DE102016010167A1 - Warm air heating - Google Patents

Abstract

Hot air heating for producing hot air with a burner (5) for combustion of solid fuels, e.g. Pellets or for the combustion of liquid or gaseous fuels, wherein in the interior of a heating housing (1) a horizontal combustion chamber (16) is arranged, to which a burner (5) is flanged, which is directed into the combustion chamber (16) burner flame (53). wherein the combustion chamber (16) is connected in an air-tight manner to a plurality of spaced exhaust flues (39-42) and an exhaust flue (41) is formed by an upper, lying flat register (33) which is separated from the fresh air of a ventilator (8). flows around the outside air and from the outside over the several flues (39-42) passes, which warm the fresh air and run as hot air from the heater housing (1), wherein the combustion chamber (16) consists of at least four exhaust flues (39 42), followed by fuel gases flowed through by airtight connection.

Description

The invention relates to a hot air heating for the production of hot air with solid or liquid fuels, in particular for combustion with pellets, and with oil or gas.

Warm air heaters are known in the form of so-called Bauheiz- or tent heaters, which are equipped with a mobile housing, which is associated with a heat generator and where an outside of the housing arranged electrically operated fan is present, which sucks in the outside air and introduces into the housing. In the housing one or more flues are present, which are flowed through by the injected fresh air for the purpose of heat absorption.

Disadvantage of the previously known hot air heaters, which are operated with gas, oil or pellets, is the low heat efficiency and also an undesirably high proportion of accumulating fine dust.

For the sake of simplicity of description, it is assumed in the following description of the invention that the hot air heating is operated with a burner which gasifies pellets, although the invention is not limited thereto. Instead of a pellet burner, other burners may be used, such as oil or gas burners.

The limitation of the description to pellet burners is therefore not intended to limit the purpose and scope of the present invention.

Part of the use of such solid fuel systems is that the air sucked from the outside via a blower, such as an axial or radial fan, flows into the mobile solid fuel system and the air is heated with high efficiency and this is blown out as warm air from the device with high air flow ,

So it is possible with devices of the known type, air quantities in the range between initial air quantities from 1500 m ³ to 36,000 m ³ per hour with a temperature of about 40 to 90 ° C to remove.

With the subject of the German utility model DE 20 2014 009 049 is such a hot air heater has become known, however, is designed as a mobile hot air device in which the upper heating coil for guiding the flue gases from rectangular profiled sheet metal channels, which are connected to each other in an airtight manner via subsequent collector.

The cited document also discloses in the rear region of the combustion chamber, a rear, standing flat register, which is flowed through on the inside by the exhaust gases. Disadvantage of this arrangement, however, is that the combustion chamber is disadvantageously formed in its axial length so that the rear combustion chamber bottom abuts directly on the rear, standing flat register, whereby an optimal air flow of the exhaust gases is hindered by the two flat registers.

This is also associated with the further disadvantage that the flat register, the principle of the DE 20 2014 009 049 U1 are known, can not work with a high degree of heat exchanger, so they are not able to optimally dissipate the resulting high exhaust gas temperatures, and tend to overheat.

In addition to the unfavorable exhaust air duct in the DE 20 2014 009 049 U1 there is the further disadvantage of hot air generation with low efficiency.

In the publication DE 20 2014 009 049 U1 a centrifugal fan is used, which blows in the fresh air directly between the heating registers, but without an optimized air duct, which is guided around the combustion chamber and around the heating coils around.

Another disadvantage of the document is that a so-called three-chamber train is disclosed, which has a poor heat transfer efficiency.

The invention is therefore based on the above DE 20 2014 009 049 U1 the object of developing such a mobile hot air device so that it has a much better efficiency lower energy consumption with the same or improved air performance. In addition, the amount of accumulating fine dust is to be reduced.

To solve the problem, the invention is characterized by the technical teaching of claim 1.

A feature of the invention is that now the hot air device according to the invention is not designed as a mobile device, but is anchored stationary on a floor, with a base plate is provided with which the device can be mounted directly on a footprint.

It is therefore apart from a mobile operation, which offers advantages in the flanging of a pellet container, and also the injection ports for the discharge of the generated hot air to be heated spaces are better controlled. They are therefore mounted in a specific, fixed angle and allow optimal, jam-free air flow. In the known mobile air heaters namely had the disadvantage that the Ausblasschläuche were kinked and therefore the efficiency was lowered.

