EP1507120A1 - Gasturbine - Google Patents

Abstract

The gas turbine comprises a compressor (5) which is connected by an air channel (27) to an annular combustion chamber (7) with an outlet (45) leading to the turbine. A grid (33) around the chamber produces turbulence in the air supply.

Description

The invention relates to an axial gas turbine, comprising a Compressor, an annular combustion chamber and a turbine part.

On industrial gas turbines, especially those above 50 megawatts, high demands are placed on efficiency, Availability and low pollutant emissions. A particularly demanding area is this Combustion system of the gas turbine, where the compressor highly compressed combustion air with the addition of fuel burned and the resulting hot exhaust gas into a turbine part where there is a turbine shaft over turbine blades set in rotation. The rotational energy of the turbine shaft can z. B. for generating electrical energy in a generator can be used.

In such gas turbines, the combustion takes place over a number from burners to which the combustion air and the fuel be supplied. In these burners are combustion air and mixed fuel and the mixture is ignited. The resulting flame burns the mixture in the combustion chamber into which the burners open. Mostly come so-called premix burners used in which combustion air and mixed fuel as homogeneously as possible before they are then fed to the combustion zone. This has the advantage of particularly low nitrogen oxide emissions, because in the homogeneous fuel-air mixture a homogeneous Temperature distribution prevails. Such lean premix combustion however, it tends to cause instabilities, i. the Flame can easily go out. Such combustion instabilities can also be used to build up so-called combustion oscillations lead, where caused by the instabilities Pressure pulses from the combustion chamber wall to the flame zone reflected be there and periodically reinforce the instabilities, which in a positive feedback to a stable Burning vibration can lead. Such combustion vibrations are both in terms of acoustic emissions as well as in terms of damaging mechanical Vibrations undesirable. Often, therefore, is the lean Vormischverbrennung stabilized by additional diffusion burners. A typical burner arrangement is a ring-channel premix burner, the one central diffusion or pilot burner surrounds.

WO 02/08592 shows a gas turbine. The gas turbine has one annular combustion chamber, short annular combustion chamber, which around the Turbine axis is arranged around. In this ring combustion chamber A number of premix burners protrude along the circumference which are stabilized by central pilot burners. A particularly efficient combustion process results here by an admixture of fuel already at the compressor outlet, whereby combustion air and fuel especially be well mixed. Branched off from the combustion air flow Cooling air for turbine blades in the turbine part is thereby also already interspersed with fuel, which when flowing out this cooling air from openings in the turbine blades leads to a reheating in the turbine part. This has one particularly high efficiency.

EP 590 297 shows a gas turbine group. In this is sought the swirling combustion air flow from the To direct compressor as directly as possible to the turbine part to there exploit the swirl so that a first row of vanes can be saved. In addition, should by the swirling the residence time of the fuel mixed Combustion air in the combustion chamber as high as possible to for a short size, sufficient residence time for the burnout to reach in the combustion chamber. This is done by achieved that the compressor directly into the combustion chamber opens, with a last Verdichterleitschaufelreihe also if necessary can be saved or only one Twist reinforcement is needed.

The US-PS 6,003,297 shows a gas turbine, in which also the compressor opens directly into the combustion chamber. Of the However, main fuel flow is already in the compressor added, so that despite the immediate confluence of the Combustion air into the combustion chamber before to a good mixing of combustion air and fuel comes. Additional pilot burner opening into the combustion chamber stabilize the combustion. Again, through maintaining the swirl from the compressor a first Leitschaufelreihe be saved in the turbine part.

The object of the invention is the specification of a gas turbine, in the at a high combustion stability, a particularly low Pressure loss for the introduced into the combustion chamber Combustion air is created.

According to the invention this object is achieved by a along an axis-directed axial gas turbine comprising a compressor with a compressor exit region, an annular combustion chamber with a combustion air inlet area for From the compressor supplied combustion air, a combustion air supply line for the supply of combustion air from Compressor outlet area to the combustion air inlet area and with a turbine part, which has a turbine inlet area connected to the annular combustion chamber, wherein the combustion air supply line is formed so that a Verdichterluftdrall existing in the compressor outlet region the combustion air to the combustion air inlet area is essentially degraded and being on Combustion air inlet area around the whole circumference the ring combustion chamber extending swirl grille for the Issuing a twist on the combustion air arranged is.

