JP2013190196A - Gas turbine combustor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a gas turbine combustor that can accelerate premixing of air in an air film or a substrate air with fuel, can reduce the amount of the substrate air, and can prevent the generation of the stagnation of the flow of the premixed gas in an area between neighboring premixng burner holes of a substrate.SOLUTION: A gas turbine combustor includes for example: an outer guide ring 39 that is located at the outer side of an extension pipe 54 and where a downstream side end 39b extends to the downstream side from the downstream end of the extension pipe 54; and an inner guide ring 38 that is located at the inner side of the extension pipe 54 and where the downstream side end extends to the downstream side from the extension pipe 54.The gas turbine combustor 31 is configured so that a gap between the downstream side end of the outer guide ring 39 and the downstream side end of the inner guide ring 38 is an annular secondary premixed region 57 that communicates with the extension pipe 54 and continuously extends over the entire circumference.

Description

  The present invention relates to a premixed combustion type gas turbine combustor.

  In recent years, many gas turbine combustors adopt a premixed combustion system for the purpose of reducing NOx and the like. The premixed combustion type gas turbine combustor includes a premixed burner (main burner) that performs premixed combustion and a pilot burner that performs diffusion combustion, and the diffusion flame generated by the pilot burner is premixed. The premixed combustion of the premixed burner can be maintained by using it as a fire type for generating a premixed flame in the burner.

  30 and 31 show a configuration example of a conventional premixed combustion type gas turbine combustor. In FIG. 30, the left side is the upstream side, and the right side is the downstream side.

  As shown in FIGS. 30 and 31, a conventional premixed combustion type gas turbine combustor 1 includes a combustor inner cylinder 2 provided inside a combustor outer cylinder (not shown), and a combustor tail cylinder 3. And have.

The combustor tail cylinder 3 has a combustion chamber 4 inside, and an upstream end is connected to a downstream end of the combustor inner cylinder 2, while a downstream end is provided with a rotor and the like. Part (not shown).
The combustor inner cylinder 2 is cylindrical. Inside the combustor inner cylinder 2, a plurality (eight in the illustrated example) of premix burners (main burners) 5 for performing premix combustion, a pilot burner 6 for performing diffusion combustion, and these burners 5 and 6 are provided. A supporting substrate 11 is provided.

  The substrate 11 has a disk shape, and is supported by the combustor inner cylinder 2 by fixing the outer peripheral portion to the inner peripheral surface of the combustor inner cylinder 2. A large number of air holes 11a are formed in the substrate 11, and pilot burner holes 11b and a plurality (eight in the illustrated example) of premix burner holes 11c are also formed. The pilot burner hole 11b is opened at the center of the substrate 11, and the plurality of premix burner holes 11c are opened at equal intervals in the circumferential direction of the substrate 11 to surround the pilot burner hole 11b.

  The pilot burner 6 is disposed in the central portion (coaxially with the combustor inner cylinder 2) in the combustor inner cylinder 2, and includes a pilot air swirler cylinder 7, pilot nozzles 8, and a plurality (six in the illustrated example). A pilot air swirler vane (pilot air swirler) 9 and a pilot cone 10 are provided.

  The pilot air swirler cylinder 7 has a cylindrical shape, is inserted into the pilot burner hole 11 b of the substrate 11, and is fixed to and supported by the substrate 11. The pilot nozzle 8 is disposed in a central portion (coaxially with the pilot air swirler cylinder 7) in the pilot air swirler cylinder 7. Although not shown, the upstream end portion of the pilot nozzle 8 is fixed and supported by a support portion provided at the upstream end portion of the combustor inner cylinder 2. A fuel injection hole 8 a is provided at the downstream end of the pilot nozzle 8. The pilot air swirler vanes 9 are interposed between the inner peripheral surface of the pilot air swirler cylinder 7 and the outer peripheral surface of the pilot nozzle 8, and are arranged at equal intervals in the circumferential direction of the pilot nozzle 8.

  The pilot cone 10 is a truncated cone-shaped tube that spreads outward in the radial direction from the upstream end to the downstream end, and the upstream end is connected to the downstream end of the pilot air swirler tube 7. It is connected. The flame holder 12 is an annular plate, the inner peripheral portion is connected to the downstream end portion of the pilot cone 10, and the downstream surface is a back step surface 12 a.

  The plurality of premix burners 5 are arranged at equal intervals in the circumferential direction of the combustor inner cylinder 2 and surround the pilot burner 6. Each of these premix burners 5 has a premix air swirler cylinder 15, a premix nozzle 16, a plurality (six in the illustrated example) of premix air swirler vanes (premix air swirl vanes) 17, and an extension pipe 18. And.

  The premixed air swirler cylinder 15 has a cylindrical shape, an upstream end is fixed to the combustor inner cylinder 2 by a bolt 13, and a downstream end is positioned in the premix burner hole 11 c of the substrate 11. . The premixing nozzle 16 is disposed at a central portion (on the same axis as the premixed air swirler cylinder 15) in the premixed air swirler cylinder 15. Although not shown, the upstream end portion of the premixing nozzle 16 is fixed and supported by the support portion. The premixed air swirler vanes 17 are fixed to the outer peripheral surface of the premixing nozzle 16 and are arranged at equal intervals in the circumferential direction of the premixing nozzle 16. The premixed air swirler vane 17 is provided with a fuel injection hole 17a.

  The extension pipe 18 communicates with the premixed air swirler cylinder 15 through the premixed burner hole 11c. More specifically, the upstream side of the extension pipe 18 is inserted into the premixing burner hole 11 c of the substrate 11 and fixed to the substrate 11, and the downstream end 18 b extends to the downstream side of the substrate 11. The extension pipe 18 has a cross-sectional shape that is circular at the upstream end 18a, is continuously deformed toward the downstream, and is rectangular at the downstream end 18b. Since the inner diameter of the upstream end 18a of the extension pipe 18 is larger than the outer diameter of the downstream end 15a of the premixed air swirler cylinder 15, the inner peripheral surface of the upstream end 18a of the extension pipe 18 and the premixed air swirler. An annular gap is formed between the outer peripheral surface of the downstream end 15a of the cylinder 15 and this gap serves as an air flow path 21 for generating an air film.

  Next, the operation of the premixed combustion type gas turbine combustor 1 will be described.

  The air a compressed by the compressor (not shown) with respect to the gas turbine combustor 1 is transferred from the air flow path (not shown) between the combustor outer cylinder and the combustor inner cylinder 2 to the combustor inner cylinder. 2 flows into the combustor inner cylinder 2 through an air hole (not shown) at the upstream end of the cylinder 2 and then into the pilot air swirler cylinder 7 of the pilot burner 6 and the premixed air swirler cylinder 15 of the premixing burner 5. The fuel f supplied to the inside, the air flow path 21, and the air holes 11 a of the substrate 11 and sent from the fuel supply system (not shown) is supplied to the pilot nozzle 8 and the premixing nozzle 16. The

  In the pilot burner 6, the air a supplied into the pilot air swirler cylinder 7 is swirled by the pilot air swirler vanes 9 while flowing through the pilot air swirler cylinder 7, and is injected into the pilot cone 10. The fuel f supplied into the nozzle 8 flows through the pilot nozzle 8 and is injected into the pilot cone 10 from the fuel injection hole 8 a of the pilot nozzle 8. Accordingly, the air a and the fuel f are mixed in the pilot cone 10 and the mixture is ignited by an ignition device (not shown), whereby diffusion combustion is performed in the pilot cone 10 and in the combustion chamber 4 ( A diffusion flame is generated).

  On the other hand, in the premix burner 5, the air a supplied into the premixed air swirler cylinder 15 is swirled by the premixed air swirler vane 17 while circulating in the premixed air swirler cylinder 15, while the premix nozzle The fuel f supplied into the gas 16 flows through the premixing nozzle 16 and the premixed air swirler vane 17, and is injected into the premixed air swirler cylinder 15 from the fuel injection hole 17 a of the premixed air swirler vane 17. These air a and fuel f are premixed in the premixed air swirler cylinder 15 and the extension pipe 18, and this premixed gas is injected into the combustion chamber 4. In the combustion chamber 4, the diffusion flame generated by the pilot burner 6 is used as a fire type, whereby the premixed gas is ignited and premixed combustion is performed.

  At this time, in the flame holder 12, a back flow as indicated by an arrow C with respect to a part of the premixed gas flowing out from the extension pipe 11 and a part of the mixed gas flowing out from the pilot cone 10 on the back step surface 12 a. By generating or decelerating, it is possible to reliably maintain the premixed combustion using the diffusion flame as a fire type.

  The air a supplied into the air flow path 21 flows through the air flow path 21 to form a film, and the air film flows along the inner peripheral surface of the extension pipe 18 so that the air a near the inner peripheral surface. It is possible to prevent the occurrence of flashback. That is, when the air film is not flowed, backfire may occur in the low flow velocity region of the premixed gas generated in the vicinity of the inner peripheral surface of the extension pipe 18, but this backfire is prevented by the air film. be able to.

  The air a supplied to the air holes 11 a of the substrate 11 passes through the air holes 11 a to become substrate air, and this substrate air is a region between the extension pipes 18 adjacent in the circumferential direction of the combustor inner cylinder 2. , Flows around the extension tube 18. For this reason, it is possible to prevent the high-temperature combustion gas generated in the combustion chamber 4 from being caught in the low flow velocity region or the reverse flow region near the substrate 11 by the substrate air.

  Examples of prior art documents in which a conventional premixed combustion type gas turbine combustor is disclosed include the following.

JP 2001-254946 A Japanese Patent No. 4070758 JP 2001-296025 A JP 2003-014232 A

In high temperature combustors, it is particularly important to reduce NOx. On the other hand, in a gas turbine combustor, it is necessary to make the fuel uniform by premixing air and fuel in a short premix burner. For this reason, conventionally, a plurality of premixing burners 5 are provided in one gas turbine combustor 1, and an extension pipe 18 is provided in each of these premixing burners 5, thereby promoting the mixing of air a and fuel f. I am trying.
In addition, by flowing an air film on the inner peripheral surface of the extension pipe 18, backfire in the low flow velocity region near the inner peripheral surface of the extension pipe 18 is prevented.
Further, by flowing the substrate air around the extension pipe 18, the hot combustion gas is prevented from being caught in the low flow velocity region or the reverse flow region near the substrate 11.

However, since the peripheral length of the extension pipe 18 is long, the amount of air for forming an air film necessary for preventing backfire increases. In addition, in the extension pipe 18, the fuel concentration in the region where the air film flows may become too low, and the air film cannot be sufficiently mixed with the premixed gas at a short distance, and the center of the premixed gas cannot be obtained. A high temperature region remains.
Furthermore, the swirling flow of the air a is formed by the premixed air swirler vane 17 to promote the mixing of the air a and the fuel f. In the extension pipe 18, the fuel concentration distribution in the radial direction is stratified, and the air The mixing ratio of a and fuel f decreases.

  Further, since it is necessary to flow the substrate air around the extension pipe 18, the amount of air a that can be used for premixing by the premixing burner 5 is reduced accordingly. For this reason, the fuel concentration of the premixed gas of the whole premixed burner 5 rises.

  Further, the substrate air flowing around the extension pipe 18 and the premixed gas coming out of the extension pipe 11 are mixed downstream from the outlet (downstream end) of the extension pipe 11, but at this time, the premixed gas is immediately burned. Be started. For this reason, there is no time for the substrate air and the premixed gas to be sufficiently mixed, and the fuel concentration of the premixed gas is burned with a non-uniform state.

  Therefore, in view of the above circumstances, the present invention promotes premixing of air and fuel such as air film and substrate air, reduces the amount of substrate air, and between adjacent premix burner holes of the substrate. It is an object of the present invention to provide a gas turbine combustor capable of preventing the stagnation of the premixed gas flow in the region.

A gas turbine combustor according to a first invention for solving the above-described problems is
With a pilot burner,
A plurality of premixing burners provided with a premixing nozzle and a premixing air swirler vane in the premixing air swirler cylinder, and arranged to surround the pilot burner;
A pilot burner hole and a plurality of premix burner holes disposed so as to surround the pilot burner hole; and a substrate for supporting the pilot burner and the premix burner;
An extension pipe that communicates with the premixed air swirler cylinder via the premix burner hole and extends to the downstream side of the substrate is provided in the combustor inner cylinder,
The inside of the premixed air swirler cylinder and the inside of the extension pipe are primary premixing regions,
A configuration in which an air film flows from an air flow path formed between the premixed air swirler cylinder and the extension pipe to the inner peripheral surface of the extension pipe, and between the adjacent extension pipes from the air holes provided in the substrate A gas turbine combustor having either or both of a configuration for flowing substrate air to the region of
An outer guide ring located outside the extension pipe and having a downstream end extending downstream from the downstream end of the extension pipe; and a downstream end located inside the extension pipe and extending the extension pipe An inner guide ring extending downstream from the downstream end of the tube,
A space between the downstream end of the outer guide ring and the downstream end of the inner guide ring communicates with the extension pipe and is continuous in the entire circumferential direction. It is a mixed region.

The gas turbine combustor of the second invention is the gas turbine combustor of the first invention.
The outer guide ring is a downstream end portion of the combustor inner cylinder.

The gas turbine combustor of the third invention is the gas turbine combustor of the first or second invention.
The width of the second premixing region is narrowed toward the downstream side.

The gas turbine combustor of the fourth invention is
With a pilot burner,
A plurality of premixing burners provided with a premixing nozzle and a premixing air swirler vane in the premixing air swirler cylinder, and arranged to surround the pilot burner;
A pilot burner hole and a plurality of premix burner holes arranged so as to surround the pilot burner hole are provided, and the pilot burner and the substrate supporting the premix burner are disposed in the combustor inner cylinder. Provided,
The premixed air swirler cylinder is a first premixed area,
In a gas turbine combustor having a configuration in which an air film flows from an air flow path formed between the premixed air swirler cylinder and a flow path cylinder,
An outer padding that fills an outer region between the adjacent premix burner holes on the downstream surface of the substrate, and is narrowed toward the downstream tip, and downstream of the substrate An inner padding that fills the inner region between the adjacent premix burner holes on the side surface and has an inner padding that narrows toward the downstream tip; and
A space between the outer stuffing and the inner stuffing communicates with the premixed air swirler cylinder through the premixed burner hole and is continuous in the entire circumferential direction. It is a region.

The gas turbine combustor of the fifth invention is
With a pilot burner,
A plurality of premixing burners provided with a premixing nozzle and a premixing air swirler vane in the premixing air swirler cylinder, and arranged to surround the pilot burner;
A pilot burner hole and a plurality of premix burner holes arranged so as to surround the pilot burner hole are provided, and the pilot burner and the substrate supporting the premix burner are disposed in the combustor inner cylinder. Provided,
The premixed air swirler cylinder is a first premixed area,
In a gas turbine combustor having a configuration in which an air film flows from an air flow path formed between the premixed air swirler cylinder and a flow path cylinder,
An outer padding that fills an outer region between the adjacent premix burner holes on the downstream surface of the substrate, and is narrowed toward the downstream tip, and downstream of the substrate The inner surface between the premixing burner holes adjacent to each other on the side surface is filled with the upstream end surface and extends to the downstream end surface, and the downstream end surface is the back step surface of the flame stabilizer. With stuffing
A space between the outer stuffing and the inner stuffing communicates with the premixed air swirler cylinder through the premixed burner hole and is continuous in the entire circumferential direction. It is a region.

The gas turbine combustor of the sixth invention is
With a pilot burner,
In a gas turbine combustor having a premixing nozzle and a premixed air swirler vane, and a plurality of premixing burners disposed so as to surround the pilot burner in an inner cylinder of the combustor,
A premix burner inner cylinder is disposed inside the combustor inner cylinder, and an annular flow path that is a space between the combustor inner cylinder and the premix burner inner cylinder is continuous over the entire circumferential direction, The downstream portion of the annular channel is a premixing region,
The premix burner is disposed in the annular flow path, and the pilot burner is disposed inside the inner tube of the premix burner.

Moreover, the gas turbine combustor of the seventh invention is the gas turbine combustor of the sixth invention,
The width of the premixing region is narrowed toward the downstream side.

The gas turbine combustor of the eighth invention is
With a pilot burner,
A plurality of premixing burners provided with a premixing nozzle and a premixing air swirler vane in the premixing air swirler cylinder, and arranged to surround the pilot burner;
A pilot burner hole, and a plurality of premix burner holes disposed so as to surround the pilot burner hole, the pilot burner and a substrate supporting the premix burner;
In the gas turbine combustor in which the premixed air swirler cylinder is a first premixed region,
The downstream surface of the substrate has a stagnation-excluding structure that fills a region between adjacent premix burner holes,
And the cross-sectional shape of the stagnation-excluding structure has a narrower width toward the downstream side,
An outer guide ring positioned outside the stagnation-excluding structure, and an inner guide ring positioned inside the stagnation-excluding structure;
A space between the outer guide ring and the inner guide ring communicates with the premixed air swirler cylinder via the premixed burner hole and is continuous in the entire circumferential direction. It is a premixing region.

Moreover, the gas turbine combustor of the ninth invention is the gas turbine combustor of the eighth invention,
An air film is caused to flow from an air flow path formed between the premixed air swirler cylinder and the flow path cylinder.

The gas turbine combustor of the tenth invention is the gas turbine combustor of the eighth or ninth invention,
A cross-sectional shape of the stagnation-excluding structure is an isosceles triangle.

Moreover, the gas turbine combustor of the eleventh invention is the gas turbine combustor of the eighth or ninth invention,
A cross-sectional shape of the stagnation-excluding structure is a bell shape.

The gas turbine combustor of the twelfth invention is the gas turbine combustor of the eighth or ninth invention,
The upstream end face of the stagnation-excluding structure is wider at the outer part and the inner part than the radial central part of the stagnation-excluding structure,
The cross-sectional shape of the stagnation-excluding structure is a bell shape in the central portion, and isosceles triangle shape in the outer portion and the inner portion.

