DE3238685A1 - Gas turbine combustion chamber - Google Patents

Abstract

The gas turbine combustion chamber consists of a large number of primary combustion chambers (1) which open into a common mixing chamber (3) and in each case have their own fuel supply (25), which can be switched in and switched off in a load-controlled manner, and combustion air supply. The primary combustion chambers (1) are dimensioned in such a manner that complete combustion takes place in them and that, after the combustion zone but before opening into the mixing chamber (3), mixing air (M) can be introduced via openings (15). As the mixing air (M) is supplied exclusively via the openings (15), direct introduction of mixing air (M) into the mixing chamber (3) is not necessary. The mixing air (M), which is introduced into the primary combustion chambers (1) immediately after the zone of the completed combustion process, acts as tempering air which prevents a further increase in nitrogen oxides by freezing the NOx formation reactions. <IMAGE>

Description

Gas turbine combustor

The invention relates to a gas turbine combustion chamber according to the preamble of claim 1.

Such a gas turbine combustion chamber is from DE-AS 10 60 667 known. The primary combustion chambers arranged in a ring shape and axially parallel to one another open in this known combustion chamber arrangement in a likewise ring-shaped and a common mixing chamber which is concentric to the gas turbine axis and in which downstream Openings for the supply of mixed air are located. The primary combustion chambers are included dimensioned so that complete combustion takes place in them. on the other hand but the primary combustion chambers should not be dimensioned longer than it is for the complete one Combustion is required because that axial length is not necessary for combustion is required, used for temperature equalization in the common mixing chamber shall be.

The known gas turbine combustion chamber has the advantage that the division the dwell time of the combustion process on many small primary combustion chambers Combustion air in the high temperature zone of the flame is shortened, resulting in a reduction which leads to NO formation. On the other hand, however, the mixing ratios of fuel and combustion air not in the narrow spaces required for low NOx formation Limits are kept, since there is a between idling and full load of the gas turbine wide range of different mixing ratios results.

The invention is based on the object of a gas turbine brake chamber with a plurality of primary combustion chambers in which the NO formation can be reduced significantly.

This task is performed with a generic gas turbine combustion chamber solved by the characterizing features of claim 1.

In the gas turbine combustion chamber according to the invention, the Switching on and off individual primary combustion chambers according to the load on the gas turbine a narrow working area designed for low-emission operation be respected. The invention is then further based on the knowledge that even after a complete combustion in the primary combustion chambers by the Residence time in the large volume of the common mixing chamber one with NOx formation associated post-reaction takes place, which only further downstream by the supply is stopped by mixed air. Accordingly, in the gas turbine combustor according to the invention all available mixed air immediately following the combustion zones introduced as quenching air into the primary combustion chambers, causing NO formation associated post-reactions before the reactants enter the mixing chamber be frozen. By supplying mixed air in front of the mixing chamber In addition to the hot gases, a particularly uniform temperature field in front of the Entry into the gas turbine can be achieved.

In a preferred embodiment of the invention it is provided that the openings for the supply of mixed air are aligned radially and respectively form a row of holes running in the circumferential direction of a primary combustion chamber.

The deterrent effect is achieved by the radial alignment of the openings the mixed air favored while by the Arrangement in a row of holes the required inflow cross-sections can be realized without the axial To increase the length of the primary combustion chambers significantly.

In a further preferred embodiment of the invention, the Primary combustion chambers equipped with premix burners. Such premix burners enable a particularly low-emission operation. On the other hand, compared to diffusion burners small working area of the premix burners due to the large number of load-dependent Primary combustion chambers that can be switched on and off can be complied with without any problems. It is it is also beneficial if the entire combustion air supply is exclusively via the Premix burner takes place. There are then no further openings in the primary combustion chambers intended for the supply of combustion air.

It is also useful if one in each of the primary combustion chambers separate ignition device is arranged and thus when switching on the primary combustion chambers perfect ignition is guaranteed.

An embodiment of the invention is shown in the drawing and is described in more detail below.

1 shows a longitudinal section through a primary combustion chamber and the associated premix burner and FIG. 2 a gas turbine combustion chamber in which a plurality of primary combustion chambers designed according to FIG. 1 into a spherical one Open the mixing chamber.

Fig. 1 shows a longitudinal section through a primary combustion chamber 1 and the associated premix burner 2. The primary combustion chamber 1, also called a flame tube are designated could consists of a cylindrical flame tube jacket 10, at one end of which an end cover 11 is arranged and at the other end of which a connecting flange 12 is arranged. The front end cover 11 has a central opening through which the premix burner 2 into the with a refractory lining 13 provided primary combustion chamber 1 opens.

The cover 13 has a further, more to the outer edge towards arranged opening, through which an ignition device designed as a pilot burner 14 opens through the refractory lining 13 into the primary combustion chamber 1. An ignition electrode is located on the upper end flange 140 of this ignition device 14 141, an air supply 142 and a gas supply 143 can be seen.

The axial length of the primary combustion chamber is slightly larger, than is necessary for complete combustion. In the one about the zone the end region protruding from the completed combustion process is then one in the circumferential direction the primary combustion chamber 1 extending row of holes is provided, the individual openings 15 radially through the flame tube jacket 10 and the refractory lining 13 open into the primary combustion chamber 1.