Incidentally, the advantage of stationary hot air heating is also that with stationary air heaters it is customary to arrange such heating modules in an enclosing space, and this enclosing space then offers the advantage that additional air preheating is provided for the fresh air to be aspirated.

The fresh air is therefore not extracted directly from the ambient air, but from the enclosing space in which the stationary hot air heating is arranged, which offers advantages in energy utilization.

Accordingly, such a hot air heater according to the invention can be installed in a container which is placed stationary, and the sucked fresh air is then removed from the container, which is preheated by the housing of the hot air heater. Thus, the radiant heat of the hot air heating is used for air preheating the fresh air sucked.

Another feature of the invention is compared to the DE 20 2014 009 049 U1 in that instead of a three-train combustion chamber, a four-stroke combustion chamber is now provided.

The term "four-stroke combustion chamber" is understood to mean that the exhaust gas stream of the burner flame produced escapes through four different, spatially separated exhaust gas trains in the direction of the exhaust pipe and is guided in such a way that the fresh air drawn in is led over a total of four different exhaust gas trains.

The use of a four-pass combustion chamber has the advantage of better energy utilization, a smaller amount of particulate matter and better cleaning options.

In a preferred embodiment of the present invention, the four-pass combustion chamber consists of a first lower horizontal exhaust flue, which merges via the rear standing flat register in a vertical lower exhaust flue which opens into a rear header and further that the third train of a Combustor near collector consists, which receives the fuel gases in the vertical direction and passes through the upper flat plate, which is also connected to the rear plenum.

In this way, four trains are described, because the flat register is the second flue and the third flue is the burner chamber near the front header, which receives the heating gases in the vertical direction and initiates in the horizontal direction in the upper horizontal flat register as the fourth throttle cable.

In principle, two mutually spaced and mutually parallel vertical exhaust trains are provided which are each connected in an air-tight manner with two mutually parallel and horizontal exhaust trains, resulting in a total of a four-train exhaust gas combustion chamber.

This is new and leads to an optimal utilization of the heat energy generated, as has not been the case in the prior art.

Thus, the energy consumption is lowered because of the improved heat transfer rate, whereby tests have shown that in comparison with a three-pass combustion chamber, the energy consumption could be reduced again by 20%.

It is assumed that the same amount of hot air can be generated.

In a warm air heating with 150 kW of the design according to the invention, a pellet consumption of 13 kilograms per hour was achieved. In comparison, an oil heater of the same heat output consumes 18 liters per hour, and this equates to the equivalent of 36 kilograms of pellets per hour.

Accordingly, the invention provides the advantage that only 13 kg per hour are consumed, which corresponds to a fuel oil consumption of 6.5 liters per hour.

This achieves a hot air volume of 12,800 cubic meters of hot air per hour at a temperature of 150 ° C.

Such optimal energy utilization is not achievable with three-chamber combustion chambers. And here lies the value of the invention, which now proposes a four-speed combustion chamber, which in conjunction with an optimal steering of the injected fresh air, an optimal utilization of heat takes place.

Another advantage of the invention is that the outer shell of the combustion chamber can be cooled to a temperature of 55 ° C, that is, the combustion chamber has no undesirably high temperature, which must be dissipated, because the energy dissipation from the combustion chamber through the vierzügige trigger system and through the optimal deflection the fresh air is achieved at the exhaust trains described.

This has the advantage that the combustion chamber can be driven at relatively low temperatures, thereby preventing overheating or even melting of combustion chamber parts.

It is not exceeded in the invention, a maximum combustion chamber outside temperature of 110 ° C. This is essential for the invention, because this results in the favorable degree of heat transfer from the exhaust gases generated in the combustion chamber, which essentially give off their heat energy via the four-draft exhaust system.

Another advantage is that due to the low surface temperatures of the combustion chamber and the surrounding other air-carrying components can be dispensed with relatively thick sheet thicknesses, for example, 4 or 5 mm, and thin sheet thicknesses can be used for the flat register of, for example, 1 mm, without that there is a deformation of the flat register. Thus, the total weight and the manufacturing cost of such a hot air generator are lowered significantly.

In a further development of the invention, it is otherwise provided that the cross section of the flat register is not rectangular, then rectangular flow cross sections are formed, but the flat register plates are approximately trapezoidal in cross-section, which means that they have a much better resistance to bending and deformation and yet develop a large heat transfer area. They can therefore be made from a thinner sheet metal.

