High pressure turbine vane cooling configuration

Information

  • Patent Grant
  • 12168938
  • Patent Number
    12,168,938
  • Date Filed
    Wednesday, August 30, 2023
    a year ago
  • Date Issued
    Tuesday, December 17, 2024
    5 days ago
Abstract
A turbine vane assembly for a gas turbine engine is disclosed herein. The turbine vane assembly includes a turbine vane including a leading edge, a pressure edge, a suction edge, and a trailing edge, a core defined by the turbine vane, an outer platform end wall connected to the turbine vane, the outer platform end wall defining an interior space, the interior space being in fluid communication with the core, and a plurality of cooling holes formed in the turbine vane, the plurality of cooling holes being in fluid communication with the core.
Description
FIELD

The present disclosure relates to gas turbine engines and, more particularly, to systems and methods used to cool airfoils within gas turbine engines.


BACKGROUND

A gas turbine engine typically includes a fan section, a compressor section, a combustor section and a turbine section. Air entering the compressor section is compressed and delivered into the combustor section where it is mixed with fuel and ignited to generate a high-speed exhaust gas flow. The high-speed exhaust gas flow expands through the turbine section to drive the compressor and the fan section.


Turbine section components, such as turbine blades and vanes, are operated in high temperature environments. To avoid deterioration in the components resulting from their exposure to high temperatures, cooling circuits are typically employed within the components. Turbine blades and vanes are subjected to high thermal loads on both the suction and pressure sides of the airfoil portions and at both the leading and trailing edges. The regions of the airfoils having the highest thermal loads can differ depending on engine design and specific operating conditions.


Turbine components in gas turbine engines often utilize active cooling as temperatures in the gas path exceed the melting point of the constituent components. However, as energy is expended to pressurize coolant flow prior to being used to cool components, the result of adding cooling flow decreases the efficiency of the turbine. Therefore, when designing turbine components, cooling flow should be used sparingly to meet part and module life targets to be within performance targets.


SUMMARY

A turbine vane assembly for a gas turbine engine is disclosed herein. The turbine vane assembly includes a turbine vane including a leading edge, a pressure edge, a suction edge, and a trailing edge, a core defined by the turbine vane, an outer platform end wall connected to the turbine vane, the outer platform end wall defining an interior space, the interior space being in fluid communication with the core, and a plurality of cooling holes formed in the turbine vane, the plurality of cooling holes being in fluid communication with the core.


In various embodiments, the turbine vane assembly is a first stage turbine vane assembly of a high pressure turbine of the gas turbine engine. In various embodiments, the turbine vane assembly further includes a second turbine vane including a second leading edge, a second pressure edge, a second suction edge, and a second trailing edge, the second turbine vane connected to the outer platform end wall, a second core defined by the second turbine vane, the second core in being fluid communication with the interior space, and a second plurality of cooling holes formed in the second turbine vane, the second plurality of cooling holes in being fluid communication with the second core.


In various embodiments, the turbine vane assembly further includes an inner platform end wall connected to the turbine vane and the second turbine vane opposite the outer platform end wall, the inner platform end wall defining a second interior space, wherein the second interior space is in fluid communication with the core and the second core. In various embodiments, the turbine vane assembly further includes a third plurality of cooling holes formed in the outer platform end wall, the third plurality of cooling holes being in fluid communication with the interior space.


In various embodiments, the turbine vane assembly further includes a fourth plurality of cooling holes formed in the inner platform end wall, the fourth plurality of cooling holes being in fluid communication with the second interior space. In various embodiments, the fourth plurality of cooling holes are located in the inner platform end wall according to coordinates of Table 4, wherein the coordinates of Table 4 are distances from a point of origin on the turbine vane assembly. In various embodiments, the third plurality of cooling holes are located in the outer platform according to coordinates of Table 3, wherein the coordinates of Table 3 are distances from a point of origin on the turbine vane assembly. In various embodiments, the second plurality of cooling holes are located in the second turbine vane according to coordinates of Table 2, wherein the coordinates of Table 2 are distances from a point of origin on the turbine vane assembly. In various embodiments, the plurality of cooling holes are located in the vane according to coordinates of Table 1, wherein the coordinates of Table 1 are distances from a point of origin on the turbine vane assembly.


Also disclosed herein is a component for a gas turbine engine, including a first turbine vane including first outer walls and a first core, the first core being partially defined by the first outer walls, a second turbine vane including second outer walls and a second core, the second core being partially defined by a the second outer walls, an outer platform end wall connected to the first turbine vane and the second turbine vane, an inner platform end wall connected to the first turbine vane and the second turbine vane opposite the outer platform end wall, a first plurality of cooling holes extending through the first outer walls into the first core, and a second plurality of cooling holes extending through the second outer walls into the second core.


In various embodiments, the outer platform end wall further includes a first interior space, the first interior space being in fluid communication with the first core and the second core and a third plurality of cooling holes extending through the outer platform end wall and into the first interior space. In various embodiments, the third plurality of cooling holes are located in the outer platform end wall according to coordinates of Table 3, wherein the coordinates of Table 3 are distances from a point of origin on the component.


