medium achieved. As a result, the construction and the control mechanism of the fluidized bed furnace compared to the conventional technique simplified.

Summarized said to be, according to the Invention, wherein the flow rates of the auxiliary air and the fluidizing air be controlled in such a way that all air speeds in each part of the furnace are different, the incombustible substances according to the airspeed differences and the density difference in the incombustible materials collected safely in the outlet chute. In the invention, it is not necessary to form the furnace bed obliquely. Furthermore, it is not necessary under the flow control of the air boxes blown air an air circulation train. So are the furnace construction and the associated control mechanism simplified.

Further is, according to the invention, prevents the formation of the non-fluidized area, thereby the incombustible substances are ejected evenly. Furthermore, it is not necessary to use a massive fluidized medium eject, whereby the minimum heat loss is achieved.

BRIEF DESCRIPTION OF THE DRAWINGS

1A Fig. 10 is a plan view of the fluidized bed furnace of Embodiment 1 of the invention. 1B is an exemplary sectional view taken along the line XX in the 1A , 1C is another exemplary sectional view taken along the line XX in the 1A , 1D is a sectional view taken along the line YY in the 1A ,

2 is a schematic view of the flat bed fluid bed furnace.

3 is a side view of an exemplary auxiliary nozzle.

4 is a schematic view of a first exemplary fluid bed furnace based on the embodiment 1 with a sloping bed, as shown in the 1C is shown.

5A FIG. 10 is a plan view of a second exemplary fluidized bed furnace based on Embodiment 1. FIG. 5B is a sectional view taken along the line Y'-Y 'in the 5A ,

6A FIG. 10 is a plan view of the flat bed type fluid bed furnace of Embodiment 2 of the invention. FIG. 6B is a sectional view along the line X'-X 'in the 6A , 6C FIG. 10 is a plan view of the inclined bed type fluid bed oven according to a comparative example. FIG. 6D is a sectional view taken along the line X '' - X '' in the 6C ,

7 is a schematic view of the in the 6A and the 6B shown incinerator.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

Now Preferred embodiments of the Invention explained with reference to the drawings. It It should be noted that the invention is not limited to specifically described sizes, Materials and relative arrangements, etc., in terms of construction elements, limited is.

Generally said burns the inventive incinerator mainly combustible substances as usual Waste, industrial waste, sewage and sewage sludge that contain incombustible substances whose density is greater than that of the fluidized Medium is like pipes, tiles & pebbles, stones, glasses, tires and lumber waste.

embodiment 1

The 1 shows a fluidized bed furnace of the embodiment 1, and the 2 FIG. 11 is a schematic view of the flat bed waste incinerator as shown in FIG 1 shown.

First, with reference to the 2 around the overall structure of the fluid bed furnace. A furnace body 11 of a (fluid bed) furnace 10 is of rectangular or cylindrical shape (in the 2 not shown). The oven 10 has one at the bottom of the furnace body 11 trained oven bed 12 , At the oven bed 12 are horizontally mounted air distribution plates available. Furthermore, under the Luftverteilplatten wind, air boxes 14 for temporarily accumulating the air to fluidize the medium (eg sand). The wind boxes 14 are by vertical partition plates 15a and 15b divided into several sub-chambers. As it is in the 1 is shown are several air nozzles (air distribution nozzle) 13 present at the air distribution plates. The air is introduced upwardly from the air distribution nozzles to fluidize the medium (eg, sand) and the waste over the air distribution plates. the air flow rate is through the in the wind boxes 14 introduced amount of air determined, the amount of air by unillustrated air supply pipes, not shown flow control valves, etc. is controlled. The air volume can be for each of the air boxes 14 be the same, or it may be different for each air box using multiple airflow control mechanisms.