Another advantage of the hot air heating according to the invention is because of the use of relatively small sheet thicknesses in that a relatively rapid warming of the fresh air sucked in and therefore when switching off the system and a rapid cooling of the system is guaranteed.

It therefore reacts quickly to temperature changes and to changes in the heating power. Lazy, heat-storing materials are not available in the heater housing.

When using an axial fan for sucking the fresh air has the advantage that can be sucked in from both end faces and the fresh air is introduced centrally into the heater housing on two opposing intake openings.

Another advantage is that the axial fan according to the invention is arranged at the top of the heater housing and the sucked fresh air is directed from top to bottom blown into the heater housing. This results in an optimum increase in temperature of the other, arranged in the heater housing sheet materials.

An advantage of this measure is that the blown in the upper part of the heater housing fresh air is already preheated to the exhaust trains according to the invention, before it sweeps over the burner housing and is further heated there.

The subject of the present invention results not only from the subject matter of the individual claims, but also from the combination of the individual claims with each other.

All information and features disclosed in the documents, including the abstract, in particular the spatial design shown in the drawings, are claimed to be essential to the invention insofar as they are novel individually or in combination with respect to the prior art.

In the following the invention will be explained in more detail with reference to drawings showing only one embodiment. Here are from the drawings and their description further features essential to the invention and advantages of the invention.

Show it:

1 : Schematically, a partial section through a hot air generating plant according to the invention

2 : one opposite 1 modified section omitting various, in 1 represented parts

3 : the same representation as 2 omitting further parts

4 a sectional view through the hot air generating plant according to the invention

5 : a half section through the warm air generating plant, omitting further parts

6 : the frontal view into the combustion chamber seen from the side of the burner in a schematic representation

The representations in the 1 to 5 differ only from each other in that the hot air generation plant a heater housing 1 has been omitted with the progression of the figure numbers each parts of the heater housing for clarity, to better insight into the inner parts of the heater housing 1 to offer.

In principle, there is the heater housing 1 to 1 from an upper sheet 2 , which is designed as a heat shield. It is therefore double-walled.

The upper, horizontal sheet metal 2 goes into a vertical, front sheet 3 about, which is also formed as a heat shield, wherein in the front panel 3 a show-ear 4 for insight into the combustion chamber 16 is provided.

At the front sheet 3 is a flanged pipe 49 for the attachment of a burner 5 arranged, which has a flange 48 is assigned (see 3 ).

At the bottom of the sheet 3 is an ash collector 6 arranged, which is closed by a lid.

In the interior of the heater housing 1 is the four-way combustion chamber 16 arranged, which will be described later in more detail.

The bottom of the heater housing 1 is through a base plate 17 formed, in the lateral receiving openings 20 are provided for retracting the tines of a truck.

In this way, the heater housing 1 be stationarily placed on a site.

In the top of the upper sheet 2 is an exhaust pipe 7 arranged, through which the exhaust gases in the arrow direction 22 flow upwards.

At the rear end of the heater housing 1 is an axial fan in the upper area 8th arranged, the two opposing, mutually aligned suction openings 24 has, so that the fresh air in the opposite directions of the arrow 23 over both intake openings 24 is sucked in and sucked on both sides of the air flow centrally into the heater housing 1 blown.

The air outlet of the generated hot air is also in the rear area, in the area of the rear panel 9 where the air outlet 11 is present, at which a non-illustrated bendable hose for discharging the hot air generated can be arranged.

Inside, the rear panel 9 through a rear heat shield 10 covered inside.

The separation of the fresh air channel in the vertical direction in the interior of the heater housing is effected by a horizontally located barrier plate 26 , which ensures that the blown fresh air from the fan 8th horizontally in the upper area of the heater housing 1 is admitted and does not fall directly downwards towards the combustion chamber.

It is essential that according to 4 a four-burner combustion chamber 16 present, which is formed by a rear, lower collector 13 which is horizontally disposed, and in which the fuel gases from the combustion chamber 16 to flow in a horizontal direction. This collector 13 is the lower (first) exhaust flue 42 , which is flowed around by the fresh air.

That in the collector 13 flowing exhaust gas coming from the combustion chamber 16 stems, flows under air deflection in the indicated arrow direction vertically upwards into the interior of the flat blades of the rear, standing flat register 12 , which are arranged parallel to each other and at a mutual distance and thus the rear, surrounded by the fresh air second flue 39 form.

