WO2011024242A1 - 分割環冷却構造およびガスタービン - Google Patents
分割環冷却構造およびガスタービン Download PDFInfo
- Publication number
- WO2011024242A1 WO2011024242A1 PCT/JP2009/004990 JP2009004990W WO2011024242A1 WO 2011024242 A1 WO2011024242 A1 WO 2011024242A1 JP 2009004990 W JP2009004990 W JP 2009004990W WO 2011024242 A1 WO2011024242 A1 WO 2011024242A1
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- WIPO (PCT)
- Prior art keywords
- cooling
- flow path
- split ring
- cavity
- combustion gas
- Prior art date
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Classifications
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F01—MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
- F01D—NON-POSITIVE DISPLACEMENT MACHINES OR ENGINES, e.g. STEAM TURBINES
- F01D25/00—Component parts, details, or accessories, not provided for in, or of interest apart from, other groups
- F01D25/08—Cooling; Heating; Heat-insulation
- F01D25/12—Cooling
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F01—MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
- F01D—NON-POSITIVE DISPLACEMENT MACHINES OR ENGINES, e.g. STEAM TURBINES
- F01D11/00—Preventing or minimising internal leakage of working-fluid, e.g. between stages
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F01—MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
- F01D—NON-POSITIVE DISPLACEMENT MACHINES OR ENGINES, e.g. STEAM TURBINES
- F01D11/00—Preventing or minimising internal leakage of working-fluid, e.g. between stages
- F01D11/08—Preventing or minimising internal leakage of working-fluid, e.g. between stages for sealing space between rotor blade tips and stator
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F01—MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
- F01D—NON-POSITIVE DISPLACEMENT MACHINES OR ENGINES, e.g. STEAM TURBINES
- F01D11/00—Preventing or minimising internal leakage of working-fluid, e.g. between stages
- F01D11/08—Preventing or minimising internal leakage of working-fluid, e.g. between stages for sealing space between rotor blade tips and stator
- F01D11/14—Adjusting or regulating tip-clearance, i.e. distance between rotor-blade tips and stator casing
- F01D11/20—Actively adjusting tip-clearance
- F01D11/24—Actively adjusting tip-clearance by selectively cooling-heating stator or rotor components
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F02—COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
- F02C—GAS-TURBINE PLANTS; AIR INTAKES FOR JET-PROPULSION PLANTS; CONTROLLING FUEL SUPPLY IN AIR-BREATHING JET-PROPULSION PLANTS
- F02C7/00—Features, components parts, details or accessories, not provided for in, or of interest apart form groups F02C1/00 - F02C6/00; Air intakes for jet-propulsion plants
- F02C7/28—Arrangement of seals
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F05—INDEXING SCHEMES RELATING TO ENGINES OR PUMPS IN VARIOUS SUBCLASSES OF CLASSES F01-F04
- F05D—INDEXING SCHEME FOR ASPECTS RELATING TO NON-POSITIVE-DISPLACEMENT MACHINES OR ENGINES, GAS-TURBINES OR JET-PROPULSION PLANTS
- F05D2240/00—Components
- F05D2240/80—Platforms for stationary or moving blades
- F05D2240/81—Cooled platforms
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F05—INDEXING SCHEMES RELATING TO ENGINES OR PUMPS IN VARIOUS SUBCLASSES OF CLASSES F01-F04
- F05D—INDEXING SCHEME FOR ASPECTS RELATING TO NON-POSITIVE-DISPLACEMENT MACHINES OR ENGINES, GAS-TURBINES OR JET-PROPULSION PLANTS
- F05D2260/00—Function
- F05D2260/20—Heat transfer, e.g. cooling
- F05D2260/201—Heat transfer, e.g. cooling by impingement of a fluid
Definitions
- the present invention relates to a cooling structure for a split ring of a gas turbine and a gas turbine.
- FIG. 11 is a cross-sectional view showing the internal structure of the turbine portion of the gas turbine.
- the gas turbine supplies the combustion gas FG generated by the combustor 3 to the turbine stationary blade 7 and the turbine rotor blade 8, and rotates the turbine rotor blade 8 around the rotating shaft 5 to convert the rotational energy into electric power.
- the turbine stationary blades 7 and the turbine rotor blades 8 are alternately arranged from the upstream side to the downstream side in the flow direction of the combustion gas FG.
- a plurality of turbine rotor blades 8 are arranged in the circumferential direction of the rotating shaft 5 and rotate integrally with the rotating shaft 5.
- the turbine stationary blade 7 is disposed, and a plurality of turbine stationary blades 7 are disposed in the circumferential direction of the rotating shaft 5 similarly to the turbine rotor blade 8.
- a split ring 60 is annularly arranged on the outer peripheral side of the turbine rotor blade 8, and a constant gap is provided between the split ring 60 and the turbine rotor blade 8 in order to avoid mutual interference.
- FIG. 12 is a cross-sectional view around a conventional split ring.
- the split ring 60 is formed of a plurality of split bodies 61 and is annularly arranged in the circumferential direction of the rotating shaft 5.
- the divided body 61 is supported by the passenger compartment 67 via the hook 62 and the heat shield ring 66 of the divided body 61.
- the collision plate 64 supported by the heat shield ring 66 includes a plurality of small holes 65.
- a plurality of cooling flow paths 63 are arranged in the axial direction of the rotating shaft 5.
- the cooling air CA that is a part of the bleed air of the compressor is supplied from the supply hole 68 of the passenger compartment 67 to each split body 61 of the split ring 60.
- the cooling air CA is jetted into a space surrounded by the collision plate 64 and the divided body 61 through the small hole 65 opened in the collision plate 64, and impingement cools the upper surface of the divided body 61.
