WO1993016331A1 - Solid fuel stove - Google Patents

Abstract

The invention describes a stove (1), especially a solid fuel stove with a combustion chamber (2) divided into a hearth (32) and an after-burner (43), and the hearth (32) with least one hearth door (4, 5) into which a primary and a secondary air supply aperture opens and which has a separate after-burner air supply device (27) for the after-burner (43) arranged between the hearth (32) and a flue gas outlet (23). The combustion chamber (2) is lined with a high-temperature-resistant insulating material (44), and the after-burner air supply device (27) is arranged in a separating wall (31) dividing the combustion chamber (2) and there are outlet apertures (35) from an air duct (33) of the after-burner air supply device (27) in a face (34) of the separating wall (31) facing opposite a combustion chamber wall (49). The passage cross-section (36) of an aperture (62) enclosed by this separating wall (31), the combustion chamber wall (49) and possibly side walls (7, 8) of the hearth (32) is smaller than 25 % of a maximum cross-sectional area of the hearth (32) running parallel to a base plate (16) of the hearth (32).

Description

Solid fuel furnace

The invention relates to a stove, in particular a stove, for solid

Fuels, as described in the preamble of claim 1.

A furnace is already known, according to DE-OS 40 03 835, by the same applicant, in which, in order to achieve almost complete combustion and thus to increase the efficiency of the known heating device, the combustion chamber is dome-like by the arrangement of one Feuerstel¬ le partially covering partition is formed. This extends between the two side walls from a rear wall in the direction of a front wall, as a result of which a cross-sectional narrowing in the flow area of the flue gases is provided. Causes the consequent longer residence time ^"of the flue gases in the combustion chamber, however structure in connection with the achievable by the dome-shaped formation of higher Feuerraumtempera¬, low pollutant emissions and increased efficiency. Act During operation of such a heating device Verände- stanchions disadvantageous in the draft conditions of , as they usually occur with changing weather conditions.

In a further known heating device - according to DE-PS 31 17 290 - the flue gases are fed from the combustion chamber to a downstream second combustion chamber into which fresh air is conducted, which is by means of a heat exchanger which forms a partition between the combustion chamber and the afterburning chamber is preheated. The partition wall designed as a heat exchanger, however, brings about a temperature reduction in the afterburning chamber, which has a disadvantageous effect on the afterburning, as a result of which an additional energy supply in the form of electrical energy in the area of the flue gas duct to the afterburning chamber is required.

The object of the invention is to provide a furnace which has an afterburning chamber arranged downstream of the combustion chamber, in which fresh air required for the afterburning is supplied with an afterburning chamber Maintaining the post-combustion of the flue gases at a suitable temperature level is achieved.

This object of the invention is achieved by the features described in patent claim 1.

The surprising advantage of this is that the arrangement of the air duct on the combustion chamber side on the partition dividing the combustion chamber preheats the post-combustion air supplied by the latter and thus promotes the post-combustion process. The heat energy extracted from the combustion chamber causes a reduction in the combustion chamber temperature, as a result of which the combustion process is slowed down and thus a uniform energy conversion is achieved. As a result of the cross-sectional high flow velocity of the flue gases in the passage cross section, an injector effect occurs at the outlet openings for the post-combustion air, which is directly dependent on the instantaneous combustion chamber output and the flue gas quantity thereby developed. This results in an automatic adjustment in the supply of the post-combustion air as a function of the combustion output, which saves further control devices and prevents incorrect regulations endangering safety.

An embodiment according to claim 2 is possible because this provides additional stiffening of the furnace in the area in which temperature peaks occur.

An advantageous further development is described in claim 3, because it achieves a level drop for the air duct arranged in the partition wall, by means of which the supply of post-combustion air, which has a low temperature level, is favored in the direction of the outlet openings arranged at the highest temperature level from the air duct .

An embodiment according to claim 4 is also advantageous, as a result of which a temperature reduction in the afterburning chamber which adversely affects afterburning is avoided. _& Also of advantage is an embodiment defined in claim 5, characterized because a streamlined and low flow resistances having Direction _t "curve is achieved for the air channel.

