The present invention relates to a cooling structure of a gas turbine combustor.
There is a demand of effective cooling means for a combustor for a gas turbine since the gas turbine combustor arises to a high temperature. In addition, there is another demand of a combustor that can reduce NOx for environment problem.
In Japanese Patent Application Publication (JP-P2005-315457A: first conventional example), a cooling structure of a gas turbine combustor is shown in FIGS. 3 to 6, in particular.
It is an object of the present invention to provide a gas turbine combustor capable of reducing NOx.
It is another object of the present invention to provide a technique suitable to efficiently cool a wall surface of a gas turbine combustor.
A gas turbine combustor according to one aspect of the present invention includes a combustion tube having an inner wall surface facing a combustion zone and an outer wall surface. A plurality of cooling passages are formed between the inner wall surface and the outer wall surface. The plurality of cooling passages includes a plurality of main coolant supply openings on an inner wall side, respectively. The gas turbine combustor further includes a guide guiding coolant supplied from the plurality of main coolant supply openings to a direction along the inner wall surface.
According to one embodiment of the present invention, the guide guides the coolant in a downstream direction from a position of a nozzle supplying fuel toward a tail tube connected to the combustion tube on an axial of the combustion tube.
According to one embodiment of the present invention, the plurality of main coolant supply openings supply the coolant into an inside of the combustion tube in a radial direction.
According to one embodiment of the present invention, the plurality of main coolant supply openings are provided on downstream ends of the plurality of cooling passages in a flow direction of the coolant, respectively.
According to one embodiment of the present invention, the gas turbine combustor further includes a plurality of auxiliary coolant supply openings supplying the coolant in a region outside of the outer wall surface into a gap formed between the inner wall surface and the guide. The coolant supplied from the plurality of auxiliary coolant supply openings is guided to the direction along the inner wall surface by the guide. The plurality of main coolant supply openings and the plurality of auxiliary coolant supply openings are formed in positions shifted from one another in a flow direction of the coolant guided by the guide.
The gas turbine combustor according to one embodiment of the present invention further includes a spacer preventing the gap from narrowing. The spacer is arranged downstream of the plurality of auxiliary coolant supply openings in the flow direction of the coolant supplied from the plurality of auxiliary coolant supply openings. The plurality of main coolant supply ports are arranged downstream of the spacer.
The gas turbine combustor according to one embodiment of the present invention further includes a spacer preventing the gap from narrowing. The spacer is arranged downstream of the plurality of main coolant supply openings in the flow direction of the coolant supplied from the plurality of main coolant supply openings. The plurality of auxiliary coolant supply openings are arranged downstream of the spacer.
The gas turbine combustor according to one embodiment of the present invention further includes a cavity to which the plurality of auxiliary coolant supply openings are opened. The coolant supplied from the coolant supply openings is supplied to the gap via the cavity. A flow rate of the coolant in the cavity is lower than a flow rate of the coolant in the gap.
According to one embodiment of the present invention, the combustion tube includes a bulge section. The bulge section is arranged upstream of a predetermined position set upstream of the plurality of main coolant supply openings in a main flow direction of the fuel in the combustion zone, and projects into the side opposite to the combustion region. The guide is substantially flat in the main flow direction near the predetermined position. The cavity is formed in a region between the inner wall surface and the guide in the bulge section. The gap is formed by a region between the inner wall surface downstream of the predetermined position in the main flow direction and the guide.
The present invention provides the gas turbine combustor capable of reducing NOx. Furthermore, the present invention provides technique adapted to efficiently cool a tube wall of a gas turbine combustor.
Hereinafter, embodiments of the present invention will be described with reference to the attached drawings.
First Embodiment
The side of the combustion zone 8 of the coolant supply opening 24 is covered with a guide 25 via the gap 26. The guide 25 is a member fixed to the wall surface of the combustion tube 2. As shown in
The height of the gap 26 between the guide 25 and the inner wall surface 23 is assumed as Δ. The coolant supply opening 24 is assumed to be a circle having a diameter d. A length from a downstream end of the coolant supply opening 24 to a downstream end of the guide 25 in a direction parallel to the central axis 19 is assumed as D. It is preferable to satisfy Δ<d and D >d in order to form good film air.
During operation of the gas turbine, a compressor supplies compressed air to the wheel chamber 4. A part of the compressed air is supplied for combustion of the fuel in the combustion zone 8. The other part of the compressed air is introduced from the coolant inlet openings 21 into the cooling passages 22 by using a pressure difference. A temperature of a combustion wall is high since the combustion tube wall is in contact with the combustion zone 8. By making the air to flow through the cooling passages 22 as coolant, the combustion wall is cooled. The air passing through the cooling passages 22 is supplied from the coolant supply openings 24 to the gap 26. A flow direction of the air in each coolant supply opening 24 is a radially inward direction of a cross section perpendicular to a central axis of a cylindrical shape around the central axis 19. The guide 25 introduces the air supplied to the gap 26 in a direction along the inner wall surface 23. The inner wall surface 23 is subjected to film cooling by this air.
By this configuration, the air passing through the cooling passages 22 and used to cool the interior of the tube wall is collected and also used for the film cooling. By efficiently using the air for cooling (“cooling air”), the cooling air can be saved and the air resulting from the saving of the cooling air can be used as the air for combustion (“combustion air”). Through increase in the combustion air, NOx generation can be suppressed.
