DE19926403A1 - Method and device for burning fuel - Google Patents

Abstract

According to the invention, the fuel is combusted in an under-stoichiometric primary zone and in an adjacent over-stoichiometric secondary zone. The combustion in the primary zone occurs in an irrotational manner, whereby a circulating radial step creates an abrupt expansion of the cross-section of the combustion chamber and stabilizes the irrotational flame. Air enriched with oxygen is fed as secondary oxygen carrier gas into the secondary zone and, to be precise, is fed to one single position laterally adjacent to the outlet of the combustion products of the primary zone. The inventive method permits the generation of high temperatures with minimal pollutant emissions.

Description

The invention relates to a method and a Vorrich device for burning fluid or fluidisable, preferably gaseous fuel in a substoichiome trical primary zone with the supply of a primary oxygen carrier gas and in a subsequent superstoichiometry secondary zone with the supply of a secondary oxygen carrier gas.

In the entire combustion technology, the aim is improve efficiency and pollutant emissions to limit. This is also the object of the invention in particular when applied to high temperature processes se.

To solve this problem is the Ver drive according to the invention characterized in that the pri mär oxygen carrier gas swirled into the primary zone leads and that the combustion products of the primary zone on their way to the secondary zone of a leaping cross section expansion.

So far it has been considered essential, the primary To introduce oxygen carrier gas with swirl into the primary zone, since it was believed that only the twist - besides his Mixing effect - could prevent the flame from breaking off.

The invention is based on the finding that the jump is able to expand the cross-section, the flame to stabilize sufficiently.

A swirling combustion leads to a short, hard flame with intense implementation and, depending on the Swirl strength, also for an internal exhaust gas recirculation in the Flame. According to the invention, however, forms in the primary zone a long, soft flame with slow conversion.

The invention offers the possibility to achieve an increase in performance and a temperature increase while at the same time minimizing pollutant emissions, in particular the generation of NO _x .

High temperature processes with temperatures above 1000 ° C are used in many different ways in technology for example when melting metals, glass or ceramics as well as when performing sintering processes. It goes it is about the materials to be heated as quickly as possible heat up, for which reason high temperatures and high Benefits are required. The requirements Invention to a great extent.

In a development of the invention it is proposed that the secondary oxygen carrier gas in one to three jets, preferably in a single jet into the secondary zone is blown in. So the reaction in the secondary zone is in a few places, preferably in a single place initiated and runs accordingly cheap, namely rela tiv slow.

The secondary oxygen carrier gas also contributes to this at a lateral distance from the primary zone and essentially parallel to their combustion products in the secondary zone blow in. The combustion products of the primary zone experienced a cross section after exiting the primary zone enlargement essentially in a bulbous shape. In these Cross-sectional expansion becomes the secondary oxygen carrier injected gas, and also swirl-free.

As a secondary oxygen carrier gas can easily Air can be used. However, Sauer is more advantageous to use material or air enriched with oxygen.

The higher the oxygen content, the lower the Proportion of nitrogen that must be heated without the To promote the combustion process. A corresponding tempera The result is an increase in power and performance.

The mixing of the reactants and the stability of the flame can be achieved with the swirl-free combustion tion process further improve that the fuel in cross flow to the primary oxygen carrier gas in the primary  zone is introduced. Compared to a swirling one Combustion can thus be done in an energetically favorable manner achieve sufficient mixing. The cross-flow win kel can be chosen arbitrarily. Particularly good results are achieved by having the primary oxygen introduces gas gas axially into the primary zone and the fuel blowing in at an angle of 45 °, centrally.

Acid can also be used as the primary oxygen carrier gas fabric or oxygen-enriched air the. It is advantageous to work in the primary zone however with normal ambient air.

The air ratio of the primary zone can easily be reduced to 0.2 be lowered if only oxygen is in the Secondary zone is injected. Usually one gets at 0.5 work up to 0.7. The total air ratio is preferably close-stoichiometric at 1.05 to 1.2. However, the Invention the advantageous way of having an atmosphere generate adjustable oxygen content, namely by appropriate choice of the oxygen-nitrogen ratio of the secondary oxygen carrier gas.

The burner for fluid or fluidisable, esp special gaseous fuels on which the invention relates further aligns with a flame holder and one itself the combustion chamber attached to the flame holder, wherein the flame holder at least one passage opening for the fuel and at least one passage opening for a primary oxygen carrier gas. That Bren ner is according to the invention to solve the task characterized in that in the flame holder trained passage opening for the primary oxygen Carrier gas is aligned so that the primary acid carrier gas enters the combustion chamber without swirl, and that the combustion chamber has a jump downstream of the flame holder has cross-sectional expansion.  