5

However, an embodiment according to claim 6 is also possible because additional components for the formation of the air duct are thereby omitted and the assembly effort in the manufacture of these furnaces is also reduced. 10

However, an embodiment according to claim 7 is also advantageous, as a result of which a symmetrical formation of the flame development in the secondary combustion chamber is achieved. earth

15 An embodiment according to claim 8 is also possible because the overall height for the furnace designed with the afterburning air supply device can thereby be kept low.

An advantageous further development is described in patent claim 9, whereby a distribution of the post-combustion air in the passage cross-section and thus thorough mixing with the flue gas for uniform oxygen enrichment is achieved.

However, an embodiment according to claim 10 is also possible, by means of which the heated post-combustion air is accelerated in the direction of flow of the flue gases.

An embodiment according to claim 11 is also possible, as a result of which the higher temperature level 30 required for the afterburning process is achieved over the entire operating period of the heating device, with the exception of heating operation.

An advantageous further development is described in claim 12, because additional flue gas ducts or components for these ducts are thereby avoided, as a result of which an inexpensive furnace equipped with the afterburning chamber is achieved. An embodiment according to claim 13 is possible because this achieves a temperature level required for the afterburning of the pollutants contained in flue gases and a long service life of the receiving chamber is achieved without the risk of local overheating of the furnace construction.

An embodiment according to claim 14 is also possible, because in this way circulation of the combustion air in the afterburning chamber, and associated use of the thermal energy contained therein, is achieved to maintain the afterburning process.

An embodiment according to claim 15 is also advantageous because it means that no additional holding and / or cladding elements are required in the area of the afterburner.

An embodiment according to claim 16 is also advantageous because this means that less assembly work is required in the delivery of the furnaces equipped with the afterburning chamber and the costs for such heaters are thus kept low.

A further advantageous embodiment is described in claim 17, because this extends the flow path of the flue gases from the afterburner into the flue pipe and thus improves the use of heat by the thermal energy contained in the flue gases.

In a further development according to claim 18, specially manufactured shaped stones can be avoided, whereby this training has a cost-reducing effect, in particular in the case of smaller series production.

An embodiment according to claim 19 is advantageous, as a result of which separate cutouts for the supply of the post-combustion air in the insulating material are dispensed with.

According to an advantageous further development, as described in claim 20, there is a time period during which a higher pollutant emission occurs, kept low.

<s $,

An advantageous further development is described in claim 21, because it achieves an automated heating operation and avoids incorrect operations which endanger the safety of the user, and also influences which are dangerous to the environment due to increased pollutant emissions.

An embodiment according to claim 22 is advantageous because it achieves automatic regulation to the temperature level required for afterburning and the risk of overheating is avoided.

A further development according to patent claim 23 is also possible because a correspondingly large and infinitely variable control range is thereby achieved.

15

Finally, an embodiment according to claim 24 is also advantageous, as a result of which effective protection against overheating is achieved for the metal components of the furnace and thus fuels with higher flame temperatures can also be fired.

20th

For a better understanding of the invention, this will be explained in more detail with reference to the exemplary embodiments shown in the drawings.

Show it:

25

1 shows an oven designed according to the invention in a simplified, diagrammatic representation;

FIG. 2 shows the furnace according to FIG. 1 in a side view, in section, according to the 30 lines II-II in FIG. 1;

Figure 3 shows a part of the furnace, cut along the lines III-III in Figure 2.

35 Figure 4 shows a part of the furnace, cut along the lines IV-IV in Figure 2; 5 shows a part of the furnace in the connection area of the partition with the air duct and the end wall;

6 shows another embodiment variant of the furnace according to the invention with the afterburner in side view, in section;

Figure 7 shows a part of the furnace, cut along the lines VII-VII in Figure 6;

8 shows a part of the furnace in a top view, partly in section;

9 shows a section of part of a furnace of a further embodiment according to the invention in a front view.

1 shows a furnace 1 which has a combustion chamber 2, which is accessible via a loading and / or cleaning opening 3, which is designed to be lockable with combustion chamber doors 4, 5.