It is necessary to secure the film air of a predetermined flow rate in order to prevent flashback from occurring in the combustor 1 during gas firing using the gas as the fuel of the combustor 1 or to prevent oil fuel used during oil firing using oil as the fuel from remaining on the wall surface. If the air necessary for the film cooling is more than minimal cooling air necessary for cooling the tube wall by the cooling passages 22, more cooling air than the minimal air can flow through the cooling passages 22 and reliability of the combustor can be further improved. Even in this case, the combustion air does not decrease.
Moreover, in the process of using the air for cooling the tube wall, the temperature of the air rises and density thereof decreases. Due to this, as compared with direct supply of the air in a same amount from the wheel chamber, the flow rate of the film air is high and a dynamic pressure of the film can be increased, even if an area of each coolant supply opening 24 for the film cooling is the same. If the dynamic pressure of the film air is high, it is particularly possible to prevent the oil from remaining on the inner wall surface 23.
A cooling structure of the coolant inlet openings 21, the cooling passages 22, the coolant supply openings 24 and the guide 25 shown in
Second Embodiment
The gas turbine combustor according to a second embodiment of the present invention differs from that of the first embodiment in a configuration of a wall surface near a location of the combustion tube 2 in which the main nozzles 14 are provided.
During driving of a gas turbine, the compressed air of the wheel chamber is introduced into the combustion tube 2 via the coolant inlet openings 21, the cooling passages 22 and the coolant supply openings 24. The guide 25 supplies the compressed air into a region along the inner wall surface 23 on the downstream side. A film formed by this air has a spotted distribution resulting from a pitch of the cooling passages 22. Each of the auxiliary coolant supply openings 28 supplies auxiliary film air into a region in which a density of the film air supplied from each coolant supply opening 24 is low and can make flow rate variation uniform at an outlet of the film. Since the uniform film can be formed, it is possible to realize a high film efficiency and prevent flashback and residence of oil.
Such a configuration is particularly suited in a case that an amount of the cooling air collected as the film air from the cooling passages 22 is smaller than an amount necessary as the film air. The air added as the film is air necessary for the film and the air in an excessive amount is unnecessary. Since a part of the film air is the air recycled after collecting the air used for cooling a combustor wall, the cooling air can be saved. Thus, it is possible to secure the combustion air and reduce NOx.
Third Embodiment
The gas turbine combustor according to a third embodiment of the present invention differs from that of the second embodiment in a configuration that a spacer member is provided between a wall surface of the combustion tube 2 and the guide 25.
The coolant supply openings 24 are arranged downstream of the respective spacers 29. The auxiliary coolant supply openings 28 are arranged upstream of the respective spacers 29. “Upstream” and “downstream” are defined herein according to a main flow direction of coolant supplied from the auxiliary coolant supply openings 28 in the gap 26. The spacers 29 and the coolant supply openings 24 are arranged at positions staggered from the auxiliary coolant supply openings 28 by a half-pitch in a direction perpendicular to a flow direction of cooling air supplied from the auxiliary coolant supply openings 28.
During operation of the gas turbine, the spacers 29 keep a slot height of a gap 25 constant. The compressed air of the wheel chamber is supplied to the gap 26 from the auxiliary coolant supply openings 28. The guide 25 introduces the supplied air into a region along the inner wall surface 23. Auxiliary film air formed by the auxiliary coolant supply openings 28 has a low flow rate on a downstream side of the spacers 29. Film air formed by the air supplied from the coolant supply openings 24 and direction-changed by the guide 25 is supplied to a region downstream of the spacers 29. By this configuration, uniform film air can be formed even if the spacers 29 keeping a slot height of the gap 26 constant are provided.
In a modification of the third embodiment, the same advantages can be obtained by arranging the coolant supply openings 24 and the auxiliary coolant supply openings 28 at opposite positions to those according to the third embodiment. The gas turbine combustor according to the modification of the third embodiment is configured so that the spacers 29 are arranged between the coolant supply openings 24a and the auxiliary coolant supply openings 28a shown in
It is preferable to arrange the spacers 29 at positions close to a downstream end of the gap 26 so that the spacers 29 can keep a slot height of the gap 26 constant. Thus, the gas turbine combustor is preferably configured so that either the auxiliary coolant supply openings 28 (corresponding to the third embodiment) or the coolant supply openings 24a (corresponding to the modification of the third embodiment) are arranged upstream of the spacers 29.
Fourth Embodiment
The gas turbine combustor according to a fourth embodiment of the present invention differs from that of the second embodiment in that the gas turbine combustor includes a cavity for reducing a flow rate of auxiliary coolant directly supplied from the wheel chamber.
Both of the air supplied from the coolant supply openings 24 and the air supplied from the auxiliary coolant supply openings 28 are supplied by using a pressure difference between the wheel chamber 4 and the combustion zone 8. A flow rate of the air supplied from the coolant supply openings 24 is low since the air passes through the cooling passages 22. On the other hand, a flow rate of the air supplied from the auxiliary coolant supply openings 28 is high since the air is directly supplied from the wheel chamber 4. As a result, the air supplied as a film has a flow rate variation. By providing the cavity 30, it is possible to reduce the flow rate of the air supplied from the auxiliary coolant supply openings 28 and form a uniform film air.
This application is based upon Japanese Patent Application No. 2007-247224 filed on Sep. 25, 2007. The disclosure thereof is incorporated herein by reference.
Number | Date | Country | Kind |
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2007-247224 | Sep 2007 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2008/067188 | 9/24/2008 | WO | 00 | 3/2/2010 |