EP0271500B1 - Pre-mix gas burner - Google Patents

Abstract

A combustion pipe (1) is designed as a cylindrical hollow body with a horizontal axis, and is provided with an inner chamber (2) which is supplied from a pre-mix gas nozzle, not illustrated, with entrainment of primary air. In the inner chamber (2) a combustion gas/primary air mixture is transported accordingly. Leading from the gas pipe which extends to the pre-mix nozzle is a branch pipe which leads to a secondary line (3) ending in distribution pipes (4) which are arranged in parallel on both sides of the effective combustion pipe but at a distance from and on the lower side of the latter. On the upper side (5) of these distribution tubes are outlet openings for combustion gas, which emerges upwardly with a wedge shape in a region (6) and thereby penetrates the region of the secondary air which is marked by arrows (7) and with which it mixes. In this way an oxygen-depleted mixture arrives in particular at the foot (8) of the main flame (9), said depletion being effected by the combustion gas itself.

Description

The present invention relates to a premix gas burner according to the preamble of the main claim.

Premix gas burners are known, for example from DE-A-3022 763.

These pre-mixed gas burners, which work quite well in themselves, need to be improved with regard to their nitrogen oxide emissions.

The object of the present invention is therefore to develop such a burner which is characterized by a minimal nitrogen oxide emission.

The problem is solved with the characterizing features of the main claim.

Further refinements and particularly advantageous developments of the invention are the subject of the remaining claims or emerge from the following description, which explain the exemplary embodiments of the invention with reference to FIGS. 1 to 13.

• Figur 1 das Prinzip einer ersten Ausführung des erfindungsgemäßen Vormischgasbrenners,
• Figur 2 das Prinzip einer zweiten Ausführung des erfindungsgemäßen Vormischgasbrenners,
• Figuren 3 bis 6 weitere Ausführungen des erfindungsgemäßen Vormischgasbrenners,
• die Figuren 7 und 8 eine Kesselbrennerdurchführung der Erfindung,
• Figur 9 einen Brenner für besonders schwierige Zündverhältnisse,
• Figuren 10 und 11 weitere Ausführungsformen des erfindungsgemäßen Vormischbrenners
• und die Figuren 12 und 13 Ausführungen als Gas-Gebläsebrenner

Show it:

• FIG. 1 shows the principle of a first embodiment of the premix gas burner according to the invention,
• FIG. 2 shows the principle of a second embodiment of the premix gas burner according to the invention,
• FIGS. 3 to 6 further versions of the premix gas burner according to the invention,
• FIGS. 7 and 8 show a boiler burner implementation of the invention,
• FIG. 9 shows a burner for particularly difficult ignition conditions,
• Figures 10 and 11 further embodiments of the premix burner according to the invention
• and Figures 12 and 13 versions as a gas forced draft burner

In all 13 figures, the same reference numerals denote the same details.

The basic principle of the invention is that fuel, in particular gas, is supplied to the secondary air of the burner in order to minimize the NO _x emission. The gas can be, for example, vaporized or gasified oil or oil as an aerosol in an oil burner, gasified liquid gas such as propane or butane or mixtures thereof in a liquid gas burner, a natural gas burner for natural gas and a city gas burner for city gas. Pure hydrogen could be used with a hydrogen burner. This means that the same fuel gas is mixed into the secondary air, which also serves to feed the actual burner. The invention is based on the knowledge that the formation of nitrogen oxides can generally be reduced by an oxygen-reducing and reducing atmosphere. However, the limit of oxygen depletion is an increase in the proportion of CO in the exhaust gas. The atmosphere is artificially depleted in its oxygen content by a sub-stoichiometric, non-ignitable addition of fresh gas to the secondary air he follows. This is done by tapping gas from the gas supply line and blowing it out through nozzles or slots into areas of the burner through which the secondary air passes.

Figure 1 shows a simple example.

A combustion tube 1 is designed as a cylindrical hollow body with a lying axis and has an interior 2 which is acted upon by a premix gas nozzle, not shown, with the entrainment of primary air. Accordingly, a fuel gas / primary air mixture is transported in the interior 2. A branch leads from the gas feed line leading to the premixing nozzle to a secondary line 3 which ends in distributor pipes 4 which are arranged on both sides in parallel but at a distance and on the underside of the actual burner pipe. On the top of these distributor pipes 4 there are auxiliary gas nozzles 5 for fuel gas, which emerges conically upwards in a region 6 and here engages in the region of the secondary air symbolized by arrows 7 and mixes with it. In particular, a mixture depleted in its oxygen content reaches the feet 8 of the main flame 9, the depletion taking place due to the fuel gas itself.