The invention is based on the recognition that the use separate, single burners that run along the circumference open an annular combustion chamber, the flow velocity for in this burner entering combustion air through a maximum tolerable pressure drop is limited. Above one certain flow rate, the pressure drop is so great, that this negatively affects the efficiency of the gas turbine effect. However, a high flow rate is desirable as a result, on the one hand, flashbacks in the Burner can be avoided, on the other hand, an acoustic decoupling from the mixing process between fuel and air and the actual combustion is generated and therefore one Tendency to combustion vibrations is reduced. After realization The invention is an essential part of the pressure loss from the dissipation of the swirl in the combustion air caused. For every single burner was previously used its own swirl grid, which Rückströmgebiete produced in the fuel air mixture, whereby a flame stabilization he follows. The generated by the vortex grid But the individual burner builds up to the entrance into the turbine again. In this loss is one Main cause of the pressure loss seen. configurations as disclosed in the above-mentioned US Pat. No. 6,003,297 or EP 590 297, which dispense with a swirl lattice and swirling compressor flow are direct into the combustion chamber, are but for various reasons for safe operation not suitable. In order now to gas turbines, which are not or hardly swirling compressor air via a combustion air supply line the annular combustion chamber is supplied with a high flow velocity when flowing into the annular combustion chamber It is now being proposed for the first time to be used Discrete, single burner to dispense and one completely new burner system concept by means of a single, circulating To introduce swirl lattice. About such a circulating Swirl lattice will be in the same direction over the Whole circumference of the annular combustion chamber distributed swirl the Combustion air impinged. This leads to a significantly less dissipation of the twist, since no opposing Flow directions as in the use of individual Burners arise. Furthermore, the effective cross section is also increased to the inflow of combustion air. Both causes the pressure loss remains low and comparatively high flow rates for in the Ring combustion chamber entering combustion air can be adjusted can. This results in a lower tendency for one Flashback in the vortex grid at the same time higher Decoupling of the combustion area from the area of Mixture between combustion air and fuel. Through this Decoupling density variations are reduced, the by combustion vibrations in the combustion chamber on the Mixed range of combustion air and fuel through Sound waves can be transmitted. This reduces the Feedback and thus the amplification mechanism of Combustion oscillations. The tendency to the formation of Combustion vibrations are thus significantly reduced. Another Advantage of the invention is a homogenization of Hot gas temperature over the circumference of the annular combustion chamber. Up there separate, discrete burner is dispensed with, it does not come more about a differently hot flow along the circumference, the previously maxima at the burner positions and minima between the burner positions showed. By a homogenization the hot gas temperatures are also the maximum temperatures reduced, which prevail in the turbine inlet area. These maximum temperatures give the consumption of cooling air for guide vanes in the turbine inlet area in front. By equalizing thus the cooling air consumption lowered, which in turn leads to greater efficiency the gas turbine leads. Finally, by the equalization Temperatures also cut significantly Nitrogen emissions achieved, as stated above, this be determined by the homogeneity of the temperature distribution. Nitrogen oxide emissions increase exponentially with temperature.

Preferably, fuel is uniform in the area of the swirl lattice distributed over the circumference of the swirl lattice in the Combustion air introduced. Further preferred are for this purpose Swirl blades of the swirl lattice at least partially as Fuel buckets formed over the fuel of the Combustion air can be supplied. Such swirl vanes of the Twist lattices are then z. B. hollow, with her Inside fuel is supplied. Via openings on the surface the swirl vanes will then be the fuel in the Combustion air introduced. This leads to a homogeneous Distribution of the fuel in the combustion air.

Preferred dimensions include the distributable by the swirl lattice Twist of combustion air on a direction of rotation in the turbine inlet area in the direction of a diversion directed in the turbine inlet guide vanes is directed. The due to the rotating swirl lattice even in the turbine inlet area substantially preserved swirl of the combustion air can now be used with the correct direction of rotation be, the vanes in the turbine inlet area smaller, since already the existing spin for used the deflection on the subsequent blades can be. This smaller size is again advantageous in terms of a lower cooling air consumption and thus thus for efficiency as well as for lower nitrogen oxide emissions.

Preferably, the gas turbine has a capacity greater than 50 Megawatts, with a flow rate generated at full load for the combustion air entering the swirl grid at a certain minimum speed.

Preferred dimensions is a ring around the annular combustion chamber circulating fuel supply line provided from the Fuel is supplied to the combustion air. By the Dispensing with individual burners, the fuel supply system be significantly simplified. This is about through the annular Fuel supply line possible from which the fuel z. B. is passed into the hollow swirl vanes. Dependent from the pressure of the fuel at the respective position of the fuel Removal for a swirl bucket can use throttles for this Removal be provided so that, despite different Circumferential positions of the removal, and associated different Pressure in the fuel supply line, to the individual swirl blades supplied equal amounts of fuel can be. As a result, a homogeneous distribution of Fuel is ensured over the circumference.