Moreover, the gas turbine combustor of the thirteenth invention is the gas turbine combustor of the eighth or ninth invention,
The cross-sectional shape of the stagnation-excluding structure is a shape having a bell-shaped portion on the upstream side and an isosceles triangular portion on the downstream side.

Moreover, the gas turbine combustor of the fourteenth invention is the gas turbine combustor of the eighth or ninth invention,
The upstream end face of the stagnation-excluding structure is wider at the outer part and the inner part than the radial central part of the stagnation-excluding structure,
The cross-sectional shape of the stagnation-excluding structure is such that the central portion has a bell-shaped portion on the upstream side and an isosceles triangular portion on the downstream side, and the outer portion and the inner portion have a bell-shaped shape. It is characterized by.

Moreover, the gas turbine combustor of the fifteenth invention is the gas turbine combustor of any one of the eighth to fourteenth inventions,
The stagnation-excluding structure has a hollow hole, and the downstream side of the hollow hole is closed, while the upstream side of the hollow hole communicates with an air hole provided in the substrate.
Alternatively, the stagnation-excluding structure has a porous portion and a coating portion that covers the surface of the porous portion, and the holes of the porous portion communicate with air holes provided in the substrate. It is characterized by.

According to the gas turbine combustor of the first invention, a pilot burner and a premixing air swirler cylinder are provided with a premixing nozzle and a premixing air swirler vane, and a plurality of pilot burners are disposed so as to surround the pilot burner. A premixing burner, a pilot burner hole, and a plurality of premixing burner holes disposed so as to surround the pilot burner hole are provided, the pilot burner and a substrate supporting the premixing burner, and the premixing burner. An extension pipe that communicates with the premixed air swirler cylinder via a mixing burner hole and extends downstream of the substrate is provided in the inner cylinder of the combustor, and in the premixed air swirler cylinder and the extension. The inside of the pipe is a first premixing region, and an air film is caused to flow from an air flow path formed between the premixed air swirler cylinder and the extension pipe to the inner peripheral surface of the extension pipe. A gas turbine combustor having either or both of a configuration in which substrate air flows from an air hole provided in the substrate to a region between adjacent extension tubes, and a downstream end located outside the extension tube An outer guide ring whose portion extends downstream from the downstream end of the extension tube, and a downstream end located inside the extension tube and extending downstream from the downstream end of the extension tube An inner guide ring, and a space between the downstream end portion of the outer guide ring and the downstream end portion of the inner guide ring communicates with the extension pipe and extends in the entire circumferential direction. In the second premixing region, the premixed gas and the air film or the substrate air, or the air film and the substrate air are: Well mixed. For this reason, premixed combustion is performed in a state where the fuel concentration of the premixed gas is uniform.
In addition, since the circumference of the secondary premixing zone is shorter than the circumference of the conventional extension pipe, the low flow velocity region near the inner peripheral surface is small, and backfire may occur in the low flow velocity region. Decreases.
Furthermore, in the premixed air swirler cylinder and the extension pipe, there is a low flow velocity region in the center of the swirling flow of the premixed gas, but since the low flow velocity region can be eliminated in the second premixed region, It is also possible to prevent backfire from occurring in a low flow rate region.

  According to the gas turbine combustor of the second invention, in the gas turbine combustor of the first invention, the outer guide ring is a downstream end side portion of the combustor inner cylinder. By effectively using the inner cylinder, the second premixing region can be provided at a low cost.

  According to the gas turbine combustor of the third invention, in the gas turbine combustor of the first or second invention, the width of the second premixing region becomes narrower toward the downstream side. Therefore, since the premixed gas is accelerated toward the outlet of the second premixed region, the boundary layer can be thinned or the fuel concentration in the vicinity of the wall surface can be thinned. For this reason, it is possible to prevent backfire from occurring in the vicinity of the wall surface.

According to the gas turbine combustor of the fourth invention, the pilot burner and the premixed air swirler cylinder are provided with the premix nozzle and the premixed air swirler vane, and a plurality of the burners are disposed so as to surround the pilot burner. A premix burner, a pilot burner hole, and a plurality of premix burner holes arranged so as to surround the pilot burner hole are provided, and the pilot burner and the substrate supporting the premix burner burn Provided in the container cylinder, the premixed air swirler cylinder is a primary premixing region, and from the air flow path formed between the premixed air swirler cylinder and the flow path cylinder, In the gas turbine combustor configured to flow an air film, an upstream end face fills an outer region between adjacent premix burner holes on a downstream face of the substrate. An upstream end surface fills an inner region between the outer padding that becomes thinner toward the downstream end and the adjacent premix burner hole on the downstream surface of the substrate, and the downstream end An inner padding that narrows toward the tip, and a space between the outer padding and the inner padding is formed in the premixed air swirler cylinder through the premix burner hole. Since it is an annular second premixing region that is continuous and continuous in the entire circumferential direction, the premixed gas and the air film are well mixed in the second premixing region. . For this reason, premixed combustion is performed in a state where the fuel concentration of the premixed gas is uniform.
In addition, since the circumference of the secondary premixing zone is shorter than the circumference of the conventional extension pipe, the low flow velocity region near the inner peripheral surface is small, and backfire may occur in the low flow velocity region. Decreases.
Furthermore, in the premixed air swirler cylinder, a low flow velocity region exists in the center of the swirling flow of the premixed gas. However, the low flow velocity region can be eliminated in the second premixed region. It is also possible to prevent backfire from occurring.
In addition, since the region between the adjacent premix burner holes is filled with padding, it is not necessary to provide air holes in this region, and the amount of substrate air can be reduced accordingly. Therefore, the air corresponding to that amount can be used for premixing, and the fuel concentration of the premixed gas in the entire premixed burner can be reduced.
In addition, the outer padding and the inner padding constituting the second premixing zone become thinner toward the tip on the downstream side, so there are few low flow velocity regions near the surface, and the low flow velocity region is backfired. The possibility of occurrence is reduced.

Further, according to the gas turbine combustor of the fifth invention, the pilot burner and the premixed air swirler vane are provided in the premixed air swirler cylinder, and are arranged so as to surround the pilot burner. A plurality of premixing burners, a pilot burner hole, and a plurality of premixing burner holes disposed so as to surround the pilot burner hole are provided, and the pilot burner and a substrate that supports the premixing burner are provided. The premixed air swirler cylinder is provided in the combustor inner cylinder, and the premixed air swirler cylinder is a primary premixing area, and is formed from an air flow path formed between the premixed air swirler cylinder and the flow path cylinder. In the gas turbine combustor configured to flow an air film, an upstream end face fills an outer region between adjacent premix burner holes on a downstream face of the substrate. An upstream end surface fills an inner region between the outer padding that becomes thinner toward the downstream end and the adjacent premix burner hole on the downstream surface of the substrate, and the downstream end An inner padding that extends to an end face and whose downstream end face is a back step face of a flame holder, and the space between the outer padding and the inner padding is the premix Since the second premixing region is an annular second premixing region that communicates with the premixed air swirler tube through the burner hole and is continuous over the entire circumferential direction, The air-fuel mixture and the air film are well mixed. For this reason, premixed combustion is performed in a state where the fuel concentration of the premixed gas is uniform.
In addition, since the circumference of the secondary premixing zone is shorter than the circumference of the conventional extension pipe, the low flow velocity region near the inner peripheral surface is small, and backfire may occur in the low flow velocity region. Decreases.
Furthermore, in the premixed air swirler cylinder, a low flow velocity region exists in the center of the swirling flow of the premixed gas. However, the low flow velocity region can be eliminated in the second premixed region. It is also possible to prevent backfire from occurring.
In addition, since the region between the adjacent premix burner holes is filled with padding, it is not necessary to provide air holes in this region, and the amount of substrate air can be reduced accordingly. Therefore, the air corresponding to that amount can be used for premixing, and the fuel concentration of the premixed gas in the entire premixed burner can be reduced.
Further, since the outer padding constituting the second premixing region becomes thinner toward the downstream end, there is little low flow velocity region near the surface, and there is a possibility that backfire occurs in the low flow velocity region. Decreases.
Further, since the inner padding constituting the second premixing region has a shape extending from the downstream end face, the premixed gas flows straight, which is advantageous for backfire resistance (backfire). Is less likely to occur). In addition, the downstream end face can be effectively used as the back step face of the flame holder.

According to the gas turbine combustor of the sixth invention, a pilot burner, a plurality of premix burners having a premix nozzle and a premix air swirler vane and disposed so as to surround the pilot burner, In the gas turbine combustor provided in the combustor inner cylinder, a premixing burner inner cylinder is disposed inside the combustor inner cylinder, and between the combustor inner cylinder and the premixing burner inner cylinder. The annular annular channel that is a space is continuous over the entire circumferential direction, the downstream portion of the annular channel is a premixing region, the premixing burner is disposed in the annular channel, Since the pilot burner is arranged inside the inner cylinder of the premix burner, fuel and air are well mixed in the premix region. For this reason, premixed combustion is performed in a state where the fuel concentration of the premixed gas is uniform.
Further, since the substrate air is unnecessary and the premixed combustion can be performed by effectively using the air for the premixing with the fuel, the average flame temperature can be lowered.

  According to the gas turbine combustor of the seventh invention, in the gas turbine combustor of the sixth invention, the width of the premixing region is narrowed toward the downstream side. Since the flow velocity of the premixed gas increases toward the outlet of the fuel, the boundary layer can be made thinner, or the fuel concentration in the vicinity of the wall surface can be made thinner, so that the occurrence of flashback in the vicinity of the surface is prevented. be able to.

According to the gas turbine combustor of the eighth invention, the pilot burner and the premixed air swirler cylinder are provided with the premix nozzle and the premixed air swirler vane, and a plurality of the burners are disposed so as to surround the pilot burner. A premix burner, a pilot burner hole, and a plurality of premix burner holes arranged so as to surround the pilot burner hole are provided, and the pilot burner and a substrate that supports the premix burner are provided. In the gas turbine combustor in which the premixed air swirler cylinder is the first premixed region, the surface between the adjacent premixed burner holes is buried in the downstream surface of the substrate. The cross-sectional shape of the stagnation-excluding structure having a structure is narrower in width toward the downstream side, and the outer gusset is located outside the stagnation-excluding structure. And a space between the outer guide ring and the inner guide ring through the premix burner hole. Since it is an annular second premixing region that communicates with the mixed air swirler cylinder and is continuous over the entire circumferential direction, it is preliminarily positioned in the vicinity of the region between adjacent premixing burner holes of the substrate. It is possible to prevent (eliminate) the flow of the air-fuel mixture by the stagnation-excluding structure.
Further, in the second premixing region, the premixed gas that has flowed out of the first premixing region (inside the premixed air swirler cylinder) and into the second premixing region flows around the second premixing region. Mix well throughout direction.

  According to the gas turbine combustor of the ninth invention, in the gas turbine combustor of the eighth invention, an air film is caused to flow from an air flow path formed between the premixed air swirler cylinder and the flow path cylinder. In the second premixing region, the premixed gas flowing out from the first premixing region (inside the premixed air swirler cylinder) and flowing into the second premixing region is the second premixing region. The mixture is well mixed over the entire circumferential direction of the next premixing region, and the premixed gas and the air film flowing out of the air flow path and flowing into the second premixing region are also well mixed.

  According to the gas turbine combustor of the tenth invention, in the gas turbine combustor of the eighth or ninth invention, since the cross-sectional shape of the stagnation-excluding structure is an isosceles triangle, The stagnation-exclusion structure can prevent (eliminate) the flow of the premixed gas in the vicinity of the region between adjacent premixing burner holes, and the stagnation-exclusion structure has an isosceles triangular cross section. Therefore, since the downstream end is sharp, there is no possibility that stagnation of the flow of the premixed gas occurs at the downstream end.

  According to the gas turbine combustor of the eleventh aspect of the invention, in the gas turbine combustor of the eighth or ninth aspect, the cross-sectional shape of the stagnation-excluding structure is a bell shape, so that the cross-sectional shape is two. The flow direction of the premixed gas changes smoothly compared to the case of an equilateral triangle. For this reason, compared with the case where a cross-sectional shape is an isosceles triangle shape, the flow rate fall degree of a premixed gas is reduced.

  According to the gas turbine combustor of the twelfth aspect of the present invention, in the gas turbine combustor of the eighth or ninth aspect of the invention, the upstream end face of the stagnation eliminating structure is compared with the central portion in the radial direction of the stagnation eliminating structure. The outer portion and the inner portion are wider in width, and the cross-sectional shape of the stagnation-excluding structure is a bell shape in the central portion, and an isosceles triangle shape in the outer portion and the inner portion. Because of the feature, in the central portion of the stagnation-excluding structure where the end face (bottom face) on the upstream side is narrow, the degree of decrease in the flow velocity of the premixed gas can be reduced, and the end face (bottom face) on the upstream side can be reduced. In the outer portion and the inner portion of the stagnation-excluding structure having a wide width, it is possible to prevent the premixed gas from being separated from the side surface of the downstream end portion at the downstream end portion of the stagnation-excluding structure.

  According to the gas turbine combustor of the thirteenth aspect, in the gas turbine combustor of the eighth or ninth aspect, the cross-sectional shape of the stagnation eliminating structure has a bell-shaped portion on the upstream side and isosceles on the downstream side. Since it has a triangular shape, the flow direction of the premixed gas changes smoothly in the bell shape and isosceles triangular shape of the stagnation-excluding structure. In addition, it is possible to prevent the premixed gas from being separated from the side surface of the downstream end portion at the downstream end portion of the stagnation-excluding structure.

  According to the gas turbine combustor of the fourteenth invention, in the gas turbine combustor of the eighth or ninth invention, the upstream end surface of the stagnation-excluding structure is compared with the central portion in the radial direction of the stagnation-excluding structure. The outer portion and the inner portion are wider, and the cross-sectional shape of the stagnation-excluding structure is such that the central portion has a bell-shaped portion on the upstream side and an isosceles triangular portion on the downstream side. Yes, because the outer portion and the inner portion are bell-shaped, so that the bell-shaped portion and the isosceles triangle-shaped portion are also provided on the outer and inner portions of the wide stagnation-excluding structure. As compared with the above, the length of the flow direction of the premixed gas in the outer part and the inner part can be shortened. For this reason, it is possible to easily dispose the stagnation-excluding structure on the upstream side of the downstream ends of the outer and inner guide rings.

  According to the gas turbine combustor of the fifteenth aspect of the invention, in the gas turbine combustor of any one of the eighth to fourteenth aspects of the invention, the stagnation eliminating structure has a hollow hole, and the downstream side of the hollow hole is On the other hand, the upstream side of the hollow hole communicates with an air hole provided in the substrate, or the stagnation-excluding structure is a porous part and a coating covering the surface of the porous part And the hole of the porous part communicates with the air hole provided in the substrate, so when the downstream end of the stagnation-excluding structure is lost due to burnout or the like, Air is ejected from the hollow hole or the hole of the porous part opened by the defect. For this reason, it can prevent that the flow of the premixed gas stagnates in the said defect | deletion part and a backfire phenomenon is induced.