The fresh air is introduced into the heater housing 1 via an injection opening 25 , So that it is ensured that the injected fresh air only in the horizontal direction, namely in the direction of arrow 27 , in the upper part of the heater housing 1 flows along and does not immediately fall down.

This purpose is also served by a front baffle 28 , which is in the area of the front sheet 3 in the interior of the heater housing 1 is arranged.

The combustion chamber 16 is with a total of four feet 14 on the base plate 17 supported, and above the base plate 17 is a lower sheet 15 arranged, which extends over the entire base of the heater housing 1 extends and part of the base plate 17 is.

In the interior of the heater housing 1 Bottom is a heat shield 18 arranged, which of the feet 14 is interspersed, so that the heat shield 18 avoids that inadmissible heat against the base plate 17 and the bottom sheet 15 is delivered.

Out 2 For more details, refer to important parts 1 in 2 were removed.

The basic features of the four-way exhaust draft system are out 2 already to be seen, although in conjunction with 4 to be described in more detail.

It is important that the combustion chamber 16 a flame in the flame direction 38 generated and in conjunction with 6 is the rear end of the combustion chamber 16 formed by that about the horizontal width of the combustion chamber 16 an angle sheet 54 extends, which consists of an upper horizontal leg 54a and a vertical leg 54b consists.

While the horizontal thigh 54a the angle sheet 54 the entire rear combustion chamber terminates in the horizontal direction, is the vertical leg 54b the angle sheet 54 formed shorter in width, so that laterally lower acute-angled inlet openings 85 for the inflow of fuel gases to the rear, in the first exhaust draft 42 result.

The inflow openings are upwards through cover plates 84 closed, so that the fuel gases only in the indicated arrow directions 86 through the inlet openings 85 can escape to the rear.

So while the fuel gases of the burner flame 53 first in the direction of the arrow 55 (please refer 6 ) impinge on the lower combustion chamber wall, through the reverse plate 56 is formed, they also meet the angle sheet 54 on and on the vertical thigh 54b in the lateral inflow openings 85 in the direction of the arrow 86 as partial flows left and right of the angle plate 54 in each case horizontally behind lying lower flue trains 42 initiated by the collector 13 are formed.

This is thus the first flue gas train, the horizontally lying exhaust flue 42 referred to as.

Through the lower (first) exhaust flue 42 the heating gases flow in the direction of the arrow 86 as partial flows and are in the direction of the arrow 37 vertically upwards, into the rear (second) flue 39 diverted.

The rear (second) exhaust flue 39 is due to the clear cross sections of the rear flat register 12 formed so that all in the horizontal lying (first) flue 42 flowing fuel gases through the interior of the heat exchanger plates arranged there 29 flow through. This is in dashed arrows in 2 indicated where with the arrow direction 37 indicated that the fuel gases from the lower flue 42 , this is the horizontal collector 13 ) in the direction of the arrow 37 be deflected and each through the inner cross sections of the heat exchanger plates 29 of the second vertical exhaust train 39 flow through it.

The rear flat register 12 with its standing heat exchanger plates 29 is as a second flue 39 air-tight with the lower, horizontal collector 13 as the first exhaust train 42 connected.

However, some of the fuel gases are diverted from this exhaust stream and through the third and fourth flue 40 . 41 guided.

This is done according to 4 in that some of the fuel gases on the reversing plate 56 is reflected and as a partial flow in the direction of arrow 60 flows back and divides there, with a first partial flow in the direction of arrow 61 under the burner 5 in the lower inlet opening of a front header 46 flows in, thus the front (third) exhaust flue 40 forms.

The other partial flow of the fuel gases flows in the direction of the arrow 60 directly into the front collector 46 and is in the direction of the arrow up in the direction of arrow 62 deflected and in the upper, lying flat register 33 as the fourth exhaust draft 41 introduced and flows through this

Characteristic of the upper, lying flat register is that there vertically upright, a mutual distance mutually engaging heat exchanger plates 34 are present, whose space is flowed through by the fresh air to be heated. The upper flat register 33 thus forms the fourth exhaust draft 41 ,

The exhaust gases flowing through the individual heat exchanger plates are thus in the direction of the arrow 62 through the interior of the heat exchanger plates 34 led through and also lead into the rear collector 35 where they are with the exhaust stream from the rear exhaust train 39 unite and in the direction of the arrow 59 from the exhaust pipe 7 flow out.