This burner allows the related to the The method according to the invention to bring about advantages len. It can be operated in any position.

At the primary oxygen passage Carrier gas can be a continuous gas, for example act or interrupted annular gap. Any come too Patterns of passage openings in question, for example of Bores or radial gaps. It is essential that the through Do not create swirl openings.

Preferably one is adjacent to the combustion chamber outlet exit opening for a substantially parallel to the Combustion chamber emerging secondary oxygen carrier gas seen. The oxygen carrier gas is therefore on a single Place in the combustion products of the primary zone tet, and only behind the combustion chamber. So it happens a strong slowdown in the combustion reaction. Possibly. can the secondary zone with no visible combustion reaction, so work flameless.

As mentioned, the one formed in the flame holder Passage opening for the primary oxygen carrier gas basically be shaped arbitrarily, for example as annular slot or pattern of bores and / or Slits. It can also be inclined to the axis of the combustion chamber his. It is advantageously aligned axially, wherein preferably a plurality of centrally arranged, after outwardly inclined passage openings for the fuel is seen. This way, with a minimum Mixing energy achieved sufficient mixing.

In a development of the invention it is proposed that abrupt cross-sectional expansion of the combustion chamber as to form a circumferential radial step. This stage that before is preferably sharp-edged, serves to blow out the flame stabilize accordingly and fix it to the flame holder. The Stage causes a recirculation of the combustion products in the Outside of the combustion chamber, where appropriate a certain proportion  the furnace atmosphere can be sucked into the combustion chamber can.

Advantageously, the cross section of the tapers Combustion chamber, starting from the flame holder sudden cross-sectional expansion and preferably also based on the sudden expansion of the cross-section towards the combustion chamber outlet. So the way of working can approach that of a pulse burner. The taper can run in an arc. However, a cone is more advantageous blunt-shaped training.

The combustion chamber is advantageously in a kerami formed burner stone, this preferably one essentially parallel to the combustion chamber Has channel for the secondary oxygen carrier gas. Dude natively there is the option to put the burner stone in one Insert housing, which of a channel or one Lance for the secondary oxygen carrier gas is interspersed. Furthermore, the entire burner can be made in one piece from ceramic be done.

The invention is based on a preferred Embodiment in connection with the accompanying Drawing explained in more detail. The drawing shows in:

Fig. 1 shows an axial section through a burner according to the invention, which is operated with natural gas.

The burner has a housing 1 in which a burner block 2 is arranged. The latter forms a combustion chamber 3 , which connects to a flame holder 4 .

The housing 1 has an air duct 5 which is connected to the combustion chamber 3 via passage openings 6 .

The housing 1 also contains a gas duct 7 , which is connected to the combustion chamber 3 via passage openings 8 .

As shown, the passage openings 6 are aligned axially. So you let the primary air enter the combustion chamber 3 without swirl. The openings 8 are arranged centrally in the flame holder 4 and inclined radially outwards at an angle of 45 °. The gas also enters the combustion chamber 3 without swirl.

There is consequently a swirl-free combustion in the combustion chamber 3 , so that a long, soft flame with slow conversion is formed. The flame is prevented from being raised by a circumferential radial step 9 , which forms a sudden cross-sectional expansion of the combustion chamber 3 . Since the gas enters the primary air at an angle, there is sufficient intensive mixing with low mixing energy and correspondingly low pressure loss.

A lance 10 , which is aligned parallel to the combustion chamber 3 , ensures the supply of a secondary oxygen carrier gas, which in the present case is oxygen. The outlet opening 11 of the lance 10 lies at the level of the combustion chamber outlet. The mixing of the secondary oxygen carrier gas into the combustion products of the primary zone thus takes place at a single point and, moreover, at a lateral distance from the combustion chamber outlet.

Therefore, the combustion reaction in the secondary zone is very slow, resulting in low NO _x emissions.

As can be seen from the drawing, the circumferential radial stage 9 , which otherwise causes a certain recirculation, divides the combustion chamber 3 into two sections, namely a first section 12 , which lies between the flame holder 4 and the stage 9 , and a second Section 13 , which extends from stage 9 to the combustion chamber outlet. Both sections are frustoconically tapered in the direction of flow, so that the speed of flow of the combustion products is accelerated a first time when passing stage 9 and a second time at the combustion chamber outlet.