It is a longitudinal cross-sectional view (the EE arrow directional cross-sectional view of FIG. 2) of the gas turbine combustor of the premixed combustion system which concerns on Embodiment 1 of this invention. 1 is a cross-sectional view (a cross-sectional view taken along the line D-D in FIG. 1) of a premixed combustion type gas turbine combustor according to Embodiment 1 of the present invention. It is a figure which extracts and shows the board | substrate in the gas turbine combustor of the premixed combustion system which concerns on Embodiment 1 of this invention. It is a longitudinal cross-sectional view (GG line arrow sectional drawing of FIG. 5) of the gas turbine combustor of the premixed combustion system which concerns on Embodiment 2 of this invention. It is a cross-sectional view (cross-sectional view taken along line FF in FIG. 4) of the gas turbine combustor of the premixed combustion method according to the second embodiment of the present invention. It is a longitudinal cross-sectional view (II-I arrow directional cross-sectional view of FIG. 7) of the gas turbine combustor of the premix combustion system which concerns on Example 3 of Embodiment of this invention. It is a cross-sectional view (HH arrow directional cross-sectional view of FIG. 6) of the gas turbine combustor of the premixed combustion system which concerns on Example 3 of Embodiment of this invention. It is a figure corresponding to FIG. 6, Comprising: It is explanatory drawing which shows the state which deleted the outer padding and the inner padding. It is a figure which extracts and shows the board | substrate in the gas turbine combustor of the premixed combustion system which concerns on Example 3 of Embodiment of this invention. It is a figure which extracts and shows the filling in the gas turbine combustor of the premixed combustion system which concerns on Example 3 of this invention, Comprising: (a) is a perspective view of an outer filling, (b) is an inner filling. It is a perspective view. It is a longitudinal cross-sectional view (KK sectional view taken on the line of KK of FIG. 12) of the premixed combustion type gas turbine combustor according to Embodiment 4 of the present invention. It is a cross-sectional view (the JJ arrow directional cross-sectional view of FIG. 11) of the gas turbine combustor of the premixed combustion system which concerns on Example 4 of this invention. It is a figure which extracts and shows the filling in the gas turbine combustor of the premixed combustion system which concerns on Example 3 of this invention, Comprising: (a) is a perspective view of an inner filling, (b) is an inner filling. It is a perspective view which shows another example. It is a longitudinal cross-sectional view (the MM arrow directional cross-sectional view of FIG. 15) of the gas turbine combustor of the premixed combustion system which concerns on Example 5 of this invention. It is a cross-sectional view (L-L arrow sectional drawing of FIG. 14) of the gas turbine combustor of the premixed combustion system which concerns on Example 5 of this invention. It is a perspective view which extracts and shows the combustor inner cylinder and the premix burner inner cylinder in the gas turbine combustor of the premix combustion system which concerns on Example 5 of this invention. FIG. 18 is a longitudinal sectional view of a premixed combustion type gas turbine combustor according to Embodiment 6 of the present invention (a sectional view taken along line OO in FIG. 18). FIG. 18 is a cross-sectional view of a premixed combustion type gas turbine combustor according to Embodiment 6 of the present invention (a cross-sectional view taken along line NN in FIG. 17). In the cross-sectional view shown in FIG. 18, it is a figure which shows the state which abbreviate | omitted illustration of the outer side guide ring, an inner side guide ring, a pilot cone, and a flame holder. It is a figure which extracts and shows the board | substrate in the gas turbine combustor of the premix combustion system which concerns on Example 6 of this invention. (A) is a side view of the stagnation-excluding structure (enlarged view of the stagnation-excluding structure shown in FIG. 17), and (b) is a front view of the stagnation-excluding structure (enlarged view of the stagnation-excluding structure shown in FIG. 18). (C) is a perspective view of the stagnation-excluding structure, (d) is a cross-sectional view taken along line A1-A1 in (a) and (b), and (e) is B1-B1 in (a) and (b). A cross-sectional view taken along line arrow, (f) is a cross-sectional view taken along line C1-C1 of (a) and (b). (A) is a diagram showing the flow of premixed gas when no stagnation exclusion structure is provided on the substrate, (b) is a two-dimensional axial flow contour diagram of the premixed gas when no stagnation exclusion structure is provided on the substrate, (C) is a diagram showing the flow of the premixed gas when the stagnation exclusion structure is provided on the substrate, and (d) is a two-dimensional axial flow contour diagram of the premixed gas when the stagnation removal structure is provided on the substrate. is there. (A) is a side view of the stagnation eliminating structure in the premixed combustion type gas turbine combustor according to Embodiment 7 of the present invention, (b) is a front view of the stagnation eliminating structure, and (c) is ( (a) and (b) A2-A2 arrow sectional view, (d) is a B2-B2 arrow sectional view (a) and (b), (e) is C2 of (a) and (b) FIG. (A) is a figure which shows the flow of premixed gas when the cross-sectional shape of a stagnation exclusion structure is an isosceles triangle shape, (b) is the premixed gas when the cross-sectional shape of a stagnation exclusion structure is a bell shape. It is a figure which shows the flow of. (A) is a side view of the stagnation eliminating structure in the premixed combustion type gas turbine combustor according to Embodiment 8 of the present invention, (b) is a front view of the stagnation eliminating structure, and (c) is ( (a) and (b) A3-A3 line arrow sectional drawing, (d) is the B3-B3 line arrow sectional view of (a) and (b), (e) is C3 of (a) and (b). It is -C3 sectional view taken on the line. (A) is a diagram showing the flow of the premixed gas when the cross-sectional shape of the stagnation-excluding structure is a bell shape and the base is wide, and (b) is the cross-sectional shape of the stagnation-excluding structure is a bell shape. It is a figure which shows the flow of the premixed gas when the width | variety of a base is narrow. (A) is a side view of the stagnation-removing structure in the premixed combustion type gas turbine combustor according to Embodiment 9 of the present invention, (b) is a front view of the stagnation-removing structure, and (c) is ( (a) and (b) A4-A4 arrow sectional view, (d) is a B4-B4 arrow sectional view (a) and (b), (e) is C4 of (a) and (b). It is -C4 sectional view taken on the line. (A) is a side view of the stagnation-removing structure in the premixed combustion type gas turbine combustor according to Embodiment 10 of the present invention, (b) is a front view of the stagnation-removing structure, and (c) is ( A) and (b) A5-A5 arrow sectional drawing, (d) is the B5-B5 arrow sectional view of (a) and (b), (e) is C5 of (a) and (b). It is -C5 sectional view taken on the line. (A) is a side view of the stagnation eliminating structure in the gas turbine combustor of the premixed combustion system according to Embodiment 11 of the present invention, (b) is a front view of the stagnation eliminating structure, and (c) is ( (a) and (b) A6-A6 line arrow sectional drawing, (d) is the B6-B6 line arrow sectional view of (a) and (b), (e) is C6 of (a) and (b). -C6 arrow sectional drawing, (f) is sectional drawing which shows the other structural example of a stagnation exclusion structure, (g) is sectional drawing which shows the other structural example of a stagnation exclusion structure. It is a longitudinal cross-sectional view (BB sectional view taken on the line of FIG. 31) of a conventional premixed combustion type gas turbine combustor. It is a cross-sectional view (AA arrow directional cross-sectional view of FIG. 30) of the conventional gas turbine combustor of a premixed combustion system.

  Embodiments of the present invention will be described below in detail with reference to the drawings.

<Embodiment 1>
A premixed combustion type gas turbine combustor according to Embodiment 1 of the present invention will be described with reference to FIGS. In FIG. 1, the left side is the upstream side, and the right side is the downstream side.

  As shown in FIGS. 1 to 3, the gas turbine combustor 31 of the premixed combustion method of the first embodiment includes a combustor inner cylinder 32 provided inside a combustor outer cylinder (not shown), And a combustor tail cylinder 33.

The combustor tail cylinder 33 has a combustion chamber 34 inside, and an upstream end is connected to a downstream end of the combustor inner cylinder 32, while a downstream end is provided with a rotor and the like. Part (not shown).
The combustor inner cylinder 32 is cylindrical. In the combustor inner cylinder 32, a plurality (eight in the illustrated example) of premixed burners (main burners) 35 for performing premixed combustion, a pilot burner 36 for performing diffusion combustion, and these burners 35, 36 are provided. A supporting substrate 37 is provided.
In the first embodiment, an inner guide ring 38 and an outer guide ring 39 are also provided inside the combustor inner cylinder 32.

  The substrate 37 has a disk shape, and is supported by the combustor inner cylinder 32 by fixing the outer peripheral portion to the inner peripheral surface of the combustor inner cylinder 32 by welding. A large number of air holes 37a are formed in the substrate 37, and a pilot burner hole 37b and a plurality (eight in the illustrated example) of premix burner holes 37c are also provided. The pilot burner holes 37b are opened at the center of the substrate 37, and the plurality of premix burner holes 37c are opened at equal intervals in the circumferential direction of the substrate 37 to surround the pilot burner holes 37b.

  The pilot burner 36 is disposed in the center of the combustor inner cylinder 32 (coaxially with the combustor inner cylinder 32), and includes a pilot air swirler cylinder 41, pilot nozzles 42, and a plurality (six in the illustrated example). A pilot air swirler vane (pilot air swirler) 45 and a pilot cone 44 are provided.

  The pilot air swirler cylinder 41 has a cylindrical shape, is inserted into the pilot burner hole 37 b of the substrate 37, is fixed to the substrate 37 by welding, and is supported. The pilot nozzle 42 is disposed at a central portion (coaxial with the pilot air swirler cylinder 41) in the pilot air swirler cylinder 41. Although not shown, the upstream end portion of the pilot nozzle 42 is fixed and supported by a support portion provided at the upstream end portion of the combustor inner cylinder 32. A fuel injection hole 42 a is provided at the downstream end of the pilot nozzle 42. The pilot air swirler vanes 45 are interposed between the inner peripheral surface of the pilot air swirler cylinder 41 and the outer peripheral surface of the pilot nozzle 42, and are arranged at equal intervals in the circumferential direction of the pilot nozzle 42.

  The pilot cone 44 is a truncated cone-shaped tube that spreads radially outward from the upstream end to the downstream end, and the upstream end is connected to the downstream end of the pilot air swirler tube 41. Connected by welding. The flame holder 43 is an annular plate, and an inner peripheral portion thereof is connected to a downstream end portion of the pilot cone 44 by welding, and a downstream surface is a back step surface 43a.

  The plurality of premix burners 35 are disposed at equal intervals in the circumferential direction of the combustor inner cylinder 32 and surround the pilot burner 36. Each of these premix burners 35 includes a premix air swirler cylinder 51, a premix nozzle 52, a plurality (six in the illustrated example) of premix air swirler vanes (premix air swirl vanes) 53, and an extension pipe 54. And.

  The premixed air swirler cylinder 51 is cylindrical, the upstream end is fixed to the combustor inner cylinder 32 by a bolt 55, and the downstream end is located in the premix burner hole 37c of the substrate 37. . The premixing nozzle 52 is disposed in a central portion (on the same axis as the premixed air swirler cylinder 51) in the premixed air swirler cylinder 51. Although not shown, the upstream end portion of the premixing nozzle 52 is fixed to and supported by the support portion. The premixed air swirler vanes 53 are fixed to the outer peripheral surface of the premixing nozzle 52 by welding, and are arranged at equal intervals in the circumferential direction of the premixing nozzle 52. The premixed air swirler vane 53 is provided with a fuel injection hole 53a. However, the present invention is not limited to this, and a fuel injection hole may be provided in the premixing nozzle 52.

  In the first embodiment, the extension pipe 54 is shorter than the conventional extension pipe 18 (FIG. 30) and is extended longer to the downstream side than the extension pipe 54, and the extension pipe An outer guide ring 39 extending longer than the downstream side 54 is provided. The downstream end of the extension pipe 54 is located upstream of the back step surface 43 a of the flame holder 43.

  More specifically, the extension pipe 54 communicates with the premixed air swirler cylinder 51 via the premixed burner hole 37c, and the upstream side is inserted into the premixed burner hole 37c of the substrate 37 and fixed to the substrate 37 by welding. The downstream end 54 b extends to the downstream side of the substrate 37. The extension tube 54 has a circular cross-sectional shape at the upstream end 54a, is continuously deformed toward the downstream side, and has a rectangular shape at the downstream end 54b.

  Conventionally, the downstream end of the extension pipe 18 is at the same position as the back step surface 12a of the flame holder 12 (FIG. 30), whereas in the first embodiment, the downstream end of the extension pipe 54 is the flame holder 43. The back step surface 43a is located on the upstream side.

  Further, since the inner diameter of the cylindrical upstream end 54 a of the extension pipe 54 is larger than the outer diameter of the downstream end 51 a of the cylindrical premixed air swirler cylinder 51, the upstream end 54 a of the extension pipe 54. An annular gap is formed between the inner circumferential surface of the premixed air swirler cylinder 51 and the outer circumferential surface of the downstream end 51a of the premixed air swirler cylinder 51, and this gap forms an air channel 56 for generating an air film. It has become.

  The inner guide ring 38 is located on the radially inner side of the combustor inner cylinder 32 with respect to the extension pipe 54, and the upstream end is fixed to the substrate 31 by welding and supported. Further, the inner guide ring 38 is a truncated cone-shaped tube that spreads outward in the radial direction from the upstream end 38a toward the downstream end 38b. Further, the inner guide ring 38 has a downstream end portion 38 b extending more downstream than the downstream end of the extension pipe 54, and the downstream end is at the same position as the back step surface 43 a of the flame holder 43.

  The outer guide ring 39 has a cylindrical shape, is positioned on the outer side in the radial direction of the combustor inner cylinder 32 with respect to the extension pipe 54, and the upstream end 39 a is fixed to the substrate 31 by welding and supported. . Further, the outer guide ring 39 has a downstream end portion 39 b extending more downstream than the downstream end of the extension pipe 54, and the downstream end is at the same position as the back step surface 43 a of the flame stabilizer 43.

  Therefore, while the inside of the premixed air swirler cylinder 51 and the extension pipe 54 are the primary premixing region, the downstream end 39b of the outer guide ring 39 and the downstream end of the inner guide ring 38 A space between the second premixing region 57 and the space 38b is formed. The second premixing region 57 communicates with the extension pipe 54 and is an annular space (annular) continuous over the entire circumferential direction of the combustor inner cylinder 32 (the circumferential direction of the guide rings 38 and 39). Mold flow path). In other words, the first premix region (in the premix air swirler cylinder 51 and the extension tube 54) is an individual premix region for each premix burner 35, whereas the second premix region 57 Is a premixing region common to all premixing burners 35. Further, the width of the second premixing region 57 (the width in the radial direction of the combustor inner cylinder 32) becomes narrower toward the downstream side.

  Next, the operation of the premixed combustion type gas turbine combustor 31 will be described.

  The air a compressed by the compressor (not shown) with respect to the gas turbine combustor 31 passes from the air flow path (not shown) between the combustor outer cylinder and the combustor inner cylinder 32 to the combustor inner cylinder. After flowing into the combustor inner cylinder 32 through an air hole (not shown) at the upstream end of 32, the inside of the pilot air swirler cylinder 41 of the pilot burner 36 and the premixed air swirler cylinder 51 of the premixing burner 35 are shown. The fuel f supplied from the fuel supply system (not shown) is supplied to the inside of the pilot nozzle 42 and the premixing nozzle 52. Is done.

  In the pilot burner 36, the air a supplied into the pilot air swirler cylinder 41 is swirled by the pilot air swirler vane 45 while being circulated in the pilot air swirler cylinder 41, and is injected into the pilot cone 44. The fuel f supplied into the nozzle 42 flows through the pilot nozzle 42 and is injected into the pilot cone 44 from the fuel injection hole 42 a of the pilot nozzle 42. Accordingly, the air a and the fuel f are mixed in the pilot cone 44, and the air-fuel mixture is ignited by an ignition device (not shown), whereby diffusion combustion is performed in the pilot cone 44 and in the combustion chamber 34 ( A diffusion flame is generated).

  In the premixing burner 35, the air a supplied into the premixed air swirler cylinder 51 is swirled by the premixed air swirler vane 53 while flowing in the premixed air swirler cylinder 51, while Is supplied to the premixing nozzle 52 and the premixed air swirler vane 53 from the fuel injection hole 53a of the premixed air swirler vane 53 or from the fuel injection hole of the premixing nozzle 52. It is injected into the swirler cylinder 51. Accordingly, the air a and the fuel f are premixed in the first premixing region (in the premixed air swirler cylinder 51 and the extension pipe 54), and this premixed gas flows into the second premixing region 57. To do.

  On the other hand, the air a supplied into the air flow path 56 circulates in the air flow path 56 to form a film, and this air film flows along the inner peripheral surface of the extension pipe 54, thereby Prevent flashback in the vicinity.

The air a supplied to the air holes 37a of the substrate 37 passes through the air holes 37a to become substrate air, and this substrate air is adjacent (hereinafter simply referred to as “adjacent”) in the circumferential direction of the pottery inner cylinder 32. It flows around the extension tube 54, such as the area between the extension tubes 54. For this reason, it is possible to prevent the high-temperature combustion gas generated in the combustion chamber 34 from being caught in the low flow velocity region or the reverse flow region near the substrate 37 by the substrate air.
By installing the extension pipe 54, the low flow velocity region and the reverse flow region of the substrate 37 are reduced. However, the low flow velocity region and the reverse flow region that cannot be completely removed by the installation of the extension tube 54 are obtained by flowing the substrate air. Since the fuel concentration can be made lower than or near the flammability limit, it is possible to prevent the presence of flames in the event of flashback.

  In the second premixing region 57, the premixed gas that has flowed out from the first premixing region (extension tube 54) and flowed into the second premixing region 57, and the first premixing region (extension tube). 54) and the air film flowing into the second premixing region 57 and the substrate air flowing in the region between the adjacent extension tubes 54 are well mixed.

More specifically, in the premix burner 35, the air a is swirled in the same direction by the premix air swirler vane 53. Therefore, the premixed gas swirled in the same direction (in the counterclockwise direction in the illustrated example) flows into the second premixed region 57 as indicated by an arrow P1 in FIG. In the second premixing region 57, the swirling flows of these premixed gas are combined to form a large swirling flow of the premixed gas over the entire circumference of the second premixing region 57. This large swirl flow is reverse swirl on the inner peripheral side and the outer peripheral side of the second premixing region 57. For this reason, in the second premixing region 57, the disturbance of the flow of the premixed gas, the air film and the substrate air is increased, and the mixing of the premixed gas, the air film and the substrate air is promoted.
Further, in the second premixing region 57, in the region (for example, the Q1 region in FIG. 2) between the adjacent premixing burners 35 (extension pipes 54), the swirl directions are opposite to each other. Since a shearing force is generated for the air film and the substrate air, the mixing of the premixed gas, the air film, and the substrate air is further promoted.

  Further, in the premixed air swirler cylinder 51 and the extension pipe 54, a low flow velocity region exists in the center of the swirling flow of the premixed gas, but the low flow velocity region can be eliminated in the second premixing region 57. For this reason, it is possible to prevent backfire from occurring in the low flow velocity region.

  Compared to the peripheral length of the conventional extension pipe 18, the second premixed region 57 has a peripheral length (that is, a length obtained by adding the peripheral length of the inner guide ring 38 and the peripheral length of the outer guide ring 39. Therefore, the possibility of backfire in the low flow velocity region is reduced.

  Further, the width of the secondary premixing region 57 is narrower on the downstream side than on the upstream side, and the premixed gas is accelerated toward the outlet of the secondary premixing region 57. The fuel concentration in the vicinity of the wall surface (inner peripheral surfaces of the inner and outer guide rings 38 and 39) can be reduced. For this reason, it is possible to prevent backfire from occurring in the vicinity of the wall surface.

  The premixed gas generated in the second premixed region 57 (the premixed gas generated by well mixing the premixed gas, the air film, and the substrate air) flows out from the second premixed region 57. And flows into the combustion chamber 34. In the combustion chamber 34, the diffusion flame generated by the pilot burner 36 is used as a fire type, whereby the premixed gas is ignited and premixed combustion is performed.

  In the flame holder 43, a reverse flow as indicated by an arrow R <b> 1 is generated on the back step surface 43 a with respect to a part of the premixed gas flowing out from the second premixing region 57 and a part of the mixed gas flowing out from the pilot cone 44 By causing deceleration, premixed combustion using the diffusion flame as a fire type can be reliably maintained.