- the cooling air CA after impingement cooling is jetted into the combustion gas space from the downstream end in the flow direction of the combustion gas of the divided body 61 (from the left side to the right side on the paper surface of FIG. 11) via the cooling flow path 63. In doing so, the divided body 61 is convectively cooled by the cooling air CA flowing through the cooling flow path 63.
- Patent Document 1 discloses a split ring including the above-described collision plate, and impingement-cooled cooling air is supplied to an opening disposed on the upper surface of the split ring (split body), and a cooling flow path (cooling) An example of cooling the split ring when it is discharged from the downstream end in the flow direction of the combustion gas FG of the split ring to the combustion gas space via the air hole) is shown.
- Patent Document 2 has a structure improved from Patent Document 2, and is a cooling in which a part of impingement cooled cooling air is jetted from the upstream end in the flow direction of the combustion gas of the split ring (split body) into the combustion gas space.
- a flow path first flow path
- most of the cooling air after impingement cooling has a cooling flow path (second flow path) that is jetted from the downstream end in the flow direction of the combustion gas to the combustion gas space. It is disclosed. This enhances the cooling of the split ring.
- the present invention has been made in view of the above-mentioned problems, and a cooling structure for a split ring and a gas turbine for the purpose of preventing the burnout of the split ring accompanying a high temperature of the combustion gas and improving the thermal efficiency by reducing the amount of cooling air
- the purpose is to provide.
- the split ring cooling structure of the present invention is formed from a plurality of annularly arranged divided bodies arranged in the circumferential direction, and the inner peripheral surface is maintained at a certain distance from the tip of the turbine rotor blade.
- a collision plate having a plurality of small holes, a cooling space surrounded by the collision plate and the main body of the divided body, A first cavity disposed upstream of the rotation direction of the combustion gas and orthogonal to the axial direction of the rotation shaft; and a first cooling flow communicating from the cooling space to the first cavity And a second cooling flow path communicating with the combustion gas space at the downstream end in the flow direction of the combustion gas of the divided body from the first cavity.
- the first cavity is provided at the upstream end of the split ring in the flow direction of the combustion gas, and the cooling air in the cooling space is supplied to the first cavity via the first cooling flow path. Furthermore, since the exhaust gas is discharged from the downstream end in the flow direction of the combustion gas to the combustion gas space via the second cooling flow path, the entire cooling flow path is lengthened, and the upstream side of the divided body having a severe heat load. Edge convection cooling is enhanced. Therefore, burning of the upstream end portion of the divided body due to the high-temperature combustion gas can be avoided.
- the split ring cooling structure of the present invention preferably includes a structure in which the first cooling flow path and the second cooling flow path are folded back in the axial direction of the rotating shaft in the first cavity.
- the entire cooling channel having a long channel length is provided. Is compactly accommodated in the main body of the split body, and the split ring can be miniaturized.
- a plurality of first cooling channels and second cooling channels are arranged in an annular shape with respect to the rotation direction of the rotation shaft, and are parallel to each other in the radial direction of the rotation shaft. It is desirable that they are arranged as follows.
- the first cooling flow path and the second cooling flow path are arranged so as to be parallel to each other, the distance between the adjacent cooling flow paths is maintained uniformly, and the upstream end portion And the cooling performance at the upstream end of the divided body is improved.
- the first cooling flow path is disposed to be inclined in the axial direction of the rotation axis with respect to the second cooling flow path.
- the cooling air supplied to the first cavity through the first cooling channel is ejected toward the bottom surface of the first cavity, and impingement cooling is performed on the bottom surface of the first cavity. Therefore, it is effective for cooling the upstream end of the divided body with severe heat load.
- the first cooling flow path is preferably shorter in length than the second cooling flow path, and is arranged on the upper surface side of the split body from the second cooling flow path.
- the first cooling channel is arranged on the upper surface side of the upstream end portion
- the second cooling channel is arranged on the lower surface side of the upstream end portion, so that the upstream side of the divided body Both the upper surface side and the lower surface side of the end portion are cooled, and the cooling performance of the upstream end portion of the divided body is improved.
- the hole diameter of the second cooling channel is smaller than the hole diameter of the first cooling channel.
- the pressure in the first cavity can be maintained high, the speed of the cooling air flowing through the second cooling flow path can be increased, and the cooling performance on the lower surface side of the divided body can be increased. improves.
- the hole pitch in the rotation direction of the rotation axis of the second cooling flow path is smaller than the hole pitch in the rotation direction of the rotation axis of the first cooling flow path.
- the second cooling flow path since the second cooling flow path has a smaller hole pitch in the rotation direction of the rotating shaft than the first cooling flow path, the cooling effect of the second cooling flow path is high, and the second cooling flow path is divided. Body cooling performance is improved.
- the third cooling flow path is arranged at the upstream side end portion in the rotational direction of the rotary shaft of the split body, and the upstream side end portion in the rotational direction of the rotary shaft of the split body. It is desirable that the cooling space communicates with the combustion gas space.
- the convective cooling of the upstream side end in the rotation direction of the rotating shaft of the divided body is enhanced.
- the fourth cooling flow path is arranged at the downstream side end portion in the rotation direction of the rotating shaft of the divided body, and the downstream side end in the rotation direction of the rotating shaft of the divided body. It is desirable to communicate with the combustion gas space from the cooling space.
- the side end portions on both the upstream side and the downstream side in the rotation direction of the rotating shaft of the divided body are cooled, so that the cooling performance of the divided body can be enhanced.
- the third cooling channel or the fourth cooling channel communicates with the first cavity via the second cavity or the third cavity.
- a part of the high-pressure cooling air supplied to the first cavity passes through the second cavity or the third cavity to the third cooling channel or the fourth cooling channel. Since it is supplied, the cooling performance of the third cooling channel or the fourth cooling channel near the upstream end is enhanced.