Further, in the flat section, in the center of the furnace bed 12 a trench-shaped outlet opening / outlet opening trench 20 designed for incombustible materials. With the end of the outlet opening 20 for incombustible substances is an outlet chute 17 for incombustible substances over a sloping section 16 connected. Here are, preferably under the outlet chute 17 , a screw conveyor for transporting the incombustible matter and the fluidized medium, a magnetic selection device for separating the incombustible matter from the fluidized medium, a vibrating screen or a classifying device for classifying the fluidized medium. Further, it is preferable to circulate means for returning the separated fluidized medium back into the furnace body 11 to install.

On the inside of the outlet opening 20 for incombustible substances are several auxiliary nozzles 18 present at a predetermined distance along the longitudinal direction of the (outlet) opening 20 are present, as it is in the 1A and the 1D is shown to thereby inject auxiliary air to assist the expulsion of the incombustible matter.

As it is in 1A . 1D . 5A and 5B are shown, the auxiliary air is divided in more than two ways, thereby in an auxiliary nozzle 18a in the sloping area of the opening 20 positio and an auxiliary nozzle 18b to be initiated at the outlet chute 17 is positioned for incombustible substances. This will be the flow controls for the nozzles 18a and 18b executed differently from each other.

As it is in the 3 is shown, has the auxiliary nozzle 18 about a rejuvenation 18c for forming an exhaust hole 18d in the lower part of the same. The auxiliary air is preferably not horizontal but by 10 deg. up to 45 deg. ejected down.

The air velocity in the furnace body 11 gets through by the air / auxiliary nozzles 13 introduced amount of air for introducing the air for fluidizing the medium and the amount of air controlled by the auxiliary nozzles 18a and 18b is initiated.

Specifically, the speed of air is above the furnace bed 12 and on both sides of the outlet opening 20 for non-combustible substances by those of the auxiliary nozzles 13 initiated amount of air controlled. The speed of air over the sloping sections of the opening 20 gets through by the auxiliary nozzle 18a Air flow rate is controlled while the speed of air over the exhaust chute 17 for non-combustible substances by those of the auxiliary nozzle 18b initiated amount of air is controlled.

The air speed is above the oven bed 12 bigger than those over the sloping sections of the opening 20 bigger than the ones above the outlet chute 17 for incombustible substances. Further, preferably, the air velocity over the sloped portions is about 90% of that above the furnace bed 12 ,

This will increase the speed of the air over the oven bed 12 and the inclined portions are controlled in such a manner that the fluidized medium and the incombustible matter are fluidized while the velocity of the air over the discharge chute 17 for incombustible materials is controlled in such a way that a downward flow of the fluidized medium is formed.

Corresponding the airspeed differences and the density differences between the fluidized medium and the incombustible materials the incombustible substances safely in the outlet chute for incombustible Collected substances. Furthermore, according to the flow control explained above, the fluidized medium is properly mixed and fluidized to thereby to properly maintain the combustion state. So be the incombustible matter through the downstream of the fluidized Medium evenly pushed out.

According to the embodiment 1, it is not necessary to form a conventional air circulation, which controls the movement of the fluidized medium. Therefore are the furnace construction and the associated control mechanism simplified, and above In addition, the incombustible substances are safe in the outlet chute collected.

Further become a first and a second application based on the embodiment 1 explained.

First, with reference to the 4 , the first exemplary application of the fluidized bed furnace based on the embodiment 1 with inclined bed, as in 1C illustrated, explained.

As it is in the 4 is shown, is the oven bed 12 slanted down to thereby the opposing walls of the furnace body 11 form towards the center, the outlet opening 20 is formed for incombustible substances in the center of the recess. Furthermore, as it is in the 1C is shown, several auxiliary nozzles 18 facing each other in the outlet opening 20 arranged for incombustible substances, the oblique sections 16 in the trench from the ends of the outlet opening 20 for incombustible substances are available, similar to the in the 2 illustrated furnace bed 12 , and beyond that is the outlet chute 17 for incombustible materials with the central portion of the sloping oven bed 12 connected.

The sloping oven bed 12 is particularly useful when more incombustible materials with larger densities, which are difficult to fluidize the air, are included.