As described above, according to the gas turbine combustor 31 of the first embodiment, the pilot burner 36, the premix nozzle 52 and the premix air swirler vane 53 are provided in the premix air swirler cylinder 51, and the pilot burner A plurality of premixing burners 35 disposed so as to surround the periphery of the pilot burner hole 37b, and a plurality of premixing burner holes 37c disposed so as to surround the periphery of the pilot burner hole 37b. A substrate 37 that supports the pilot burner 36 and the premixing burner 35, and an extension pipe 54 that communicates with the premixed air swirler cylinder 51 via the premixing burner hole 37c and extends to the downstream side of the substrate 37, are provided in the combustor. The premixed air swirler cylinder 51 and the extension pipe 54 are provided in the cylinder 32 as a first premixing area. The premixed air swirler cylinder 51 and the extension pipe 5 A configuration in which an air film is caused to flow from the air flow path 56 formed between the extension tube 54 to the inner peripheral surface of the extension tube 54 and a configuration in which the substrate air is caused to flow from an air hole 37a provided in the substrate 37 to a region between adjacent extension tubes In the gas turbine combustor 31, the outer guide ring 39 that is located outside the extension pipe 54 and has a downstream end portion 39 b extending downstream from the downstream end of the extension pipe 54, and the extension pipe 54 An inner guide ring 38 located on the inner side and extending downstream from the downstream end of the extension tube 54, and the inner end of the outer guide ring 39 and the inner end thereof. Since the space between the downstream end portion of the guide ring 38 is an annular second premixing region 57 that communicates with the extension pipe 54 and is continuous over the entire circumferential direction. Premixing in the secondary premixing region 57 When, the air film and the substrate air is well mixed. For this reason, premixed combustion is performed in a state where the fuel concentration of the premixed gas is uniform.
Further, since the peripheral length of the second premixing region 57 is shorter than the peripheral length of the conventional extension pipe 18, the low flow velocity region near the inner peripheral surface is small, and backfire occurs in the low flow velocity region. The possibility decreases.
Furthermore, in the premixed air swirler cylinder 51 and the extension pipe 54, a low flow velocity region exists at the center of the swirling flow of the premixed gas, but the low flow velocity region can be eliminated in the second premixing region 57. Therefore, it is possible to prevent backfire from occurring in the low flow velocity region.

  Further, according to the gas turbine combustor 31 of the first embodiment, since the width of the secondary premixing region 57 is narrowed toward the downstream side, the secondary Since the premixed gas is accelerated toward the outlet of the premixing region 57, the boundary layer can be made thinner, or the fuel concentration in the vicinity of the wall surface can be reduced, so that the occurrence of flashback in the vicinity of the wall surface is prevented. can do.

In the above description, the outer guide ring 39 is provided. However, the present invention is not necessarily limited to this. Instead of the outer guide ring 39, the downstream portion of the combustor inner cylinder 32 is used as the outer guide ring. You can also
When the downstream end side portion of the combustor inner cylinder 32 is used as an outer guide ring, the second premixing region 57 can be provided at low cost by effectively using the combustor inner cylinder 32.

<Embodiment 2>
A premixed combustion type gas turbine combustor according to Embodiment 2 of the present invention will be described with reference to FIGS. 4 and 5. 4 and 5, the same parts as those in the first embodiment (FIGS. 1 to 3) are denoted by the same reference numerals, and detailed description thereof is omitted.

  As shown in FIGS. 4 and 5, in the gas turbine combustor 61 of the second embodiment, the extension pipe 54 is extended to the downstream side longer than the case of the first embodiment. That is, the extension pipe 54 has the same length as the conventional extension pipe 18 (FIG. 30). On the other hand, in the gas turbine combustor 61 of the second embodiment, the extension pipe 54 is formed by extending the inner guide ring 38 and the outer guide ring 39 longer than those in the first embodiment. It extends longer to the downstream side.

  Therefore, as in the first embodiment, the space between the downstream end 39b of the outer guide ring 39 and the downstream end 38b of the inner guide ring 38 is the second premix region. 57. The second premixing region 57 also communicates with the extension pipe 54 and is an annular space (annular) continuous over the entire circumferential direction of the combustor inner cylinder 32 (the circumferential direction of the guide rings 38 and 39). Mold flow path).

  Further, the pilot cone 44 also extends to the downstream side longer than the pilot cone 44 of the first embodiment, and the flame holder 43 connected to the downstream end portion of the pilot cone 44 is replaced with the first embodiment. The first flame holder 43 is positioned on the downstream side. Accordingly, the downstream ends of the inner and outer guide rings 38 and 39 are located at the same position as the back step surface 43a of the flame stabilizer 43 as in the case of the first embodiment, and the downstream end of the extension pipe 54 Is positioned upstream of the back step surface 43 a of the flame holder 43.

  Other configurations of the gas turbine combustor 61 of the second embodiment are the same as those of the gas turbine combustor 31 of the first embodiment. The operation of the gas turbine combustor 61 is the same as that of the gas turbine combustor 31 of the first embodiment.

  Therefore, also in the gas turbine combustor 61 of the second embodiment, the same effects as the gas turbine combustor 31 of the first embodiment can be obtained.

  In the second embodiment, instead of the outer guide ring 39, the downstream portion of the combustor inner cylinder 32 may be used as the outer guide ring.

<Embodiment 3>
A premixed combustion type gas turbine combustor according to Embodiment 3 of the present invention will be described with reference to FIGS. 6 and 7, the same reference numerals are given to the same parts as those in the first embodiment (FIGS. 1 and 2), and the detailed description thereof is omitted.

As shown in FIGS. 6 to 10, in the gas turbine combustor 71 of the third embodiment, the extension pipe 54 and the guide ring 38 in the gas turbine combustor 31 of the first embodiment (FIGS. 1 and 2). , 39, an outer padding 72 and an inner padding 73, which are three-dimensional objects, are provided in order to fill the low flow velocity region and the reverse flow region of the substrate 37.
Further, the gas turbine combustor 71 of the third embodiment generates an air film instead of the upstream end 54a of the extension pipe 54 in the gas turbine combustor 31 of the first embodiment (FIG. 1). For this purpose, a flow path cylinder 74 is provided.

  The flow path cylinder 74 is inserted into the premixing burner hole 37 c of the substrate 37, fixed to the substrate 37 by welding, and supported, and protrudes upstream of the substrate 37. Since the inner diameter of the flow path cylinder 74 is larger than the outer diameter of the downstream end 51 a of the cylindrical premixed air swirler cylinder 51, the inner peripheral surface of the flow path cylinder 74 and the downstream of the premixed air swirler cylinder 51. An annular gap is formed between the outer peripheral surface of the side end 51a, and this gap serves as an air flow path 76 for generating an air film.

The outer padding 72 is a region (triangle) on the outer surface (that is, the outer side in the radial direction of the combustor inner cylinder 32) between the adjacent premix burner holes 37c (premix burner 35) on the downstream surface 37d of the substrate 37. (Zone) 37e is fixed by welding (FIGS. 8 and 9). That is, the outer padding 72 fills the outer region (triangular zone) 37e.
The inner padding 73 is welded to a region (triangular zone) 37f on the inner side (that is, the inner side in the radial direction) between the adjacent premix burner holes 37c (premix burner 35) on the downstream surface 37d of the substrate 37. (FIGS. 8 and 9). That is, the inner padding 72 fills the inner region (triangular zone) 37f.
The outer padding 72 and the inner padding 73 are spaced apart in the radial direction.

  The outer padding 72 has a triangular pyramid shape, and the upstream end surface 72b covers (fills) the outer region (triangular zone) 37e and becomes thinner toward the downstream end 72a.

More specifically, the upstream end surface 72b of the outer padding 72 has a side 72c curved along the circumferential direction of the combustor inner cylinder 32 and one of the premix burner holes 37c adjacent to each other. This is a triangular surface composed of a side 72d curved along the circumferential direction and a side 72e curved along the circumferential direction of the other premixing burner hole 37c among the adjacent premixing burner holes 37c.
The outer surface 72f of the outer padding 72 extends in the axial direction of the combustor inner cylinder 32, and both sides of the side 72c and the two outer corners 72g and 72h on the end surface 72b extend to the tip 72a. It is a triangular surface composed of 72i and side 72j.
One side surface 72k of the outer padding 72 is a triangular surface composed of a side 72d, a side 72i, and a side 72n extending from the inner corner 72m of the end surface 72b to the tip 72a. The side 72n is like a ridge line that is inclined outward in the radial direction of the combustor inner cylinder 32 in a curved state.
The other side surface 72o of the outer padding 72 is a triangular surface composed of a side 72e, a side 72j, and a side 72n.

  The inner padding 73 has a triangular pyramid shape, and the upstream end surface 73b covers (fills) the inner region (triangular zone) 37f and becomes thinner toward the downstream end 73a.

More specifically, the upstream end surface 73b of the inner padding 73 has a side 73c curved along the circumferential direction of the combustor inner cylinder 32 and one of the premix burner holes 37c adjacent to each other. This is a triangular surface composed of a side 73d curved along the circumferential direction and a side 73e curved along the circumferential direction of the other premixing burner hole 37c among the adjacent premixing burner holes 37c.
The inner surface 73f of the inner stuffing 73 extends in the axial direction of the combustor inner cylinder 32, and both sides extend from the side 73c and the two inner corners 73g and 73h of the end surface 73b to the tip 73a. It is a triangular surface composed of 73i and side 73j.
One side surface 73k of the inner padding 73 is a triangular surface composed of a side 73d, a side 73i, and a side 73n extending from the outer corner 72m of the end surface 73b to the tip 72a. The side 73n is curved and is inclined inward in the radial direction of the combustor inner cylinder 32 so as to form a ridgeline.
The other side surface 73o of the inner padding 73 is a triangular surface composed of a side 73e, a side 73j, and a side 73n.

  In Embodiment 3, the inside of the premixed air swirler cylinder 51 is the first premixing area, while the space between the outer padding 72 and the inner padding 73 is the second premixing area. It is a mixed region 75. The second premixing region 75 is an annular space that communicates with the premixed air swirler cylinder 51 and is continuous over the entire circumferential direction of the combustor inner cylinder 32. In other words, the first premixing region (in the premixed air swirler cylinder 51) is an individual premixing region for each premixing burner 35, whereas the second premixing region 75 is the entire premixing region. This is a premixing region common to the burner 35.

  Further, since the regions 37e and 37f between the adjacent premix burner holes 37c are filled with the fillings 72 and 73, the air holes 37a are not provided in the regions 37e and 37f. The air holes 37 a are provided only on the outer peripheral side and the inner peripheral side of the substrate 37.

  Other configurations of the gas turbine combustor 71 of the third embodiment are the same as those of the gas turbine combustor 31 of the first embodiment.

  Next, the operation of this premixed combustion type gas turbine combustor 71 will be described.

  The air a compressed by the compressor (not shown) with respect to the gas turbine combustor 71 is transferred from the air flow path (not shown) between the combustor outer cylinder and the combustor inner cylinder 32 to the combustor inner cylinder. After flowing into the combustor inner cylinder 32 through an air hole (not shown) at the upstream end of 32, the inside of the pilot air swirler cylinder 41 of the pilot burner 36 and the premixed air swirler cylinder 51 of the premixing burner 35 are shown. The fuel f supplied to the inside, the air flow path 76, and the air hole 37a of the substrate 37 and sent from the fuel supply system (not shown) is supplied to the pilot nozzle 42 and the premixing nozzle 52. Is done.

  In the pilot burner 36, the air a supplied into the pilot air swirler cylinder 41 is swirled by the pilot air swirler vane 45 while being circulated in the pilot air swirler cylinder 41, and is injected into the pilot cone 44. The fuel f supplied into the nozzle 42 flows through the pilot nozzle 42 and is injected into the pilot cone 44 from the fuel injection hole 42 a of the pilot nozzle 42. Accordingly, the air a and the fuel f are mixed in the pilot cone 44, and the air-fuel mixture is ignited by an ignition device (not shown), whereby diffusion combustion is performed in the pilot cone 44 and in the combustion chamber 34 ( A diffusion flame is generated).

  In the premixing burner 35, the air a supplied into the premixed air swirler cylinder 51 is swirled by the premixed air swirler vane 53 while flowing in the premixed air swirler cylinder 51, while Is supplied to the premixing nozzle 52 and the premixed air swirler vane 53 from the fuel injection hole 53a of the premixed air swirler vane 53 or from the fuel injection hole of the premixing nozzle 52. It is injected into the swirler cylinder 51. Accordingly, the air a and the fuel f are premixed in the first premixing region (in the premixed air swirler cylinder 51), and this premixed gas flows into the second premixing region 75.

On the other hand, the air a supplied into the air flow path 76 circulates in the air flow path 56 to form a film, and this air film is formed on the surface (side surfaces 72k, 72o) of the outer padding 72 and the inner padding 73. By flowing along the surface (side surfaces 73k, 73o), backfire can be prevented in the vicinity of the surface.
The air a supplied to the air holes 37a of the substrate 37 passes through the air holes 37a and becomes substrate air, and flows to the outer peripheral side and the inner peripheral side of the substrate 37. For this reason, it is possible to prevent the high-temperature combustion gas generated in the combustion chamber 34 from being caught in the low flow velocity region or the reverse flow region near the substrate 37 by the substrate air.

  In the second premixing region 75, the premixed gas that has flowed out from the first premixing region (premixed air swirler cylinder 51) and into the second premixing region 75, and out of the air flow path 76. Then, the air film that has flowed into the second premixing region 75 is well mixed.

More specifically, in the premix burner 35, the air a is swirled in the same direction by the premix air swirler vane 53. Therefore, the premixed gas swirled in the same direction (in the counterclockwise direction in the illustrated example) flows into the second premixed region 75 as indicated by an arrow P2 in FIG. In the second premix region 75, the swirling flows of these premixed gas are combined to form a large swirl flow of the premixed gas over the entire circumference of the second premixed region 75. This large swirl flow is reverse swirl on the inner peripheral side and the outer peripheral side of the second premixing region 75. For this reason, in the 2nd premix area 75, disorder of the flow of premixed gas and an air film becomes large, and mixing of premixed gas and an air film is promoted.
Further, in the second premixing region 75, in the region between adjacent premixing burners 35 (for example, the Q2 region in FIG. 7), the swirl directions are opposite to each other, and the premixed air and the air film Since shearing force is generated, mixing of the premixed gas and the air film is further promoted.

  Further, in the premixed air swirler cylinder 51, a low flow velocity region exists at the center of the swirling flow of the premixed gas, but the low flow velocity region can be eliminated in the second premixed region 75. For this reason, it is possible to prevent backfire from occurring in the low flow velocity region.

  Further, since the outer padding 72 and the inner padding 73 constituting the second premixing region 75 become thinner toward the downstream ends 72a, 73a, there are few low flow velocity regions near the surface, The possibility of backfire in the low flow rate range is reduced.

  The premixed gas generated in the second premixed region 75 (the premixed gas generated by well mixing the premixed gas and the air film) flows out of the second premixed region 75 and burns. It flows into the chamber 34. In the combustion chamber 34, the diffusion flame generated by the pilot burner 36 is used as a fire type, whereby the premixed gas is ignited and premixed combustion is performed.

  In the flame holder 43, a backflow as indicated by an arrow R <b> 2 is generated on the back step surface 43 a with respect to a part of the premixed gas flowing out from the second premixed region 75 and a part of the mixed gas flowing out from the pilot cone 44. By causing deceleration, premixed combustion using the diffusion flame as a fire type can be reliably maintained.

As described above, according to the gas turbine combustor 71 of the third embodiment, the pilot burner 36, the premixing nozzle 52 and the premixed air swirler vane 53 are provided in the premixed air swirler cylinder 51, and the pilot burner A plurality of premixing burners 35 disposed so as to surround the periphery of the pilot burner hole 37b, and a plurality of premixing burner holes 37c disposed so as to surround the periphery of the pilot burner hole 37b. A pilot burner 36 and a substrate 37 that supports the premixing burner 35 are provided in the combustor inner cylinder 32, and the premixed air swirler cylinder 51 is a primary premixing region, and the premixed air swirler In the gas turbine combustor 71 having a configuration in which an air film flows from an air flow path 76 formed between the cylinder 51 and the flow path cylinder 74, downstream of the substrate 37. An outer padding 72 which fills an outer region 37e between adjacent premix burner holes 37c on the surface 37d of the surface 37d and becomes narrower toward the tip 72a on the downstream side; An inner padding 73 that fills an inner region 37f between adjacent premixing burner holes 37c on the side surface 37d and is narrowed toward the downstream end 73a. A space between the outer padding 72 and the inner padding 73 communicates with the premixed air swirler cylinder 51 through the premixing burner hole 37c and is continuous over the entire circumferential direction. Since it is the premixing region 75, the premixed gas and the air film are well mixed in the second premixing region 75. For this reason, premixed combustion is performed in a state where the fuel concentration of the premixed gas is uniform.
Further, since the peripheral length of the secondary premixing region 75 is shorter than the peripheral length of the conventional extension pipe 18, the low flow velocity region near the inner peripheral surface is small, and backfire occurs in the low flow velocity region. The possibility decreases.
Furthermore, in the premixed air swirler cylinder 51, a low flow velocity region exists at the center of the swirling flow of the premixed gas. However, since the low flow velocity region can be eliminated in the second premixed region 75, the low flow velocity region is eliminated. It is also possible to prevent backfire from occurring in the flow velocity region.
Further, since the regions 37e and 37f between the adjacent premix burner holes 37c are filled with the fillings 72 and 73, it is not necessary to provide the air holes 37a in this region, and the amount of the substrate air is reduced correspondingly. be able to. Therefore, the air corresponding to that amount can be used for premixing, and the fuel concentration of the premixed gas in the entire premixed burner 35 can be reduced.
Further, since the outer padding 72 and the inner padding 73 constituting the second premixing region 75 become thinner toward the downstream ends 72a, 73a, there are few low flow velocity regions near the surface, The possibility of backfire in the low flow rate range is reduced.

<Embodiment 4>
A premixed combustion type gas turbine combustor according to Embodiment 4 of the present invention will be described with reference to FIGS. 11 and 12, the same parts as those in the first embodiment (FIGS. 1 and 2) and the third embodiment (FIGS. 6 to 10) are denoted by the same reference numerals and overlapped. Detailed description is omitted.