The loading and / or cleaning opening 3 is arranged in an end wall 6 of a one-piece component 9 which also forms side walls 7, 8 and has a substantially U-shaped or C-shaped cross section. Corner areas 10, 1 1 between the end wall 6 and the side walls 7, 8 are, for. B. to these angled. The combustion chamber 2 is further delimited by a rear wall 12 and this top wall 14 which limits it in the direction of a height 13 and a combustion chamber grate 15. The component 9 and the rear wall 12 protrude beyond the top wall 14 and the combustion chamber grate 15 in the direction of the longitudinal extent of the furnace 1 in the direction of a bottom plate 16 and a top plate 17 and is connected to them in a non-moving manner, e.g. B. screwed, welded or the like. In the area between the top wall 14 and the top plate 17, a warming compartment 18 is arranged and accessible via an opening 19 in the front wall 6. In the area between the combustion chamber grate 15 and the base plate 16, an ash drawer 20 is arranged via an opening in the end wall 6 for receiving combustion residues falling through the combustion chamber grate 15. The combustion chamber 2 has on the side walls 7, 8 of the Rear wall 12 and the top wall 14 a highly heat-resistant lining 21, for. B. by firebricks 22.

On the cover plate 17, a flue gas pipe socket 25 is assigned to an opening 24 forming a flue gas outlet 23, for. B. screwed to the cover plate 17, welded etc.

In the end wall 6, in the area between the combustion chamber doors 4, 5 and the top wall 14, inflow openings 26 of a post-combustion air supply device 27 are arranged, via which fresh air - shown schematically by arrows 28 - is supplied to the combustion chamber 2. Furthermore, a fresh air regulating device 29 for the direct and controlled supply of combustion air required for combustion - arrow 30 - is arranged in the area below the combustion chamber grate 15 in the end wall 6 in the area of the ash drawer 20.

2 to 5 show the furnace 1 with the combustion chamber 2, which, through a partition wall connected to the end wall 6 in the area of the inflow openings 26, runs obliquely downwards in the direction of the combustion chamber grate 15 and the rear wall 12 31 is divided into two superimposed areas.

The partition 31 is also connected to the side walls 7 and 8 in a fixed manner. In the area between the combustion chamber grate 15, the partition 31, the combustion chamber doors 4 and 5 and the rear wall 12, a combustion chamber 32 is formed for the combustion of fuels. The partition 31 has, on the side facing the combustion chamber grate 15, an air duct 33, in which on an end face 34, which faces the rear wall 12, outlet openings 35 for the exit of post-combustion air into one, from the end face 34 and the rear wall 12 limited passage cross section 36 are formed.

The air duct 33 is formed from a U-shaped profile 39, which is fastened via its legs 37 to a lower side 38 of the partition 31, and which extends in the region of the inflow openings 26 arranged in the combustion chamber doors 4, 5 and the end wall 6 an inner surface 40 of the combustion chamber doors 4 or the end wall 6 with the legs 37 and a web 41 sealingly and forms a flow connection for the post-combustion air - arrow 42 - between the inflow openings 26 and the outlet openings 35.

The region of the combustion chamber 2 which is arranged above the combustion chamber 32 in the direction of the top wall 14 forms an afterburning chamber 43, in which the combustible residues contained in the flue gas supply under oxygen, which is achieved by the supply of the afterburning air - arrow 42 - for afterburning be, whereby an increase in efficiency of the furnace 1 is achieved with a simultaneous reduction in pollutant emissions.

The afterburner 43 is covered by the top wall 14 with insulating material 44, for. B. highly refractory firebricks lined, side of the partition wall 31 and a dome-shaped receiving chamber 45, which is designed such that a covering plate 36 covering the passage cross section 46 is arranged at a height 47 in the direction of the cover wall 14, which beginning of the rear wall 12, running obliquely downwards in the direction of the combustion chamber grate 15 and over a depth 48 in the direction of the end wall 6.

Due to the arrangement of the cover plate 46 of the afterburning chamber 43, covering the passage cross section 36 of the flue gases from the combustion chamber 32 into the afterburning chamber 43, the flue gases are deflected from the air duct 33 in the direction of the end wall 6 after the admixing of the afterburning air - arrow 42. The turbulence that occurs results in better oxygen distribution, combined with better post-combustion behavior of the flue gas / fresh air mixture. The rear wall 12 is lined with insulating material 44 in the area of the combustion chamber 32 and the afterburning chamber 43. This insulating material 44 forms a combustion chamber wall 49 on the side facing the combustion chamber 32 or the afterburning chamber 43.

