DE9309168U1 - Heating device for heating poultry and cattle houses - Google Patents

Description

The invention relates to a heating device for heating poultry and livestock houses, in particular using gas and in recirculation mode, with a housing, a burner, a combustion chamber arranged in the housing and a fan for supplying air, in particular for supplying recirculation air into the housing or through it, whereby hot combustion gases arising in the combustion chamber are mixed with the supplied air or emerge from the housing alongside it.

In general, it is a heating system in which a fuel, especially natural gas or propane gas, is burned and the hot combustion gases are fed directly into a

&igr; room. The air required for combustion is drawn in from the room or supplied as fresh air from outside. In addition, an air flow is generated in the heating system by a fan so that the hot combustion gases are entrained and carried far into the room. The air required for this is conveyed through the housing of the heating system by an additional fan. Here, too, the required amount of air can be taken from the room air (recirculation mode) or supplied from outside as fresh air. Preferably, this is a heating system that works in recirculation mode.

The use of such heating systems is well known for heating poultry and livestock houses. Preferably natural gas or propane gas is burned as optimally as possible by a regulated burner. The hot combustion gases are blown together with circulating air directly into the house to be heated. The air in such a house can contain dust. As soon as dust gets into the circulating air flowing through the housing or into the combustion air supplied to the burner, dangerous sparks can easily fly from glowing dust particles. Either the dust is burned directly, creating sparks, or dust comes into contact with the hot combustion gases escaping from the combustion chamber and starts to glow. Both represent a major fire hazard for the room to be heated.

The object of the present invention is to create a heating device of the type mentioned at the outset in which the risk of an unwanted fire, in particular due to flying sparks, is largely reduced.

According to the invention, the object is achieved in that the combustion chamber is followed by a further (second) combustion chamber through which the hot combustion gases flow. The combustion process can be carried out in the second combustion chamber

&igr; further closed. The flame in the first combustion chamber can reach the second combustion chamber. In the second combustion chamber, the combustion gases can cool down further. Sparks already present in the combustion gases can still be extinguished in the second combustion chamber. Direct contact between the flames and the supplied air (circulating air) is largely excluded. The second combustion chamber therefore functions as an extension of the first combustion chamber.

Advantageously, the two combustion chambers together are longer than the housing, at least longer than the length available for one combustion chamber, so that a longer distance is available for complete combustion than would be possible with just one combustion chamber. The length of the housing is therefore better utilized.

A particularly advantageous embodiment is one in which the first, in particular tubular, combustion chamber defines a longitudinal extension and a flow direction of the combustion gases and in which the second combustion chamber is arranged opposite to this flow direction, with overflow channels being provided at the end of the first combustion chamber for introducing the combustion gases into an inlet area of the second combustion chamber. The hot combustion gases are therefore returned in the opposite direction to their original direction. This means that the available housing length can be used particularly well.

According to a further feature of the invention, the first combustion chamber and/or the second combustion chamber are surrounded by the air conveyed through the housing. The combustion chambers are therefore cooled from the outside, so that the hot combustion gases emerging from the combustion chambers have a reduced temperature.

- 4 -Advantageously, the second combustion chamber has an outlet

entry area for the hot combustion gases, which is offset relative to the end of the first combustion chamber against the flow direction of the air conveyed through the housing, i.e. is arranged upstream, with the exit area facing the entry side for the air (circulating air) in the housing, so that the combustion gases are diverted twice before they exit the housing and travel a maximum of three times the length of the housing, preferably three times the length of the combustion chamber. The formation or escape of sparks from the housing is thus virtually impossible. The multiple diversions and the mixing with the circulating air result in complete combustion and at the same time cooling of the combustion gases. Solids entering with the circulating air can no longer burn or glow. Sparks contained in the combustion gases are extinguished in any case before they exit the housing.