  As shown in FIGS. 11 to 13, in the gas turbine combustor 81 of the fourth embodiment, instead of the inner padding 73 in the gas turbine combustor 71 of the third embodiment (FIGS. 6 to 10). And an inner padding 82 that is a three-dimensional object.

The inner padding 82 is fixed to the aforementioned inner region (triangular zone) 37f (FIGS. 8 and 9) by welding on the downstream surface 37d of the substrate 37. That is, the inner padding 82 fills the inner region (triangular zone) 37f.
The outer padding 72 and the inner padding 82 are separated from each other in the radial direction of the combustor inner cylinder 32.

  The inner padding 82 has a triangular prism shape, and the upstream end surface 82b covers (fills) the inner region (triangular zone) 37f and extends to the downstream end surface 82a. The downstream end surface 82a serves as a back step surface and functions as a flame holder.

More specifically, the upstream end face 82b of the inner padding 82 has a side 82c curved along the circumferential direction of the combustor inner cylinder 32 and one premix burner hole 37c of the adjacent premix burner holes 37c. This is a triangular surface composed of a side 82d curved along the circumferential direction and a side 82e curved along the circumferential direction of the other premixing burner hole 37c among the adjacent premixing burner holes 37c.
An end face 82a on the downstream side of the inner padding 82 has the same shape as the end face 82b on the upstream side, of the side 82p curved along the circumferential direction of the combustor inner cylinder 32, and between the adjacent premix burner holes 37c. A side 82q curved along the circumferential direction of one premixing burner hole 37c and a side 82r curved along the circumferential direction of the other premixing burner hole 37c among the adjacent premixing burner holes 37c. It is a triangular surface.
The inner surface 82f of the inner stuffing 82 extends in the axial direction of the combustor inner cylinder 32, and is provided on both sides of the side 82c and the two inner corners 82g and 82h on the end surface 82b. It is a quadrangular surface composed of sides 82i and 82j and side 82p.
One side surface 82k of the inner padding 82 extends in the axial direction, and includes a side 82d, a side 82i, a side 82n extending in the axial direction from an outer corner 82m of the end surface 823b, and a side 82q. A rectangular surface.
The other side surface 82o of the inner padding 82 extends in the axial direction, and is a quadrangular surface composed of a side 82e, a side 82j, a side 823n, and a side 81r.

  The inner padding 82 is not limited to the shape as described above (FIG. 13A), and may be a shape as shown in FIG. 13B. In FIG. 13B, the height of the downstream end surface 81a is lower than that of the upstream end surface 82b, and the side 82n is inclined inwardly toward the downstream side. Also in this case, the downstream end surface 82a serves as a back step surface and functions as a flame holder.

  In Embodiment 4, the inside of the premixed air swirler cylinder 51 is the first premixing area, while the space between the outer padding 72 and the inner padding 82 is the second premixing area. A mixed region 83 is formed. The second premixing region 83 is an annular space that communicates with the premixed air swirler cylinder 51 and is continuous over the entire circumferential direction of the combustor inner cylinder 32. In other words, the first premixing region (in the premixed air swirler cylinder 51) is an individual premixing region for each premixing burner 35, whereas the second premixing region 83 has all premixing regions. This is a premixing region common to the burner 35.

  Further, since the regions 37e and 37f between the adjacent premix burner holes 37c are filled with the fillings 72 and 82, the air holes 37a are not provided in the regions 37e and 37f. The air holes 37 a are provided only on the outer peripheral side and the inner peripheral side of the substrate 37.

  Other configurations of the gas turbine combustor 81 of the fourth embodiment are the same as those of the gas turbine combustors 31 and 71 of the first and third embodiments.

  Next, the operation of the premixed combustion type gas turbine combustor 81 will be described.

  The air a compressed by the compressor (not shown) with respect to the gas turbine combustor 81 flows from the air flow path (not shown) between the combustor outer cylinder and the combustor inner cylinder 32 to the combustor inner cylinder. After flowing into the combustor inner cylinder 32 through an air hole (not shown) at the upstream end of 32, the inside of the pilot air swirler cylinder 41 of the pilot burner 36 and the premixed air swirler cylinder 51 of the premixing burner 35 are shown. The fuel f supplied to the inside, the air flow path 76, and the air hole 37a of the substrate 37 and sent from the fuel supply system (not shown) is supplied to the pilot nozzle 42 and the premixing nozzle 52. Is done.

  In the pilot burner 36, the air a supplied into the pilot air swirler cylinder 41 is swirled by the pilot air swirler vane 45 while being circulated in the pilot air swirler cylinder 41, and is injected into the pilot cone 44. The fuel f supplied into the nozzle 42 flows through the pilot nozzle 42 and is injected into the pilot cone 44 from the fuel injection hole 42 a of the pilot nozzle 42. Accordingly, the air a and the fuel f are mixed in the pilot cone 44, and the air-fuel mixture is ignited by an ignition device (not shown), whereby diffusion combustion is performed in the pilot cone 44 and in the combustion chamber 34 ( A diffusion flame is generated).

  In the premixing burner 35, the air a supplied into the premixed air swirler cylinder 51 is swirled by the premixed air swirler vane 53 while flowing in the premixed air swirler cylinder 51, while Is supplied to the premixing nozzle 52 and the premixed air swirler vane 53 from the fuel injection hole 53a of the premixed air swirler vane 53 or from the fuel injection hole of the premixing nozzle 52. It is injected into the swirler cylinder 51. Accordingly, the air a and the fuel f are premixed in the first premixing region (in the premixed air swirler cylinder 51), and this premixed gas flows into the second premixing region 83.

On the other hand, the air a supplied into the air flow path 76 circulates in the air flow path 76 to form a film, and this air film is formed on the surface (side surfaces 72k, 72o) of the outer padding 72 and the inner padding 82. By flowing along the surface (side surfaces 82k, 82o), backfire can be prevented in the vicinity of the surface.
The air a supplied to the air holes 37a of the substrate 37 passes through the air holes 37a and becomes substrate air, and flows to the outer peripheral side and the inner peripheral side of the substrate 37. For this reason, it is possible to prevent the high-temperature combustion gas generated in the combustion chamber 34 from being caught in the low flow velocity region or the reverse flow region near the substrate 37 by the substrate air.

  In the second premixing region 83, the premixed gas that has flowed out from the first premixing region (premixed air swirler cylinder 51) and into the second premixing region 83, and out of the air flow path 76. Then, the air film that has flowed into the second premixing region 75 is well mixed.

More specifically, in the premix burner 35, the air a is swirled in the same direction by the premix air swirler vane 53. For this reason, the premixed gas swirled in the same direction (in the counterclockwise direction in the illustrated example) flows into the second premixed region 83 as shown by an arrow P3 in FIG. In the second premixing region 83, the swirling flows of these premixed gas are combined to form a large swirling flow of the premixed gas over the entire circumference of the second premixing region 83. This large swirl flow is reverse swirl on the inner peripheral side and the outer peripheral side of the second premixing region 83. For this reason, in the 2nd premix area 83, disorder of the flow of premixed gas and an air film becomes large, and mixing of premixed gas and an air film is promoted.
Furthermore, in the second premixing region 83, in the region between adjacent premixing burners 35 (for example, the Q3 region in FIG. 12), the swirl directions are opposite to each other, and the premixed air and the air film Since shearing force is generated, mixing of the premixed gas and the air film is further promoted.

  Further, in the premixed air swirler cylinder 51, a low flow velocity region exists at the center of the swirling flow of the premixed gas, but the low flow velocity region can be eliminated in the second premixed region 83. For this reason, it is possible to prevent backfire from occurring in the low flow velocity region.

  Further, since the outer padding 72 constituting the second premixing region 83 becomes thinner toward the downstream end 72a, the low flow velocity region in the vicinity of the surface is small, and backfire occurs in the low flow velocity region. The potential for occurrence is reduced.

  Further, since the inner padding 82 constituting the second premixing region 83 has a shape extending to the downstream end face 82a, the premixed gas flows straight, which is advantageous for backfire resistance. (Reverse fire is unlikely to occur.)

  The premixed gas generated in the second premixed region 83 (the premixed gas generated by well mixing the aforementioned premixed gas and the air film) flows out of the second premixed region 83 and burns. It flows into the chamber 34. In the combustion chamber 34, the diffusion flame generated by the pilot burner 36 is used as a fire type, whereby the premixed gas is ignited and premixed combustion is performed.

  Then, at the downstream end face 82 a of the inner padding 82 that functions as the back step surface of the flame stabilizer, a part of the premixed gas flowing out from the second premixing region 83 and the mixed gas flowing out from the pilot cone 44 are mixed. By causing the reverse flow or deceleration as indicated by the arrow R3 for a part, it is possible to reliably maintain the premixed combustion using the diffusion flame as a fire type.

As described above, according to the gas turbine combustor 81 of the fourth embodiment, the pilot burner 36, the premix nozzle 52 and the premix air swirler vane 53 are provided in the premix air swirler cylinder 51, and the pilot burner A plurality of premixing burners 35 disposed so as to surround the periphery of the pilot burner hole 37b, and a plurality of premixing burner holes 37c disposed so as to surround the periphery of the pilot burner hole 37b. A pilot burner 36 and a substrate 37 that supports the premixing burner 35 are provided in the combustor inner cylinder 32, and the inside of the premixed air swirler cylinder 51 is the first premixing region, and the premixed air swirler cylinder 51 In the gas turbine combustor 81 having a configuration in which an air film flows from the air flow path 76 formed between the flow path cylinder 74 and the downstream surface of the substrate 37. 7d, an outer padding 72 which fills the outer region 37e between the adjacent premixing burner holes 37c and which becomes narrower toward the downstream tip 72a, and a downstream side of the substrate 37 In the surface 72d, the upstream end surface 82b fills the inner region 37f between the adjacent premix burner holes 37c and extends to the downstream end surface 82a, and the downstream end surface 82a is the back step surface of the flame stabilizer. A space between the outer padding 72 and the inner padding 82 communicates with the premixed air swirler cylinder 51 through the premixing burner hole 37c and extends in the entire circumferential direction. Since the second premixing region 83 is an annular second continuous premixing region 83, the premixed gas and the air film are not mixed in the second premixing region 83. It is mixed. For this reason, premixed combustion is performed in a state where the fuel concentration of the premixed gas is uniform.
Further, since the circumference of the secondary premixing region 83 is shorter than the circumference of the conventional extension pipe, the low flow velocity region in the vicinity of the inner peripheral surface is small, and backfire can occur in the low flow velocity region. Sex is reduced.
Furthermore, in the premixed air swirler cylinder 51, a low flow velocity region exists at the center of the swirling flow of the premixed gas. However, since the low flow velocity region can be eliminated in the second premixed region 83, the low flow velocity region can be eliminated. It is also possible to prevent backfire from occurring in the flow velocity region.
Further, since the regions 37e and 37f between the adjacent premix burner holes 37c are filled with the fillings 72 and 82, it is not necessary to provide the air holes 37a in the regions 37e and 37f, and the amount of the substrate air is correspondingly increased. Can be reduced. Therefore, the air corresponding to that amount can be used for premixing, and the fuel concentration of the premixed gas in the entire premixed burner 35 can be reduced.
Further, since the outer padding 72 constituting the second premixing region 83 becomes thinner toward the downstream end 72a, the low flow velocity region in the vicinity of the surface is small, and backfire occurs in the low flow velocity region. The potential for occurrence is reduced.
Further, since the inner padding 82 constituting the second premixing region 83 has a shape extending to the downstream end face 82a, the premixed gas flows straight, which is advantageous for backfire resistance. (Backfire is difficult to occur). In addition, the downstream end surface 82a can be effectively used as the back step surface of the flame holder.

<Embodiment 5>
A premixed combustion type gas turbine combustor according to Embodiment 5 of the present invention will be described with reference to FIGS. In FIG. 14, the left side is the upstream side, and the right side is the downstream side.

  As shown in FIGS. 14 to 16, the premixed combustion type gas turbine combustor 91 according to the fifth embodiment has an annular space (annular flow) in a region where the premixed burner (main burner) 95 is disposed. Road) 111.

  More specifically, the gas turbine combustor 91 includes a combustor inner cylinder 92 provided inside a combustor outer cylinder (not shown), a premix burner inner cylinder 112, and a combustor tail cylinder 93. Yes.

The combustor tail cylinder 93 has a combustion chamber 94 inside, and an upstream end is connected to a downstream end of the combustor inner cylinder 92, while a downstream end includes a rotor and the like. Part (not shown).
The combustor inner cylinder 92 is cylindrical. The premix burner inner cylinder 112 is cylindrical, has a smaller diameter than the combustor inner cylinder 92, and has a shape in which the downstream side extends outward in the radial direction. Although not shown, the upstream end portion of the premix burner inner cylinder 112 is fixed and supported by a support portion provided at the upstream end portion of the combustor inner cylinder 92.

  The premix burner inner cylinder 112 is disposed inside the combustor inner cylinder 92 (coaxially disposed with the combustor inner cylinder 92). An annular flow path 111 that is a space between the combustor inner cylinder 92 and the premix burner inner cylinder 112 is continuous over the entire circumferential direction of the combustor inner cylinder 92 (premix burner inner cylinder 112). . The downstream portion of the annular flow path 111 is a premixing area 111a. Therefore, the premixing region 111a is of course continuous over the entire circumferential direction. The width of the premixing region 111a (the width in the radial direction of the combustor inner cylinder 92) becomes narrower toward the downstream side.

  The annular channel 111 is provided with a plurality (eight in the illustrated example) of premix burners (main burners) 95 that perform premix combustion. A pilot burner 96 that performs diffusion combustion is provided inside the premixed burner inner cylinder 112.

  The pilot burner 96 is disposed at the center inside the premixing burner inner cylinder 112 (coaxially with the premixing burner inner cylinder 112), and includes a pilot air swirler cylinder 98, a pilot nozzle 99, and a plurality (in the illustrated example). 6 pieces) A pilot air swirler vane (pilot air swirler) 97 and a pilot cone 100 are provided.

  The pilot air swirler cylinder 98 is cylindrical. The pilot nozzle 99 is disposed at a central portion (coaxial with the pilot air swirler tube 98) in the pilot air swirler tube 98. Although not shown, the upstream end portion of the pilot nozzle 99 is fixed and supported by a support portion provided at the upstream end portion of the combustor inner cylinder 92. A fuel injection hole 99 a is provided at the downstream end of the pilot nozzle 99. The pilot air swirler vanes 97 are interposed between the inner peripheral surface of the pilot air swirler cylinder 97 and the outer peripheral surface of the pilot nozzle 99, and are arranged at equal intervals in the circumferential direction of the pilot nozzle 99.

  The pilot cone 100 is a truncated cone-shaped cylinder that gradually spreads outward in the radial direction from the upstream end to the downstream end, and the upstream end is the downstream end of the pilot air swirler cylinder 98. It is connected to the part by welding. The flame holder 101 is an annular plate, and an inner peripheral portion is connected to a downstream end portion of the pilot cone 100 by welding, and a downstream surface is a back step surface 101a. The downstream end of the premix burner inner cylinder 112 is at the same position as the back step surface 101a.

  The plurality of premix burners 95 are arranged at equal intervals in the circumferential direction of the annular flow path 111 in the annular flow path 111 and surround the periphery of the pilot burner 96. Each of these premix burners 95 includes a premix nozzle 102 and a plurality (six in the illustrated example) of premix air swirler vanes (premix air swirl vanes) 103. Although not shown, the upstream end portion of the premixing nozzle 102 is fixed to and supported by the support portion. The premixed air swirler vanes 103 are fixed to the outer peripheral surface of the premixing nozzle 102 by welding, and are arranged at equal intervals in the circumferential direction of the premixing nozzle 102. The premixed air swirler vane 103 is provided with a fuel injection hole 103a. However, the present invention is not limited to this, and a fuel injection hole may be provided in the premixing nozzle 102. The premixing region 111 a is located on the downstream side of the premixed air swirler vane 103.

  Next, the operation of the premixed combustion type gas turbine combustor 91 will be described.

  The air a compressed by the compressor (not shown) with respect to the gas turbine combustor 91 is transferred from the air flow path (not shown) between the combustor outer cylinder and the combustor inner cylinder 92 to the combustor inner cylinder. 92 flows into the combustor inner cylinder 92 through the air hole (not shown) at the upstream end of 92, and further premixes through the air hole (not shown) at the upstream end of the premix burner inner cylinder 112. After flowing into the burner inner cylinder 112, the fuel f supplied to the pilot air swirler cylinder 98 of the pilot burner 96 and the annular flow path 111 and sent from the fuel supply system (not shown) is the pilot f It is supplied into the nozzle 99 and the premixing nozzle 102.

  In the pilot burner 96, the air a supplied into the pilot air swirler cylinder 98 is swirled by the pilot air swirler vane 97 while being circulated in the pilot air swirler cylinder 98, and is injected into the pilot cone 100. The fuel f supplied into the nozzle 99 flows through the pilot nozzle 99 and is injected into the pilot cone 100 from the fuel injection hole 99a of the pilot nozzle 99. Accordingly, the air a and the fuel f are mixed in the pilot cone 44, and the mixture is ignited by an ignition device (not shown), whereby diffusion combustion is performed in the pilot cone 100 and in the combustion chamber 94 ( A diffusion flame is generated).

  In the annular flow path 111 provided with the premixing burner 95, the air a supplied into the annular flow path 111 is swirled by the premixed air swirler vane 103 while circulating in the annular flow path 111, The fuel f supplied into the premixing nozzle 102 flows through the premixing nozzle 102 and the premixed air swirler vane 103 and from the fuel injection hole 103a of the premixed air swirler vane 103, or the fuel injection hole of the premixing nozzle 102. Are injected into the annular channel 111.

  In the premixing region 111a of the annular channel 111, the air a and the fuel f are premixed. In the premixing region 111a, the air a and the fuel f are well mixed.