The combustion chamber 3 , as mentioned, is formed by the burner block 2 , which, in contrast to the illustration according to FIG. 1, can also contain a channel for the secondary oxygen carrier gas.

Within the scope of the invention, further modifications are quite possible possible. So can on the conical taper supply in one or both of the combustion chamber sections to be waived. There is also the possibility of using a A plurality of lances for the secondary oxygen carrier gas work. However, the number should be limited to the Combustion reaction in the secondary zone is not too strong accelerate. Various come for the flame holder Variants in question what the shape of the passage openings for the primary air and the gas. Is essential however, that the primary zone works swirl-free. Instead of simple air can also be oxygen-enriched air be blown into the primary zone. As a secondary sour Carrier gas has pure oxygen or air with it proven with a high oxygen content. Simple air is equally applicable, if it is not about a to generate a hot furnace atmosphere with a high oxygen content.

Otherwise, the use of one or more lances for the secondary oxygen carrier gas is only one of the constructive ones Possibilities for loading the secondary zone.

It is essential that the secondary oxygen carrier gas one place or at most a few places in the second därzone reaches, and at a lateral distance from the distillery chamber outlet. Overall, the invention allows burning without temperature peaks with even distribution of the Flame in the room.

Claims (15)

1. A method for burning fluid or fluidizable fuel in a substoichiometric primary zone with the supply of a primary oxygen carrier gas and in a subsequent superstoichiometric secondary zone with the supply of a secondary oxygen carrier gas, characterized in that the primary oxygen carrier gas is introduced into the primary zone without swirl and that Combustion products of the primary zone on their way to the secondary zone are subjected to a sudden cross-sectional expansion. 2. The method according to claim 1, characterized in that that the secondary oxygen carrier gas in one to three jets len, preferably in a single beam, into the secondary zone is blown. 3. The method according to claim 2, characterized in that that the secondary oxygen carrier gas at a lateral distance from the primary zone and substantially parallel to its Combustion products are blown into the secondary zone. 4. The method according to any one of claims 1 to 3, characterized characterized in that sow as a secondary oxygen carrier gas air or oxygen-enriched air becomes. 5. The method according to any one of claims 1 to 4, characterized characterized in that the fuel cross-flows to the primary Oxygen carrier gas is introduced into the primary zone.   6. The method according to any one of claims 1 to 5, characterized characterized in that air is the primary oxygen carrier gas is used. 7. burner for fluid or fluidisable fuel, with a flame holder ( 4 ) having at least one passage opening ( 8 ) for the fuel and at least one passage opening ( 6 ) for a primary oxygen carrier gas, and with one on the flame holder ( 4th ) subsequent combustion chamber ( 3 ), characterized in that the passage opening ( 6 ) formed in the flame holder ( 4 ) for the primary oxygen carrier gas is oriented such that the primary oxygen carrier gas enters the combustion chamber ( 3 ) without swirl, and that the combustion chamber ( 3 ) downstream of the flame holder ( 4 ) has a sudden cross-section expansion. 8. Burner according to claim 7, characterized by an outlet opening adjacent to the combustion chamber outlet ( 11 ) for a substantially parallel to the combustion chamber ( 3 ) austre tending secondary oxygen carrier gas. 9. Burner according to claim 7 or 8, characterized net gekennzeich that the flame formed in the holder (4) the passage openings are directed (6) for the primary oxygen carrier gas axially from. 10. Burner according to one of claims 7 to 9, characterized in that the flame holder ( 4 ) has a plurality of centrally arranged passage openings ( 8 ) for the fuel, which are arranged inclined to the outside. 11. Burner according to one of claims 7 to 10, characterized in that the sudden cross-sectional expansion of the combustion chamber ( 3 ) as a circumferential radial step ( 9 ) is formed. 12. Burner according to one of claims 7 to 11, characterized in that the cross section of the combustion chamber ( 3 ), starting from the flame holder ( 4 ), tapers towards the abrupt cross-sectional expansion. 13. Burner according to one of claims 7 to 12, characterized in that the cross section of the combustion chamber ( 3 ), starting from the sudden cross-sectional expansion, tapers towards the combustion chamber outlet. 14. Burner according to one of claims 7 to 13, characterized in that the combustion chamber ( 3 ) is formed in a ceramic burner block ( 14 ). 15. Burner according to claim 14, characterized in that the ceramic burner block ( 14 ) has a substantially parallel to the combustion chamber ( 3 ) channel for the secondary oxygen carrier gas.