The invention also includes an embodiment of a heating device according to the preamble of claim 1, in which the hot combustion gases (before exiting the housing) are first mixed with the supplied air (circulating air) and only exit from the housing after passing through at least a partial length, wherein the

^y

mixed gases (air and combustion gases) in the housing are preferably guided against the flow direction of the burner and exit the housing. In this way, a longer path is created over which the combustion gases can cool down and any sparks can be extinguished.

Further features of the invention emerge from the claims and the description. Advantageous embodiments of the invention are explained in more detail below with reference to drawings. They show:

Fig. 1 is a side view of the heating device according to the invention,

Fig. 2 is a cutaway plan view of the heating device from the direction of arrows 11 - 11 in Fig. 1.

Fig. 3 is a front view of the heating device according to the arrow III in Fig. 1,

Fig. 4 is a front view of combustion chambers inside the heating device according to Fig. 2,

Fig. 5 a (oblique) top view of the combustion chambers

according to arrow V in Fig. 4,

Fig. 6 is a section through the combustion chambers along the line VI-VI in Fig. 4.

A heating device 10 according to the invention has a housing 11 with a housing wall 11a in the form of a pipe section. On the outside of the housing 11 there is an electrical control box 12, a connection 13 for a gas supply with a connected gas line 14 and an air supply 15 with an adjustable radial fan 16.

The housing 11 can be mounted on a frame, for example, by means of retaining plates 17 arranged in the lower area.

In Fig. 1 on the left is the inlet side 18 and on the right is the outlet side 19 of the housing.

According to Fig. 2, inside the housing 11, as seen from the inlet side 18, there is an axial fan 20 with propeller 21, the gas line 14 leading into the housing interior,

&igr; also the air supply 15 and combustion chambers 22, 23 with a burner 24 immersed in the middle are arranged. The latter is not described in more detail. The combustion chambers 22,

23 extend over approximately half the length of the housing 11 (middle to end). The burner output is preferably in the range of 15 kW to 124 kW.

The axial fan 20 can be clearly seen again in the front view of Fig. 3. An inlet grille 25 is arranged in front of the propeller 21.

Fig. 4 to 6 show the structure of the combustion chambers 22, 23 in more detail. Fig. 4 shows a view of the front side of the combustion chambers along the section line IV-IV according to Fig. 2, without surrounding parts (housing, air supply). In the middle is a flange 26 with holes 27 distributed around the circumference for fastening the burner insert (not shown) (burner

24 in Fig. 2). The burner insert is located centrally in the first inner combustion chamber 23. This is designed as a tube shaped section, similar to the housing 11, but with a much smaller diameter. The second, outer combustion chamber 22 sits as a ring-shaped shell around the first combustion chamber 23 and is just as long as the latter.

At the downstream end of the first combustion chamber 23, overflow channels 28 are arranged for connection to the second, outer combustion chamber 22. The overflow channels 28 extend from the first combustion chamber 23 in the radial direction directly into the second combustion chamber 22.

Outlet openings 29 are provided for the gases to exit the second combustion chamber 22. These are again directed radially outwards and arranged at a small distance from the flange 26 (see Fig. 2).

To center the combustion chambers 22, 23 in the housing 11, L-shaped spacers 30 are provided, of which four are attached to the

- 7 -&igr; are arranged distributed around the circumference.

A circumferential annular gap 31 is formed between the two combustion chambers 22, 23. A similar annular gap 32 exists between the second outer combustion chamber 22 and the housing 11. Spacers 33 are arranged in the annular gap 31 adjacent to the flange 26.

The overflow channels 28 and the outlet openings 29 are evenly distributed around the circumference of the combustion chambers (four outlet openings and overflow channels each). As can be clearly seen in Fig. 4, there is an offset of approximately 45° in the circumferential direction between the outlet openings 29 and the overflow channels 28. The corresponding angle is designated with α. In the axial direction, there is an offset anyway, since the outlet openings 29 are arranged near the flange 26 and the overflow channels 28 near the outlet side 19.

