EP2052184A1 - Combustion system, particularly for a gas turbine - Google Patents

Abstract

The burner (1) has a nozzle pipe (7) and a fuel fluid inlet pipe (9), which are in connection with the nozzle pipe for feeding the fuel fluid into the nozzle pipe, is proposed. The nozzle pipe has a nozzle discharge opening (15) and is designed for spraying a stream of fuel fluid or a mixture of air and fuel fluid into a combustion chamber (3) and further comprises in the region of the nozzle discharge opening protruding elements (19) towards the center of the opening. The elements are formed by a nozzle tube section extending to nozzle discharge opening with inner circumferential surfaces.

Description

 Combustion system, in particular for a gas turbine

The present invention relates to a combustion system, in particular a combustion system for a gas turbine with a combustion chamber and at least one nozzle tube, which opens into the combustion chamber with a nozzle outlet opening.

Recently, so-called jet flames have been discussed as an alternative to swirl flames in combustion systems for gas turbine plants. In jet flames, a fuel fluid or a mixture of fuel fluid and air is introduced by means of a nozzle tube as a jet into the combustion chamber. Jet flames enable emissions of nitrogen oxides (NO _x) emissions, which are as low as in premixed flames swirl, while at the same time allow the distribution of heat release over a greater compared to the premixed swirl flame region in the combustor. As a result of the heat release over a larger area, jet flames open up a potential for reducing thermoacoustically induced vibrations. Furthermore, jet flames enable the burning of very different fuel fluids, which ensures a high flexibility of the combustion system. High flexibility is one of the main goals of modern combustion systems.

The stabilization of a jet flame, however, remains an incompletely solved task. So far, jet flames are mainly stabilized by the entrainment of hot reaction gases from an outer recirculation zone of the combustion chamber. The entrainment of the hot reaction gases has been improved by increasing the jet velocity and adjusting the geometry of the combustion assembly. The adjustment of the geometry is usually carried out by establishing a specific ratio between the diameter of the combustion chamber and the diameter of the nozzle opening into the combustion chamber of the nozzle tube. The Flame stability, however, may still be unsatisfactory, in particular with regard to different operating points of gas turbine plants or when using fuels with a high hydrogen content, which lead to a high combustion speed.

In contrast, it is an object of the present invention to provide an advantageous burner for jet flames and an advantageous combustion system for jet flames.

This object is achieved by a burner according to claim 1 or by a combustion system according to claim 12. The dependent claims contain advantageous embodiments of the invention.

A burner according to the invention, which in particular can be configured as a burner for a gas turbine, comprises at least one nozzle tube and a fuel fluid supply line communicating with the nozzle tube for supplying a

Fuel Fluids in the nozzle tube and possibly in addition an associated with the nozzle tube air supply line for supplying combustion air into the nozzle tube. The nozzle tube has a nozzle outlet opening and is designed for injecting a jet of fuel fluid or of a mixture of air and fuel fluid into a combustion chamber. The nozzle tube has in the region of the nozzle outlet opening to the center of the opening projecting elements. The elements projecting towards the center of the opening thus increase the turbulent fluctuations in the area of the boundary surface between the jet and the recirculated combustion exhaust gases in the discharged jet, which in turn increases the entrainment of the combustion exhaust gases. As a consequence, the stability of the flame is increased.

In a first implementation of the invention, the projecting elements are provided by a nozzle tube section with corrugated inner peripheral surface extending up to the nozzle outlet opening. formed. This realization leads to an enlargement of the surface of the jet emerging from the nozzle opening. Since the number of turbulent fluctuations depends on the size of the interface between the jet and the hot reaction gases, ie the combustion gases, in the recirculation zone, in this implementation the amplification of vortex formation is essentially due to the increased radiation surface.

The corrugated inner peripheral surface at the nozzle exit opening may in particular be designed such that it has a maximum deflection A about a mean opening radius R of the nozzle exit opening and the ratio of the deflection to the mean opening radius through the relationship

given is.

The corrugated inner peripheral surface may in particular have the shape of a sine wave extending over the circumference of the nozzle outlet opening. But other in the broadest sense corrugated forms, such as sawtooth shapes, are possible.