By the arrangement of the four spaced apart exhaust trains 39 . 40 . 41 . 42 Thus, an optimal distribution of the exhaust gas produced is achieved, so that so large, heat-emitting parts are wetted by the fresh air and thus there is an improved energy transfer to the injected fresh air.

The heating of the fresh air stream will be described below.

The of the axial fan 8th sucked fresh air 64 flows into a rear injection chamber 65 , the bottom through the barrier plate 26 air-tight with respect to the interior of the heater housing 1 is sealed.

The fresh air 64 therefore flows around a portion of the rear exhaust train 39 and the rear collector 35 ,

It is therefore in the direction of the arrow 68 in the upper area of the heater housing 1 along the upper flue 41 guided along, but at the same time flows from bottom to top through the upper flat register 33 as it is with the arrow direction 66 is specified. In the injection chamber 65 fresh air injected under pressure therefore also flows in the direction of the arrow 66 through the lower side of the upper flat register 33 and flows around the heat exchanger plates arranged there 34 because the air flow in the direction of the arrow 69 through the spaces between the heat exchanger plates 34 goes through and in the direction of the arrow 70 is diverted.

He therefore unites in an upper injection chamber 67 which is formed lying horizontally.

The injection chamber 67 is forward towards the front plate 3 from an arcuate air baffle 32 limited so that there in the direction of arrows 68 and 70 along flowing, already partially heated fresh air on this air baffle 32 in the direction of the arrow 72 in the deflection chamber arranged there 71 is deflected and in the direction of arrow down into a front-trained circulating air space 51 into flows.

The fresh air that is increasingly heated there 64 is located in the front, vertical circulating air space 51 is derived downwards and becomes in the direction of arrow 73 redirected bottom and flows on the ground 87 the combustion chamber 16 along.

It is important that the fresh air to be heated 64 also in the direction of the arrow 66 through the, the front collector 46 passing through pipes 31 in the horizontal direction forward in the front side arranged circulating air space 51 flows.

In this way takes place in the circulating air space 51 a union of the air flows flowing from top to bottom, of the deflection chamber 71 come, with the horizontal, in the direction of the arrow 66 over the passage pipes 31 flowing airflow.

Due to the arrangement of the spaced apart and horizontally lying passage tubes 31 , which conducts heat with the surfaces of the front header 46 are connected, there is an optimal heat transfer to the direction of the arrow 66 horizontally these passage pipes 31 flowing hot air stream.

The circulating air space 51 is on the bottom side with an air baffle 30 completed, which the air flow in the indicated direction of the arrow 73 deflected and on the ground 87 the combustion chamber 16 leads along the outside.

The air flow thus flows in the horizontal direction of the arrow 74 on the ground 87 the combustion chamber 16 along and arrives in the indicated direction of the arrow in the circulating air space 19 which is the entire combustion chamber 16 surrounds, so that the heated fresh air from the arrow 74 coming in the direction of the arrow 75 continues to flow, the circulating air space 19 flows through and in the rear area in the arrow direction 77 is diverted.

It thus enters a rear mixing chamber 78 where they are in the direction of the arrow 76 emanates and into the air outlet 11 under pressure in the direction of the arrow 21 is blown out.

It is mentioned that the lower exhaust draft 42 at the rear end by a flap 58 which is open and through which the revision work can be carried out.

The 5 shows that in the rear collector 35 a lid 80 is arranged for a cleaning opening. The 5 also shows that the respective profile of the heat exchanger plates 29 of the upper flat register 33 and the rear standing flat register 12 is formed approximately trapezoidal, and thus trapezoidal outflow or flow openings 79 form.

Thus, the heat exchanger plates have a trapezoidal flow profile.

The 5 also shows that the combustion chamber 16 at the rear end by a barrel-shaped combustion chamber floor 81 is complete, and in 5 is also a part plate indicated, which previously with the reference numeral 56 was called reverse plate. The barrel-shaped combustion chamber floor 81 has good reflection properties for the inside reflected there burner flame 53 and forms a large heat transfer surface on the outside.

Below is the function of one in the combustion chamber 16 arranged angle plates 54 described in more detail.

Out 5 it can be seen that the angle plate 54 from a horizontal leg 54a and a vertical leg 54b consists.