- the gas turbine of the present invention has the above-described split ring cooling structure.
- the amount of cooling air in the gas turbine is reduced, and the thermal efficiency of the gas turbine is improved.
- the cooling of the upstream end portion of the split ring is enhanced, and the burnout of the split ring is avoided.
- FIG. 1 shows an overall configuration of a gas turbine according to the present invention.
- FIG. 2 is a cross-sectional view of a main part of the split ring according to the first embodiment.
- FIG. 3 is a perspective view of the divided body according to the first embodiment.
- FIG. 4 is a plan view of the divided body shown in the first embodiment.
- FIG. 5 shows an AA cross-sectional view of the divided body shown in FIG. 6 shows a BB side view of the divided body shown in FIG.
- FIG. 7 is a cross-sectional view taken along the line CC of the divided body shown in FIG.
- FIG. 8 shows a CC cross-sectional view of the divided body shown in the first modification.
- FIG. 9 is a partial cross-sectional view of the upstream end portion of the divided body shown in the second embodiment.
- FIG. 10 is a plan view of the divided body shown in the third embodiment.
- FIG. 11 shows a cross-sectional structure of the turbine section.
- FIG. 12 is a cross-sectional view of the main part of the split ring shown in the conventional example.
- FIG. 1 is an overall configuration diagram of a gas turbine.
- the gas turbine 1 includes a compressor 2 that compresses combustion air, a combustor 3 that injects and burns fuel FL into the compressed air sent from the compressor 2, and generates combustion gas, and the combustor 3.
- the turbine part 4 which is located in the downstream of this, and is driven with the combustion gas which came out of the combustor 3, the generator 6, and the rotating shaft 5 which fastens the compressor 2, the turbine part 4, and the generator 6 integrally are main. It is a component.
- FIG. 2 shows a cross section of the main part of the split ring of the gas turbine.
- the split ring 10 is a constituent member of the turbine unit 4 supported by the casing 67, and includes a plurality of split bodies 11 that are arranged in the circumferential direction of the rotating shaft 5 and have an annular shape.
- the divided body 11 is disposed such that a certain gap is secured between the inner peripheral surface 11a of the divided body and the tip 8a of the rotor blade 8.
- the split ring 10 is made of, for example, a heat resistant nickel alloy.
- symbol 7 in a figure is a turbine stationary blade of the turbine part 4.
- the divided body 11 includes a main body (bottom plate) 12, a hook 13, and a collision plate 14 as main components.
- the divided body 11 is attached to the heat shield ring 28 via hooks 13 provided on the upstream side and the downstream side in the flow direction of the combustion gas FG, and supported by the vehicle compartment 67 via the heat shield ring 28.
- the divided body 11 includes a main body 12, a collision plate 14, hooks 13 disposed upstream and downstream in the flow direction of the combustion gas FG, and a direction substantially perpendicular to the axial direction of the rotary shaft 5 (of the rotary shaft 5).
- a cooling space (hereinafter referred to as “cooling space”) 29 surrounded by side end portions 18 and 19 (see FIG.
- the cooling space 29 is a space formed in the divided body 11 and in contact with the upper surface 12 a side of the main body 12 positioned on the back surface (outer circumferential surface) when viewed from the inner circumferential surface 11 a of the divided body 11.
- the collision plate 14 is installed above the cooling space 29.
- a large number of small holes 15 through which the impingement cooling cooling air CA passes are formed in the collision plate 14.
- a receiving space 30 into which the cooling air CA in the passenger compartment 67 is introduced through the supply hole 68 is disposed.
- the cooling air CA supplied into the receiving space 30 is ejected from the small hole 15 in a state where the whole pressure is equalized to substantially the same pressure, and impingement cools the lower surface of the cooling space 29 (the upper surface 12a of the main body 12).
- FIG. 3 shows a perspective view of the divided body 11.
- the combustion gas FG flows from the left side to the right side on the paper surface, and the rotation direction R of the rotation shaft 5 (rotation direction of the turbine blade) is a direction orthogonal to the axial direction of the rotation shaft.
- the divided body 11 is supported by the heat shield ring 28 via the hook 13.
- a collision plate 14 is fixed to the center of the divided body 11 with respect to the inner wall 12 b of the main body 12 of the divided body 11.
- the collision plate 14 has a shape in which the central portion 14a is recessed from the peripheral portion 14b. That is, since the main body 12 of the divided body 11 is placed at a temperature higher than that of the collision plate 14, the thermal expansion is larger than that of the collision plate 14 in the axial direction of the rotation shaft and the rotation direction R of the rotation shaft. Therefore, the collision plate 14 is pulled from the inner wall 12 b side of the main body 12, and thermal stress is generated in the collision plate 14.
- providing the concave portion in the central portion 14a of the collision plate 14 has the effect of increasing the flexibility of the entire collision plate and reducing the generated thermal stress. Even when the central portion 14a of the collision plate 14 is formed in a convex shape, the same effect is obtained. Note that it is desirable to provide the small holes 15 not only in the central portion 14a of the collision plate 14 but also in the peripheral portion 14b in order to effect impingement cooling uniformly over the entire upper surface 12a of the main body 12.
- FIG. 4 is a plan view of the divided body viewed from the collision plate side of the divided body 11 in the direction of the rotation axis.
- the first cavity 20 is disposed in the upstream end portion 16 on the upstream side in the flow direction of the combustion gas FG and in a direction substantially orthogonal to the axial direction of the rotating shaft 5.
- a cooling flow path (first cooling flow path) 21 that connects the cooling space 29 and the first cavity 20 is provided in the axial direction of the rotary shaft 5, and the flow direction of the combustion gas FG from the first cavity 20.