Preferably, in the region of the exit of the combustion air from the swirl lattice over the circumference of the annular combustion chamber distributed pilot burners provided a stabilization serve the combustion.

Preferred dimensions is the swirl lattice on the radially outer edge arranged the combustion air inlet region. hereby is at the radially inner edge of the annular combustion chamber, d. H. hub side, creates a single, annular Rückströmgebiet, which effectively stabilizes combustion.

Figur 1

eine Gasturbine,

Figur 2

einen Querschnitt durch eine Ringbrennkammer einer Gasturbine,

Figur 3

eine Drallschaufel und

Figur 4

die Anströmung einer ersten Leitschaufelreihe.

The invention will be explained in more detail by way of example with reference to the drawing. They show partly schematically and not to scale:

FIG. 1

a gas turbine,

FIG. 2

a cross section through an annular combustion chamber of a gas turbine,

FIG. 3

a swirl bucket and

FIG. 4

the flow of a first row of vanes.

The same reference numerals have in the various figures same meaning.

FIG. 1 shows a gas turbine 1. The gas turbine 1 is along a turbine axis 3 directed. It includes a compressor 5, an annular combustion chamber 7 and a turbine part 9. On one not shown shaft of the gas turbine 1 are wheel discs 11 for compressor blades 15 and wheel discs 13 arranged for turbine blades 17. In the axial direction alternately to the blades 15 are 5 compressor blades in the compressor 19 and in the turbine part 9 turbine vanes 21 arranged. The compressor 5 ends with a Last Verdichterleitschaufelreihe 19 in a compressor exit area 23. In the compressor 5 compressed ambient air is considered combustion air 25 in a combustion air supply line 27 one of the annular combustion chamber 7 fluidically upstream combustion air inlet region 29 is supplied. In the combustion air inlet region 29 is in a radially outer region around the entire circumference of the annular combustion chamber 7, a swirl grid 33 is arranged, through which the combustion air 25 is introduced into the combustion chamber 7 becomes. The combustion air 25 is in the swirl grid 33, as explained in more detail later with reference to FIG. 3, fuel admixed, the one of an annular fuel supply line 37th is taken, in turn, from a fuel main 35 is supplied. The fuel air mixture passes as one Homogeneous premix in the annular combustion chamber 7, where there is a Hot gas 41 is burned. A hub side annular Recirculation zone 43 stabilizes the combustion process. The hot gas 41 then becomes a turbine inlet area 45 headed. In the turbine inlet region 45 a first row of vanes 21 is arranged. The Gas turbine 1 is enclosed by an outer housing 10. The Ring combustion chamber 7 is with a ceramic heat shield brick lining 8 lined.

Due to the arrangement of the swirl grating 33 is first at a such gas turbine ring combustion chamber 7 omitted it, to carry out the combustion process via separate burners, which are arranged along the circumference of the annular combustion chamber 7. Rather, it becomes a continuous entry for the combustion air 25 about that over the entire circumference of the annular combustion chamber 7 extending swirl grille 33 is provided. As a result, the hot gas 41 is an over the circumference of the annular combustion chamber 7 same spin granted, the only partially dissipates and to a considerable extent even in the turbine inlet area 45 is obtained. This leads to an im Comparison to the arrangement with separate burners, respectively have a single swirl lattice, to a lower one Pressure loss. Conversely, with the same pressure loss, the Flow velocity of the incoming combustion air 25 be increased significantly. This has a reduced risk of Flame flashbacks in the swirl grille 33 result. moreover As a result, the combustion area is acoustically better from Range of mixture of combustion air 25 and fuel decoupled. This has the particular advantage that pressure fluctuations in the annular combustion chamber 7 less in this Be transferred mixing area. This will be in this mixing area less density fluctuations caused the otherwise turn to flame instabilities and thus again to Can cause pressure fluctuations in the annular combustion chamber 7. A such feedback is often the starting point for the Structure of a combustion oscillation. Thus, the better acoustic decoupling a slight inclination of the gas turbine for the formation of combustion vibrations result.

Furthermore, the hot gas 41 becomes along the circumference of the annular combustion chamber 7 evenly heated. Opposite an arrangement with separate burners, this has a uniform temperature distribution in the turbine inlet area result. The lesser Maximum temperatures thus take more agile Vanes 21, but also subsequent rows of blades. This means a reduced need for cooling air, that of the compressor air 25 removed and fed to the turbine blades becomes. This cooling air is no longer available to the combustion process available, resulting in reduced efficiency and also leads to higher nitrogen oxide emissions. The saving of cooling air by the temperature uniformity by means of the swirl lattice 33 thus has an increase in efficiency of the gas turbine 1 and reduced nitrogen oxide emissions result.