The cover plate 46 of the receiving chamber 45 is formed from insulating material 44. From an end edge 50 which faces the end wall 6 forms the end of the cover plate 46, is offset by a distance 51 in the direction of the rear wall 12, on the underside, projecting towards the combustion chamber grate 15, an increase 52 made of insulating material is arranged, which, like the cover plate 46, laterally through the side walls 7 and 8 is limited. On the inner side of the top wall 14 facing the combustion chamber grate 15 there is an inner top wall insulation 53 which is laterally delimited by the side walls 7 and 8 and which extends to a plane 54 which is perpendicular to a contact surface 55 and parallel to the front wall 6 on the front edge 50 runs, extends. An inner edge 56 is formed by the side of the inner wall insulation 53 and the level 54 facing the combustion chamber grate 15. The inner edge 56 projects beyond the end edge 50 by a height 57 in the direction of the top wall 14 and thus forms a flow cross section 58 for flue gases.

The further is on the side of the end wall facing the rear wall 12

6 an end wall inner insulation 59 arranged through the side walls

7 and 8, and by the insulating material 44 running on the side of the partition wall 31 facing the top wall 14 and the top wall interior insulation 53. As can also be seen from FIG. 2, the ash drawer 20 is located below the combustion chamber grate 15, projecting above it in the direction of the base plate 16. A glow trap 60 is arranged approximately parallel to the end wall 6 between the combustion chamber doors 4 and 5 and the combustion chamber grate 15 . It prevents a possible escape of glowing or burning heating material from the combustion chamber 32 when the firebox doors 4 and 5 are opened. The operating principle of the furnace 1 and the afterburning chamber 43 is now as follows: the flue gases which arise in the combustion chamber 32 when the heating material burns pass through the passage cross-section 36 on the combustion chamber wall 49 from below into the post-combustion chamber 43, the flue gases being enriched in the passage cross-section 36 by means of fresh air from the post-combustion air supply device 27 via the air duct 33 and the outlet openings 35. Due to the cover plate 46 and the elevation 52, the flue gases are swirled and afterburning occurs. The flue gases flow between the elevation 52 and the partition 31 in the direction of the end wall 6, and are deflected by about 180 ° on the inside wall insulation 59 and the inside cover wall 53 and pass through the Flow cross section 58 via the cover plate 46 into the flue gas outlet 23.

A further embodiment variant of the furnace 1 is shown in FIGS. This has the combustion chamber 2 divided by the partition 31 into the combustion chamber 32 and the afterburning chamber 43. The partition 31 is made of sheet metal and has approximately in the middle between the side walls 7, 8 on the underside 38 of the U-shaped profile 39 running in the direction of the rear wall 12, which extends from the end wall 6 to the region of an end edge 61 of a recess 62 of the partition wall 31 forming the passage cross section 36 and forms the air duct 33 for supplying the post-combustion air from the inflow opening 26 arranged in the end wall 6 to the passage cross section 36. The end face 34 of the partition wall 31 or the air duct 33, which end face is towards the rear wall 12, is inclined in an arc shape in the direction of the top wall 14 and points in