The premix burner 2 consists of a substantially cylindrical trained burner housing 20, which at its one end face a Swirl body 21 and a fuel nozzle 22 and at its other front end a flame holder 23 carries. In between the swirl body 21 and the flame holder 23 formed premixing chamber 24 is supplied via a fuel supply 25 and liquid fuel atomized in the fuel nozzle 22 is vaporized and with the Combustion air indicated by arrows V mixed. So that this intermingling is as intense as possible, the combustion air becomes V as it flows through the swirl body 21 ver swirls. That from the supplied combustion air V and The existing homogeneous mixture of the evaporated fuel is only in the primary combustion chamber 1 ignited with the ignition device 14, the flame holder 23 for stabilization serves the flame, but still a flashback of the flame into the premixing chamber 24 prevented.

When using gaseous fuels is also within the premixing chamber 24 forms a homogeneous mixture with the combustion air V, the pre-evaporation is then of course omitted. Instead of those designed as pilot burners Ignition device 14 can be used to ignite the mixture in the primary combustion chamber 1 an electric igniter can also be used if necessary.

As already stated, the combustion of the in the premix burner 2 generated mixture within the primary combustion chamber 1 before the openings 15 completely completed. Immediately after the zone of the completed combustion process mixed air indicated by arrows M is then introduced into the primary combustion chamber 1. This mixed air M acts as a quenching air, which cools the hot gases and passes through them Freezing the NOx formation reactions prevents a further increase in nitrogen oxides.

Fig. 2 shows a gas turbine combustor in which a plurality of primary combustion chambers 1 equipped with premix burners 2 into a common one Open into mixing chamber 3.

The mixing chamber 3 has the shape of a sphere, the primary combustion chamber 1 are arranged on circles of latitude of this sphere in such a way that their longitudinal axes hit at least approximately in the center of the ball. This makes one special intensive mixing of the gas jets emerging from the individual primary combustion chambers 1 achieved. After mixing the mixing chamber 1, the hot gases then leave the spherical interior space via a cylindrical one that establishes the connection to the gas turbine Transition section 30.

The outer Breankaemermantel 4 has the shape of a mixing chamber 3 at a distance enclosing ball, to which a gas turbine connection substantially frustoconical transition section 40 with a connecting flange 41 connects. The outer Brerinkkammer jacket 4 also has a plurality of radially aligned nozzle 42 into which the premix burners 2 of the primary combustion chambers 1 immerse. The fuel supply 25 of the premixing chamber 2 is in each case through a closure cover 4-20 of the associated nozzle 42 passed through, which is shown schematically Valves 250 is indicated that the fuel supply 25 according to the load the gas turbine can be switched on and off.

When the gas turbine combustion chamber is in operation, it is indicated by arrows L. Buft from the compressor into the between the cylindrical transition section 30 and the frustoconical transition 3 section 40 formed annulus. Die'Luft L then passes into the between the mixing chamber 3 and the spherical Area of the combustion chamber jacket 4 lying interspace and divides there into the Combustion air V and the mixed air M. To have the highest possible deterrent effect of the mixed air M and thus the lowest possible NO formation is achieved all of the available mixed air M exclusively via the openings 15 and the adjoining end portions of the primary combustion chambers 1 into the mixing chamber 3 initiated. In the mixing chamber 3 there are no further openings for the Intake of mixed air M is provided. Becomes a primary combustion chamber 1 during partial load operation switched off, the combustion air supplied to the switched-off premix burner 2 arrives V through the primary combustion chambers 1 as a cold air jet into the mixing chamber 3. The spherical shape of the mixing chamber 3 results in intensive mixing of the the connected primary combustion chambers 1 exiting hot gas jets with the exiting the primary combustion chambers 1 that have been switched off Cold air rays achieved, so that the gas mixture indicated by arrows G before entering the Gas turbine has a uniform temperature profile.

5 claims 2 figures

Claims (5)

Claims 1. Gas turbine combustion chamber with - a variety of Primary combustion chambers (1) which open into a common mixing chamber (3), - a separate fuel supply (25) for each Prit combustion chamber (1), - its own Combustion air supply to each primary combustion chamber (1) and with openings (15) for the Supply of mixed air (M) to the hot gases, g e k e n n n z e i c h n e t d u r c h the following features: - the fuel supply (25) to each of the primary combustion chambers (1) can be switched on and off depending on the load, - the openings (15) for the supply of mixed air (M) are located exclusively in the areas behind the combustion zone and in front of the Confluence into the mixing chamber (3) lying areas of the primary combustion chambers (1). 2. Gas turbine combustion chamber according to claim 1, d a d u r c h g e k e n n z e i c h n e t that the openings (15) for the supply of mixed air (M) are radial are aligned unü each one in the circumferential direction of a primary combustion chamber (1) Form a running row of holes. 3. Gas turbine combustion chamber according to claim 1 or 2, d a -d u r c h g e k e n n n n e i n e t that the primary combustion chambers (1) with premix burners (2) are equipped. 4. Gas turbine combustion chamber according to claim 3, d a d u r c h g e k e n It should be noted that the entire combustion air supply is exclusively via the Premix burner (2) takes place. 5. Gas turbine combustion chamber according to one of the preceding claims, d a d u r c h e k e n n n z e i c h n e t that in each of the primary combustion chambers (1) a separate ignition device (14) is arranged.