Next, referring to the 5A , the second exemplary application of the fluidized bed furnace based on the embodiment 1 explained. The 5A is a top view of the oven bed. The 5B is a sectional view taken along the line Y'-Y 'in the 5A , In this case, the oven bed can be flat or bevelled.

As it is in the 58 is shown, is the outlet opening 20 formed for incombustible substances in the center of the recess. Further, an oblique section 16 present from one end of the opening 20 to the other of which runs obliquely. The outlet chute 17 For incombustible substances is with the bottom of the sloping section 16 ie the other end of the opening 20 , connected. Similar to the first exemplary application are multiple auxiliary nozzles 18 opposite each other in the outlet opening 20 arranged for incombustible substances.

Here, in the first and second exemplary applications, the incombustible differences are controlled, and the auxiliary air is supplied from the auxiliary nozzle 18 ejected down.

embodiment 2

The 6A FIG. 10 is a plan view of the flat bed type fluid bed oven according to Embodiment 2 of the invention. FIG. The 6B is a sectional view along the line X'-X 'in the 6A , The 6C FIG. 10 is a plan view of the oblique bed type fluid bed oven according to a comparative example. FIG. The 6B is a sectional view taken along the line X'-X in the 6C , The 7 is a schematic view of the in the 6A and 6B shown incinerator.

With reference to the 7 becomes the overall structure of the fluid bed furnace 10 briefly explained. The furnace body 11 of the fluid bed oven 10 is of square or unrepresented cylindrical shape. The oven 10 has one at the bottom of the furnace body 11 trained oven bed 12 , At the oven bed 12 are horizontally arranged air distribution plates (no reference numeral is given, however, substantially and substantially becomes the top of the (oven) bed 12 With reference to the (air / auxiliary) nozzles 13 are available) available. Furthermore, under the Luftverteilplatten air boxes 14 for temporarily accumulating the air to fluidize the medium (eg, sand). The wind boxes 14 are by vertical partition plates 15 divided into several sub-chambers. This can be the kiln bed 12 be flat or sloping.

In the air distribution plates are several air nozzles (air distribution nozzles) 13 educated. The air is introduced upwardly from the air distribution plates to fluidize the medium and the waste above them. The air flow rate is through the in the wind boxes 14 initiated air quantity determined.

Further, in the center of the oven bed 12 an outlet opening 20 incombustible material, which may be circular, square, rectangular or of any other shape, and is integral with the downwardly extending discharge chute 19 connected for incombustible substances.

On the inside of the outlet / outlet 20 for incombustible substances are several auxiliary nozzles 18 present, which are arranged at a predetermined distance. The flow rate of the auxiliary nozzle 18 introduced auxiliary air is controlled by a single flow control mechanism.

The auxiliary air is expelled downwards, as it is in the 3 is shown.

The flow rates of the air for fluidizing the fluidized medium and the incombustible matter and the auxiliary air are controlled in such a manner that the air velocity over the (outlet) chute 19 smaller than the one above the oven bed 12 is. According to the speed difference and the density differences between the fluidized medium and the incombustible matter, the incombustible matter in the chute becomes 19 collected. Further, the downward flow of the fluidized medium, which by the downward flow promotes that of the auxiliary nozzles 18 ejected auxiliary air is generated, the ejection of the incombustible substances.

Further, it is preferable that the jet length of the auxiliary nozzles 18 adjusted auxiliary air, thereby forming a Be rich, in which the jet stream, the center of the opening 20 not reached. According to the steel length adjustment, incombustible materials with small densities can be used from the center of the opening 20 safely blown out without being obstructed by the auxiliary air.