The outlet openings 35 open in the direction of the top wall 14, as a result of which an injector effect is formed on the flue gas flowing from the combustion chamber 32 in the direction of the afterburning chamber 43. The afterburning chamber 43 has in its area assigned to the rear wall 12 a dome-shaped shaped block 63 that spans the recess 62 and in its area facing the end wall 6 cladding elements 64. B. consist of firebricks, ceramics, fiber materials etc. Of course, the cladding elements 64, like the shaped block 63, can also consist of a one-piece molded element. The shaped block 63 forms the receiving chamber 45, in which the dome-shaped formation of heat builds up, by means of which the ignition of the combustion gases enriched with the oxygen of the post-combustion air - arrow 42 - is promoted. Approximately in the area of a contact surface 65 between the molded block 63 and the cladding element 64, the molded block 63 has the elevation 52 which projects beyond the inner surface in the direction of the partition wall 31, as a result of which a swirling of the flue gases is achieved which increases the dwell time the flue gases in the receiving chamber 45 are extended, thereby promoting the formation of the heat accumulation. As can now be better seen in FIGS. 7 and 8, the shaped block 63 has a U-shaped cross section, a width 66 of the legs 67 which extend approximately parallel to the side walls 7, 8 in the direction of the partition wall 31 being smaller is an inner width 68 of the combustion chamber 2, but is greater than a width 69 of the recess 62 in the partition wall 31. A web 70 connecting the legs 67 along the top wall 14 is in the transition region to the legs 67 in the direction of the partition wall 31 angled, which results in bevels 71 which form an angle 72 of approximately 90 between them.

The cladding elements 64 adjoin the contact surface 65 in the direction of the end wall 6. These form the top wall inner insulation 53, the end wall inner insulation 59 and the lining 21 facing the side walls 7, 8. The lining elements 64 can also be made of a shaped element, e.g. be made in one piece from cast fireclay, cast ceramic, magnesite, etc.

Flue gases, shown schematically by arrows 73, now flow after the afterburning the combustible components contained in the flue gas, the afterburning chamber 43 in the direction of the end wall 6, wherein they are deflected in the direction of the flow towards the rear wall 12. From the difference between the inner width 68 and the width 66 of the legs 67 of the shaped block 63 and its central arrangement between the side walls 7, 8, flow channels 74 in the direction of the rear wall 12 and through the bevels 71 of the shaped block 63 are formed on both sides of the shaped block 63 63 formed in the direction of the top wall 14. In this, approximately rectangular, oval, circular inflow openings 75 are arranged approximately symmetrically with respect to a plane of symmetry 76, which extends parallel and at the same center distance from the side walls 7 and 8 over the entire height of the furnace 1, in such a way that they are outside the area of the web 70 of the shaped block 63, as a result of which there is a free passage in a flue gas collecting duct 77 arranged downstream of the inflow openings 75. This is delimited by the rear wall 12, the side walls 7, 8, the cover plate 17 and an intermediate wall 78 delimiting them in the direction of the warming compartment 18. The smoke gases - arrow 73 - are passed on through the opening from the smoke gas collection channel 77 24 in the cover plate 17 and further through a smoke pipe 79 connected to the flue gas pipe socket 25.

In this embodiment variant, a closure flap 80 for supplying combustion air - arrow 30 - is arranged on the rear wall 12 in the area between the combustion chamber grate 15 and the base plate 16. This closure flap 80 is mechanically operatively connected via a control linkage 81 to a temperature sensor 82 with a sensor element 83 projecting into the afterburning chamber 43.

The automatic control of the furnace 1 achieved thereby provides for the closure flap 80 to be kept open for heating the furnace 1 until a temperature level predetermined by the temperature sensor 82 is reached in the afterburning chamber 43. This temperature level is adjusted to a value ^'in which the Nachverbrennungsvorgang that in the flue gas - burns combustible component contained - arrow 73rd Experience has shown that this temperature level is around 280 ° C. Once this temperature level has been reached, the closure flap 80 is closed via the temperature sensor 82 and the control link 81. If the temperature level falls below the predetermined value, the closing flap 80 is opened in the opposite manner.

In a simple embodiment variant, the temperature sensor 82 is a known bimetallic element 84, the temperature-related change in position of which actuates the control linkage 81 of the closure flap 80 mechanically. In another embodiment variant, however, it is also possible to close the closure flap 80 via a drive motor 85 shown in dashed lines, which is acted upon by an energy source 86 and to which a control unit 87 and the temperature sensor 82 designed as a measuring sensor 88 are arranged adjust.

