AT404873B - AIR SUPPLY DEVICE FOR THE SECONDARY AIR OF A HEATING DEVICE - Google Patents

Description

AT 404 873 B

The invention relates to a supply air guide device for secondary air in a heating device with a supply air control device which has outflow openings for the secondary air in a combustion chamber in the area of an upper edge of a door cutout of the heating device and with an air guide device which is arranged on a grate plate of the combustion chamber at least in the area of the door cutout. and has a partition wall and a floor guiding element which extends at a distance from the inside of the door and the grate plate facing the combustion chamber in the direction of the cover plate of the combustion chamber, an air distribution channel being formed between the inside of the door and the partition wall and the partition wall in the region of the grate plate over at least a breakthrough is connected to the combustion chamber.

Various furnaces are already known which are designed differently to control the combustion process or have different draft control devices. Known stoves are provided in the area of the grate or the combustion chamber doors with inlet openings, the cross-section of which can be adapted to different operating states of the heater or the heating device by adjusting adjustment elements.

DE 42 01 738 AI discloses an air guiding device for a heating device, which is arranged in the region of a lower edge of the door cutout. In this air guide device, a partition is provided which extends from the bottom of the combustion chamber in the direction of the upper edge of the door cutout. The partition is provided with an opening, which creates a connection between the air duct formed between the partition and the inside of the door and an air duct arranged on the side of the partition facing the combustion chamber. The disadvantage of this known air guiding device is that a different level of pollutant emissions cannot be completely avoided when using the same.

In the so-called stoves of the more modern design, e.g. According to DE 40 03 779 A1 and DE 40 03 835 A1, which consist of a sheet steel jacket for the combustion chamber and a convection jacket arranged upstream of it and are equipped with large combustion chamber doors with transparent panes, the problem has repeatedly arisen that those in the combustion chamber doors arranged transparent windows have started up after a relatively short period of operation or soot parts and combustion residues have been burned into these transparent windows. For this reason, supply air guiding devices for the secondary air have already been arranged in these stoves, in which air is supplied in the area of the upper ends of the combustion chamber doors, so that the fresh combustion air supplied, which is usually considerably colder than the combustible gases contained in the combustion chamber and the flue gases fall down as an air curtain over the inside of the transparent panes of the combustion chamber doors. The air supplied in this way then served as secondary air for the combustion. The disruption of the combustion process due to this cold fresh air was particularly disadvantageous during the heating process.

Furthermore, it has also been proposed, inter alia, to provide a combined primary and secondary air control device in the area of the ash drawer - in accordance with DE 39 03 739 A1 - whereby, depending on the position of the control device, some of the fresh air supplied has been brought into the area above the combustion chamber doors via distribution channels from there to fall down into the combustion chamber. Such air supply systems have proven themselves in themselves. However, a uniform distribution of the supply air, in particular the secondary air in the area of the grate plate for heating devices which have a circular, polygonal or rectangular cross section in plan view, was not always ensured. This is particularly the case when the side lengths of the side walls vary considerably.

The present invention is therefore based on the object of providing a heating device in which a favorable combustion process and thus good economy can be achieved and in which pollutant emissions can also be reduced.

This object of the invention is achieved in that the partition is spaced above vertical grate elements above the grate plate and a guide surface of the floor guide element extends from a region near the lower edge of the door cutout in the direction of the cover plate, with, as is known per se, a distance between the bottom guide element and the inside of the door increases with increasing distance from the grate plate, and the height of the guide surface of the bottom guide element above the grate plate is smaller than the height of the partition above the grate plate. It is advantageous with this solution that a direct inflow of secondary air, which is guided as an air curtain along a viewing window of a door into the combustion chamber, is prevented by the supply air guiding device. The supply air guiding device ensures that the secondary air flow is divided, and the fireplace is comprehensively guaranteed on all sides, a flow direction being achieved in which the secondary air is guided into the area of the flame tips. This prevents cooling directly at the fireplace and at the same time allows oxygen to be fed into the gassing area of the flame, as a result of which the combustible parts of the flue gases are afterburned. This results in an increase in the efficiency of the heating device and a reduction in pollutant emissions. 2nd