- a cooling flow path (second cooling flow path) 22 that opens to the downstream end 17 on the downstream side is disposed in the axial direction of the rotation shaft.
- the first cavity 20 serves as a manifold that connects the first cooling channel 21 and the second cooling channel 22 to each other.
- FIG. 5 shows a cross section (cross section AA) of the divided body shown in FIG. 4, and FIG. 6 shows a side view (cross section BB).
- FIG. 7 shows a cross section (cross section CC) of the divided body 11 as viewed from the axial direction of the rotating shaft 5.
- the structure of the first cooling channel 21 and the second cooling channel 22 will be described.
- the first cooling channel 21 and the second cooling channel. 22 is formed so as to penetrate the cross section of the main body 12 of the divided body 11 in the axial direction of the rotary shaft 5.
- the first cooling flow path 21 and the second cooling flow path 22 are in the vertical direction (the radial direction of the rotation shaft 5) when viewed from the axial direction of the rotation shaft 5. Are arranged in parallel at regular intervals so as to be arranged in a row.
- a plurality of cooling flow paths 21 and 22 are annularly arranged at a predetermined hole pitch with respect to the rotation direction R of the rotating shaft 5. . That is, at the upstream end 16 of the divided body 11, the first cooling flow path 21 and the second cooling channel are formed from the upstream side end 18 to the downstream side end 19 in the rotation direction R of the divided body 11.
- the flow paths 22 are arranged so as to overlap in two rows in the vertical direction.
- the first cooling flow path 21 and the second cooling flow path 22 are arranged at a predetermined hole pitch so that adjacent cooling flow paths are parallel to each other in the rotation direction R of the rotary shaft 5.
- the Furthermore, the first cooling flow path 21 and the second cooling flow path 22 are arranged so as to be parallel to each other in the axial direction of the rotating shaft 5.
- the portion excluding the upstream end portion 16 and the side end portions 18 and 19 extends along the lower surface 11 a of the divided body 11 from the first cavity 20 to the downstream end portion 17.
- a cooling channel (second cooling channel 22) disposed in the axial direction of the rotating shaft 5 is provided.
- the second cooling flow path 22 is arranged at the upstream end portion 16 so as to overlap the first cooling flow path 21 in the vertical direction when viewed from the axial direction of the rotary shaft 5, so that the combustion gas is left as it is. It extends to the downstream end 17 on the downstream side in the flow direction, and opens to the combustion gas space W at the downstream end surface 17a.
- the upstream end 16 of the divided body 11 is a portion of the divided body 11 that is sandwiched between the upstream end surface 16a and the upstream inner wall 12b of the main body 12 and below the mounting height of the collision plate 14.
- the downstream end 17 of the divided body 11 is a portion of the divided body 11 that is sandwiched between the downstream end surface 17 a and the inner wall 12 b on the downstream side of the main body 12 and below the mounting height of the collision plate 14.
- the first cooling channel 21 is folded at the first cavity 20 and connected to the second cooling channel 22. Since the structure is provided, a cooling channel having a long channel length can be selected with respect to the axial direction of the rotating shaft 5. That is, the first cooling flow path 21 is disposed in the divided body 11 close to the upper surface side of the upstream end portion 16 of the divided body 11. On the other hand, the first cooling channel 21 is folded back at the first cavity 20 and connected to the second cooling channel 22, and is divided closer to the lower surface side than the first cooling channel 21 at the upstream end 16. It arrange
- the cooling channel having a long channel length is It can be stored compactly in the main body of the divided body, and the divided body can be cooled efficiently.
- a third cooling passage 25 communicating from the cooling space 29 to the combustion gas space W is provided at the upstream side end 18 in the rotation direction R of the rotating shaft of the divided body 11.
- the third cooling channel 25 has one side communicating with the cooling space 29 and the other side opened to the combustion gas space W.
- the upstream end portion 16 and the downstream end portion 17 are formed with a second cavity 24 whose one side communicates with the cooling space 29 and the other side extends in the axial direction of the rotating shaft and whose end is blocked.
- a part of the third cooling flow path 25 communicates with the cooling space 29 via the second cavity 24.
- the fourth cooling flow path 27 at the side end 19 on the downstream side in the rotation direction R of the divided body 11 can also have the same configuration as the third cooling flow path 25. That is, the fourth cooling channel 27 has one side communicating with the cooling space 29 and the other side opened to the combustion gas space W. Further, at the upstream end portion 16 and the downstream end portion 17, a third cavity 26 is formed in which one side communicates with the cooling space 29 and the other side extends in the axial direction of the rotating shaft, and the end is closed. A part of the third cooling flow path 25 communicates with the cooling space 29 via the third cavity 26. Depending on the operating conditions of the gas turbine, the cooling flow path at the side end 19 on the downstream side in the rotation direction R of the divided body 11 may not be provided, and the convective cooling of the side end 19 may be omitted.
- the side end portion 18 is sandwiched between the upstream inner wall 12 c and the upstream end surface 18 a in the rotation direction R of the main body 12, and refers to a portion below the mounting height of the collision plate 14.
- the side end portion 19 is sandwiched between the inner wall 12c on the downstream side in the rotation direction R of the main body 12 and the downstream end surface 19a and refers to a portion below the mounting height of the collision plate 14.
- cooling air in this embodiment will be described below.
- a part of the cooling air CA supplied to the turbine unit 4 is supplied to the receiving space 30 via the supply hole 68.
- the cooling air CA is jetted into the cooling space 29 through the small holes 15 provided in the collision plate 14, and impingement cools the upper surface 12 a of the main body 12 of the divided body 11.