In a development of the burner with the corrugated inner circumferential surface, the nozzle tube has a nozzle tube section remote from the nozzle opening and a transition section. The transition section represents a transition from the nozzle tube section with a circular opening cross-section to the nozzle tube section with the corrugated inner circumferential surface. The maximum amplitude of the corrugated inner circumferential surface is reached directly at the nozzle outlet opening. The ratio of the length L _{τ of} the transition region to the maximum amplitude A is given by the formula

K ^L / _2A <5 given. In the given by the formula ratio of the length of the transition region to the maximum amplitude can be achieved particularly advantageous results for flame stability.

In an alternative embodiment of the burner, the protruding elements are formed by vanes arranged in the region of the nozzle outlet opening on the inner circumferential surface of the nozzle tube, which can be, in particular, delta wings. Delta wings have the shape of a triangle and have a relatively small profile thickness in relation to their length and depth. The wings, in particular the delta wings lead to an increased vortex formation in the area of the wing edges. In contrast to the first implementation, the increased vortex formation is not first induced by the enlarged radiation surface, but is already present at the exit of the jet from the nozzle outlet opening.

The vanes protrude at the nozzle exit opening via the path S from the inner circumferential surface, which is formed at the nozzle opening in a circular shape with an opening diameter D, into the nozzle opening. The ratio of the distance S to the opening diameter D is determined by the relationship

given. The conditions which satisfy the given relationship lead to particularly good results in stabilizing the jet flame.

In a particular embodiment of the implementation with wings in the region of the nozzle outlet opening the wings are inclined at an angle α with respect to the radial direction of the nozzle outlet opening. The angle α can in this case be in the range 65 ° <α <85 °, in particular. The inclined wings, in particular those with angles of inclination in the specified range, lead to a particularly advantageous vortex formation in the O-ring. Surface area of the emerging from the nozzle outlet opening fluid jet. This leads in particular to good results for the flame stability, if the ratio of the distance S to the opening diameter D of the nozzle outlet opening satisfies the relationship given above.

According to the invention, a combustion system with a combustion chamber and a burner is also provided. The burner comprises at least one nozzle tube and a fuel fluid supply line communicating with the nozzle tube for supplying a fuel fluid into the nozzle tube and optionally additionally an air supply line communicating with the nozzle tube for supplying combustion air into the nozzle tube. The nozzle tube has a nozzle outlet opening which opens into the combustion chamber and is designed to inject a jet of fuel fluid or a mixture of air and fuel fluid into the combustion chamber. In the combustion system according to the invention, the nozzle tube projects into the combustion chamber. In particular, the nozzle tube may have an opening diameter D and a length L in the

Projecting the combustion chamber, wherein the ratio of the length L to the opening diameter D by the relationship

0.3 < ^L / _D <3

given is. The projection of the nozzle tube into the combustion chamber increases the effect that the entrainment of hot combustion exhaust gases of the recirculation zone exerts on the jet because the nozzle exit orifice is near the recirculation zone or led into it.

The nozzle tube projecting into the combustion chamber can be equipped, in particular in the region of the nozzle outlet opening, with elements projecting towards the center of the opening, as have been described with reference to the burner according to the invention. In other words, the burner may in particular be a burner according to the invention. Further features, properties and advantages of the present invention will become apparent from the following description of embodiments with reference to the accompanying figures.

1 shows a combustion system according to the invention with a burner and a combustion chamber in a schematized, sectional side view.

FIG. 2 shows a plan view of the nozzle outlet opening of the burner from FIG. 1.

Fig. 3 shows an alternative embodiment of the burner in the combustion system of Fig. 1 in a sectioned, schematic side view.

Fig. 4 shows a plan view of the nozzle exit opening of the alternative embodiment of the burner.

5 shows a second exemplary embodiment of a combustion system according to the invention with a burner and a combustion chamber in a schematized, sectional side view.

An embodiment of a combustion system according to the invention is shown in a highly schematic representation in Fig. 1. The figure shows a section through the longitudinal axis of the combustion system and shows a burner 1 and a combustion chamber 3.

The burner is designed to generate a jet flame 5. It comprises a nozzle tube 7, which in the present embodiment is in communication with a fuel supply line 9 and an air supply line 11. The fuel fluid supplied via the fuel supply pipe 9, for example, gas (such as natural gas) or oil (such as fuel oil) is mixed in a mixer 13 and supplied to the nozzle pipe 7. Via a nozzle outlet opening 15, the premixed air / fuel mixture is injected into the combustion chamber 3 to form the jet flame 5. Usually, the diameter of the nozzle outlet opening with the dimension of the combustion chamber opening W in the ratio 1 <W / D <4.