The flow of the combustion gases is explained below using Fig. 6. In the area of the flange 26, combustion air, in this case fresh air mixed with combustible gas, such as natural gas or propane gas, enters the first inner combustion chamber 23 in the direction of arrow 34. At a The gas mixture is burned in the burner nozzle (not shown) and flows as hot combustion gas along the arrows 35 through the overflow channels 28 into the second outer combustion chamber 22. There it then flows in the opposite direction to the arrow 34 to the outlets (not shown in Fig. 6). outlet openings 29, see Fig. 5. The flame at the burner nozzle may reach the second combustion chamber 22. Only hot combustion gases will be released from the outlet openings 29. These will mix with the air blown into the housing 11 by the fan 20. conveyed circulating air and flow in the direction of arrows 36 to the outlet side 19 and from there out of the housing 11. At the same time, the incoming circulating air (arrows 37) is guided through the circumferential annular gap 31. This creates an external

&igr; Wall 38 of the first inner combustion chamber 23 as well as inner and outer walls 39, 40 of the second outer combustion chamber 22 are cooled by the incoming circulating air. In this way, an effective heat exchange with the hot combustion gases. The gases exiting the housing 11 on the outlet side 19 are strongly mixed with the incoming circulating air, are significantly cooler than the hot combustion gases occurring immediately after the burner flame and are free of still glowing sparks.

&iacgr;&ogr; The temperature of the combustion gases when mixed with the circulating air is so low that any solids present in the circulating air can no longer form sparks. If they do, they are extinguished on the long path to the outlet side 19. The second outer combustion chamber 22 In this sense, the chamber referred to can also be referred to as a cooling section.

The previously described arrangement of the overflow channels 28 and the outlet openings 29 offset by 45° is particularly favorable, since the hot combustion gases exiting from the outlet openings 29 are guided in the annular gap 31 between two overflow channels 28. However, an arrangement without offset or with other offset angles is also possible.

Various safety devices are provided inside the housing 11. Of particular importance is a so-called wind vane switch 41 downstream of the propeller 21. If there is no signal from the wind vane switch 41, the gas supply and thus also the burner 24 are switched off via a solenoid valve 42.

Applicant;

Jan Hindrik Brink Birger-Forellstrasse

4459 Neugnadenfeld

18 June 1993/4521 BNK-Il-DE

Reference list

10 Heating device 35 Pfei Ie 11 Housing 36 Arrows 11a Housing wall 37 Pfei Ie 12 Electrical control box 38 outer wall 13 Connection 39 inner wall 14 Gas line 40 outer wall 15 Air supply 41 Wind vane switch 16 Radial blower 42 Solenoid valve 1 17 Retaining plates &agr; angle 18 Entrance page 19 Exit side 20 Axial fan 21 propeller 22 Combustion chamber 23 Combustion chamber 24 burner 25 Inlet grille 26 flange 27 Drilling 28 Transfer channels 29 Outlet openings 30 Spacers 31 Annular gap 32 Annular gap 33 Spacers 34 Arrow

Claims (15)