AT 404 873 B is also possible in accordance with claim I, according to which the height of the partition wall, in particular starting from the vertical central region of the door cutout, decreases in the direction of the side walls. This creates a cross-sectional configuration for the air distribution duct as a function of the flow volume of the secondary air. s According to an advantageous further development according to claim 3, the guide surface of the floor guide element and the partition form an air guide channel which extends from an area near the lower edge of the door cutout in the direction of the center of the combustion chamber. It is thereby achieved that the direction of flow of the secondary air is guided in the direction of the gassing zone of the flue gases and thus in the area in which post-combustion is to take place. io In the embodiment according to claim 4, a cross-sectional area of the air duct in a horizontal plane perpendicular to the rear wall is larger than a cross-sectional area of an air distribution channel between the partition and the inside of the door. As a result, the flow velocity of the secondary air can be reduced before reaching the combustion chamber, as a result of which eddy formation, so-called cyclone effects, is avoided when the secondary air is mixed with the flue gases. 75 According to an advantageous development according to claim 5, a longitudinal axis of the air duct extends from a lower edge of the door cutout into a central region of the ramming zone. As a result, a directional effect is achieved with which the oxygen supplied by means of the secondary air acts on the ram surface, so that the smoke gases are prevented from spreading before the afterburning process. An embodiment according to claim 6 is also possible, in which the partition and the guide surface of the floor guide element run essentially parallel to one another, as a result of which the supply air guide device can be used advantageously, in particular also with combustion chambers having a greater height.

According to the advantageous designs according to claims 7 and 8, according to which on the one hand the partition wall and the floor guide element extend along the front wall and the side walls up to the rear wall and on the other hand the partition wall and the floor guide element also extend over the rear wall, one of the spatial conditions of the Combustion chamber adapted supply air guide reached.

According to a development according to claim 9, openings, in particular bores, are arranged in the partition wall in the region of the rear wall connecting the air distribution duct to the combustion chamber. 30 With this measure, a portion of the secondary air is fed to the fireplace in addition to primary air.

A further embodiment is provided in that the floor guide element in the area of the door cut-out has a spacer element which is offset from its support surface on the grate plate and engages in a free area between the grate plate and the T-shaped cut-out. This ensures an exact positioning and mounting of the air supply device.

Finally, however, a design as described in claim 11 is also possible, according to which the partition wall and the floor guide element are in particular formed in one piece with one another and are preferably formed as a cast part, in particular made of cast iron. In this way, inexpensive and high-quality reproducible and therefore easily replaceable elements are achieved. 40 For a better understanding of the invention, it will be explained in more detail with reference to the exemplary embodiments shown in the drawings.

1 shows a heating device with the supply air guide device according to the invention in a perspective, schematic representation; Figure 2 is a side view of a combustion chamber of the heating device with the supply air guiding device; Figure 3 shows the supply air guide device in front view. 4 shows the supply guide device in plan view; 5 another embodiment variant of the air supply device according to the invention, cut in a side view; Rg. 6 the supply air guide device in plan view; Rg. 7 the supply air control device in front view; 8 shows a further embodiment of an air supply device according to the invention in a side view, in section; Rg. 9 the supply air guide device according to Rg. 8 in plan view.

Rg.1 shows a heating device 1, in particular for solid fuels. This has a combustion chamber 2, a baking and / or warming compartment 3 following the combustion chamber 2 and a cover plate 4 delimiting the heating device 1 in the vertical direction. A storage space 6 for fuel 7 is arranged between the combustion chamber 2 and a base plate 5, in which an ash pan 10 is assigned to a grate plate 8 for a fire part 9 of the combustion chamber 2. The combustion chamber 2 is of polygonal design, in particular polygonal, and has an operating opening 13 that can be closed by a door 55 12. The inner jacket 11 is enclosed at a distance from an outer jacket 15 formed by cladding elements 14. In the combustion chamber 2, the inner jacket 11 is preceded by plate-shaped heat-resistant cladding elements 16, in particular chamotte plates 17, in the direction of the fire parts 9. The combustion chamber 2 is in the direction of the baking and / or warming compartment 3 3

AT 404 873 B is limited by a cover plate 18 with a supply air control device 19 arranged therein, which is assigned to an upper edge 20 of a door cutout 21 forming the operating opening 13. The supply air control device 19 is arranged in the area between the cover plate 18 and a cladding plate 23 forming a storage space 22 for the baking and / or holding compartment 3, in particular a tile 24 formed from ceramic material. The cladding elements 14 are constructed in several pieces in the vertical direction of the heating device 1 and are spaced between the base plate 5 and the cover plate 4 and held parallel to them, mounting profiles 25 which run a side and / or height guide 26 for the cladding elements 14 in a convection space 27 Distance 28 to the inner jacket 11 set. In the combustion chamber 2 on the grate plate 8 in the area of a lower edge 29 jo and door 12 are assigned and in the vertical direction projecting beyond the edge 29 an air supply device 30 is arranged, which has an air duct 31 for a supply air control device 19 fed into the combustion chamber 2 - Arrow 32 - training. At the same time, the supply air guide device 30 forms a splash guard for a glass pane 33 arranged in a door frame.

As can now be seen better in FIGS. 2 to 4, the secondary air supplied to the combustion chamber 2 via the supply air control device 75 direction 19 flows - arrow 32 - as an air curtain due to the lower weight compared to the smoke gases - arrow 34 - forming an air curtain along the Door 12 or glass pane 33 in the direction of grate plate 8.

