JP5982169B2 - Gas turbine combustor - Google Patents

Description

  The present invention relates to a gas turbine combustor, and in particular, as a fuel supply means, includes a two-fluid internal mixing nozzle that mixes compressed air and liquid fuel supplied from a gas turbine and then injects them into the combustor. The present invention relates to a gas turbine combustor that improves the atomization performance of liquid fuel and achieves low emission pollution.

  A turbine driven by combustion gas and a compressor that compresses air are connected to a common drive shaft, and the compressed air and fuel from the compressor are guided to the combustion cylinder for combustion, and the generated combustion gas is supplied to the turbine to drive the drive shaft. The gas turbine device that rotates the power generator is widely used in applications such as a stationary power generator. As this type of gas turbine device, for example, one having a diffusion combustion type combustor as described in Patent Document 1 is known, but the applicant of the present application pre-mixed in Japanese Patent Application No. 2011-119285. Proposes a combustion type combustor.

  In the diffusion combustion type combustor described in Patent Document 1 shown in FIG. 5, an ignition pressure injection nozzle 101 (pressure injection method) that pressurizes and injects liquid fuel is provided downward on the top of the combustor 100. Furthermore, a swirler airflow atomization nozzle 102 (airflow atomization method) is provided so as to surround the pressure injection nozzle 101. According to this gas turbine combustor, the liquid fuel injected from the pressure injection nozzle 101 and the airflow atomization nozzle 102 is mixed with compressed air inside the combustor 100 after going out of the nozzle (external mixing), It burns in the combustion zone B which is the upper part of the combustor 100.

  FIG. 6 shows a novel premixed combustion type combustor proposed by the present applicant in Japanese Patent Application No. 2011-119285. In this combustor 200, a premixing tube 201 that mixes the supplied fuel and air is provided at the top of the combustor 200 and communicates with the inside of the combustor 200. An air supply hole is provided in the top portion and side peripheral surface of the premixing tube 201, and air is configured to flow into the inside thereof. An ignition pressure injection nozzle 202 (pressure injection method) for injecting the liquid fuel by pressurizing and injecting the liquid fuel is provided downward on the top of the premixing tube 201. Further, on the side peripheral surface of the premixing tube 201, A pressure injection nozzle 203 (pressure injection method) for injecting liquid fuel under pressure is provided inward. According to the gas turbine combustor 200, the liquid fuel injected from the nozzles 202 and 203 is mixed with the compressed air inside the premixing pipe 201 (external mixing), and combusted in the combustion region B corresponding to the upper part of the combustor 200. To do.

JP 2010-101514 A

  However, the diffusion combustion type combustor described in Patent Document 1 and the premixed combustion type combustor proposed by the present applicant in Japanese Patent Application No. 2011-119285 have a pressure injection method (pressure injection nozzle) and an air flow. In any fuel injection method of the atomization method (air flow atomization nozzle), from the viewpoint of the mixing method of liquid fuel and air, external mixing that begins mixing with air after the liquid fuel is injected from the nozzle to the outside It was a method.

  Regarding the mixing and combustion process of liquid fuel and air in the combustor of the gas turbine, the liquid fuel becomes atomized oil droplets, and each oil droplet is in a good air supply situation where each oil droplet is uniformly mixed with air. Although single droplet combustion is performed, which is individually surrounded by the entire circumference flame, if the atomization performance of the liquid fuel deteriorates, such a good combustion state cannot be obtained. That is, according to the above-described prior art gas turbine combustor, when the fuel pressure is reduced in the pressure injection method or when the liquid film thickness is increased with the increase in the fuel flow rate in the air atomization method, There is a possibility that the atomization performance of the fuel may be significantly reduced. In such a case, in the region where the supply of oxygen is insufficient, the form of a group flame in which a plurality of oil droplets are burned together is promoted, and in the oil droplet particles In addition, unburned components due to the low oxygen state increased, and there was a risk of NOx increase due to local flame concentration.