A further variant of the partition 31 is shown in FIG. This is non-moving, preferably welded, connected to the side walls 7 and 8 and has a U-shaped recess 89 in the plane of symmetry 76, which extends in the direction of the combustion chamber 32. The partition 31 with the U-shaped recess 89 which the Air duct 33 forms is made of one piece, preferably sheet metal. The passage cross section 36 of the partition wall 31 is formed by a, preferably rectangular, cross section, which is delimited by the combustion chamber wall 49, the end face 34 of the air duct 33 facing the combustion chamber wall 49, which has the preferably rectangular, circular or oval shaped outlet openings 35 and the width 69 of the recess 62. Furthermore, the partition 31 is in the area between the passage cross section 36 and the side walls 7 and 8 with the rear wall 12 z. B. connected by welding.

Of course, ^"the formation of the furnace 1 according to the invention with the secondary combustion space 43 is not limited to those described in the embodiments, the outer contour shapes of the furnace 1 and are die¬ se only used by way of example in the examples shown.

Furthermore, for a better understanding of the invention, a scale representation has been omitted on the basis of the figures and individual elements are shown disproportionately to one another.

Finally, it should also be pointed out that in each case individual combinations of features described in the individual exemplary embodiments, in particular those characterized in the subclaims, can also represent independent, separate, inventive designs.

Reference numbering

61 front edge

21 lining 62 recess

22 firebrick 63 molded brick

23 flue gas outlet 64 cladding element

24 opening 65 contact surface

25 flue gas pipe socket

66 width

26 inflow opening 67 legs

27 Post-combustion air supply 68 width device 69 width

28 arrow 70 footbridge

29 Fresh air control device

30 Arrow 71 bevel

72 angles

31 partition 73 arrow

32 combustion chamber 74 flow channel

33 air duct 75 inflow opening

34 end face

35 outlet opening 76 plane of symmetry

77 flue gas collecting duct

36 Cross section 78 Partition

37 legs 79 smoke pipe

38 underside 80 closure flap

39 profile

40 inner surface 81 control linkages

82 temperature sensors

83 sensor element

84 bimetal element

85 drive motor

86 energy source

87 control unit

88 transmitter

89 deepening

Claims

Patent claims

1. Stove, especially solid fuel stove with a

Combustion chamber which is subdivided into a combustion chamber and an afterburning chamber and the combustion chamber has at least one combustion chamber door and that a primary air supply device and a secondary air supply device open into this and with a separate afterburning air supply device for the afterburning chamber arranged between the combustion chamber and a flue gas outlet, thereby characterized in that the combustion chamber (2) is lined with a high-temperature-resistant insulating material (44) and that the post-combustion air supply device (27) is arranged in a partition (31) dividing the combustion chamber (2) and outlet openings (35) from an air duct (33 ) of the post-combustion air supply device (27) are arranged in an end face (34) of the partition wall (31) facing an opposite combustion chamber wall (49). A passage cross section (36) of one of this partition wall (31), the combustion chamber wall (49 ) and, if applicable, from side walls (7,8) of the recess (62) enclosed in the combustion chamber (32) is smaller than 25% of a maximum cross-sectional area of the combustion chamber (32) running approximately parallel to a base plate (16) of the combustion chamber (32).

2. Furnace according to claim 1, characterized in that the partition (31) in the area between the combustion chamber door (4, 5) and a deck wall (14) of the afterburner (43) with an end wall (6) and Seiten¬ walls (7, 8) of the furnace (1) connected, in particular welded.

3. Oven according to claim 1 or 2, characterized in that the

Partition wall (31) with a part of the end wall (6) extending from it in the direction of the base plate (16) encloses an angle which is less than 90 °.

4. Oven according to one or more of claims 1 to 3, characterized in that the air duct (33) for the post-combustion air the bottom plate (16) of the combustion chamber (32) facing the underside (38) of the partition (31) is arranged.

5. Furnace according to one or more of claims 1 to 4, characterized in that the air channel (33) from the end wall (6) in the direction of an opposite combustion chamber wall (49) of the combustion chamber (32) runs ver.

6. Oven according to one or more of claims 1 to 5, characterized in that the air duct (33) as a recess (89) formed by a U-profile-shaped material penetration of the partition (31) and on one of the base of the U Profile-shaped material enforcement opposite side through a sheet metal plate or an insulating material (44) arranged on an upper side of the partition (31) facing the cover wall (14), eg. B. firebricks is limited.