More specifically, in the premix burner 95, the air a swirls in the same direction by the premix air swirler vane 103. For this reason, in the premixing region 111a, the air a and the fuel swirl in the same direction (counterclockwise in the illustrated example) as indicated by an arrow P4 in FIG. And in the premixing area | region 111a, when these swirl | flow flows merge, it becomes a big swirl | flow current over the perimeter of the premixing area | region 111a. This large swirl flow is reverse swirl on the inner peripheral side and the outer peripheral side of the premixing region 111a. For this reason, in the premixing region 111a, the disturbance of the flow of the air a and the fuel increases, and the mixing of the air a and the fuel is promoted.
Further, in the premixing region 111a, in the region between the adjacent premixing burners 95 (for example, the Q4 region in FIG. 15), the swirl directions are opposite to each other, and shear force is generated for the air a and the fuel. Mixing of air a and fuel is further promoted.
Further, since the swirl directions are opposite to each other in the region between the adjacent premix burners 95, the reverse swirl component weakens the speed component in the radial direction of the combustor inner cylinder 92, and the combustor inner cylinder 92 and The flow toward the wall surface of the premixed burner inner cylinder 112 is suppressed, and backfire can be prevented.

The premixed gas generated in the premixing region 111a flows out of the premixing region 111a and flows into the combustion chamber 94. In the combustion chamber 94, the diffusion flame generated by the pilot burner 96 is used as a fire type, whereby the premixed gas is ignited and premixed combustion is performed.
At this time, the gas turbine combustor 91 according to the fifth embodiment does not require the substrate air, and that air is effectively used for premixing with the fuel and premixed combustion is performed. Reduce average flame temperature.

  Further, in the premixing region 111a, the swirling of the premixed gas is weakened, and the premixed gas in which the swirling is weakened flows into the combustion chamber 94, so that the flame becomes longer in the axial direction. For this reason, it is advantageous for reducing NOx.

  In the flame holder 101, on the back step surface 101a, a part of the premixed gas flowing out from the premixing region 111a and a part of the mixed gas flowing out from the pilot cone 100 are backflowed or decelerated as indicated by an arrow R4. By generating the above, it is possible to reliably maintain the premixed combustion using the diffusion flame as a fire type.

As described above, according to the gas turbine combustor 91 of the fifth embodiment, the pilot burner 96, the premixing nozzle 102, and the premixed air swirler vane 103 are provided so as to surround the periphery of the pilot burner 96. In the gas turbine combustor 91 in which the plurality of premixed burners 95 provided are provided in the combustor inner cylinder 92, the premix burner inner cylinder 112 is provided inside the combustor inner cylinder 92, The annular flow path 111 that is a space between the combustor inner cylinder 92 and the premixing burner inner cylinder 112 is continuous over the entire circumferential direction, and a downstream portion of the annular flow path 111 becomes a premixing region 111a. The premix burner 95 is disposed in the annular flow path 111, and the pilot burner 96 is disposed inside the premix burner inner cylinder 112. In 1a, and the fuel f and air a, is well mixed. For this reason, premixed combustion is performed in a state where the fuel concentration of the premixed gas is uniform.
Further, since the substrate air is unnecessary and the premixed combustion can be performed by effectively using the air a for the premixing with the fuel f, the average flame temperature can be lowered.

  Further, according to the gas turbine combustor of the fifth embodiment, since the width of the premixing region 111a is narrowed toward the downstream side, it is directed toward the outlet of the premixing region 111a. By increasing the flow rate of the premixed gas, the boundary layer can be made thinner or the fuel concentration in the vicinity of the wall surface can be made thinner, so that it is possible to prevent backfire from occurring in the vicinity of the surface.

<Embodiment 6>
A premixed combustion type gas turbine combustor according to Embodiment 6 of the present invention will be described with reference to FIGS. In FIG. 17, the left side is the upstream side and the right side is the downstream side.

  As shown in FIGS. 17 to 20, the gas turbine combustor 121 of the premixed combustion method according to the sixth embodiment includes a combustor inner cylinder 122 provided inside a combustor outer cylinder (not shown), And a combustor transition piece 123.

The combustor tail cylinder 123 has a combustion chamber 124 inside, and an upstream end is connected to a downstream end of the combustor inner cylinder 122, while a downstream end includes a rotor and the like. Part (not shown).
The combustor inner cylinder 122 is cylindrical. In the combustor inner cylinder 122, a plurality (eight in the illustrated example) of premixed burners (main burners) 125 that perform premixed combustion, a pilot burner 126 that performs diffusion combustion, and these burners 125 and 126 are provided. A supporting substrate 127 is provided.

  Further, in the sixth embodiment, a stagnation removing structure (stuffing) 128A, an inner guide ring 129, and an outer guide ring 130 are also provided in the combustor inner cylinder 122.

  The substrate 127 has a disk shape, and is supported by the combustor inner cylinder 122 by fixing the outer peripheral portion to the inner peripheral surface of the combustor inner cylinder 122 by welding. The substrate 127 is provided with pilot burner holes 127a and a plurality (eight in the illustrated example) of premix burner holes 127b. In addition, air holes 127 c are also provided on the inner peripheral side and the outer peripheral side of the substrate 127. The pilot burner hole 127a is opened at the center of the substrate 127, and the plurality of premix burner holes 127b are opened at equal intervals in the circumferential direction of the substrate 127 to surround the pilot burner hole 127a.

  The pilot burner 126 is disposed at a central portion (coaxially with the combustor inner cylinder 122) in the combustor inner cylinder 122, and includes a pilot air swirler cylinder 131, pilot nozzles 132, and a plurality (six in the illustrated example). A pilot air swirler vane (pilot air swirler) 133 and a pilot cone 134 are provided.

  The pilot air swirler cylinder 131 has a cylindrical shape, is inserted into the pilot burner hole 127a of the board 127, and is fixed to and supported by the board 127 by welding. The pilot nozzle 132 is disposed at a central portion (coaxial with the pilot air swirler tube 131) in the pilot air swirler tube 131. Although not shown, the upstream end portion of the pilot nozzle 132 is fixed and supported by a support portion provided at the upstream end portion of the combustor inner cylinder 122. A fuel injection hole 132 a is provided at the downstream end of the pilot nozzle 132. The pilot air swirler vanes 133 are interposed between the inner peripheral surface of the pilot air swirler cylinder 131 and the outer peripheral surface of the pilot nozzle 132, and are arranged at equal intervals in the circumferential direction of the pilot nozzle 132.

  The pilot cone 134 is a truncated cone-shaped tube that spreads outward in the radial direction from the upstream end to the downstream end, and the upstream end is connected to the downstream end of the pilot air swirler tube 131. Connected by welding. The flame holder 135 is an annular plate, the inner peripheral portion thereof is connected to the downstream end portion of the pilot cone 134 by welding, and the downstream surface is a back step surface 135a.

  The plurality of premix burners 125 are arranged at equal intervals in the circumferential direction of the combustor inner cylinder 122 and surround the pilot burner 126. Each of these premix burners 125 includes a premix air swirler cylinder 141, a premix nozzle 142, and a plurality (six in the illustrated example) of premix air swirler vanes (premix air swirl vanes) 143. .

  The premixed air swirler cylinder 141 is fixed to the combustor inner cylinder 122 by welding. The upstream portion 141a of the premixed air swirler cylinder 141 is cylindrical. The downstream portion 141b of the premixed air swirler cylinder 141 (the portion downstream of the premixed air swirler vane 143) has a cross-sectional shape that is circular at the upstream end portion 141c, but is continuous toward the downstream. The downstream end 141d has a rectangular shape. The downstream end portion 141 d of the premixed air swirler cylinder 141 is located in the premixed burner hole 127 b of the substrate 127.

  The premixing nozzle 142 is disposed in a central portion (on the same axis as the premixed air swirler cylinder 141) in the premixed air swirler cylinder 141. Although illustration is omitted, the upstream end portion of the premixing nozzle 142 is fixed to and supported by the support portion. The premixed air swirler vanes 143 are interposed between the inner peripheral surface of the premixed air swirler cylinder 141 and the outer peripheral surface of the premixing nozzle 142, and are arranged at equal intervals in the circumferential direction of the premixing nozzle 142. The premixed air swirler vane 143 is provided with a fuel injection hole 143a. However, the present invention is not limited to this, and the fuel injection hole may be provided in the premixing nozzle 142.

  A plurality (eight in the illustrated example) of stagnation-excluding structures 128A are provided on the downstream surface of the substrate 127, and are arranged at equal intervals in the circumferential direction of the substrate 127. Each of the stagnation-excluding structures 128A is formed integrally with the substrate 127, and fills the region between the adjacent premix burner holes 127b. The stagnation-excluding structure 128A is not limited to the one formed integrally with the substrate 127, and may be a separate member from the substrate 127 (in this case, it is fixed to the substrate 127 by fixing means such as welding). ) The stagnation eliminating structure 128 </ b> A is located upstream of the downstream end of the inner guide ring 129 and the downstream end of the outer guide ring 130.

  The inner guide ring 129 is positioned on the inner side in the radial direction of the combustor inner cylinder 122 with respect to the stagnation eliminating structure 128A, and the upstream end portion 129a is fixed to and supported by the substrate 127 by welding. Further, the inner guide ring 129 is a generally truncated cone-shaped tube that spreads outwardly in the radial direction from the upstream end 129a toward the downstream end 129b. Further, the inner guide ring 129 has a downstream end portion 129b extending more downstream than the downstream end of the stagnation exclusion structure 128A, and the downstream end is at the same position as the back step surface 135a of the flame stabilizer 135. Yes.

  The outer guide ring 130 is positioned on the outer side in the radial direction of the combustor inner cylinder 122 with respect to the stagnation eliminating structure 128A, and the upstream end portion 130a is fixed to and supported by the substrate 127 by welding. Further, the outer guide ring 130 is a generally truncated cone-shaped tube that spreads outwardly in the radial direction from the upstream end portion 130a toward the downstream end portion 130b. Further, the outer guide ring 130 has a downstream end portion 130b extending further downstream than the downstream end of the stagnation exclusion structure 128A, and the downstream end is at the same position as the back step surface 135a of the flame stabilizer 135. Yes.

  The inner guide ring 129 and the outer guide ring 130 are not limited to being separate from the substrate 127, and may be formed integrally with the substrate 127, and further formed integrally with the stagnation-excluding structure 128A. It may be. That is, the substrate 127, the stagnation removing structure 128A, the inner guide ring 129, and the outer guide ring 130 may be integrated.

  In addition, the substrate 127 is also provided with a flow channel 144 for generating an air film. Like the downstream end portion 141d of the premixed air swirler tube 141, the flow channel tube 144 has a rectangular cross-sectional shape, and is fixed to and supported by the upstream surface of the substrate 127 by welding. Protrudes upstream. Since the channel tube 144 is larger than the downstream end portion 141d of the premixed air swirler tube 141, the inner peripheral surface of the channel tube 144 and the outer peripheral surface of the downstream end portion 141d of the premixed air swirler tube 141 are An annular gap is formed between them, and this gap serves as an air flow path 145 for generating an air film.

  Further, the inside of the premixed air swirler cylinder 141 is the first premixing region, whereas the space between the outer guide ring 129 and the inner guide ring 130 becomes the second premixing region 146. Yes. The second premixing region 146 communicates with the premixed air swirler cylinder 141 and has an annular shape continuous over the entire circumferential direction of the combustor inner cylinder 122 (the circumferential direction of the guide rings 129 and 130). It is a space (annular channel). In other words, the primary premixing area (in the premixed air swirler cylinder 141) is an individual premixing area for each premixing burner 125, while the secondary premixing area 146 is all premixing. This is a premixing region common to the burner 125.

  The stagnation-excluding structure 128A has a cross-sectional shape that becomes narrower toward the downstream side. Based on FIG. 21, the configuration of the stagnation-excluding structure 128A will be described in detail.

  As shown in FIGS. 21 (a) to 21 (c), the stagnation removing structure 128A has a substantially triangular prism shape, and has five surfaces, that is, an upstream surface 128a, an outer peripheral surface 128b, and an inner surface. It has a peripheral surface 128c, one side surface 128d, and the other side surface 128e.

The downstream end portion 141d of the premixed air swirler cylinder 141 has a rectangular cross section and rounded corners (FIGS. 18 and 19), and the premixed burner hole 127b of the substrate 127 is also rectangular in accordance with this. And the corners are all rounded (FIGS. 18 to 20 and FIG. 21B). For this reason, the region between the adjacent premix burner holes 127b is wider in the radially outer portion and the inner portion than the radially central portion of the combustor inner cylinder 122 (substrate 127) (that is, FIG. 21). The width in the left-right direction in (b) is wide.
Therefore, the upstream surface 128a of the stagnation-exclusion structure 128A conforms to the shape of the region between the adjacent premix burner holes 127b as described above, and the radially outer portion and The inner portion is wider (that is, the width in the left-right direction in FIG. 21B). The width of the upstream surface 128a smoothly changes from the central portion toward the outer portion and the inner portion.
The outer peripheral surface 128b of the stagnation-excluding structure 128A is curved along the outer guide ring 130, and the inner peripheral surface 128c of the stagnation-excluding structure 128A is curved along the inner guide ring 129.

  As shown in FIGS. 21D to 21F, the cross-sectional shape of the stagnation-excluding structure 128A (the cross-sectional shape along the flow direction of the premixed gas from upstream to downstream) is the stagnation-excluding structure. The radial center portion (FIG. 21E), the radially outer portion (FIG. 21D), and the radially inner portion (FIG. 21F) of the article 128A are all upstream. This is an isosceles triangle having the base (upstream surface 128a) as the base. That is, the stagnation-excluding structure 128A has an isosceles triangular shape as a whole in cross section.

  Moreover, the cross-sectional shapes of the central portion, the outer portion, and the inner portion in the radial direction of the stagnation-excluding structure 128A are set so that the angle θ of the base is the same, and the flow direction of the premixed gas is abruptly changed. I try not to change. For this reason, the stagnation-excluding structure 128A is compared with the outer portion (FIG. 21D) and the inner portion (FIG. 21F) having a wide bottom side compared to the central portion (FIG. 21E) having a narrow bottom width. The length of the premixed gas in the flow direction is long.

  Next, the operation of this premixed combustion type gas turbine combustor 121 will be described.

  The air a compressed by the compressor (not shown) with respect to the gas turbine combustor 121 flows from the air flow path (not shown) between the combustor outer cylinder and the combustor inner cylinder 122 to the combustor inner cylinder. After flowing into the combustor inner cylinder 122 through an air hole (not shown) at the upstream end of 122, the pilot air swirler cylinder 131 of the pilot burner 126 and the premixed air swirler cylinder 141 of the premixing burner 125. The fuel f supplied to the inside, the air flow path 145, and the air hole 127c of the substrate 127 and sent from the fuel supply system (not shown) is supplied to the pilot nozzle 132 and the premixing nozzle 142. Is done.

  In the pilot burner 126, the air a supplied into the pilot air swirler cylinder 131 is swirled by the pilot air swirler vane 133 while flowing through the pilot air swirler cylinder 131, and is injected into the pilot cone 134. The fuel f supplied into the nozzle 132 flows through the pilot nozzle 132 and is injected into the pilot cone 134 from the fuel injection hole 132a of the pilot nozzle 132. Accordingly, the air a and the fuel f are mixed in the pilot cone 134, and the mixture is ignited by an ignition device (not shown), whereby diffusion combustion is performed in the pilot cone 134 and in the combustion chamber 124 ( A diffusion flame is generated).

  In the premixing burner 125, the air a supplied into the premixed air swirler cylinder 141 is swirled by the premixed air swirler vane 143 while circulating in the premixed air swirler cylinder 141, while The fuel f supplied to the premixing nozzle 142 and the premixed air swirler vane 143 flows through the premixed air swirler vane 143 from the fuel injection hole 143a or from the premixing nozzle 142 fuel injection hole. It is injected into the swirler cylinder 141. Accordingly, the air a and the fuel f are premixed in the first premixing region (in the premixed air swirler cylinder 141), and this premixed gas flows into the second premixing region 146.

  On the other hand, the air a supplied into the air flow path 145 flows through the air flow path 145 to form a film, and this air film flows along the inner peripheral surfaces of the rings 129 and 130, thereby Prevent backfire near the surface.

  The air a supplied to the air holes 127 c of the substrate 127 passes through the air holes 127 c and becomes substrate air, and flows to the outer peripheral side and the inner peripheral side of the substrate 127. For this reason, it is possible to prevent the high-temperature combustion gas generated in the combustion chamber 124 from being caught in the low flow velocity region or the backflow region near the substrate 127 by the substrate air.

  Since the stagnation eliminating structure 128A fills the region between the adjacent premix burner holes 127b, the premixed gas flow is prevented from stagnation in the vicinity of the region.

That is, as shown in FIG. 22A, when the region 127d between the adjacent premix burner holes 127b is not filled with the stagnation exclusion structure 128A, the premixed gas is large in the vicinity of the region 127d. It may slow down and back flow. The two-dimensional axial flow velocity contour diagram of FIG. 22B shows the velocity distribution of the premixed gas when the stagnation eliminating structure 128A is not provided. The speed of the premixed gas decreases as it approaches the region 127d between the adjacent premixed burner holes 127b, and the premixed gas is greatly decelerated or backflowed in the vicinity of the region 127d to generate a stagnation region 161. In this stagnation region 161, there is a possibility of inducing a flashback phenomenon.
On the other hand, as shown in FIG. 22C, when the region 127d between the adjacent premixing burner holes 127b is filled with the stagnation exclusion structure 128A, the premixing is performed in the vicinity of the region 127d. It is possible to prevent the stagnation-excluding structure 128A from greatly decelerating or backflowing. The two-dimensional axial flow velocity contour diagram of FIG. 22D shows the velocity distribution of the premixed gas when the stagnation eliminating structure 128A is provided. Although the speed of the premixed gas decreases as it approaches the region 127d between the adjacent premixed burner holes 127b, the premixed gas greatly decelerates or reversely flows in the vicinity of the region 127d. Since it can be prevented by 128A, a stagnation region does not occur in the vicinity of the region 127d.

