EP2881666A1 - Nozzle holder made of metallic foam - Google Patents

Abstract

The invention relates to a nozzle carrier (1) for a jet burner, comprising a nozzle carrier body (2) comprising a hot side (3) facing a combustion chamber during operation and a cold side (4) facing away from the combustion chamber, between which a peripheral edge (5) extends , wherein passages (6) in the nozzle carrier body (2) extend from the cold side (4) to the hot side (3) and form premix zones, wherein the nozzle carrier body (2) is made of metal foam (7) and inner walls (8) of the passages (8). 6) are designed gas-tight for Vormischzonen.

Description

The invention relates to a nozzle carrier for a jet burner.

Jet-stabilized combustion systems, where the fuel is burned in a jet flame downstream of the burner, have a simpler premixing zone compared to spin-stabilized systems. Since the pressure difference in the burner is converted exclusively into the axial velocity component, these burners are characterized by a low flashback tendency, which is why even highly reactive combustion mixtures with a higher hydrogen content can be burned with this burner. Furthermore, no spin-induced vortex structures are generated in jet-stabilized combustion systems, which can cause flame instabilities.

Such a jet-stabilized burner comprises, for example, a jet carrier with a plurality of nozzles, which can usually be arranged concentrically on one or more rings.

The design of the nozzle carrier is usually very solid and therefore associated with high material and processing costs.

Furthermore, the nozzle carrier must be coated and cooled.

The nozzle carrier is made by forging. On the one hand, this shaping method is very expensive and, on the other hand, is only suitable for the production of simple geometries due to the process.

Furthermore, after forging machining is necessary to remove breakthroughs eg for the premixing zone from the forging.

The object of the invention is to further develop said nozzle carrier, so that it is at least easier and cheaper to manufacture.

The invention solves this problem by providing that in such a nozzle carrier for a jet burner, comprising a nozzle carrier body comprising a hot side facing a combustion chamber in operation and a cold side facing away from the combustion chamber, between which a peripheral edge extends, wherein passages in Düsenträgerkörper extend from the cold side to the hot side and form Vormischzonen, the nozzle carrier body is made of metal foam and inner walls of the passages for Vormischzonen are gas-tight.

The nozzle carrier is no longer massively forged and machined, but it is a nozzle carrier body made of foamed metal powder. Cavities or breakthroughs (e.g., for premix zone and pilot cone) can be shaped directly upon foaming. This eliminates the editing. As the material, a high-temperature resistant material should be used (for example, nickel-based alloy).

Metal foam can be made with different pore sizes. Due to the sponge-like structure, it offers a very large surface area, is gas-permeable and combines a low weight with good strength. Similar to any type of insulation material, a sponge structure is well suited to breaking and absorbing frequencies.

Due to the gas permeability of the metal foam, the passages for the premix zones, in which fuel and combustion air are to mix, must be made gas-tight by suitable measures.

This results in a significant cost reduction during production. Despite the foam structure, the component remains stable and ductile.

With regard to the gas-tight design of the passages for the premixing zones, it is particularly advantageous if the inner walls are formed by tubes arranged in the passages for premixing zones. This ensures that no fuel enters the nozzle carrier uncontrolled and away from the premix zones.

Furthermore, it is advantageous if a plate, in particular a metal plate, is firmly connected to the hot side. As a result, the temperature in front of the foam can be lowered somewhat or the nozzle carrier made of metal foam can thus be sealed against the penetration of the hot gas from the combustion chamber. The metal plate should be made as thin as possible on the hot side, so that they can forward similar to a membrane vibrations of the burner on the associated metal foam. The vibrations are absorbed and absorbed by the metal foam.

In the presence of such a metal plate, it is expedient if it has a thermal barrier coating in order to further improve the temperature protection for the nozzle carrier.

In an advantageous embodiment of the invention, a correspondingly shaped enclosure is firmly connected to the peripheral edge. One possibility is, for example, to surround the body of metal foam with a cylinder of a shaped metal plate. Compressor air, which is guided past the nozzle carrier during operation, before it is guided around the burner back wall and into the premixing passages of the nozzle carrier, can thus be conducted better past the nozzle carrier. In addition, the mechanical stability of the nozzle carrier improves.