According to 6 hits the burner flame 53 with the accompanying fuel gases in the direction of the arrow 55 in the right angle on the vertical leg 54b the angle sheet 54 , The fuel gases are thereby laterally in the direction of arrow 86 deflected and flow through small-sized, lateral inlet openings 85 in the direction of the arrow 55 from.

The openings are above the horizontal leg 54a through cover plates 84 covered so that only relatively small-sized lower inlet openings 85 laterally on the vertical leg 54b the angle sheet 54 available.

The vertical leg 54b the angle sheet 54 is doing through the side edges 88 limited.

The vertical leg 54b the angle sheet 54 points towards the ground 87 the combustion chamber 16 an exemption 83 on, through which the exhaust gas flow in the indicated arrow direction in the underlying exhaust flue 42 flows.

Accordingly, the vertical leg forms 54b the angle sheet 54 a train reversal for the exhaust flow, and thus a better heat transfer surface.

Advantage of the hot air generating system according to the invention is the four-stroke exhaust flue 39 . 40 . 41 . 42 , which leads to an optimal heating of the sucked fresh air flow.

The fresh air flow is at a plurality of heated surfaces of the four-stroke exhaust flue 39 - 42 heated, resulting in a favorable heat transfer with high efficiency.

By the arrangement of a standing, rear flat register 12 There is the advantage that accumulating fine dust in the lower, lying exhaust flue 42 is accumulated and over the graduation flap 58 can be removed.

Due to the fact that the upper, lying exhaust draft 41 is indirectly flowed through already cooled exhaust gases, there is the advantage that lying in this flat register 33 only a small particulate matter deposit arises. There resulting fine dust is with the exhaust gases in the rear collector 35 guided and falls there through the trapezoidal openings of the heat exchanger plates of the rear flat register in the collector arranged underneath 13 and can be done by opening the tailgate 58 easily from the collector 13 be removed.

This results in the greater part of the fine dust deposit in the lower collector 13 (flue gas draft 42 ), while the upper exhaust draft 41 Of fine dust is hardly loaded, because there is little and the small amount of fine dust in the end ultimately in the lower collector 13 arrives.

This also applies to the front exhaust flue 40 because it is only coated by cooled exhaust gases, and therefore a separation of fine dust in this standing flue 40 not to be feared.

LIST OF REFERENCE NUMBERS

1

heater housing

2

upper sheet

3

front sheet

4

viewing tube

5

burner

6

ash collector

7

exhaust pipe

8th

fan

9

rear sheet

10

rear heat shield

11

air outlet

12

rear flat register

13

lower collector

14

stand

15

lower sheet

16

combustion chamber

17

baseplate

18

Heat Shield

19

circulation space

20

receiving opening

21

Arrow direction (warm air)

22

Arrow direction (exhaust gas)

23

Arrow direction (fresh air)

24

suction

25

inflation opening

26

locking plate

27

arrow

28

baffle

29

heat exchanger plate

30

Air baffle, bottom

31

threading pipe

32

Air baffle, top

33

upper flat register

34

heat exchanger plate

35

rear collector

36

arrow

37

arrow

38

direction of the flame

39

rear flue (first)

40

front flue (third)

41

upper exhaust flue (fourth)

42

lower flue (second)

43

arrow

44

arrow

45

arrow

46

front collector

47

48

Flange for burner 5

49

Flange pipe for burner 5

50

Cover for cleaning (front)

51

recirculated air space

52

draw plate

53

burner flame

54

Winkelblech 54a . 54b

55

arrow

56

reverse sheet

57

arrow

58

closing flap

59

arrow

60

arrow

61

arrow

62

arrow

63

arrow

64

fresh air

65

Blow-in chamber, rear

66

arrow

67

Blow-in chamber, above

68

arrow

69

arrow

70

arrow

71

deflection

72

arrow

73

arrow

74

arrow

75

arrow

76

arrow

77

arrow

78

rear mixing chamber

79

outflow

80

Cover for cleaning opening (rear)

81

Combustion chamber floor

82

Partial flow (exhaust gas)

83

exemption

84

cover sheet

85

inflow

86

arrow

87

Ground of 16

88

Side edges of 54

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 202014009049 [0008]
• DE 202014009049 U1 [0010, 0011, 0012, 0014, 0021]

Claims (10)