  Further, in the second premixing region 146, the premixed gas that has flowed out of the first premixing region (premixed air swirler cylinder 141) and flowed into the second premixing region 146 becomes the second premixing region. 146 is well mixed over the entire circumferential direction, and the premixed gas and the air film flowing out from the air flow path 145 and flowing into the second premixing region 146 are also well mixed.

More specifically, in the premix burner 125, the air a is swirled in the same direction by the premix air swirler vane 143. For this reason, the premixed gas swirled in the same direction (in the counterclockwise direction in the illustrated example) flows into the second premixed region 146 as shown by an arrow P5 in FIG. In the second premixing region 146, the swirling flows of these premixed gas are combined to form a large swirling flow of the premixed gas over the entire circumference of the second premixing region 146. This large swirl flow is reverse swirl on the inner peripheral side and the outer peripheral side of the second premixing region 146. For this reason, in the second premix region 57, the premixed gas and the air film flow are greatly disturbed, and the premixed gas is well mixed over the entire circumferential direction of the second premixed region 146. Premixed air and air film are also well mixed.
Further, in the second premixing region 146, in the region between adjacent premixing burners 125 (for example, the Q5 region in FIG. 18), the swirl directions are opposite to each other, and the premixed gas and the air film are sheared. Since force is generated, mixing of the premixed gas and the air film is further promoted.

  The premixed gas generated in the second premixed region 146 (the premixed gas generated by well mixing the premixed gas and the air film) flows out of the second premixed region 146 and burns. Flows into the chamber 124. In the combustion chamber 124, the diffusion flame generated by the pilot burner 126 is used as a fire type, whereby the premixed gas is ignited and premixed combustion is performed.

  In the flame stabilizer 135, a backflow as indicated by an arrow R5 or a part of the premixed gas flowing out from the second premixing region 146 or a part of the mixed gas flowing out from the pilot cone 134 on the back step surface 135a By causing deceleration, premixed combustion using the diffusion flame as a fire type can be reliably maintained.

As described above, according to the gas turbine combustor 121 of the sixth embodiment, the pilot burner 126, the premix nozzle 142 and the premix air swirler vane 143 are provided in the premix air swirler cylinder 141, and the pilot burner 126, a plurality of premixing burners 125 disposed so as to surround the periphery of the pilot hole 126, a pilot burner hole 127a, and a plurality of premixing burner holes 127b disposed so as to surround the periphery of the pilot burner hole 127a. The pilot burner 126 and the substrate 127 that supports the premixing burner 125 are provided. The premixed air swirler cylinder 141 is a first premixing region, and the premixed air swirler cylinder 141 and the flow path cylinder 144 are In the gas turbine combustor configured to flow an air film from the air flow path 145 formed therebetween, the downstream side of the substrate 127 The surface has a stagnation-excluding structure 128A in which a region 127d between adjacent premix burner holes 127b is filled, and the stagnation-excluding structure 127A has an isosceles triangle shape (as it goes downstream). And has an outer guide ring 130 positioned outside the stagnation-excluding structure 128A and an inner guide ring 129 positioned inside the stagnation-excluding structure 128A. The space between the guide ring 130 and the inner guide ring 129 communicates with the premixed air swirler cylinder 141 via the premixed burner hole 127b and is continuous in the entire circumferential direction. Since it is a mixing region 146, the premixed gas flows in the vicinity of the region 127d between the adjacent premixing burner holes 127b of the substrate 127. And it is possible to prevent (eliminated) by stagnation elimination structure 128A.
Further, since the cross-sectional shape of the stagnation-excluding structure 128A is an isosceles triangle, the downstream end is sharp, so there is no risk of stagnation of the premixed gas flow at the downstream end.
In the second premixing region 146, the premixed gas flowing out from the first premixing region (in the premixed air swirler cylinder 141) and flowing into the second premixing region 146 is second premixed. The mixture is well mixed over the entire circumferential direction of the region 146, and the premixed gas and the air film flowing out from the air flow path 145 and flowing into the second premixing region 146 are also well mixed.

<Embodiment 7>
A premixed combustion type gas turbine combustor according to Embodiment 7 of the present invention will be described with reference to FIGS.

The gas turbine combustor according to the seventh embodiment is the same as the gas turbine combustor according to the sixth embodiment (FIGS. 17 to 20), instead of the stagnation eliminating structure 128A. Other configurations are the same as those of the gas turbine combustor of the sixth embodiment.
Therefore, here, the stagnation eliminating structure 128B will be described, and the description and illustration of the overall configuration of the gas turbine combustor will be omitted (see FIGS. 17 to 20).
Further, in the configuration of the stagnation-excluding structure 128B shown in FIG. 23, the same reference numerals are given to portions corresponding to the configuration of the stagnation-excluding structure 128A shown in FIG.

  The stagnation-excluding structure 128B in the seventh embodiment also fills the region between the adjacent premixing burner holes 127b in the same manner as the stagnation-excluding structure 128A in the sixth embodiment, and goes toward the downstream side. Therefore, it has a cross-sectional shape that makes the width narrower. Based on FIG. 23, the configuration of the stagnation-excluding structure 128B will be described in detail.

  As shown in FIGS. 23 (a) and 23 (b), the stagnation-excluding structure 128B is substantially triangular in shape like the stagnation-excluding structure 128A, and has five surfaces, that is, an upstream surface 128a, It has an outer peripheral surface 128b, an inner peripheral surface 128c, one side surface 128d, and the other side surface 128e.

A surface 128a on the upstream side of the stagnation exclusion structure 128B in accordance with the shape of the region between the adjacent premix burner holes 127b is compared with the radial center portion of the combustor inner cylinder 122 (substrate 127) in the radial direction. The width of the outer part and the inner part is larger (the width in the left-right direction in FIG. 23B).
The outer peripheral surface 128b of the stagnation-excluding structure 128B is curved along the outer guide ring 130, and the inner peripheral surface 128c of the stagnation-excluding structure 128B is curved along the inner guide ring 129.

23C to 23E, the cross-sectional shape of the stagnation-excluding structure 128B (the cross-sectional shape along the flow direction of the premixed gas from the upstream to the downstream) is the stagnation-excluding structure. Each of the radially central portion (FIG. 23 (d)), the radially outer portion (FIG. 23 (c)), and the radially inner portion (FIG. 23 (e)) of the article 128B is located downstream. It has a sharp bell shape. That is, the stagnation-excluding structure 128B has a bell-shaped cross section as a whole. In addition, this cross-sectional shape can also be said to be a spindle shape with a pointed downstream (one side).
Since the stagnation eliminating structure 128B has a bell shape (spindle shape) in cross section, the upstream end is tangent to the downstream end 141d (premix burner hole 127b) of the premixed air swirler cylinder 141. (It extends along the axial direction of the premixed air swirler cylinder 141).

When the cross-sectional shape is an isosceles triangle like the stagnation exclusion structure 128A, as shown in FIG. 24A, the premixed air that has flowed out of the premixed air swirler cylinder 141 is side surface 128d of the stagnation exclusion structure 128A. , 128e, the flow direction of the premixed gas suddenly changes.
On the other hand, when the cross-sectional shape is a bell shape like the stagnation exclusion structure 128B, the premixed gas flowing out from the premixed air swirler cylinder 141 is stagnation exclusion structure 128B as shown in FIG. When flowing along the side surfaces 128d and 128e, the flow direction of the premixed gas changes smoothly.

  As described above, according to the gas turbine combustor of the seventh embodiment, the cross-sectional shape of the stagnation-excluding structure 128B is characterized by the bell shape, so that the cross-sectional shape is an isosceles triangle shape. The flow direction of the premixed gas changes smoothly compared to. For this reason, compared with the case where a cross-sectional shape is an isosceles triangle shape, the flow rate fall degree of a premixed gas is reduced.

<Embodiment 8>
A premixed combustion type gas turbine combustor according to Embodiment 8 of the present invention will be described with reference to FIGS. 25 and 26.

The gas turbine combustor according to the eighth embodiment is the same as the gas turbine combustor according to the sixth embodiment (FIGS. 17 to 20) except for the stagnation eliminating structure 128A shown in FIG. Other configurations are the same as those of the gas turbine combustor of the sixth embodiment.
Therefore, here, the stagnation eliminating structure 128C will be described, and the description and illustration of the overall configuration of the gas turbine combustor will be omitted (see FIGS. 17 to 20).
Further, in the configuration of the stagnation-excluding structure 128C shown in FIG. 25, the same reference numerals are given to the portions corresponding to the configuration of the stagnation-excluding structure 128A shown in FIG.

  The stagnation-excluding structure 128B in the present eighth embodiment also fills the region between the adjacent premixing burner holes 127b in the same manner as the stagnation-excluding structure 128A in the sixth embodiment, and goes toward the downstream side. Therefore, it has a cross-sectional shape that makes the width narrower. Based on FIG. 25, the configuration of the stagnation-excluding structure 128C will be described in detail.

  As shown in FIG. 25A and FIG. 25B, the stagnation-excluding structure 128C is substantially triangular like the stagnation-excluding structure 128A, and has five surfaces, that is, an upstream surface 128a, It has an outer peripheral surface 128b, an inner peripheral surface 128c, one side surface 128d, and the other side surface 128e.

A surface 128a on the upstream side of the stagnation exclusion structure 128C in accordance with the shape of the region between the adjacent premix burner holes 127b is compared to the radial central portion of the combustor inner cylinder 122 (substrate 127) in the radial direction. The width of the outer part and the inner part is larger (the width in the left-right direction in FIG. 25B).
The outer peripheral surface 128b of the stagnation-excluding structure 128C is curved along the outer guide ring 130, and the inner peripheral surface 128c of the stagnation-excluding structure 128B is curved along the inner guide ring 129.

  As shown in FIGS. 25C to 25E, the stagnation-excluding structure 128C has a cross-sectional shape (a cross-sectional shape along the flow direction of the premixed gas from upstream to downstream). The central portion (FIG. 25 (d)) in the radial direction of the object 128C has a bell shape with a sharp downstream side, while the radially outer portion (FIG. 25 (c)) and the radially inner portion ( In FIG. 25 (e), the shape is an isosceles triangle having an upstream side (upstream surface 128a) as a base. In this case, the cross-sectional shape of the stagnation-excluding structure 128C is continuously deformed from a bell shape to an isosceles triangle shape from the central portion toward the outer portion and the inner portion. In addition, it is not limited to this, You may make it change from a bell shape to an isosceles triangle shape in the middle position of the said radial direction.

When the cross-sectional shape of the outer portion and the inner portion where the width of the upstream surface 128a is wide like the stagnation-excluding structure 128B of the seventh embodiment is changed to a bell shape, the stagnation as shown in FIG. There is a case where the flow of the premixed gas is separated from the side surfaces 128d and 128e of the stagnation exclusion structure 128B at the downstream end portion of the exclusion structure 128B.
On the other hand, in the central portion where the width of the upstream surface 128a is narrow, even if the cross-sectional shape is a bell shape, the premixed gas is mixed with the side surface 128d of the stagnation eliminating structure 128B as shown in FIG. , 128e flows smoothly, and there is no possibility of peeling at the downstream end portions of the side surfaces 128d, 128e.

  Therefore, in the stagnation-excluding structure 128C according to the eighth embodiment, the cross-sectional shapes of the outer portion and the inner portion are isosceles triangles as a countermeasure when there is a risk of peeling as described above.

  As described above, according to the gas turbine combustor of the eighth embodiment, the end surface 128a on the upstream side of the stagnation eliminating structure 128C has an outer portion and a central portion in the radial direction of the stagnation eliminating structure 128C. The width of the inner portion is wider, and the cross-sectional shape of the stagnation-excluding structure 128C is characterized by a bell shape at the central portion and an isosceles triangle shape at the outer portion and the inner portion. In the central portion of the stagnation eliminating structure 128C where the width of the upstream end surface 128a (bottom surface) is narrow, the degree of decrease in the flow rate of the premixed gas can be reduced, and the width of the upstream end surface 128a (bottom surface). In the outer portion and the inner portion of the stagnation exclusion structure 128C having a large width, the premixed gas is transferred from the side surfaces 128d and 128e of the downstream end portion at the downstream end of the stagnation exclusion structure 128C. It is possible to prevent the peeling.

<Embodiment 9>
A premixed combustion type gas turbine combustor according to Embodiment 9 of the present invention will be described with reference to FIG.

The gas turbine combustor according to the ninth embodiment is the same as the gas turbine combustor according to the sixth embodiment (FIGS. 17 to 20), except for the stagnation eliminating structure 128A. Other configurations are the same as those of the gas turbine combustor of the sixth embodiment.
Therefore, the stagnation eliminating structure 128D will be described here, and the description and illustration of the overall configuration of the gas turbine combustor will be omitted (see FIGS. 17 to 20).
In addition, in the configuration of the stagnation-excluding structure 128D shown in FIG. 27, portions corresponding to the configuration of the stagnation-excluding structure 128A shown in FIG.

  The stagnation-excluding structure 128D in the ninth embodiment also fills the region between the adjacent premixing burner holes 127b in the same manner as the stagnation-excluding structure 128A in the sixth embodiment, and goes toward the downstream side. Therefore, it has a cross-sectional shape that makes the width narrower. The configuration of the stagnation-excluding structure 128D will be described in detail based on FIG.

  As shown in FIG. 27A and FIG. 27B, the stagnation-excluding structure 128D is substantially triangular in shape like the stagnation-excluding structure 128A, and has five surfaces, that is, an upstream surface 128a, It has an outer peripheral surface 128b, an inner peripheral surface 128c, one side surface 128d, and the other side surface 128e.

A surface 128a on the upstream side of the stagnation exclusion structure 128D in accordance with the shape of the region between the adjacent premix burner holes 127b is compared to the radial central portion of the combustor inner cylinder 122 (substrate 127). The outer portion and the inner portion have a wider width (width in the left-right direction in FIG. 27B).
The outer peripheral surface 128b of the stagnation-excluding structure 128D is curved along the outer guide ring 130, and the inner peripheral surface 128c of the stagnation-excluding structure 128D is curved along the inner guide ring 129.

  27C to 27E, the cross-sectional shape of the stagnation-excluding structure 128D (the cross-sectional shape along the flow direction of the premixed gas from upstream to downstream) is the stagnation-excluding structure. Each of the radially central portion (FIG. 27 (d)), the radially outer portion (FIG. 27 (c)), and the radially inner portion (FIG. 27 (e)) of the article 128D is upstream. Has a bell-shaped portion 128f and an isosceles triangular portion 128g on the downstream side. That is, the stagnation-excluding structure 12D has a cross-sectional shape that is a combination of a bell shape and an isosceles triangle shape as a whole.

  Thus, since the cross-sectional shape of the stagnation-excluding structure 128D is a shape having the bell shape portion 128f and the isosceles triangle shape 128g, the premixed gas flowing out from the premixed air swirler cylinder 141 is separated from the bell shape portion 128f. It changes smoothly along the equilateral triangular shape 128g.

  As described above, according to the gas turbine combustor of the ninth embodiment, the stagnation eliminating structure 128D has a bell-shaped portion 128f on the upstream side and an isosceles triangular portion 128g on the downstream side. Since the flow direction of the premixed gas smoothly changes in the bell-shaped portion 128f and the isosceles triangular portion 128g of the stagnation-excluding structure 128D, the flow velocity of the premixed gas is reduced. The degree can be reduced, and the premixed gas can be prevented from being separated from the side surfaces 128d and 128e of the downstream end portion at the downstream end portion of the stagnation eliminating structure 128D.

<Embodiment 10>
A premixed combustion type gas turbine combustor according to Embodiment 10 of the present invention will be described with reference to FIG.

The gas turbine combustor of the tenth embodiment is the same as the gas turbine combustor of the sixth embodiment (FIGS. 17 to 20), except for the stagnation eliminating structure 128A. Other configurations are the same as those of the gas turbine combustor of the sixth embodiment.
Therefore, here, the stagnation eliminating structure 128E will be described, and description and illustration of the overall configuration of the gas turbine combustor will be omitted (see FIGS. 17 to 20).
Further, in the configuration of the stagnation-excluding structure 128E shown in FIG. 28, portions corresponding to the configuration of the stagnation-excluding structure 128A shown in FIG.

  The stagnation-excluding structure 128E in the tenth embodiment also fills the region between the adjacent premixing burner holes 127b in the same manner as the stagnation-excluding structure 128A in the sixth embodiment, and goes toward the downstream side. Therefore, it has a cross-sectional shape that makes the width narrower. Based on FIG. 28, the configuration of the stagnation-excluding structure 128E will be described in detail.

  As shown in FIGS. 28 (a) and 28 (b), the stagnation-excluding structure 128E is generally triangular in shape like the stagnation-excluding structure 128A, and has five surfaces, that is, an upstream surface 128a, It has an outer peripheral surface 128b, an inner peripheral surface 128c, one side surface 128d, and the other side surface 128e.

A surface 128a on the upstream side of the stagnation exclusion structure 128E in accordance with the shape of the region between the adjacent premix burner holes 127b is compared to the radial central portion of the combustor inner cylinder 122 (substrate 127). The outer portion and the inner portion have a wider width (width in the left-right direction in FIG. 28B).
The outer peripheral surface 128b of the stagnation-excluding structure 128E is curved along the outer guide ring 130, and the inner peripheral surface 128c of the stagnation-excluding structure 128E is curved along the inner guide ring 129.