- Most of the cooling air CA after impingement cooling is provided at the upstream end 16 and is opened to the inner wall 12a on the upstream side in the flow direction of the combustion gas FG of the main body 12 of the divided body 11. , And flows in the direction opposite to the flow direction of the combustion gas FG, mainly convectively cools the upper surface side of the upstream end portion 16 and then blows out into the first cavity 20 once.
- the cooling air CA in the first cavity 20 is folded back in the first cavity 20, and the second air disposed below the first cooling flow path 21 in a cross-sectional view viewed from the axial direction of the rotating shaft 5. It is supplied to the cooling flow path 22. Further, the cooling air CA flows along the lower surface 11a of the divided body 11 toward the downstream end portion 17 of the divided body 11, mainly convectively cools the lower surface side of the divided body 11, and burns from the downstream end surface 17a. It is discharged into the gas space W. That is, since the folded structure as described above is provided, a cooling channel having a long channel length can be selected, which is effective for cooling the divided body.
- the pressure of the combustion gas FG around the divided body 11 changes along the flow direction.
- the pressure is highest near the upstream end face 16a on the upstream side in the combustion gas FG flow direction, and the pressure is lowest near the downstream end face 17a on the downstream side. That is, in the example shown in Patent Document 2, the cooling air CA from the cooling space 29 flows in the upstream end portion 16 toward the upstream side in the flow direction of the combustion gas FG, and from the upstream end surface 16a to the combustion gas space W. Therefore, a large differential pressure between the pressure of the cooling air CA in the cooling space 29 and the pressure of the combustion gas in the vicinity of the upstream end face 16a cannot be obtained. Therefore, in order to sufficiently cool the upstream end portion 16, it is necessary to flow a large amount of cooling air flowing in the first cooling flow path 21, which causes an increase in the amount of cooling air.
- the cooling air CA in the cooling space 29 is supplied to the first cavity 20 via the first cooling flow path 21 and is directly upstream. Instead of being discharged from the side end face 16 a into the combustion gas space W, it is folded back by the first cavity 20 and discharged to the downstream end face 17 a via the second cooling flow path 22. That is, the cooling air CA is discharged to the combustion gas space W at the downstream end surface 17a where the combustion gas pressure is the lowest, so that the pressure difference between the cooling air in the cooling space 29 and the combustion gas near the downstream end surface 17a is maximized. Therefore, compared with the examples of Patent Document 1 and Patent Document 2, the flow velocity in the cooling flow path can be increased, and the amount of cooling air can be significantly reduced.
- a part of the cooling air CA impingement cooled in the cooling space 29 passes through the third cooling channel 25 and the fourth cooling channel 27.
- the side ends 18 and 19 are convectively cooled.
- a part of the side end portions 18 and 19 temporarily supplies the cooling air CA introduced from the cooling space 29 to the second cavities 24 and 26, and then passes through the second cavities 24 and 26 to the third cavities. It is supplied to the cooling channels 25 and 27.
- the cooling air CA is discharged from the third cooling flow path 25 to the combustion gas space W, the side end portions 18 and 19 are convectively cooled.
- the cooling air supplied from the cooling space 29 to the second cavity 24 is supplied via the connection path 31, but like the third cavity 26, the cooling space is supplied.
- the method of introducing directly from 29 may be used.
- the cooling air for the purpose of convection cooling of the side end portions 18 and 19 supplies the high-pressure cooling air after impingement cooling to the third cooling flow path 25 and the fourth cooling flow path 27.
- the differential pressure between the cooling air and the combustion gas in the vicinity of the side end portion end faces 18a and 19a can be used, and is effective for cooling the side end portions.
- the longest cooling flow path length can be adopted with respect to the axial direction of the rotating shaft, and the differential pressure of the cooling air can be utilized to the maximum, so that it is most effective for cooling the divided body.
- the first cooling channel and the second cooling channel are arranged so as to overlap in the vertical direction, the first cooling channel is arranged on the upper surface side, and the second cooling channel is arranged on the lower surface side. Since the cooling flow path is arranged, the cooling performance at the upstream end is improved.
- the first cooling channel and the second cooling channel are arranged in parallel to each other in the vertical direction (the radial direction of the rotating shaft), and are parallel to the rotating direction R of the rotating shaft at the same hole pitch. Since the cooling channels are arranged at the same interval, the cooling channels are arranged at the same interval, the temperature distribution in the upstream end is reduced, and uniform cooling is possible.
- FIG. 8 shows an arrangement example different from the first embodiment regarding the first cooling channel and the second cooling channel.
- the first modification is the same as the first embodiment in that the cooling channels are annularly arranged with the same hole pitch with respect to the rotation direction R of the rotating shaft 5, but the second cooling is the same.
- the channel 22 is different in that a hole diameter smaller than that of the first cooling channel 21 is adopted. Further, the difference is that the hole pitch in the rotation direction R of the rotating shaft 5 of the second cooling channel 22 is larger than the hole pitch in the rotation direction R of the second cooling channel 22. If such hole diameters and hole pitches of the first cooling flow path 21 and the second cooling flow path 22 are adopted, a sufficient amount of cooling air supplied to the second cooling flow path is secured. Compared with the first embodiment, the cooling performance on the main body (bottom surface) side of the divided body is improved.
- the cooling of the main body of the divided body, particularly the upstream end portion 16 of the main body 12 is most problematic, but the second cooling flow path 22 contributes most to the cooling of the main body.
- the first cooling flow path 21 has a relatively larger hole diameter than the second cooling flow path 22 to reduce the pressure loss in the first cooling flow path, so that the inside of the first cavity 20 The cooling air pressure at is as high as possible.
- the second cooling channel 22 has a smaller diameter than the first cooling channel 21, and the hole pitch is made smaller.