  The present invention has been made to solve the above-described problems in the prior art, and in a gas turbine combustor using liquid fuel, the atomization performance of the liquid fuel is improved and the exhaust emission is reduced to low pollution ( The purpose is to reduce CO and NOx.

In order to achieve the above object, a gas turbine combustor according to claim 1 comprises:
A turbine driven by combustion gas and a compressor for compressing air are provided in a coaxially mounted gas turbine device, and liquid fuel is combusted by compressed air from the compressor to generate combustion gas supplied to the turbine A gas turbine combustor having a combustion cylinder,
An ignition pressure injection nozzle that is provided at one end of the combustion cylinder and injects liquid fuel into the combustion cylinder along the central axis of the combustion cylinder;
An orifice is provided at one end of the combustion cylinder so as to surround the pressure injection nozzle, and the supplied liquid fuel and compressed air supplied from the compressor outlet to the mixing section through an air supply path are mixed in the mixing section. comprising a plurality of two-fluid internal mixing nozzle for supplying a fuel mixture inside the combustion cylinder by injecting inclined in a direction extending at a predetermined angle outward with respect to the injection direction of the pressure jet nozzle from It is characterized by that.

A gas turbine combustor according to claim 2 is the gas turbine combustor according to claim 1,
The two-fluid internal mixing nozzle
A mixing section for mixing the supplied compressed air and liquid fuel;
Is connected to the outlet side of the compressor by the air supply path, an air path for supplying compressed air to the mixing unit communicates with the mixing unit,
A fuel path for supplying liquid fuel to the mixing section;
A pressure injection nozzle that is provided between the fuel path and the mixing unit and injects liquid fuel supplied from the fuel path into the mixing unit;
An orifice that is provided in the mixing section and injects compressed air and liquid fuel mixed in the mixing section to the outside;
It is characterized by having.

According to the invention of the gas turbine combustor described in claim 1 , the atomized liquid fuel is sufficiently mixed with air by attaching the pressure injection nozzle for ignition and the two-fluid internal mixing nozzle to the combustion cylinder. Therefore, the following effects can be achieved in the diffusion combustion type gas turbine combustor. That is, the two-fluid internal mixing nozzle mixes the supplied liquid fuel and the compressed air from the compressor inside, and in the state where the atomized liquid fuel is sufficiently mixed with the air , along the central axis of the combustion cylinder. It is possible to inject in the injection direction that spreads outward by a predetermined angle with respect to the injection direction of the pressure injection nozzle that injects the fuel into the combustion cylinder. Therefore, to promote the atomization of liquids fuel reduces the density of localized flame, low pollution exhaust emissions in a gas turbine combustor (low CO and low NO _X reduction) can be achieved . In addition, the two-fluid internal mixing nozzle used in the present invention uses compressed air supplied from the compressor of the gas turbine device, so there is no need to use an external power source for external supply of air. , Can promote power saving. Since the difference between the outlet pressure of the compressor of the gas turbine combustor and the internal pressure of the combustor is usually very small, less than 0.1 MPa, the present invention is not a two-fluid internal mixing nozzle that operates with high-pressure air. For example, a two-fluid internal mixing nozzle that operates with low-pressure air of less than 0.1 MPa is adopted.

According to the gas turbine combustor described in claim 2 , the liquid fuel supplied from the fuel path of the two-fluid internal mixing nozzle is injected into the mixing unit in a state of being atomized by the pressure injection nozzle, and then from the air path. After being mixed with the supplied compressed air inside the mixing section, it is injected outside through the orifice and supplied into the combustion cylinder. For this reason, the atomization of the liquid fuel and the mixing with the air are further sufficiently performed, the concentration of the local flame in the combustion cylinder is further reduced, and the reduction of exhaust emissions is further greatly promoted.