Expectations 1. Heating device for heating poultry and livestock houses, in particular using gas and in recirculation mode, with a housing (11), a burner (24), a combustion chamber (23) arranged in the housing (11) and a fan (20) for supplying air, in particular for supplying recirculation air into the housing (11) or through it, whereby hot combustion gases arising in the combustion chamber (23) are mixed in the housing (11) with the supplied air or emerge from the housing (11) alongside it, characterized in that the combustion chamber (23) is followed by a further (second) combustion chamber (22) through which the hot combustion gases flow. 2. Heating device according to claim 1, characterized in that the two combustion chambers (23, 22) together are longer than the housing, at least longer than the the length available to a combustion chamber, so that a total distance available for complete combustion is longer than would be possible with only one combustion chamber. &iacgr;&ogr; 3. Heating device according to claim 1 or 2, characterized in that the first, in particular tubular, combustion chamber (23) defines a longitudinal extension and a flow direction (arrow 34) of the combustion gases and that the second combustion chamber (22) is arranged opposite this flow direction is arranged opposite, wherein overflow channels (28) are provided at the end of the first combustion chamber (23) for introducing the combustion gases into an inlet region of the second combustion chamber (22). 4. Heating device according to one or more of claims 1 to 3, characterized in that the first combustion chamber (23) and/or the second combustion chamber (22) are surrounded by the air (circulating air) conveyed through the housing (11). 5. Heating device according to one or more of claims 1 to 4, characterized in that the second combustion chamber (22) has an outlet area (outlet openings 29) for the hot combustion gases, which is relatively towards the end (overflow channels 28) of the first combustion chamber (23) against the flow direction (arrows 34, 37) of the air conveyed through the housing (11), i.e. is arranged upstream, and that the outlet area (outlet openings 29) in particular of the inlet side (18) for the air in the housing (11) is arranged so that the combustion gases are diverted twice before exiting the housing (11) and are a maximum of three times the housing length, preferably three times the combustion chamber length, - 11 &igr; as a route. 6. Heating device according to one or more of claims 1 to 5, characterized in that the first combustion chamber (23) in the housing (11) is arranged in the direction transverse to the longitudinal extension preferably approximately centrally and the second combustion chamber (22) at least partially encloses the first combustion chamber (23) in the form of a jacket or ring. 7. Heating device according to claim 6, characterized in that a gap, in particular an annular gap (31), is provided between the combustion chambers (23, 22) for the passage of the air flowing through the housing (11). 8. Heating device according to one or more of claims 1 to 7, characterized in that a gap, in particular an annular gap (32), is provided between the housing wall (Ha) and the second combustion chamber (22) for the passage of the air flowing through the housing (11) and that the outlet region of the second combustion chamber (22) has at least one outlet opening (29) in particular opposite this gap. 9. Heating device according to one or more of claims 1 to 8, characterized in that combustion air can be supplied to the burner (24) at the beginning of the first combustion chamber (23) via an additional, separate air duct (air supply 15). 10. Heating device according to claim 9, characterized in that a preferably controllable fan (16) is arranged upstream of the air duct (air supply 15) for the combustion air. 11. Heating device according to one or more of claims 1 to 10, characterized in that the housing (11) is tubular with a fan, preferably an axial fan (20), on an inlet side - 12 &igr; (18). 12. Heating device according to one or more of claims 1 to 11, characterized in that the two combustion chambers (23, 22) are arranged together as a unit within the housing (11) and are held in the housing (11) by, in particular, L-shaped profile pieces (spacers 30). 13. Heating device according to one or more of claims 1 to 12, characterized in that a flow switch, in particular a wind vane switch (41) is arranged in the housing (11) between the fan (20) on the inlet side (18) and the combustion chambers (23, 22) arranged downstream, by means of which preferably the fuel supply or the burner (24) can be switched off. 14. Heating device according to one or more of claims 3 to 13, characterized in that the overflow channels (28) and the outlet openings (29) are arranged offset from one another in the circumferential direction of the combustion chambers (23, 22), preferably by 45° each in the case of four overflow channels and four outlet openings. 15. Heating device for heating poultry and livestock houses, in particular using gas and in circulating air mode, with a housing (11), a burner (24), a combustion chamber (23) arranged in the housing (11) and a fan (20) for supplying air, in particular for supplying circulating air into the housing (11) or through it, whereby hot combustion gases arising in the combustion chamber (23) are mixed with the supplied air or emerge from the housing alongside it, in particular according to one or more of claims 1 to 14, characterized in that the hot combustion gases (before emerging from the housing 11) are first mixed with the supplied air and only emerge from the housing (11) after passing through at least a partial length, and that the mixed mixed gases (air and combustion gases) in the housing are preferably guided against the flow direction of the burner (24) and exit from the housing (11).