- the pressure loss of the cooling air increases due to the small diameter, but the pressure in the first cavity 20 is maintained at a high pressure, and the differential pressure from the combustion gas side is maximized. Therefore, the cooling efficiency of the entire second cooling flow path is improved, and the cooling of the main body (bottom surface) 12 of the divided body is enhanced as compared with the first embodiment.
- FIG. 9 shows a partial cross section of the upstream end of the divided body according to the second embodiment.
- This embodiment is different from the first embodiment in that the first cooling flow path has an inclination in the axial direction of the rotation axis with respect to the second cooling flow path. Is the same as in the first embodiment.
- symbol as 1st Embodiment are used for the component which is common in 1st Embodiment, and detailed description is abbreviate
- the second cooling flow path 45 is arranged along the lower surface 11 a of the divided body 11 to the downstream end surface 17 a with respect to the axial direction of the rotation shaft 5, and with respect to the rotation direction R of the rotation shaft.
- annularly with the same hole pitch is the same as that of 1st Embodiment.
- the first cooling flow path 44 communicating with the first cavity 43 has an inclination in the axial direction of the rotary shaft 5 toward the upstream end face 16a, and at the angle ⁇ on the bottom face 43a of the first cavity 43. The intersection is different.
- both the 1st cooling flow path 44 and the 2nd cooling flow path 45 are the points where several cooling flow paths are cyclically
- the cooling air CA blown out from the cooling space 29 to the bottom surface 43 a of the first cavity 43 through the first cooling flow path 44 is impinged with respect to the bottom surface 43 a of the first cavity 43.
- the cooling of the upstream end 16 is enhanced as compared with the first embodiment.
- the cooling air CA introduced from the cooling space 29 flows down the first cooling flow path 44 having a downward inclination toward the upstream side end face 16a and reaches the first cavity 43.
- the upper surface side of the upstream end portion 16 is convectively cooled.
- the cooling air CA collides with the bottom surface 43 a of the first cavity 43, gives an impingement cooling effect to the bottom surface 43 a, and enhances cooling of the upstream end portion 16.
- the cooling air CA returning from the first cavity 43 flows toward the downstream side in the flow direction of the combustion gas FG via the second cooling flow path 45 and enters the combustion gas space W from the downstream end 17. Discharged. That is, in the case of the present embodiment, as shown in FIG. 9, the cooling air CA flowing in the first cooling flow path 44 is rotated by the first cooling flow path 44 relative to the second cooling flow path 45. By providing a downward inclination in the axial direction of the shaft 5 toward the bottom surface 43a of the first cavity 43, an impingement cooling effect is provided in the first cavity 43 as compared with the first embodiment. As a result, the cooling of the upstream end 16 is enhanced over the entire width of the divided body 11 in the rotation direction R, and the amount of cooling air in the divided ring can be further reduced.
- the same configuration as that of the first modification can be adopted. That is, the hole diameter of the second cooling channel 45 is made smaller than the hole diameter of the first cooling channel 44, and the hole pitch in the rotation direction R of the second cooling channel 45 is set to be the first cooling channel 44. The hole pitch in the rotation direction R can be made smaller.
- the cooling effect of the main body of the divided body can be improved. Can be increased. As a result, the amount of cooling air can be reduced as compared with the first embodiment, so that the thermal efficiency of the gas turbine is further improved.
- FIG. 10 is a plan view of a divided body according to the third embodiment. This embodiment is different from the first embodiment in the cooling structure of the side end portion of the split ring, but the other configuration is the same as that of the first embodiment.
- symbol as 1st Embodiment are used for the component which is common in 1st Embodiment, and detailed description is abbreviate
- the second cavity 24 and the third cavity 26 communicate with the first cavity 20 on the upstream side in the flow direction of the combustion gas, and the third cooling channel 25 and the fourth cavity are on the downstream side. It communicates with the cooling flow path 27. That is, in the present embodiment, the third cooling channel 25 and the fourth cooling channel 27 are not directly connected to the cooling space 29, and the first cavity 20, the second cavity 24, and the third cavity 26 are not connected. The point which is connected to the cooling space 29 via is different from the first embodiment.
- the cooling capacity in the vicinity of the upstream end portion 16 of the third cooling channel 25 and the fourth cooling channel 27 is enhanced as compared with the first embodiment. That is, the cooling air CA is supplied from the cooling space 29 to the first cavity 20 and is introduced from the first cavity 20 into the second cavity 24 and the third cavity 26. Further, when the cooling air CA is discharged from the second cavity 24 or the third cavity 26 to the combustion gas space W via the third cooling channel 25 or the fourth cooling channel 27, the side end 18 , 19 is convectively cooled.
- the upstream end 16 on the upstream side in the flow direction of the combustion gas is easily exposed to the high-temperature combustion gas.
- the cooling air flowing through the third cooling channel 25 or the fourth cooling channel 27 near the upstream end 16 of the side ends 18 and 19 It is desirable to increase the pressure to increase the flow rate.
- the cooling air flowing through the third cooling flow path 25 or the fourth cooling flow path 27 communicating with the second cavity 24 or the third cavity 26 has a limit in increasing its flow rate.
- the second cavity 24 and the third cavity 26 are directly connected to the first cavity 20 maintained at a high pressure, so that the pressure of the cooling air is near the upstream end portion 16. Kept at high pressure. Accordingly, the cooling air flowing through the third cooling flow path 25 or the fourth cooling flow path 27 in the vicinity of the upstream end portion 16 communicating with these maintains a high flow rate, and convection cooling is enhanced.
- the cooling of the side end is provided with only the third cooling channel connected to the first cavity via the second cavity, and the fourth cooling channel is installed. It does not have to be.
- the amount of cooling air used can be minimized, and the cooling efficiency and the cooling capacity of the split body 11 and the split ring 10 including the split body 11 can be further improved. Can do.