It is sectional drawing which shows the whole structure of the gas turbine apparatus which concerns on 1st Embodiment of this invention. It is sectional drawing which shows the structure of the combustor (diffusion combustion type) of the gas turbine apparatus which concerns on 1st Embodiment of this invention. (A) is sectional drawing which shows the structure of the 2 fluid internal mixing nozzle in the combustor of the gas turbine apparatus which concerns on 1st Embodiment of this invention, (b) is sectional drawing which shows the 2 fluid internal mixing nozzle of a modification. It is. It is sectional drawing which shows the structure of the combustor (premixed combustion type) of the gas turbine apparatus which concerns on 2nd Embodiment of this invention. It is sectional drawing which shows the structure and combustion area | region of the combustor (diffusion combustion type) of the conventional gas turbine apparatus. It is sectional drawing which shows the structure, combustion area, etc. of the combustor (premixed combustion type) of the novel gas turbine apparatus which the present applicant proposed in Japanese Patent Application No. 2011-119285.

A first embodiment of the present invention will be described with reference to FIGS.
First, the configuration of this gas turbine apparatus will be described.
As shown in FIG. 1, the gas turbine apparatus 1 includes a turbine 3 and a compressor 4 attached to a common drive shaft 2, and a diffusion combustion type combustor 5 provided with fuel supply means. Compressed air is supplied from the compressor 4 to the combustor 5, and fuel supply means (a pressure injection nozzle 8 and a two-fluid internal mixing nozzle 11 described later) supply liquid fuel (hereinafter simply referred to as fuel) to the combustor 5. By supplying the fuel, the fuel is combusted in the combustor 5 to generate high-temperature combustion gas, and this combustion gas is guided to the turbine 3 to rotate the drive shaft 2. The rotation of the drive shaft 2 is used as power, and the thermal energy of the combustion gas discharged after driving the turbine 3 can also be used by using an appropriate recovery means.

  FIG. 2 is an enlarged view of the combustor 5 provided in the gas turbine apparatus 1. In FIGS. 1 and 2, reference numeral 6 denotes a substantially cylindrical casing 6. Inside, compressed air from the compressor 4 is supplied from below to above. A substantially cylindrical combustion cylinder 7 is installed in the casing 6 at a predetermined interval from the inner surface of the casing 6. A pressure injection nozzle 8 for ignition is attached downward in the center of the upper end portion of the combustion cylinder 7. The pressure injection nozzle 8 is adapted to be supplied with liquid fuel from an external fuel supply source (not shown) through a fuel supply path that passes through the casing 6 and is guided to the outside. The fuel can be injected and supplied in the atomized state inside the combustion cylinder 7.

  As shown in FIG. 2, a spark plug 9 is provided on the upper peripheral surface of the combustion cylinder 7. Further, a position close to the spark plug 9 on the side peripheral surface of the combustion cylinder 7 and a position outside the pressure injection nozzle 8 and the two-fluid internal mixing nozzle described later at the top of the combustion cylinder 7 are located in the combustion cylinder 7. A plurality of introduction holes 10 are provided for taking in air.

  As shown in FIG. 2, a plurality of two-fluid internal mixing nozzles 11 are provided at the upper end of the combustion cylinder 7 so as to surround the pressure injection nozzle 8 at equal angular intervals in a plan view circumferential direction. . As shown in FIG. 3A, the base body 12 of the two-fluid internal mixing nozzle 11 has a substantially cylindrical shape as a whole, but the inside of the vicinity of the tip thereof is for mixing the supplied compressed air and liquid fuel. A mixing portion 13 that is a cylindrical cavity is formed. Inside the base 12, a fuel path 14 for liquid fuel is formed along the cylindrical central axis and communicates with one end face of the mixing portion 13. In addition, a plurality of air paths 15 are formed in the base 12 so as to surround the fuel path 14 in parallel with the fuel path 14, and communicate with the side peripheral surface of the mixing unit 13. In addition, an orifice 16 is provided between the other end surface of the mixing unit 13 and the tip end surface of the base 12, and the mixing unit 13 communicates with the outside. 2, the injection direction of the two-fluid internal mixing nozzle 11 is outward with respect to the injection direction of the pressure injection nozzle 8 that injects downward along the central axis of the combustion cylinder 7. It inclines in the direction which spreads only a predetermined angle toward.