As FIG. 2 shows, one can do without the secondary line 3 and the distribution pipes 4 by simply providing outlet openings 11 on the underside 10 of the combustion tube 1, from which the fuel gas enriched with air emerges and along the periphery of the burner tube upwards into the area the flame feet strokes.

FIG. 3 shows a premix gas burner in the manner of a series burner with a plurality of burner chambers 12 arranged parallel and next to one another at a distance. The distances are denoted by 13, the fuel mixture outlet openings by 14. The gas nozzle 15 blows into the injector channel 16 and tears primary air out of the gap 17 With. After a certain distance 18, the gas jet bears against the inner wall 19 of the injector 16 and at a further distance there are 20 gas outlet openings from which fuel gas enriched with air escapes due to the flow conditions in the injector tube, which now continues along the outer periphery of the burner chamber or strokes the upper end of the injector tube into the distance 13 and thus influences the secondary air which also runs along here in terms of its oxygen content.

FIG. 4 shows a grate burner made up of several burner chambers with three burner chambers 12 between which are distances 13 through which the secondary air sweeps from bottom to top. There are a plurality of injector tubes 16 arranged one behind the other per burner chamber, each of which is fed by an associated main gas nozzle 15. Auxiliary gas nozzles 5 are present between these main gas nozzles 15 and blow fuel gas from the fuel gas feed line 21 into the intermediate spaces 13. Here, too, this fuel gas will mix with the secondary air and lead to the previously mentioned oxygen-depleted atmosphere of the secondary air.

FIG. 5 shows a burner similar to FIG. 4, in which three burner tubes 22 are shown as a cylindrical body in a view of the jacket. These burner tubes 22 with horizontal axes analogous to that shown in FIG. 1 have a large number of fuel gas air mixture outlet openings 23 in their upper half region. Gas is blown into the interior of the burner tubes 22 via gas nozzles 15, specifically into the injector channel 16 already mentioned. Primary air is entrained through the gap 17. Auxiliary gas channels 24 branch off from the gas line 21 and extend parallel and at a distance from the burner tubes 22. They have auxiliary gas outlet openings 20 which enrich the secondary air rising between the burner tubes 22 with fuel gas.

In particular, the openings 20 can be designed as shown enlarged in FIG.

The exemplary embodiment in FIG. 7 is again a boiler burner with individual burner tubes 1 lying next to one another. An auxiliary burner tube 25 is arranged between two burner tubes 1 and touches the two burner tubes 1 with its outer circumference. The interior 26 of the auxiliary burner tube 25 is fed with a fuel gas / air mixture, for example via a burner nozzle. At the top 27 there is a large number of fuel mixture outlet openings, so that here the fuel gas air mixture now representing secondary air for the burner tubes 1 emerges from the interior 26 of the auxiliary burner tube 25 and represents the oxygen-depleted atmosphere of the secondary air already described for the actual main burner tubes 1. It is essential that the secondary air-gas mixture must not be ignitable, that is, the proportion of the fuel gas mixed with the secondary air is so small that this mixture is not ignitable.

FIG. 8 shows how the three tubes of FIG. 7 are fed. Fuel gas is blown into the injector tubes 16 from the common fuel gas line 21 through three gas nozzles, two main gas nozzles 15 and an auxiliary gas nozzle 5, of which the middle one only serves to enrich the fuel gas To form secondary air for the flames of the two outer main pipes.

In the event that a non-ignitable mixture of secondary air and fuel gas is difficult to produce, the embodiment shown in Figure 9 can be used. Regardless of the design of the burner tube itself, a sieve 28 is introduced into the area of the secondary air, this sieve 28 ensuring better distribution of the secondary air / fuel gas mixture or forming a backstop for the possibly igniting secondary air / fuel gas mixture. In particular, in the embodiment of FIG. 9 it is provided that the burner is designed approximately as in FIG. 3, that is to say there are outlet openings 20 from which the fuel gas enriched with air for enriching the secondary air in the fuel gas is produced. If there is a risk of formation of an ignitable secondary air / fuel gas mixture, sieves 28 are provided where the mixture has access to the flames of the main burner. The sieves consist of metal wire mesh. The idea of these screens 28 can also be applied to the other burner tube constructions.