7. Furnace according to one or more of claims 1 to 6, characterized in that the air channel (33) approximately in the middle between the two at right angles to the end wall (6) extending side walls (7, 8) of the combustion chamber (32) is arranged.

8. Oven according to one or more of claims 1 to 7, characterized in that the air duct (33) is formed by a U-shaped profile (39), the leg (37) with one of the bottom plate (16) of the furnace (1 ) facing underside (38) of the partition (31) are connected, in particular welded.

9. Furnace according to one or more of claims 1 to 8, characterized in that the outlet openings (35) for the post-combustion air receiving end face (34) of the partition (31) with respect to the opposite combustion chamber wall (49) is concavely curved forms is.

10. Oven according to one or more of claims 1 to 9, characterized in that the partition (31) in its end face (34) opposite end region ge in the direction of the top wall (14) of the subsequent combustion chamber (43) rises or is curved.

1 1. Oven according to one or more of claims 1 to 10, characterized in that between the partition (31) and the night

5 combustion chamber (43), in particular lying on the top of the partition (31), a high-temperature-resistant insulating material (44) is arranged.

12. Oven according to one or more of claims 1 to 1 1, da¬ characterized in that the recess (62) in the direction of the night

10 combustion chamber (43) opens into a trough-shaped receiving chamber (45) which is open in the direction of the combustion chamber (32) and has a smaller width (69) than an inner width of the afterburning chamber (43) and of which an interior space via outlet openings with the flue gas outlet (23) is connected.

15

13. Oven according to one or more of claims 1 to 12, da¬ characterized in that the receiving chamber (45) made of a highly heat-resistant material, for. B. a vacuum stone made of ceramic fiber or egg nem ceramic material, and in particular as a shaped stone (63)

20 forms is.

14. Oven according to one or more of claims 1 to 13, characterized in that a back plate facing the opening in the direction of the combustion chamber wall (49) opposite the end face (34)

25 rests on the dividing wall (31) or on a high-heat-resistant lining resting on its upper side, and a cover plate (46) in its end region facing away from this combustion chamber wall (49) has a surface facing the combustion chamber (32) and projecting therefrom by a Elevation (52) formed air baffle.

30

15. Oven according to one or more of claims 1 to 14, characterized in that the receiving chamber (45) extends into the region of the end wall (6) of the afterburner (43).

35 16. Oven according to one or more of claims 1 to 15, characterized in that the receiving chamber (45) preferably consists of two is formed in divided plane parallel to the combustion chamber wall (49).

17. Oven according to one or more of claims 1 to 16, characterized in that the outlet openings (35) in the direction of

Flue gas outlet (23) are arranged within the legs (67) of the receiving chamber (45) which run parallel to the side walls (7, 8) of the afterburner chamber (43).

18. Oven according to one or more of claims 1 to 17, characterized in that the receiving chamber (45) is composed of several individual parts.

19. Furnace according to one or more of claims 1 to 18, characterized in that an inflow opening of the air duct (33) is formed by openings in the end wall (6) and / or the combustion chamber doors (4, 5) of the furnace (1) are.

20. Oven according to one or more of claims 1 to 19, characterized in that an inflow opening for the primary air is arranged between the base plate (16) and a combustion chamber grate (15) of the combustion chamber (32) and this has a closure flap (80) is assigned, which can be closed by a drive.

21. Oven according to one or more of claims 1 to 20, characterized in that the drive for the closure flap (80) is formed by a control linkage (81) which the closure flap (80) with in the afterburning chamber (43) or the bimetallic element (84) arranged in the receiving chamber (45) is motionally connected.

22. Oven according to one or more of claims 1 to 21, characterized in that, when the bimetallic element (84) is at a temperature of> 280 ° C, the control linkage (81) corresponds to a closed position of the closure flap (80) Position is adjusted.

23. Oven according to one or more of claims 1 to 22, characterized in that the closure flap (80) is assigned a drive motor (85) which is connected via a control device to a transmitter (88) for the temperature in the afterburning chamber (43) or the receiving chamber (45).

24. Furnace according to one or more of claims 1 to 23, characterized in that the combustion chamber (32) is lined with high-temperature-resistant insulating stones.