  As shown in FIG. 1, the outlet side (symbol (1) in the figure) of the compressor 4 of the gas turbine apparatus 1 and the air path 15 of the two-fluid internal mixing nozzle 11 are schematically shown by solid arrows in the figure. They are connected by an air supply path 17. Further, a fuel supply source (not shown) and the fuel path 14 of the two-fluid internal mixing nozzle 11 are connected by a fuel supply path 18 schematically shown by a broken-line arrow in the drawing.

  As described above, the two-fluid internal mixing nozzle 11 used in the present invention uses the compressed air supplied from the compressor 4 of the gas turbine apparatus 1, but the outlet side of the compressor 4 (reference numeral in FIG. 1). The difference between the pressure of (1)) and the pressure inside the combustor 5 (reference numeral (2) in FIG. 1) is usually very small, 0.1 MPa or less. Therefore, for example, a two-fluid internal mixing nozzle that uses high-pressure air such as 1 to 4 MPa cannot be used as a component of the present invention. In the present invention, a low pressure that operates at a very low air pressure such as less than 0.1 MPa. It is necessary to use a two-fluid internal mixing nozzle of the type. Thus, according to the two-fluid internal mixing nozzle 11 used in this embodiment, the relatively low-pressure compressed air supplied from the compressor 4 of the gas turbine apparatus 1 and the supplied fuel are mixed by the mixing unit 13. Then, the fuel fine particles can be injected into the combustion cylinder 7 in a sufficiently mixed state with air.

Next, the operation and effect of the gas turbine apparatus 1 will be described.
As can be understood from FIGS. 1 and 2, during operation of the gas turbine apparatus 1 of this example, compressed air from the compressor 4 is sent into the casing 6, and the compressed air in the casing 6 is burned. The cylinder 7 is supplied into the combustion cylinder 7 from a large number of introduction holes 10 provided on the top and side peripheral surfaces. At startup, fuel is injected from the pressure injection nozzle 8 and mixed with air in the combustion cylinder 7, and the spark plug 9 ignites this mixture, and in this state, the two-fluid internal mixing nozzle 11 mixes in the combustion cylinder 7. Combustion starts by injecting and igniting qi.

  As shown in FIGS. 2 and 3A, the two-fluid internal mixing nozzle 11 mixes the supplied liquid fuel and the compressed air from the compressor 4 in the mixing unit 13, and converts the atomized liquid fuel into air. It can be supplied by being injected into the combustion cylinder 7 from the orifice 16 in the state of a sufficiently mixed gas mixture. According to such a two-fluid internal mixing nozzle 11, the liquid fuel becomes atomized oil droplets, and each oil droplet is uniformly mixed with air. The desired combustion state of single drop combustion that is enclosed and burned is obtained. Accordingly, the density of the local flame is reduced, and low emission pollution (low CO and low NOx) in the gas turbine device 1 can be achieved.

  Further, as in the present embodiment, by providing the low pressure type two-fluid internal mixing nozzle 11 so that the compressed air generated by the compressor 4 of the gas turbine apparatus 1 can be used, it is not necessary to supply the air externally. Therefore, it is not necessary to use an external power source for supplying external air, and it is possible to meet the strong demand for power saving in recent years.