This causes the glass pane 33 to be kept free from contaminants, e.g. Soot - fly ash etc. The secondary air - arrow 32 - flows up to the area of a guide surface 35 of the supply air guide device 30, which forms an air distribution channel 36 in the area of the door 12 and the base plate 5. As a result of the heating that has now occurred, which is increasingly caused in the area of the supply air guiding device 30, in particular by the emission of radiant heat from the structural parts of the supply air guiding device 30 directly exposed to the fireplace 9, the secondary air is deflected - arrow 32 - approximately in a diagonal direction, ie approximately in the direction of the cover plate 18 and the cladding element 16 arranged opposite the operating opening 13 25. The direction of flow is achieved by the spatial arrangement of the air guide channel 31. The air guide channel 31 is formed between the partition 37 forming the guide surface 35 and a floor guide element 38 delimiting the air guide channel 31 in the direction of the fireplace 9, which has a guide surface 39 which is at an angle 40 of approximately 45 to 75 degrees, preferably 60 degrees Grate plate 8 is arranged. 30 By the angle 40 of the floor guide 38 and the approximately parallel orientation of the floor guide 38 and the partition 37 ensures that the secondary air - arrow 32 - not directed directly to the fireplace 9, but rather in the area of the flue gas generation, i.e. This means that it is directed approximately into the area of the middle flame zone and there supplies the flue gases - arrow 34 - oxygen, as a result of which the flammable gas components contained in the flue gases - arrow 34 - are afterburned in this area before they reach one in the cover plate 18 arranged smoke outlet 41 get. The efficiency of the heating device 1 is thus increased through the complete use of the combustible components and the emission of pollutants into the environment is reduced.

A width 42 of the supply guide device 30 is equal to or less than an inner width 43 of the combustion chamber 2. Furthermore, end walls 45 of the floor guide element 38 facing side walls 44 are designed to be conical in the direction of the cover plate 4, which means that a portion of the secondary air -arrow 32 - the fireplace 9 flows laterally in the direction of a rear wall 46. Furthermore, the rear wall 46 or the cladding elements 16 of the rear wall 46 have strip-shaped extensions 47 projecting in the direction of the combustion chamber 2 and extending in the direction of the base plate 5, by means of which a tight contact of the fuel 7 on a surface 48 of the cladding element 16 is prevented 45, which also Combustion air can enter this area and thus improve the result of the combustion.

An upper edge 49 of the partition 37 has a height 50, measured perpendicular to the grate plate 8, of approximately 6 cm to 12 cm, preferably 8 cm. An upper edge 51 of the floor guide element 38 has a height 52, measured perpendicular to the grate plate 8, of approximately 4 cm to 6 cm, preferably 5 cm. Such a lower edge 53 of the partition 37 runs approximately in a plane of the upper edge 51 of the floor guide element 38. This results in connection with the angle 40, after flowing through the air guide channel 31, a flow direction of the secondary air - arrow 32 - through which this as a directed air flow flows into the central area of the flame zone, i.e. into the mixing zone of the flame, and this supplies oxygen. This supply of oxygen leads to afterburning 55 of the combustible components in the area of the mixing zone and thus to the already described increase in the efficiency of the heating device 1 and to a reduction in the pollutants that occur.

5 to 7 show another embodiment of the supply air guide device 30 for the heating device 1. This has the partition wall 37 and the floor guide element 38, which the guide surfaces 35, 39 for 4

Claims (11)