Warm air heating for the production of hot air with a burner ( 5 ) for the combustion of solid fuels, eg pellets or for the combustion of liquid or gaseous fuels, wherein in the interior of a heating housing ( 1 ) a horizontal combustion chamber ( 16 ) is arranged, on which a burner ( 5 ) flanged into the combustion chamber ( 16 ) directed burner flame ( 53 ), wherein the combustion chamber ( 16 ) with a plurality of spaced apart exhaust trains ( 39 - 42 ) is connected in an air-tight manner and an exhaust flue ( 41 ) from an upper, lying flat register ( 33 ) formed by the fresh air of a fan ( 8th ) is sucked in, the outside air sucks from the outside and on the multiple flues ( 39 - 42 ), which heat the fresh air and as warm air from the heater housing ( 1 ), characterized in that to the combustion chamber ( 16 ) one of at least four flues ( 39 - 42 ) existing, fuel gas flowing through combustion gases followed by airtight. Warm air heater according to claim 1, characterized in that the first exhaust draft ( 42 ) from an air-tight to the combustion chamber ( 16 ), lower horizontal collectors ( 13 ), the airtight with an adjoining vertical flat register ( 12 ) as a second flue ( 39 ) that the combustion chamber ( 16 ) also with a front close, front, vertical collector ( 46 ) connected to the third flue ( 40 ) formed in an upper lying flat register ( 33 ) as the fourth exhaust gas train ( 41 ), which ends in a rear, upper collector ( 35 ) into which also the fuel gases of the second exhaust gas train ( 39 ) and that the upper collector ( 35 ) with an exhaust pipe leading to the outside ( 7 ) connected is. Warm air heater according to claim 1 or 2, characterized in that at the rear and upper end of the heater housing 1 an axial fan ( 8th ) is arranged, the two opposing, mutually aligned suction ports ( 24 ), and that the fresh air ( 64 ) in opposite directions ( 23 ) via both intake openings ( 24 sucked and centrally into a blow-in chamber ( 65 ) of the heater housing ( 1 ) is inflatable. Warm air heater according to one of claims 1 to 3, characterized in that the burner flame ( 53 ) on a stationary, frontally, the combustion chamber ( 16 ) rear end closing plate ( 56 ) and in there back into the combustion chamber ( 16 ) is reflected. Warm air heater according to one of claims 1 to 4, characterized in that burner flame ( 53 ) on a stationary, in the lower part of the combustion chamber ( 16 ) arranged angle plate ( 54 ) impinges the fuel gases via lateral inlet openings ( 85 ) in the first exhaust train ( 42 ), while a proportion of the combustion gases from the combustion chamber ( 16 ) in the front close third flue ( 40 ) can be introduced. Warm air heater according to one of claims 1 to 5, characterized in that the third exhaust draft ( 40 ) by a vertical collector ( 46 ) formed by fresh air-flowed through pipes ( 31 ) is interspersed. Warm air heater according to one of claims 1 to 6, characterized in that in the upper injection chamber ( 65 ) pressed fresh air ( 64 ) as at least two different partial flows into the interior of the heater housing ( 1 ) flows, that the first partial flow first through the heat exchanger plates ( 39 ) of the rear flat register ( 12 ) and the combustion chamber floor ( 81 ) flows and that the second partial flow via the rear header ( 35 ) and the upper flat register connected thereto ( 33 ) in the direction of the front of the heater housing ( 1 ) flows. Warm air heater according to claim 7, characterized in that the first partial flow of the heated fresh air after flowing around the front header ( 46 ) also by the front collector ( 46 ) penetrating through pipes ( 31 ) flows and into a front, vertical Umluftraum ( 51 ), the hot air flow over the combustion chamber floor ( 87 ) of the combustion chamber ( 16 ) and over the first flue ( 42 ) in a rear, vertical mixing chamber ( 78 ) connected to the air outlet ( 11 ) connected is. Warm air heater according to one of claims 1 to 8, characterized in that the warm air-side recirculation air space ( 51 ) on the bottom side with an air baffle ( 30 ), which deflects the flow of hot air and at the bottom ( 87 ) of the combustion chamber ( 16 ) leads along the outside. Warm air heater according to one of claims 1 to 9, characterized in that at the rear end of the first flue ( 42 ) a flap ( 58 ) is arranged over which the in the upper flat register ( 33 ) and in the upper collector ( 35 ), as well as in the rear flat register ( 12 ) particulate matter is removable.

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