  As described above and shown in FIG. 3A, the two-fluid internal mixing nozzle 11 used in this embodiment supplies and mixes fuel and compressed air into the mixing unit 13 to mix the mixture. Was a nozzle that injects the gas from the orifice 16 to the outside. However, if the two-fluid internal mixing nozzle 21 as shown in FIG. 3B is used, the atomization of the fuel and the mixing with the air are further improved. The two-fluid internal mixing nozzle 21 of the modified example shown in FIG. 3B has a configuration in which a pressure injection nozzle 19 is provided between the fuel path 14 and the mixing unit 13, and the other structure is shown in FIG. It is the same as the nozzle of a). According to the two-fluid internal mixing nozzle 21 of this modification, fuel supplied under pressure is injected into the mixing unit 13 by the pressure injection nozzle 19 through the fuel path 14 and is first atomized, and further compressed. The particles are secondarily atomized at the stage of being mixed with air in the mixing unit 13.

  For this reason, atomization of liquid fuel and mixing with air are performed more sufficiently than in the case of the two-fluid internal mixing nozzle 11 shown in FIG. The light and shade of the flame is further reduced, and a distinct and remarkable effect is obtained in which the reduction of exhaust emissions is further promoted.

A second embodiment of the present invention will be described with reference to FIG.
The gas turbine apparatus of the second embodiment is the same as that of the first embodiment except for the premixed combustion type combustor 25, and therefore, mainly the different parts are described and the description is omitted. About the description of 1st Embodiment is used.

  FIG. 4 shows a premixed combustion type combustor 25 provided in the gas turbine apparatus of the second embodiment. A combustion cylinder 27 as a main body has a substantially cylindrical shape, and a premixing tube 20 described later is attached to the top of the combustion cylinder 27 so as to communicate with the combustion cylinder 7. The combustion cylinder 7 and the premixing pipe 20 are surrounded by a casing 6 communicating with the outlet of the compressor 4, and the lower opening of the combustion cylinder 27 communicates with the exhaust side of the gas turbine 3. Although not shown, a spark plug is provided at a predetermined position on the side peripheral wall of the combustion cylinder 27.

  The premixing tube 20 has a cylindrical shape smaller in diameter than the combustion cylinder 27 and is attached to the combustion cylinder 27 with the axes aligned. The premixing tube 20 is a device that mixes the supplied fuel and air and supplies the mixed fuel and air into the combustion cylinder 27. The premixing pipe 20 has a lower peripheral wall 22 that communicates with the combustion cylinder 27 and an inner diameter that is substantially the same as the lower peripheral wall 22. And an upper peripheral wall 23 that communicates with the upper peripheral wall 23. A number of holes 24 are formed in the upper peripheral wall 23 along the tangential direction so that a swirling flow of air can be introduced into the inside.

  Inside the upper peripheral wall 23, a generally inverted frustoconical cylindrical inner wall 26 is provided. The inner wall 26 is disposed concentrically with the upper peripheral wall 23, and its upper end is fixedly connected to the upper end of the upper peripheral wall 23 over the entire circumference. Therefore, a gap S that is substantially cylindrical and is opened downward is formed between the upper peripheral wall 23 and the inner wall 26, and the air taken into the inside from the hole 24 of the upper peripheral wall 23 swirls in the gap S. A flow is generated.

  As shown in FIG. 4, the upper end surface of the inner wall 26 is provided with a substantially circular plate 30 in which a large number of holes (not shown) are formed in order to take in air. At the center of the plate 30, a pressure injection nozzle 28 for ignition is disposed downward along the axial direction. Further, adjacent to the pressure injection nozzle 28, the first two-fluid internal mixing nozzle 11a is attached to the plate 30 so as to face downward along the axial direction. The lower end surface of the inner wall 26 is an opening 31, and the straight flow of air flowing in through the hole of the plate body 30, the fuel injected from the pressure injection nozzle 28, and the mixing injected from the two-fluid internal mixing nozzle 11 The air is supplied from the opening 31 into the combustion cylinder 27 through the lower peripheral wall 22. The pressure injection nozzle 28 is connected to a fuel supply source (not shown) through a fuel supply path 18 that passes through the casing 6 and is guided to the outside.