FIG. 2 shows a cross section through an annular combustion chamber 7. Around the turbine axis 3, the swirl lattice 33 is arranged in a circle. The swirl lattice 33 is formed of swirl vanes 61, which will be described in more detail later with reference to FIG. Around the swirl grille 33 extends an annular fuel supply line 37. In this fuel supply line 37 is via a fuel main 35 from a fuel reservoir 53 fuel 54 initiated. From the fuel supply line 37 is then via swirl vane feeders 51, each of the swirl vanes 61 is supplied with fuel. In Direction of flow after the swirl lattice 33 are pilot burners 57 arranged through a pilot fuel supply line 55 supplied from the fuel reservoir 53 with fuel 54 become. The pilot burners 57 are diffusion burners, d. H. Fuel and combustion air are only in the Combustion zone mixed. This burn is richer Fuel and more stable than a lean premix combustion. Because with such a diffusion combustion more nitrogen oxide formation follows, their share is kept as low as possible. The Pilot burners 57 serve primarily to stabilize the Premix combustion generated via the swirl lattice 33.

FIG. 3 shows a swirl blade 61. The swirl blade 61 is hollow executed. Into the interior of the swirl blade 61 is Fuel 54 initiated. This fuel 54 exits Openings 63 on the airfoil surface of the swirl vane 61 and mixes with the combustion air 25. This becomes a radially homogeneous distribution of Fuel reaches 54. By the introduction into a variety of swirl vanes 61 evenly over the circumference of the combustion chamber 7 is also distributed a homogeneous distribution of Fuel 54 and combustion air 25 in the circumferential direction reached.

FIG. 4 shows the flow of the gas turbine guide vane 21 in the turbine inlet region 45 from the hot gas 41. The hot gas 41 has a twist 71. This corresponds to a decomposition of Flow direction of the hot gas 41 in an axial and a to vertical component, wherein a twisting reflector 72 is stretched is, which has in the direction of a Umlenksektors 73, by the deflection of the hot gas 41 through the vanes 21 is shown. Due to the sense of rotation of the swirl 71 Thus, the hot gas 41 is already a component in the direction the deflection by the vanes 21 issued. With that you can the vanes 21 are made smaller, which in turn reduces the cooling air requirement for the guide vane 21.

Claims (8)

Axial axial gas turbine (1), comprising a compressor (5) with a compressor exit region (23),
an annular combustion chamber (7) with a combustion air inlet region (29) for combustion air (25) supplied by the compressor (5),
a combustion air supply line (27) for the supply of combustion air (25) from the compressor outlet region (23) to the combustion air inlet region (29) and
with a turbine part (9) which is connected to the annular combustion chamber (7) via a turbine inlet region (45),
wherein the combustion air supply line (27) is designed so that a Verdichterluftdrall of the combustion air (25) in the compressor outlet region (23) is substantially degraded to the combustion air inlet region (29) and wherein the combustion air inlet region (29) around the entire circumference of the annular combustion chamber ( 7) extending swirl grille (33) is arranged for the issue of a twist on the combustion air. Gas turbine (1) according to claim 1,
wherein in the region of the swirl grating (33) fuel (54) is uniformly distributed over the circumference of the swirl grating (33) into the combustion air (25) is introduced. Gas turbine (1) according to claim 1 or 2,
in which individual swirl vanes (61) are arranged in the swirl lattice (33), wherein at least part of the swirl vanes (61) are designed as fuel vanes (61), via which fuel (54) can be fed to the combustion air (25). Gas turbine according to claim 1, 2 or 3,
in which the swirl (71) of the combustion air (25), which can be distributed by the swirl grille (33), has a direction of rotation which is directed in the turbine inlet region (45) in the direction of a deflection (73) through guide vanes (21) arranged in the turbine inlet (45) , Gas turbine (1) according to one of the preceding claims,
with a power> 50 MW, in which a flow rate generated in full load operation for the entering into the swirl grille (33) combustion air (25) is at a minimum speed. Gas turbine (1) according to one of the preceding claims,
in which an annular ring around the annular combustion chamber (7) circulating fuel supply line (37) is provided, from which the fuel (54) of the combustion air (25) is supplied. Gas turbine (1) according to one of the preceding claims,
in which in the region of the exit of the combustion air from the swirl grid (33) distributed over the circumference of the annular combustion chamber (7) pilot burner (57) are provided, which serve to stabilize the combustion. Gas turbine (1) according to one of the preceding claims,
in which the swirl lattice (33) is arranged on the radially outer edge of the combustion air inlet region (29).

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