In the outer region of the combustion chamber 3 is formed at the present jet flame 5, a recirculation zone 6, in which hot combustion gases flow back in the radially outer region of the combustion chamber 3 in the direction of the burner 7 and in the upstream region of the combustion chamber 3 in its direction of movement in the direction of the deflected radially inner region of the combustion chamber. Between the recirculated exhaust gas 17 and the peripheral surface of the air / fuel mixture in the jet flame 5, shear forces occur, which entrain the recirculated exhaust gas 17 in the flow direction F of the air / fuel mixture. Due to this entrainment effect, the jet flame 5 is stabilized in the combustion chamber 3. The entrainment effect is primarily due to turbulent fluctuations in the peripheral surface of the jet flame 5.

The nozzle tube 7 of the burner 1 has a corrugated tube wall 19 in the region of the nozzle outlet opening 15. In the present exemplary embodiment, the corrugation is realized in that the pipe wall 19 has the shape of a standing sine wave oscillating about an average pipe radius R with an amplitude A. However, the corrugation can also be implemented in its inner wall by incorporating a sinusoidal contour in the circumferential direction of the nozzle tube. The curl does not necessarily have sinusoidal form. Other shapes, such as sawtooth shapes, are possible.

The amplitude A of the corrugation has its maximum value at the nozzle outlet opening 15. It decreases towards upstream pipe sections until finally reaching a pipe section 21 in which the pipe has a circular cross-section. The transition area, in the amplitude decreases from its maximum value A to zero, has in the axial direction of the nozzle tube 7 has a length L _τ . The ratio of the length L _{τ of} the transition region to the maximum amplitude A is defined by the relationship given.

Due to the corrugation of the nozzle tube 7 in the region of the nozzle outlet opening 15, the surface of the jet emerging from the nozzle outlet opening 15 is off

Compared to an air / fuel mixture emitted from a nozzle outlet opening with a round cross-section and the radius R beam of air / fuel mixture increases. The enlargement of the surface of the jet leads to more turbulent fluctuations and thus to an amplification of the described entrainment effect. Particularly advantageously, the entrainment effect can be enhanced if the ratio of the deflection A of the corrugation to the mean radius R of the nozzle outlet opening is enhanced by the relationship

given is. It should be noted at this point that Fig. 2 is merely exemplary and schematic of the shape of the corrugation. In particular, the number of wave crests and troughs may also be smaller or larger than shown in FIG.

Fig. 3 shows a second embodiment of the nozzle tube of the burner according to the invention. The figure shows the nozzle tube 107 according to the second variant in a schematic section along its central longitudinal axis. In contrast to the nozzle tube 7 of the first embodiment, the nozzle tube 107 of the second embodiment in the region of the nozzle outlet opening 115 no corrugation. Instead are arranged in the region of the inner circumferential surface of the nozzle outlet opening 115 delta wing 119. The delta wings 119 protrude beyond the distance S into the nozzle outlet opening 115. The ratio of the distance S to the diameter D of the nozzle outlet opening 115 is in this case in particular by the relationship

given. In addition, the delta wings 119 are present in the

Embodiment by an angle α in the range between 65 ° and 85 ° against the radial direction in the nozzle tube 107 inclined. But there are also embodiments without inclination possible.

At the edges of the delta wings 119 arranged in the region of the nozzle outlet opening 115, vortex formation takes place, which continues in the surface of the jet emerging from the nozzle outlet opening 115. The vortices increase the turbulent fluctuations in the boundary between the jet and the recirculated exhaust gas, thus increasing the entrainment effect.

A further exemplary embodiment of the combustion system according to the invention is shown in FIG. The figure shows the combustion system in a section along its longitudinal axis and shows a burner 201 and a combustion chamber 203.

The burner comprises a nozzle tube 207, a fuel supply line 209 and an air supply line 211 and a mixer 213, which is connected upstream of the nozzle tube 207 and into which the fuel supply line 209 and the air supply line 211 open. In contrast to the burner in the first exemplary embodiment of the combustion system according to the invention, the nozzle tube 207 has neither a corrugation nor delta wings in the region of its nozzle outlet opening 215. However, it should be mentioned at this point that the burner is also used in the second embodiment. Example of the combustion system can be equipped with a corrugation or with delta wings in the region of its nozzle outlet opening 215.