AT 404 873 B form the secondary air. The guide surface 35 facing the door cutout 21 or the glass pane 33 is concavely curved in the direction of the glass pane 33 and has an opening 54 in the direction of the edge 29 of the door cutout 21, through which the secondary air flowing along the glass pane 33 as an air curtain - arrow 32 - gets into the air duct 31. The floor guide element 38, which delimits the air duct 31 in the direction of the fireplace 9, is inclined at an angle 40 with respect to the grate plate 8 and rises in the direction of the combustion chamber 2. An end region 55 of the bottom guide element 38 is shaped in the direction of the cover plate 18, as a result of which in the region of an outflow cross section 56 the air guide channel 31 tapers and thus accelerates the flow velocity of the secondary air - arrow 32. In the direction of the side walls 44, support elements 57 are arranged at an angle of approximately 90 * to the grate plate 8, by means of which the partition wall 37 and the floor guide element 38 are connected. The supply air guiding device 30 is preferably formed from a one-piece casting and has the base and / or grate plate 8 facing spacer elements 58 for positioning and holding in the combustion chamber 2. 8 and 9 show a further embodiment of the supply air guide device 30 for a heating device 1. This consists of a one-piece, U-shaped, in particular cast part, which has the dividing wall 37 and the bottom part 38 and comprises the fireplace 9 along an end wall 59 and the rare walls 44. As further shown in broken lines, it is also possible to supply the air supply device 30 to form a ring around the fireplace 9. These designs therefore make it possible to supply the secondary air - arrow 32 - to the combustion chamber 2 both from the direction of the front wall 59 and the side walls 44, but also from the direction of the rear wall 46. By forming the guide surfaces 35, 39, the secondary air - arrow 32 - is fed to the gassing zone, thereby preventing a direct inflow to the fireplace 9 and thus cooling it, and rather the secondary air - arrow 32 - which, as already described, precedes the air curtain the glass pane 33 forms, the flue gases, including the fireplace 9, for post-combustion. An embodiment is also possible in which the regions of the supply air guiding device 30 running along the side walls 44 and optionally the rear wall 46 are designed as separate duct elements 60 from the region running along the end wall 59, the supply with the secondary air via connection regions 61 of the supply air guiding device 30 running along the end wall 59. These channel elements 60 can be tubular in themselves, which have holes 62 on their surface, in particular in the direction of the cover plate 4. In a simple embodiment, the supply air guiding device 30 can be formed by strip-shaped elements which partially surround the fireplace 9 and which have bores in the direction of the fire parts 9. These bores are possible in all variants, as a result of which the supply air guide device 30 is also suitable for heating devices 1 which have no rust for the primary air supply from below into the fireplace 9. It should also be mentioned that for better illustration of the supply air control device according to the invention, the illustrations are partially schematic and parts are disproportionate to each other. 1. Supply air guide device for the secondary air in a heating device with a supply air control device which has outflow openings for the secondary air in a combustion chamber in the region of an upper edge of a door cutout of the heating device and with an air guide device which is arranged on a grate plate of the combustion chamber at least in the area of the door cutout. and a partition wall and a floor guide element which extends at a distance from the inside of the door facing the combustion chamber and the grate plate in the direction of the cover plate of the combustion chamber, an air distribution channel being formed between the inside of the door and the partition wall and the partition wall in the region of the grate plate over at least a breakthrough is connected to the combustion chamber, characterized in that the partition (37) is spaced above vertical grate elements (57) above the grate plate (8) and a guide surface (39) of the floor guide element (38) sic h extends from a region near the lower edge of the door cutout (21) in the direction of the cover plate (4), with, as is known per se, a distance between the floor guide element (38) and the inside of the door (12) with increasing distance from the grate plate (8) is greater, and the height (52) of the guide surface (39) of the floor guide element (38) above the grate plate (8) is smaller than the height (50) of the partition wall (37) above the grate plate (8). 2. Air supply device according to claim 1, characterized in that the height (50) of the partition (37), in particular starting from the vertical central region of the door cutout (21), decreases in the direction of the 5 AT 404 873 B side walls (44). 3. Supply air guide device according to claim 1 or 2, characterized in that the guide surface (39) of the floor guide element (38) and the partition (37) form an air guide channel (31) which extends from an area near the lower edge of the door cutout (21) Extends towards the center of the combustion chamber. 4. Supply air guide device according to one of claims 1 to 3, characterized in that a cross-sectional area of the air guide duct (31) in a horizontal plane perpendicular to the rear wall (46) is larger than a cross-sectional area of an air distribution duct (36) between the partition (37) and the inside the door (12). 5. Air supply device according to one of claims 1 to 4, characterized in that a longitudinal axis of the air duct (31) extends from a lower edge (29) of the door cutout (21) into a central region of the flame zone. 6. Air supply device according to one of claims 1 to 5, characterized in that the partition (37) and the guide surface (39) of the floor guide element (38) run substantially parallel to each other. 7. Air supply device according to one of claims 1 to 6, characterized in that the partition (37) and the floor guide (38) along the end wall and the side walls (59, 44) to the rear wall (46). 8. supply air guide device according to claim 7, characterized in that the partition (37) and the bottom guide element (38) also extend over the rear wall (46). 9. air supply device according to claim 8, characterized in that in the partition (37) in the region of the rear wall (46) the air distribution channel (36) with the combustion chamber (2) connecting openings, in particular bores (62) are arranged. 10. Air supply device according to one of claims 1 to 9, characterized in that the floor guide (38) in the area of the door cutout (21) with respect to its bearing surface on the grate plate (8) offset, in a free area between the grate plate (8) and the door cutout (21) engaging spacer element (58). 11. Supply air guide device according to one of claims 1 to 10, characterized in that the partition (37) and the bottom guide element (38) are in particular integrally formed with one another and are preferably formed as a casting, in particular made of cast iron. Including 7 sheets of drawings 6