  As shown in part in FIG. 4, a plurality of second two-fluid internal mixing nozzles for injecting an air-fuel mixture on the peripheral wall of the lower peripheral wall 22 of the premixing tube 20 at a position close to the opening 31 of the inner wall 26. 11b is attached. The plurality of two-fluid internal mixing nozzles 11c are arranged so as to be equiangularly spaced with respect to the central axis when viewed in a plane orthogonal to the central axis of the lower peripheral wall 22, and the injection direction of each is a combustion The tube 27 is directed toward the central axis.

  As shown in FIG. 4, a third two-fluid internal mixing nozzle 11 c is attached to the side peripheral wall slightly below the central portion of the combustion cylinder 27 with its injection direction directed toward the central axis of the combustion cylinder 27. Yes. The position where the two-fluid internal mixing nozzle 11c is attached to the combustion cylinder 27 corresponds to a downstream region where the concentration of fuel is reduced by the progress of combustion in the combustion cylinder 27.

  As described above, in the premixed combustion type combustor 5 of the second embodiment, the two-fluid internal mixing nozzle 11a is provided at three locations on the top of the premixing tube 20, the lower peripheral wall 22, and the side peripheral wall of the combustion cylinder 27. 11b, 11c (collectively referred to as a two-fluid internal mixing nozzle 11). Each of these two-fluid internal mixing nozzles 11 has an air passage 15 connected to the outlet side (reference numeral (1) in FIG. 1) of the compressor 4 of the gas turbine device 1 via an air supply passage 17, and its fuel. The path 14 is connected to a fuel supply source (not shown) via a fuel supply path 18. The structure of these two-fluid internal mixing nozzles 11 is the same as that of the first embodiment, and any of the nozzles shown in FIGS. 3A and 3B can be used. In the present embodiment, a plurality of two-fluid internal mixing nozzles 11b attached to the lower peripheral wall 22 of the premixing tube 20 and a plurality of other two-fluid internal mixing nozzles 11a and 11c are provided at one position. Also, one or more can be used depending on the performance of the apparatus, the amount of fuel supplied, and other conditions.

Next, the operation and effect of this gas turbine apparatus will be described.
Compressed air is supplied from the compressor 4 into the casing 6. In this state, fuel is injected from the pressure injection nozzle 28 and ignited by a spark plug. Thereafter, the air-fuel mixture is supplied from the first to third two-fluid internal mixing nozzles 11a, 11b, and 11c to ignite, and then the pressure is increased. The fuel is continuously injected by the injection nozzle 28 and the first to third two-fluid internal mixing nozzles 11a, 11b, and 11c to continue combustion.

  The combustion state will be described in detail. First, the compressed air supplied into the casing 6 enters the inside of the plate 30 of the premixing tube 20 and mixes with the fuel injected from the pressure injection nozzle 28. It becomes a straight flow, and after ignition, it becomes a flame for igniting the air-fuel mixture from the first to third two-fluid internal mixing nozzles 11a, 11b, 11c.

  The air supplied to the inside of the casing 6 flows into the inside through a hole 24 provided in the upper peripheral wall 23 of the premixing tube 20, and becomes a swirl flow in the cylindrical gap S between the upper peripheral wall 23 and the inner wall 26. , Descend along the inner peripheral surface of the lower peripheral wall 22. The air-fuel mixture injected from the two-fluid internal mixing nozzle 11b provided on the lower peripheral wall 22 swirls on this swirling flow and is sent to the inside of the lower peripheral wall 22 from the opening 31 of the inner wall 26. While the straight flow and a part merge, most of them are fed into the combustion cylinder 27 while turning.

  Then, the air-fuel mixture sent to the combustion cylinder 27 spreads in the combustion region at the upper part of the combustion cylinder 27 close to the premixing tube 20, and most of the mixture is quickly evaporated, and is ignited by the flame of the pressure injection nozzle 28 and ignited uniformly. In this manner, the gas is completely combusted and becomes high-temperature combustion gas, which is supplied to the exhaust side of the gas turbine device from the lower opening of the combustion cylinder 27.