Claims (6)

Fluid bed furnace ( 10 ), in which a fluidized medium and combustible substances containing incombustible substances with a density above that of the fluidized medium, mixed and burned, comprising: - an air distribution device ( 14 . 15 . 15a . 15b ) attached to a kiln bed ( 12 ) is arranged to introduce fluidizing air for fluidizing the fluidized medium; - an outlet opening trench ( 20 ) for incombustible materials, which is arranged in the center of the furnace bed and an oblique section ( 16 ) and an outlet chute ( 17 ) to expel the incombustible matter, wherein the inclined portion ( 16 ) from one end of the outlet opening trench ( 20 ) for incombustible substances obliquely to the center or to one side and wherein the outlet chute ( 17 ) at the lower end of the oblique section ( 16 ) on the lower side of the outlet opening trench ( 20 ) and connected to an unburnt material outlet; - several auxiliary nozzles ( 18 . 18a . 18b ) on inner pages ( 15a ) of the outlet opening trench and facing each other to blow auxiliary air into the Auslassöffnungsgraben, wherein auxiliary nozzles ( 18a ) above the oblique section ( 16 ) and auxiliary nozzles ( 18b ) above the outlet chute ( 17 ) are arranged; and - wherein the air distribution device ( 14 . 15 . 15a . 15b ) is designed so that the speed of the auxiliary nozzles ( 18a ) above the oblique Ab sectioned auxiliary air greater than that of the auxiliary nozzles ( 18b ) is above the discharge chute ejected auxiliary air, so that the air velocity over the furnace bed ( 12 ) greater than that above the oblique section ( 16 ), which is larger than the one above the outlet chute ( 17 ) so that they contain non-combustible substances in the outlet chute ( 17 ), based on the difference in density between the fluoridized medium and the incombustible materials, as well as controlling the flow rates of fluidizing air through flow rate controls. Fluid bed furnace ( 10 ) according to claim 1, wherein the auxiliary nozzles ( 18 ) blow the auxiliary air downwardly with respect to the horizontal direction, thereby at the inclined portion (FIG. 16 ) and above the outlet chute ( 17 ) to produce an air flow down. Fluid bed furnace ( 10 ), in which a fluidized medium and combustible materials containing incombustible substances with a density above that of the fluidized medium are mixed and incinerated, comprising: - an air distribution device attached to a furnace bed ( 12 15) is arranged to introduce fluidizing air for fluidizing the fluidized medium; - an outlet opening ( 20 ) for incombustible materials located in the center of the kiln bed ( 12 ) is arranged to expel the incombustible matter, which is the outlet opening 20 surrounding oven bed is flat; - an outlet chute ( 19 incombustible material disposed at the lower end of the discharge port, the discharge chute being connected to an incombustible exit located at the lower side of the incombustible discharge port; - several auxiliary nozzles ( 18 ) disposed opposite to each other on the inside of the discharge port to discharge auxiliary air toward the center of the discharge port; Flow rate controls for controlling the flow rates of the fluidizing air and the auxiliary air; Wherein the plurality of auxiliary nozzles blow the auxiliary air into the outlet opening in a direction that is downward in relation to the horizontal, and the flow rates of the fluidizing air and the auxiliary air are controlled by the flow rate controls so that a downwardly flowing airflow is generated in the outlet opening and thus the incombustible Substances are collected in the outlet chute. Fluid bed furnace ( 10 ) according to claim 3, wherein the air velocity above the outlet opening ( 20 ) surrounding furnace bed larger than that above the outlet chute ( 19 ) by controlling the flow rates of the fluidizing air on the side of the air distributor and the auxiliary air on the side of the auxiliary nozzles (FIG. 18 ) he follows. Fluid bed furnace ( 10 ) according to claim 2 or 4, wherein the auxiliary nozzles ( 18 ) along the horizontal direction on the inside of the outlet opening trench (FIG. 20 ) or the outlet opening ( 20 ) are arranged and the auxiliary air from Ausblaslöchern ( 18d ) is blown out, which are present at the front ends of the auxiliary nozzles. Fluid bed furnace ( 10 ) according to claim 4, wherein the jet lengths of the auxiliary nozzles ( 18 ) are adjusted in such a manner that the jet does not reach the center of the discharge port.