- this invention is not limited to embodiment mentioned above, In the range which does not deviate from the summary of this invention, it can change suitably.
- the split ring cooling structure of the present invention cooling of the upstream end portion of the split ring is strengthened, and burning of the split ring is avoided.
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Abstract
Description
本願は、2009年8月24日に米国に出願された米国特許出願番号61/236,310に基づいて優先権を主張し、その内容をここに援用する。
すなわち、本発明の分割環冷却構造は、周方向に配設されて環状をなす複数の分割体から形成され、内周面がタービン動翼の先端から一定の距離を保つようにして車室内に配設されるガスタービンの分割環を冷却する分割環冷却構造において、複数の小孔を備えた衝突板と、該衝突板と前記分割体の本体により囲まれた冷却空間と、前記分割体の燃焼ガスの流れ方向の上流側端部であって、回転軸の軸方向に直交するように配置された第1のキャビティと、前記冷却空間から前記第1のキャビティに連通する第1の冷却流路と、前記第1のキャビティから前記分割体の燃焼ガスの流れ方向の下流側端部において燃焼ガス空間に連通する第2の冷却流路とを含むことを特徴とする。
第1の実施形態について、図1から図7および図11に基づき以下に説明する。
図1は、ガスタービンの全体構成図である。ガスタービン1は、燃焼用空気を圧縮する圧縮機2と、圧縮機2から送られてきた圧縮空気に燃料FLを噴射して燃焼させ、燃焼ガスを発生させる燃焼器3と、この燃焼器3の下流側に位置し、燃焼器3を出た燃焼ガスにより駆動されるタービン部4と、発電機6と、圧縮機2とタービン部4と発電機6を一体に締結する回転軸5を主たる構成要素とする。
分割環10は、車室67に支持されたタービン部4の構成部材であって、回転軸5の周方向に配設されて環状をなす複数の分割体11で構成される。分割体11は、分割体の内周面11aと動翼8の先端8aの間に一定の隙間が確保されるように配置されている。分割環10は、たとえば耐熱性ニッケル合金等から形成されている。なお、図中の符号7は、タービン部4のタービン静翼である。
本実施形態の分割体11には、燃焼ガスFGの流れ方向の上流側の上流側端部16であって、回転軸5の軸方向に略直交する方向に第1のキャビティ20が配置されている。また、冷却空間29と第1のキャビティ20を連結する冷却流路(第1の冷却流路)21が回転軸5の軸方向に設けられ、第1のキャビティ20から燃焼ガスFGの流れ方向の下流側の下流側端部17に開口する冷却流路(第2の冷却流路)22が回転軸の軸方向に配置されている。第1のキャビティ20は、第1の冷却流路21と第2の冷却流路22を互いに連結するマニホールドの役割を果たしている。
図4に示すように、分割体11の回転軸の回転方向Rの上流側の側端部18には、冷却空間29から燃焼ガス空間Wに連通する第3の冷却流路25が、回転軸に略直交する方向に配列されている。第3の冷却流路25は、一方側が冷却空間29に連通し、他方側が燃焼ガス空間Wに開口している。また、上流側端部16および下流側端部17には、一方側が冷却空間29に連通し、他方側が回転軸の軸方向に延設して、末端が閉塞された第2のキャビティ24が形成され、第3の冷却流路25の一部は第2のキャビティ24を介して冷却空間29に連通している。
図8は、第1の冷却流路および第2の冷却流路に関して、第1の実施形態とは異なる配置例を示す。第1変形例は、第1の実施形態と比較して、回転軸5の回転方向Rに対して、同じ孔ピッチで冷却流路を環状に配置する点では同じであるが、第2の冷却流路22は、第1の冷却流路21より小さい孔径を採用している点が異なっている。また、第2の冷却流路22の回転軸5の回転方向Rの孔ピッチが、第2の冷却流路22の回転方向Rの孔ピッチより大きい点が異なっている。このような第1の冷却流路21および第2の冷却流路22の孔径および孔ピッチを採用すれば、第2の冷却流路に供給される冷却空気は、冷却に十分な量は確保され、第1の実施形態と比較して、分割体の本体(底面)側の冷却性能が向上する。
図9は、第2の実施形態に係わる分割体の上流側端部の部分断面を示している。
本実施形態は、第1の実施形態と比較して、第1の冷却流路が、第2の冷却流路に対して回転軸の軸方向に傾きを有する点が異なっており、その他の構成は第1の実施形態と同じである。なお、第1の実施形態と共通する構成要素は、第1の実施形態と同じ部品名称および符号を使用し、詳細説明は省略する。
図10は、第3の実施形態に係わる分割体の平面図を示す。
本実施形態は、第1の実施形態と比較して、分割環の分割体の側端部の冷却構造が異なっているが、他の構成は第1の実施形態と同じである。
なお、第1の実施形態と共通する構成要素は、第1の実施形態と同じ部品名称および符号を使用し、詳細説明は省略する。
2 圧縮機
3 燃焼器
4 タービン部
5 回転軸
6 発電機
7 タービン静翼
8 タービン動翼
10、40、50、60 分割環
11、41、51、61 分割体
12、42 本体
13 フック
14、64 衝突板
15、65 小孔
16 上流側端部(燃焼ガス流れ方向の上流側)
16a 上流側端面(燃焼ガス流れ方向の上流側)
17 下流側端部(燃焼ガス流れ方向の下流側)
17a 下流側端面(燃焼ガス流れ方向の下流側)
18 側端部(回転方向の上流側)
18a 側部端面(回転方向の上流側)
19 側端部(回転方向の下流側)
19a 側部端面(回転方向の下流側)
20、43 キャビティ(第1のキャビティ)
21、44 冷却流路(第1の冷却流路)
22、45 冷却流路(第2の冷却流路)
24 キャビティ(第2のキャビティ)
25 冷却流路(第3の冷却流路)
26 キャビティ(第3のキャビティ)
27 冷却流路(第4の冷却流路)
28 遮熱環
29 冷却空間
30 受入空間
31 連結路
66 遮熱環
67 車室
68 供給孔
R 回転軸の回転方向
W 燃焼ガス空間
CA 冷却空気
FG 燃焼ガス
FL 燃料
Claims (11)