The exemplary embodiment according to FIG. 10 shows a burner working particularly advantageously. Here is one Upper plate 30 covering the entire burner area is provided, which has all fuel mixture outlet openings, so that flames form above the plate 30. Below the plate 30 there is an intermediate space 31 which is delimited at the bottom by a lower plate 32. Sections 34 and 35 are formed in any number by retracted intermediate walls 33 between the upper and lower plates 32. All sections 34 are each assigned an injector tube 36, into which fuel gas is blown through a nozzle 15, entraining primary air. The sections 35 are assigned another injector tube 36, into which 5 fuel gas is blown in from an auxiliary gas nozzle. The sections 35 are provided on both sides of two sections 34 and serve to supply the secondary air / fuel gas mixture for oxygen depletion to the main flames of the burner occurring at the top of the sections 34. This means that the outer sides of the burner are each formed by a section 35. All sections 34 are in the middle of the burner. The burners according to FIG. 10 can have almost any length or width extension. They can be polygonal or round in cross-section. It is only essential that each main burner section 34 is surrounded by a secondary air supply section 35, and as far as possible on all sides.

The upper sides of the sections 35 can in this case be formed by metal sieves 28 according to FIG. 9 or also by plate regions which are provided with many holes arranged next to one another.

FIG. 11 shows, by way of example, that the sections 34 and 35 do not necessarily have to have the same configuration over the entire length or width of the burner, so in one case there can be narrower and wider areas which vary over the length in order to both produce undesired CO formation avoid, as well as to facilitate the ignition.

Finally, it should be noted that the principle described is independent of whether liquid or gaseous fuel is originally used or whether it is an atmospheric or a fan burner. Instead of fuel gas, an inert gas can also be used to artificially reduce the proportion of oxygen in the secondary air.

The invention has the advantage that the ratio of the admixed secondary air to the fuel gas mixture (primary air and gas) remains largely the same both in the full load and in the partial load ratio. This results in a largely constant efficiency or one in the partial load range of that of the Full load range not significantly different combustion quality. This allows the combustion chamber to be closed as much as possible.

The following generally applies to the dimensioning of the nozzle surfaces:

The area cross section of one or more auxiliary gas nozzle (s) 5 assigned to a main gas nozzle 15 is 0.01 to 0.4 of the area of the main gas nozzle when the burner is supplied with town gas. When fed with natural gas, the ratio is 0.05 to 0.9 and for LPG between 0.02 and 1.3.

Figures 12 and 13 show an application of the invention also on a gas forced draft burner, since the previous exemplary embodiments have all referred to atmospheric burners.

FIG. 12 shows a first embodiment of a forced draft burner which has a flame tube 50 which is attached to a housing 51. The latter has an air inlet 52 to which air is supplied from a blower, not shown. The interior of the housing 51 or of the flame tube 50 is penetrated by a gas supply tube 53, which extends via a solenoid valve is fed a gas network not shown. The flame-side part 54 of the flame tube 50 is provided with a baffle plate 55 which has air passage slots 56, via which the interior 62 of the housing 51 communicates with the interior of the end 54 of the flame tube. The baffle plate 55 is penetrated by a nozzle head 57, the main gas nozzles 58 of which are arranged radially on a jacket of the nozzle head 57. A slot 56 is assigned to each main gas nozzle 57. In the area of the interior 62, auxiliary gas nozzles 59 are arranged on the jacket of the gas supply pipe 53, via which gas emerges into the interior 62, namely upstream of the baffle plate 55 described design rule set. Air for the burner is thus mixed with natural gas according to the principles already explained.

While there is no separation into primary air and secondary air in the embodiment according to FIG. 12, this division is also made in the embodiment according to FIG. For this purpose, the flame tube 50 has a tube insert 60, through which an annular secondary air duct 61 is created. The auxiliary gas nozzles 59 are designed or arranged such that they can only blow the auxiliary gas into the secondary air ring duct. The primary air remains unaffected by the auxiliary gas.