In contrast to the combustion system illustrated in FIG. 1, in the combustion system illustrated in FIG. 5, the nozzle tube 207 projects into the combustion chamber 203 by the distance L. The distance L, by which the nozzle tube 207 protrudes into the combustion chamber 203, is with the opening diameter D of the nozzle outlet opening preferably in a relationship by

0.3 < ^L / _D <3

given is. Due to the projecting into the combustion chamber 203, the nozzle outlet opening 215 can be brought closer to the recirculation zone in the combustion chamber so that the entrainment effect occurs shortly after the jet 205 leaves the nozzle outlet opening 215. The entrainment effect can therefore stabilize the jet flame 205 largely over its entire length.

By means of the invention, the entrainment effect for the hot gases in the outer recirculation zone is increased. In addition, the increased turbulent fluctuations ensure uniform combustion with low acoustic amplitudes, thus suppressing the occurrence of combustion oscillations. An optimization of the stability of the jet flame can be brought about by combining the burner illustrated in FIGS. 1 to 4 with the combustion system illustrated in FIG. 5.

Claims

claims

A burner (1, 101), in particular for a gas turbine, having at least one nozzle tube (7, 107) and a fuel fluid supply line (9) in communication with the nozzle tube (7, 107) for supplying a fuel fluid into the tube Nozzle tube (7, 107), wherein the nozzle tube (7, 107) has a nozzle outlet opening (15, 115) and is designed for injecting a jet (5) of fuel fluid or of a mixture of air and fuel fluid into a combustion chamber (3), characterized in that the nozzle tube (7, 107) in the region of the nozzle outlet opening (15, 115) to the center of the opening projecting elements (19, 119).

2. Burner (1) according to claim 1, characterized in that the protruding elements are formed by a nozzle outlet opening (15) reaching nozzle tube section with corrugated inner peripheral surface (19).

3. burner (1) according to claim 2, characterized in that the corrugated inner peripheral surface (19) at the nozzle outlet opening (15) has a maximum deflection A about a mean Öffnungsradis R of the nozzle outlet opening (15) and the ratio of the deflection to the average Öffnungsradi- us through the relationship

given is.

4. burner (1) according to claim 2 or 3, characterized in that the corrugated inner peripheral surface (19) has the shape of a sine wave.

5. burner (1) according to claim 2 or 3, characterized in that the corrugated inner peripheral surface (19) has sawtooth shape.

6. Burner (1) according to one of claims 2 to 5, characterized in that the nozzle tube (7) one of the nozzle opening (15) remote nozzle pipe section (21) having a circular opening cross-section and a transition section of the nozzle pipe section (21) with the round opening cross section to the nozzle tube section having the corrugated Innenum- receiving surface (19), wherein the maximum amplitude A of the corrugated inner peripheral surface (19) at the Düsenaustrittsöff- opening (15) is achieved and the ratio of the length L _τ of

Transition region to the maximum amplitude A through the relationship given is .

7. burner (101) according to claim 1, characterized in that the protruding elements by in the region of the nozzle outlet opening (115) on the inner peripheral surface (107) of the nozzle tube arranged vanes (119) are formed.

8. Burner (101) according to claim 7, characterized in that the wings are designed as delta wings (119).

9. burner (101) according to claim 7 or 8, characterized in that the wings (119) projecting at the nozzle outlet opening (115) over the distance S from the inner peripheral surface into the nozzle opening, the inner peripheral surface at the nozzle opening a circular circumference having the opening diameter D and the ratio of the distance S to the opening diameter D through the relationship

given is.

10. burner assembly (101) according to any one of claims 7 to 9, characterized in that the wings (119) are inclined by an inclination angle ^a with respect to the radial direction of the nozzle outlet opening (115).

11. burner (101) according to claim 10, characterized in that the inclination angle ^a in the range 65 ° < ^a <85 °.

12. combustion system, in particular for a gas turbine, with a combustion chamber (203) and a burner (201), in particular with a burner according to one of the preceding claims, which at least one nozzle tube (207) and one with the nozzle tube (207) in connection standing Fuel nozzle feed line (209) for feeding a fuel fluid into the nozzle tube (207), the nozzle tube (207) having a nozzle exit opening (215) opening into the combustion chamber (203) and injecting a jet (205) of fuel fluid or a mixture is configured of air and fuel fluid in the combustion chamber (203), characterized in that the nozzle tube (207) protrudes into the combustion chamber.

13. A combustion system according to claim 12, characterized in that the nozzle tube (207) has an opening diameter D and projects over a length L in the combustion chamber (203), wherein the ratio of the opening diameter D to the length L by the relationship

0.3 <L / _D <3

given is.