  As shown in FIGS. 28 (c) to 28 (e), the cross-sectional shape of the stagnation-excluding structure 128E (the cross-sectional shape along the flow direction of the premixed gas from upstream to downstream) is the stagnation-excluding structure. The central portion (FIG. 28 (d)) in the radial direction of the object 128E has a bell-shaped portion 128f on the upstream side and an isosceles triangular portion 128g on the downstream side. The outer portion (FIG. 28C) and the radially inner portion (FIG. 28E) have a bell shape with a pointed downstream side. In this case, the cross-sectional shape of the stagnation-excluding structure 128E is continuously deformed from a shape having a bell shape portion 128f and an isosceles triangle shape portion 128g from the central portion toward the outer portion and the inner portion, to a bell shape. doing. However, the present invention is not limited to this, and it may be changed from a shape having a bell-shaped portion 128f and an isosceles triangular portion 128g to a bell-shaped shape at an intermediate position in the radial direction.

  As described above, according to the gas turbine combustor of the tenth embodiment, the end surface 128a on the upstream side of the stagnation-excluding structure 128E has an outer portion and a central portion in the radial direction of the stagnation-excluding structure 128E. The width of the inner portion is wider, and the cross-sectional shape of the stagnation-excluding structure 128E is a shape having a bell-shaped portion 128f on the upstream side and an isosceles triangular portion 128g on the downstream side in the central portion, Since the outer portion and the inner portion have a bell shape, the bell portion and the isosceles triangle portion are also provided on the outer portion and the inner portion of the wide squeeze eliminating structure 128E. In comparison, the length in the flow direction of the premixed gas in the outer part and the inner part can be shortened. For this reason, the stagnation exclusion structure 128E can be easily disposed on the upstream side of the downstream ends of the outer and inner guide rings 129 and 130.

<Embodiment 11>
A premixed combustion type gas turbine combustor according to Embodiment 11 of the present invention will be described with reference to FIG.

The gas turbine combustor according to the eleventh embodiment is the same as the gas turbine combustor according to the sixth embodiment (FIGS. 17 to 20) except for the stagnation eliminating structure 128A shown in FIG. Other configurations are the same as those of the gas turbine combustor of the sixth embodiment.
Accordingly, the stagnation eliminating structure 128F will be described here, and the description and illustration of the overall configuration of the gas turbine combustor will be omitted (see FIGS. 17 to 20).
In addition, in the configuration of the stagnation-excluding structure 128F shown in FIG. 29, portions corresponding to the configuration of the stagnation-excluding structure 128A shown in FIG.

  The stagnation eliminating structure 128F in the eleventh embodiment also fills the region between the adjacent premixing burner holes 127b in the same manner as the stagnation eliminating structure 128A in the sixth embodiment, and goes toward the downstream side. Therefore, it has a cross-sectional shape that makes the width narrower. The configuration of the stagnation-excluding structure 128F will be described in detail based on FIG.

  As shown in FIGS. 29 (a) and 29 (b), the stagnation-excluding structure 128F is generally triangular prism-like like the stagnation-excluding structure 128A, and has five surfaces, that is, an upstream surface 128a, It has an outer peripheral surface 128b, an inner peripheral surface 128c, one side surface 128d, and the other side surface 128e.

A surface 128a on the upstream side of the stagnation exclusion structure 128F in accordance with the shape of the region between the adjacent premix burner holes 127b is compared with the radial center portion of the combustor inner cylinder 122 (substrate 127). The outer portion and the inner portion have a wider width (width in the left-right direction in FIG. 29B).
The outer peripheral surface 128b of the stagnation-excluding structure 128F is curved along the outer guide ring 130, and the inner peripheral surface 128c of the stagnation-excluding structure 128F is curved along the inner guide ring 129.

  29C to 29E, the cross-sectional shape of the stagnation-excluding structure 128F (the cross-sectional shape along the flow direction of the premixed gas from the upstream to the downstream) is the stagnation-excluding structure. The downstream side of the radially central portion (FIG. 29 (d)), the radially outer portion (FIG. 29 (c)), and the radially inner portion (FIG. 29 (e)) of the article 128F is It has a sharp bell shape.

  The stagnation-excluding structure 128F has a plurality of hollow holes 128h. The downstream side of the hollow hole 128h is closed (not opened) in a normal state in which the downstream end of the stagnation exclusion structure 128F is not missing. On the other hand, the upstream side of the hollow hole 128h communicates with a hollow hole air hole 127e provided in the substrate 127 so as to correspond to each of the hollow holes 128h.

Further, as shown in FIG. 29 (f), a space portion 128i is provided in the upstream portion of the stagnation-excluding structure 128F, and the hollow hole 128h of the stagnation-excluding structure 128F is provided via the space portion 128i. You may comprise so that it may connect with the air hole 127e for hollow holes provided in the board | substrate 127. FIG. In this case, the number of air holes 127e provided in the substrate 127 may be one as shown in the figure, or a plurality of air holes 127e.
In addition, as shown in FIG. 29 (g), another structure example is shown, in which a stagnation-excluding structure 128F is formed of a porous portion 128j formed of a porous material (such as a porous metal), and the surface of the porous portion 128j. It is good also as a structure which has the coating part 128k which covered. The coating part 128k is formed by coating with a coating material (such as a metal that is not porous) and closes the hole of the porous part 128i. On the other hand, on the upstream side of the stagnation eliminating structure 128F, the hole of the porous portion 128j communicates with the air hole 127e for the porous portion provided in the substrate 127.

In the above description, the hollow hole 128h is provided in the stagnation-excluding structure 128F having a bell-shaped cross section. However, the present invention is not limited to this, and the stagnation-excluding structure having other cross-sectional shapes, for example, FIGS. A hollow hole may be provided in the stagnation-excluding structures 128A, 128C, 128D, 128E having a cross-sectional shape as shown in FIGS.
In the above description, the porous portion 128i and the coating portion 128 are provided in the stagnation-excluding structure 128F having a bell-shaped cross section. However, the present invention is not limited to this. The stagnation-excluding structures 128A, 128C, 128D, and 128E having cross-sectional shapes as shown in FIGS. 21, 25, 27, and 28 may be provided with a porous portion and a coating portion.

  As described above, according to the gas turbine combustor of the eleventh embodiment, the stagnation removing structure 128F has the hollow hole 128h, and the downstream side of the hollow hole 128h is closed, while the hollow hole 128h. The stagnation-excluding structure 128F has a porous portion 128j and a coating portion 128k covering the surface of the porous portion 128j. The upstream side of the substrate 127 communicates with an air hole 127e provided in the substrate 127. Since the hole of the porous portion 128j communicates with the air hole 127e provided in the substrate 127, when the downstream end portion of the stagnation-excluding structure 128 is lost due to burning or the like, it is opened by the loss. Air (air compressed by a compressor) is ejected from the hollow holes 128h or the holes of the porous portion 128j. For this reason, it can prevent that the flow of the premixed gas stagnates in the said defect | deletion part and a backfire phenomenon is induced.

  In the sixth to eleventh embodiments, the case where the stagnation-excluding structure is applied to the configuration in which the premix burner holes of the substrate are rectangular and the corners are rounded is described, but the present invention is limited to this. Rather, the premixing burner hole of the substrate has other configurations, for example, a circular shape as shown in FIG. 3 or a rectangular shape without rounded corners. Can be applied. That is, the region may be filled with a stagnation eliminating structure having an upstream surface having a shape corresponding to the shape of the region between adjacent premix burner holes.

  The present invention relates to a premixed combustion type gas turbine combustor, which promotes premixing of air and fuel such as air film and substrate air, reduces the amount of substrate air, and premix burner holes adjacent to the substrate. It is useful when applied to prevent the occurrence of stagnation of the premixed gas flow in the intervening region.

31 Gas turbine combustor 32 Combustor inner cylinder 33 Combustor tail cylinder 34 Combustion chamber 35 Premix burner (main burner)
36 Pilot burner 37 Substrate 37a Air hole 37b Pilot burner hole 37c Premix burner hole 37d Downstream surface 37e Outside area (triangular zone)
37f Inner area (triangular zone)
38 Inner guide ring 38a Upstream end portion 38b Downstream end portion 39 Outer guide ring 39a Upstream end portion 39b Downstream end portion 41 Pilot air swirler cylinder 42 Pilot nozzle 42a Fuel injection hole 43 Flame stabilizer 43a Back step surface 44 Pilot cone 45 Pilot air swirler vane 51 Premixed air swirler cylinder 51a Downstream end 52 Premixed nozzle 53 Premixed air swirler vane 53a Fuel injection hole 54 Extension pipe 54a Upstream end 54b Downstream end 55 Bolt 56 Air flow path 57 Primary premixing region 61 Gas turbine combustor 71 Gas turbine combustor 72 Outer padding 72a Downstream end 72b Upstream end surface 72c, 72d, 72e Side 72f Outer surface 72g, 72h Angle 72i, 72j Side 72k Side 72 Corner 72n side 72o side surface 73 inner padding 73a downstream end 73b upstream end surface 73c, 73d, 73e side 73f inner surface 73g, 73h corner 73i, 73j side 73k side 73m corner 73n side 73o side cylinder 74 75 Second premix region 76 Air flow path 81 Gas turbine combustor 82 Inner padding 82a Downstream end surface 82b Upstream end surface 82c, 82d, 82e Side 82f Inner surface 82g, 82h Angle 82i, 82j Side 82k Side 82m square 82n side 82o side surface 82p, 82q, 82r side 83 secondary premixing region 91 gas turbine combustor 92 combustor inner cylinder 93 combustor tail cylinder 94 combustion chamber 95 premix burner (main burner)
96 Pilot burner 97 Pilot air swirler vane 98 Pilot air swirler cylinder 99 Pilot nozzle 99a Fuel injection hole 100 Pilot cone 101 Flame holder 101a Back step surface 102 Premixing nozzle 103 Premixed air swirler vane 103a Fuel injection hole 111 Annular flow path 111a Premixing Area 112 Premixed burner inner cylinder 121 Gas turbine combustor 122 Combustor inner cylinder 123 Combustor tail cylinder 124 Combustion chamber 125 Premix burner (main burner)
126 Pilot burner 127 Substrate 127a Pilot burner hole 127b Premix burner hole 127c Air hole 127d Area between adjacent premix burner holes 127e Air hole 128A, 128B, 128C, 128D, 128E, 128F Stagnation elimination structure 128a Upstream side Surface 128b outer peripheral surface 128c inner peripheral surface 128d, 128e side surface 128f bell-shaped portion 128g isosceles triangular portion 128h hollow hole 128i space portion 128j porous portion 128k coating portion 129 inner guide ring 129a upstream end portion 129b Downstream end portion 130 Outer guide ring 130a Upstream end portion 130b Downstream end portion 131 Pilot air swirler cylinder 132 Pilot nozzle 132a Fuel injection hole 133 Pilot air swirler vane 34 Pilot cone 135 Flame stabilizer 135a Back step surface 141 Premixed air swirler cylinder 141a Upstream portion 141b Downstream portion 141c Upstream end 141d Downstream end 142 Premixing nozzle 143 Premixed air swirler vane 143a Fuel injection hole 144 Flow Road cylinder 145 Air flow path 146 Second premixing zone

Claims (15)

With a pilot burner,
A plurality of premixing burners provided with a premixing nozzle and a premixing air swirler vane in the premixing air swirler cylinder, and arranged to surround the pilot burner;
A pilot burner hole, and a plurality of premix burner holes disposed so as to surround the pilot burner hole, and a substrate for supporting the pilot burner and the premix burner;
An extension pipe that communicates with the premixed air swirler cylinder via the premix burner hole and extends to the downstream side of the substrate is provided in the combustor inner cylinder,
The inside of the premixed air swirler cylinder and the inside of the extension pipe are primary premixing regions,
A configuration in which an air film flows from an air flow path formed between the premixed air swirler cylinder and the extension pipe to the inner peripheral surface of the extension pipe, and between the adjacent extension pipes from the air holes provided in the substrate A gas turbine combustor having either or both of a configuration for flowing substrate air to the region of
An outer guide ring located outside the extension pipe and having a downstream end extending downstream from the downstream end of the extension pipe; and a downstream end located inside the extension pipe and extending the extension pipe An inner guide ring extending downstream from the downstream end of the tube,
A space between the downstream end of the outer guide ring and the downstream end of the inner guide ring communicates with the extension pipe and is continuous in the entire circumferential direction. A gas turbine combustor which is a mixing region. The gas turbine combustor according to claim 1.
The gas turbine combustor, wherein the outer guide ring is a downstream end portion of the combustor inner cylinder. The gas turbine combustor according to claim 1 or 2,
The gas turbine combustor, wherein the width of the second premixing region becomes narrower toward the downstream side. With a pilot burner,
A plurality of premixing burners provided with a premixing nozzle and a premixing air swirler vane in the premixing air swirler cylinder, and arranged to surround the pilot burner;
A pilot burner hole and a plurality of premixing burner holes disposed so as to surround the pilot burner hole are provided, and the pilot burner and the substrate supporting the premixing burner are disposed in the combustor inner cylinder. It is provided in
The premixed air swirler cylinder is a first premixed area,
In a gas turbine combustor having a configuration in which an air film flows from an air flow path formed between the premixed air swirler cylinder and a flow path cylinder,
An outer padding that fills an outer region between the adjacent premix burner holes on the downstream surface of the substrate, and is narrowed toward the downstream tip, and downstream of the substrate An inner padding that fills the inner region between the adjacent premix burner holes on the side surface and has an inner padding that narrows toward the downstream tip; and
A space between the outer stuffing and the inner stuffing communicates with the premixed air swirler cylinder through the premixed burner hole and is continuous in the entire circumferential direction. A gas turbine combustor characterized in that it is a region. With a pilot burner,
A plurality of premixing burners provided with a premixing nozzle and a premixing air swirler vane in the premixing air swirler cylinder, and arranged to surround the pilot burner;
A pilot burner hole and a plurality of premixing burner holes disposed so as to surround the pilot burner hole are provided, and the pilot burner and the substrate supporting the premixing burner are disposed in the combustor inner cylinder. Provided in
The premixed air swirler cylinder is a first premixed area,
In a gas turbine combustor having a configuration in which an air film flows from an air flow path formed between the premixed air swirler cylinder and a flow path cylinder,
An outer padding that fills an outer region between the adjacent premix burner holes on the downstream surface of the substrate, and is narrowed toward the downstream tip, and downstream of the substrate The inner surface between the premixing burner holes adjacent to each other on the side surface is filled with the upstream end surface and extends to the downstream end surface, and the downstream end surface is the back step surface of the flame stabilizer. With stuffing
A space between the outer stuffing and the inner stuffing communicates with the premixed air swirler cylinder through the premixed burner hole and is continuous in the entire circumferential direction. A gas turbine combustor characterized in that it is a region. With a pilot burner,
In the gas turbine combustor having a premixing nozzle and a premixed air swirler vane, and a plurality of premixing burners disposed so as to surround the pilot burner in the inner cylinder of the combustor,
A premix burner inner cylinder is disposed inside the combustor inner cylinder, and an annular flow path that is a space between the combustor inner cylinder and the premix burner inner cylinder is continuous over the entire circumferential direction, The downstream portion of the annular channel is a premixing region,
The gas turbine combustor, wherein the premixing burner is disposed in the annular flow path, and the pilot burner is disposed inside the inner tube of the premixing burner. The gas turbine combustor according to claim 6.
The gas turbine combustor, wherein the width of the premixing region is narrowed toward the downstream side. With a pilot burner,
A plurality of premixing burners provided with a premixing nozzle and a premixing air swirler vane in the premixing air swirler cylinder, and arranged to surround the pilot burner;
A pilot burner hole, and a plurality of premix burner holes disposed so as to surround the pilot burner hole, the pilot burner and a substrate supporting the premix burner;
In the gas turbine combustor in which the premixed air swirler cylinder is a first premixed region,
The downstream surface of the substrate has a stagnation-excluding structure that fills a region between adjacent premix burner holes,
And the cross-sectional shape of the stagnation-excluding structure has a narrower width toward the downstream side,
An outer guide ring positioned outside the stagnation-excluding structure, and an inner guide ring positioned inside the stagnation-excluding structure;
A space between the outer guide ring and the inner guide ring communicates with the premixed air swirler cylinder via the premixed burner hole and is continuous in the entire circumferential direction. A gas turbine combustor which is a premixing region. The gas turbine combustor according to claim 8.
A gas turbine combustor having a configuration in which an air film is caused to flow from an air flow path formed between the premixed air swirler cylinder and a flow path cylinder. The gas turbine combustor according to claim 8 or 9,
The gas turbine combustor characterized in that a cross-sectional shape of the stagnation-excluding structure is an isosceles triangle. The gas turbine combustor according to claim 8 or 9,
The gas turbine combustor characterized in that a cross-sectional shape of the stagnation-excluding structure is a bell shape. The gas turbine combustor according to claim 8 or 9,
The upstream end face of the stagnation-excluding structure is wider at the outer part and the inner part than the radial central part of the stagnation-excluding structure,
The gas turbine combustor according to claim 1, wherein a cross-sectional shape of the stagnation-excluding structure is a bell shape at the central portion and isosceles triangle shape at the outer portion and the inner portion. The gas turbine combustor according to claim 8 or 9,
The gas turbine combustor characterized in that the cross-sectional shape of the stagnation eliminating structure has a bell-shaped portion on the upstream side and an isosceles triangular portion on the downstream side. The gas turbine combustor according to claim 8 or 9,
The upstream end face of the stagnation-excluding structure is wider at the outer part and the inner part than the radial central part of the stagnation-excluding structure,
The cross-sectional shape of the stagnation-excluding structure is such that the central portion has a bell-shaped portion on the upstream side and an isosceles triangular portion on the downstream side, and the outer portion and the inner portion have a bell-shaped shape. A gas turbine combustor. The gas turbine combustor according to any one of claims 8 to 14,
The stagnation-excluding structure has a hollow hole, and the downstream side of the hollow hole is closed, while the upstream side of the hollow hole communicates with an air hole provided in the substrate.
Alternatively, the stagnation-excluding structure has a porous portion and a coating portion that covers the surface of the porous portion, and the holes of the porous portion communicate with air holes provided in the substrate. A gas turbine combustor.

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