- 周方向に配設されて環状をなす複数の分割体から形成され、内周面がタービン動翼の先端から一定の距離を保つようにして車室内に配設されるガスタービンの分割環を冷却する分割環冷却構造において、
複数の小孔を備えた衝突板と、
該衝突板と前記分割体の本体により囲まれた冷却空間と、
前記分割体の燃焼ガスの流れ方向の上流側端部であって、回転軸の軸方向に直交するように配置された第1のキャビティと、
前記冷却空間から前記第1のキャビティに連通する第1の冷却流路と、
前記第1のキャビティから前記分割体の燃焼ガスの流れ方向の下流側端部において燃焼ガス空間に連通する第2の冷却流路と、
を含むことを特徴とする分割環冷却構造。 - 前記第1の冷却流路と前記第2の冷却流路は、前記第1のキャビティにおいて、回転軸の軸方向に折り返す構造を備えていることを特徴とする請求項1に記載の分割環冷却構造。
- 前記第1の冷却流路と前記第2の冷却流路は、それぞれが回転軸の回転方向に対して環状に複数配列され、径方向に互いに平行となるように配列されていることを特徴とする請求項1または請求項2に記載の分割環冷却構造。
- 前記第1の冷却流路と前記第2の冷却流路は、それぞれが回転軸の回転方向に対して環状に複数配列され、前記第1の冷却流路は前記第2の冷却流路に対して回転軸の軸方向に傾斜して配置されていることを特徴とする請求項1または請求項2に記載の分割環冷却構造。
- 前記第1の冷却流路は、前記第2の冷却流路より長さが短く、前記分割体の燃焼ガスの流れ方向の上流側端部において、前記第2の冷却流路より前記分割体の本体の上面側に配置されていることを特徴とする請求項1から請求項4のいずれか1項に記載の分割環冷却構造。
- 前記第2の冷却流路の孔径が、前記第1の冷却流路の孔径より小さいことを特徴とする請求項1から請求項4のいずれか1項に記載の分割環冷却構造。
- 前記第2の冷却流路の回転軸の回転方向の孔ピッチが、前記第1の冷却流路の回転軸の回転方向の孔ピッチより小さいことを特徴とする請求項1から請求項6のいずれか1項に記載の分割環冷却構造。
- 前記分割体の回転軸の回転方向の上流側の側端部に配置され、前記冷却空間から該側端部において燃焼ガス空間に連通する第3の冷却流路を含むことを特徴とする請求項1から請求項4のいずれか1項に記載の分割環冷却構造。
- 前記分割体の回転軸の回転方向の下流側の側端部に配置され、前記冷却空間から該側端部において燃焼ガス空間に連通する第4の冷却流路を含むことを特徴とする請求項1から請求項4並びに請求項8のいずれか1項に記載の分割環冷却構造。
- 前記第3の冷却流路または前記第4の冷却流路は、第2のキャビティまたは第3のキャビティを介して、前記第1のキャビティに連通していることを特徴とする請求項8または請求項9に記載の分割環冷却構造。
- 請求項1から請求項4のいずれか1項に記載の分割環冷却構造を備えたガスタービン。
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CN200980158960.8A CN102414398B (zh) | 2009-08-24 | 2009-09-29 | 分割环冷却结构和燃气轮机 |
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- 2009-09-29 CN CN201410174274.2A patent/CN103925015B/zh active Active
- 2009-09-29 WO PCT/JP2009/004990 patent/WO2011024242A1/ja active Application Filing
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KR20160124216A (ko) | 2014-03-27 | 2016-10-26 | 미츠비시 히타치 파워 시스템즈 가부시키가이샤 | 분할환 냉각 구조 및 이것을 갖는 가스 터빈 |
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JP2018096307A (ja) * | 2016-12-14 | 2018-06-21 | 三菱日立パワーシステムズ株式会社 | 分割環及びガスタービン |
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US11248527B2 (en) | 2016-12-14 | 2022-02-15 | Mitsubishi Power, Ltd. | Ring segment and gas turbine |
JP2018128017A (ja) * | 2017-02-06 | 2018-08-16 | ドゥサン ヘヴィー インダストリーズ アンド コンストラクション カンパニー リミテッド | 直線型冷却ホールを含むガスタービンリングセグメント及びこれを含むガスタービン |
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Also Published As
Publication number | Publication date |
---|---|
EP2405103B1 (en) | 2016-05-04 |
CN103925015A (zh) | 2014-07-16 |
US20110044805A1 (en) | 2011-02-24 |
EP2405103A4 (en) | 2015-02-25 |
US9540947B2 (en) | 2017-01-10 |
KR101366908B1 (ko) | 2014-02-24 |
CN103925015B (zh) | 2016-01-20 |
CN102414398B (zh) | 2014-10-29 |
US8777559B2 (en) | 2014-07-15 |
US20140234077A1 (en) | 2014-08-21 |
EP3006678A1 (en) | 2016-04-13 |
JPWO2011024242A1 (ja) | 2013-01-24 |
KR20120018753A (ko) | 2012-03-05 |
EP3006678B1 (en) | 2017-12-20 |
JP5291799B2 (ja) | 2013-09-18 |
EP2405103A1 (en) | 2012-01-11 |
CN102414398A (zh) | 2012-04-11 |
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