  And according to the combustor 25 of the gas turbine device of the second embodiment, the first two-fluid internal mixing nozzle 11a is attached to the top of the premixing tube 20 downward, so that the atomized liquid fuel is sufficiently mixed with air. In a state of being mixed with each other, it can be directly injected into the inner wall 26 of the premixing tube 20 and further mixed with the compressed air supplied from the casing 6 side. Further, by attaching the second two-fluid internal mixing nozzle 11b to the lower peripheral wall 22 of the premixing tube 20, the liquid fuel atomized from the mixture 31 ejected from the opening 31 of the inner wall 26 in the premixing tube 20 and A further air mixture can be added. Since the high-pressure air blown into the inside of the hole 24 of the upper peripheral wall 23 enters the lower peripheral wall 22 as a swirling flow in the gap S, the first and second two-fluid internal mixing nozzles 11a and 11b. The air-fuel mixture injected from is further sufficiently mixed with air and supplied from the lower peripheral wall 22 into the combustion cylinder 27. Therefore, since the fuel is completely atomized and burned in the combustion cylinder 27 in a sufficiently mixed state with air, local flame concentrations are unlikely to occur in the combustion in the combustion cylinder 27, and the exhaust emission is low. Pollution reduction (low CO and low NOx) can be achieved reliably.

  Furthermore, according to the combustor 25 of the gas turbine apparatus of the second embodiment, the third two-fluid internal mixing different from the first and second two-fluid internal mixing nozzles 11a and 11b attached to the premixing pipe 20 is provided. Since the nozzle 11c is further attached to the combustion cylinder 27, an air-fuel mixture in which the atomized fuel is sufficiently mixed with air is directly injected into the downstream area of the combustion cylinder 27 where the concentration of the fuel is reduced by combustion. Therefore, the total amount of liquid fuel charged into the combustor 25 of the gas turbine apparatus can be increased, and the output and the amount of combustion gas can be increased.

DESCRIPTION OF SYMBOLS 1 ... Gas turbine apparatus 3 ... Turbine 4 ... Compressor 5, 25 ... Combustor 7, 27 ... Combustion cylinder 8, 28 ... Pressure injection nozzle 11, 11a, 11b, 11c, 21 ... 2 Fluid internal mixing nozzle 13 ... Mixing part 16 ... orifice 19 ... pressure injection nozzle 20 provided in the two-fluid internal mixing nozzle 20 ... mixing tube S ... gap

Claims (2)

A turbine driven by combustion gas and a compressor for compressing air are provided in a coaxially mounted gas turbine device, and liquid fuel is combusted by compressed air from the compressor to generate combustion gas supplied to the turbine A gas turbine combustor having a combustion cylinder,
An ignition pressure injection nozzle that is provided at one end of the combustion cylinder and injects liquid fuel into the combustion cylinder along the central axis of the combustion cylinder;
An orifice is provided at one end of the combustion cylinder so as to surround the pressure injection nozzle, and the supplied liquid fuel and compressed air supplied from the compressor outlet to the mixing section through an air supply path are mixed in the mixing section. comprising a plurality of two-fluid internal mixing nozzle for supplying a fuel mixture inside the combustion cylinder by injecting inclined in a direction extending at a predetermined angle outward with respect to the injection direction of the pressure jet nozzle from A gas turbine combustor. The two-fluid internal mixing nozzle
A mixing section for mixing the supplied compressed air and liquid fuel;
Is connected to the outlet side of the compressor by the air supply path, an air path for supplying compressed air to the mixing unit communicates with the mixing unit,
A fuel path for supplying liquid fuel to the mixing section;
A pressure injection nozzle that is provided between the fuel path and the mixing unit and injects liquid fuel supplied from the fuel path into the mixing unit;
An orifice that is provided in the mixing section and injects compressed air and liquid fuel mixed in the mixing section to the outside;
The gas turbine combustor according to claim 1, comprising:

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