In a further advantageous embodiment, a plate is firmly connected to the cold side. It is expedient if the plate is a metal plate. Fastening elements of the nozzle carrier can be attached to this metal plate by means of which the nozzle carrier can be mounted on a burner back plate (cover plate).

For cooling the front panel, it is advantageous if at least one cooling tube is incorporated in the metal foam. This cooling tube can already be incorporated during foaming in the metal foam. Through the cooling tube cooling air can be directed through the foam targeted to the plate on the hot side.

It is particularly advantageous if cooling air holes are provided in the plate on the hot side to divert the cooling air into the combustion chamber can.

• Figur 1 einen Schnitt durch einen Düsenträger und
• Figur 2 einen weiteren Schnitt durch einen Düsenträger.

The invention will be explained in more detail by way of example with reference to the drawings. Shown schematically and not to scale:

• FIG. 1 a section through a nozzle holder and
• FIG. 2 another section through a nozzle carrier.

The FIG. 1 shows schematically and by way of example a section through a nozzle carrier 1 for a jet burner, with a nozzle carrier body 2, comprising a combustion chamber during operation facing a hot side 3 and a remote from the combustion chamber cold side 4, between which a circumferential edge 5 extends.

Passages 6 in the nozzle carrier body 2 extend from the cold side 4 to the hot side 3. In operation, combustion air flows from the cold side 4 into the passages 6 and mixes with fuel from fuel lances which project into the passages 6. Thus, premix zones are formed in the passages 6.

According to the invention, the nozzle carrier body 2 is made of metal foam 7 and the inner walls 8 of the passages 6 for premixing zones are gas-tight, for example by means of metallic tubes 9 for the premixing zone, which are firmly incorporated into the metal foam 7 of the nozzle carrier body 2.

Furthermore, the shows FIG. 1 two metallic plates 10, 13, between which the metal foam 7 is foamed firmly adhering.

The plate 10 on the hot side 3 has a thermal barrier coating 11 in order to lower the temperature in the nozzle carrier 1. The plate 13 connected to the cold side 4 may, for example, have fastening elements (not shown) with which the nozzle carrier 1 can be mounted in, for example, a gas turbine.

Next shows the FIG. 1 a correspondingly shaped, in the example of FIG. 1 hollow cylindrical enclosure 12 which is fixedly connected to the peripheral edge 5 of the nozzle carrier body 2.

In the embodiment of the FIG. 2 a cooling tube 14 is incorporated in the metal foam 7. The cooling tube 14 serves to cool the plate 10 on the hot side 3 of the nozzle carrier 1 and allows cooling air 15 targeted, ie without high pressure loss, to lead to the plate 10, where they by additional, introduced into the plate 10 cooling air holes 16 in a Combustion chamber can be derived.

Next shows FIG. 2 in that a plate 13 does not necessarily have to be provided at least on the cold side 4.

Claims (7)

Nozzle carrier (1) for a jet burner, with a nozzle carrier body (2) comprising a hot side (3) facing a combustion chamber during operation and a cold side (4) facing away from the combustion chamber, between which a peripheral edge (5) extends, wherein passages (6) in the nozzle carrier body (2) extend from the cold side (4) to the hot side (3) and form premix zones, characterized in that the nozzle carrier body (2) is made of metal foam (7) and inner walls (8) of the passages (6 ) are designed gas-tight for Vormischzonen. Nozzle carrier (1) according to claim 1, wherein the inner walls (8) are formed by tubes (9) arranged in the passages (6) for premix zones. Nozzle carrier (1) according to one of claims 1 or 2, wherein a plate (10) is fixedly connected to the hot side (3). Nozzle carrier (1) according to claim 3, wherein the plate (10) has a thermal barrier coating (11). Nozzle carrier (1) according to one of the preceding claims, wherein a correspondingly shaped enclosure (12) is fixedly connected to the peripheral edge (5). Nozzle carrier (1) according to one of the preceding claims, wherein a plate (13) is fixedly connected to the cold side (4). Nozzle carrier (1) according to one of the preceding claims, wherein at least one cooling tube (14) is incorporated in the metal foam (7).
Nozzle carrier (1) according to claims 3 and 7, wherein cooling air bores (16) are provided in the plate (10).

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