Claims (22)

1. A premixing burner comprising at least one main gas nozzle (15) and an injector (16), which is associated with said nozzle and opens into a burner tube (12, 22), which has gas-air exit openings (23), which are flown around by secondary air (7), characterized in that at least one main gas nozzle (15) has at least one auxiliary gas nozzle (5) associated with it and the main and auxiliary gas nozzles are fed with the same fuel gas so that a non-ignitable mixture of secondary air and fuel gas is formed.

2. A premixing gas burner according to claim 1, characterized in that in a burner fed with city gas the crosssectional area of one or more auxiliary gas nozzle(s) (5) associated with a main gas nozzle (15) amounts to 0.01 to 0.4 time the area of the main gas nozzle(s) (4).

3. A premixing gas burner according to any of the preciding claims, characterized in that the main gas nozzles (15) and the auxiliary gas nozzles (5) are disposed on at least one circle.

4. A premixing gas burner according to any of the preceding claims, characterized in that the burner tube is horizontal and the auxiliary gas nozzles (5) consist of tubes, which are parallel to and spaced from the burner tube, and the auxiliary gas emerges on the upper side of the shell of said tubes.

5. A premixing gas burner according to any of the preceding claims, characterized in that the burner tube is horizontal, the gas-air exit openings (23) are provided on the upper side of said burner tube and the auxiliary gas exit openings (20) are disposed on the underside of the same burner tube.

6. A premixing gas burner according to any of claims 1 to 3, characterized in that it consists of a row burner having upright mixing tubes and the auxiliary gas exit openings (20) are disposed on the side walls of the injectors (16).

7. A premixing gas burner according to claim 6, characterized in that the auxiliary gas exit openings (20) are disposed in that region (19) of the injector (16) in which the gas jet coming on the burner nozzle (15) contacts the surface of the injector (16).

8. A premixing gas burner according to any of the preceding claims, characterized in that the main and auxiliary gas nozzles are connected to the same gas line.

9. A premixing gas burner according to any of the preceding claims, characterized in that an auxiliary gas nozzle (5) is provided between two main gas nozzles (15) and blows the auxiliary gas into the space between two combustion chambers (12).

10. A premixing gas burner according to any of the preceding claims, characterized in that the auxiliary gas exit openings (20) are provided on tubes which are disposed between the burner tubes (22) and are spaced from and parallel to and disposed between the burner tubes (22).

11. A premixing gas burner according to any of the preceding claims, characterized in that the auxiliary gas exit openings (20) consist of slots formed directly in the auxiliary gas tubes.

12. A premixing gas burner according to any of the preceding claims, characterized in that the main burner tubes (1) and the auxiliary burner tubes (25) contact each other.

13. A premixing gas burner according to any of the preceding claims, characterized in that the auxiliary burner tubes (25) are disposed on a lower level than the main burner tubes (1).

14. A premixing gas burner according to any of the preceding claims, characterized in that the spaces between the burner tubes (22) or burner chambers (12) are covered by a sieve (28).

15. A premixing gas burner according to any of the preceding claims, characterized in that the entire burner consists of a sandwich comprising an upper burner plate (30) and a lower housing plate (32) and is divided by a plurality of vertical partitions (33) so that main and auxiliary burner chambers are formed.

16. A premixing gas burner according to claim 15, characterized in that the sandwich is covered by a sieve (28) adjacent to the auxiliary burner chambers.

17. A premixing gas burner according to claim 15 or 16, characterized in that the burner plate is flat throughout the surface of the main and auxiliary burner chambers.

18. A premixing gas burner according to any of claims 15 to 17, characterized in that the distances between the partitions (33) vary over the entire extent of the burner.

19. A premixing gas burner according to any of the preceding claims, characterized in that the combustion chamber directly contacts the periphery of the burner on all sides so that additional combustion air cannot enter the combustion chamber.

20. A premixing gas burner according to any of the preceding claims, characterized in that the wall of the combustion chamber is cooled by water on all sides.

21. A premixing gas burner according to any of the preceding claims, characterized in that in a fan-assisted gas burner comprising a flame tube (50), an orifice plate (55) and main gas nozzles (58) is provided with auxiliary gas nozzles (59) which are disposed in the air passage upstream of the orifice plate (55).

22. A premixing gas burner according to claim 21, characterized in that a tubular insert (60) is provided in the flame tube (50) and defines an annular secondary air passage (61).

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