In various embodiments, the inner platform end wall further includes a second interior space, the second interior space being in fluid communication with the first core and the second core and a fourth plurality of cooling holes extending through the inner platform end wall and into the first interior space. In various embodiments, the fourth plurality of cooling holes are located in the inner platform end wall according to coordinates of Table 4, wherein the coordinates of Table 4 are distances from a point of origin on the component.


In various embodiments, the first plurality of cooling holes are located in the first turbine vane according to coordinates of Table 1, wherein the coordinates of Table 1 are distances from a point of origin on the component. In various embodiments, the second plurality of cooling holes are located in the second turbine vane according to coordinates of Table 2, wherein the coordinates of Table 2 are distances from a point of origin on the turbine vane assembly.


Also disclosed herein is a method of cooling a turbine vane assembly of a gas turbine engine. The method includes receiving a turbine vane assembly including a first turbine vane, a second turbine vane, an outer platform end wall, and an inner platform end wall, the first turbine vane disposed adjacent the second turbine vane, the outer platform end wall connected to the first turbine vane and the second turbine vane, and the inner platform end wall connected to the first turbine vane and the second turbine vane opposite the outer platform end wall, forming a first plurality of cooling holes in a first turbine vane, wherein the first plurality of cooling holes are located in the first turbine vane according to coordinates of Table 1, wherein the coordinates of Table 1 are distances from a point of origin in the turbine vane assembly, and forming a second plurality of cooling holes in a second turbine vane that is adjacent the first turbine vane, wherein the second plurality of cooling holes are located in the first turbine vane according to coordinates of Table 2, wherein the coordinates of Table 3 are distances from a point of origin in the turbine vane assembly.


In various embodiments, the method further includes forming a third plurality of cooling holes in the outer platform end wall, wherein the third plurality of cooling holes are located in the outer end wall according to coordinates of Table 3, wherein the coordinates of Table 3 are distances from a point of origin in the turbine vane assembly. In various embodiments, the method further includes forming a fourth plurality of cooling holes in the inner platform end wall, wherein the fourth plurality of cooling holes are located in the inner platform end wall according to coordinates of Table 4, wherein the coordinates of Table 4 are distances from a point of origin in the turbine vane assembly.


The foregoing features and elements may be combined in any combination, without exclusivity, unless expressly indicated herein otherwise. These features and elements as well as the operation of the disclosed embodiments will become more apparent in light of the following description and accompanying drawings.





BRIEF DESCRIPTION OF THE DRAWINGS

The subject matter of the present disclosure is particularly pointed out and distinctly claimed in the concluding portion of the specification. A more complete understanding of the present disclosure, however, may best be obtained by referring to the following detailed description and claims in connection with the following drawings. While the drawings illustrate various embodiments employing the principles described herein, the drawings do not limit the scope of the claims.



FIG. 1 illustrates a schematic representation of a gas turbine engine, in accordance with various embodiments.



FIGS. 2A, 2B, 2C, 2D, and 2E illustrate a front, back, and cross section views of a vane of a gas turbine engine, in accordance with various embodiments.





DETAILED DESCRIPTION

The following detailed description of various embodiments herein makes reference to the accompanying drawings, which show various embodiments by way of illustration. While these various embodiments are described in sufficient detail to enable those skilled in the art to practice the disclosure, it should be understood that other embodiments may be realized and that changes may be made without departing from the scope of the disclosure. Thus, the detailed description herein is presented for purposes of illustration only and not of limitation. Furthermore, any reference to singular includes plural embodiments, and any reference to more than one component or step may include a singular embodiment or step. Also, any reference to attached, fixed, connected, or the like may include permanent, removable, temporary, partial, full or any other possible attachment option. Additionally, any reference to without contact (or similar phrases) may also include reduced contact or minimal contact. It should also be understood that unless specifically stated otherwise, references to “a,” “an” or “the” may include one or more than one and that reference to an item in the singular may also include the item in the plural. Further, all ranges may include upper and lower values and all ranges and ratio limits disclosed herein may be combined.


Disclosed herein, accordance with various embodiments, is a turbine vane assembly including a right vane, a left vane, an inner platform end wall, and an outer platform end wall. Each surface of the left vane, the right vane, the inner platform end wall, and the outer platform end wall may contain a plurality of cooling holes. In various embodiments, the plurality of cooling holes may break from an interior, or backside, surface of the left vane, right vane, inner platform end wall, and/or outer platform end wall to an exterior gas path side. In various embodiments, each of the plurality of cooling holes may emerge on the external surface in accordance with a defined set of Cartesian coordinate values. In various embodiments, these values may reference dimensions from a specified point within the turbine vane assembly. In various embodiments, the turbine vane assembly as described herein may provide improved durability and/or neutral performance changes as compared to current turbine vane designs.


Referring now to FIG. 1, a schematic of a gas turbine engine 100 is illustrated, in accordance with various embodiments. The gas turbine engine 100 is disclosed herein as a two-spool turbofan that generally incorporates a fan section 102, a compressor section 104, a combustor section 106 and a turbine section 108. The fan section 102 drives air along a bypass flow path B in a bypass duct defined within a nacelle 110, while the compressor section 104 drives air along a primary or core flow path C for compression and communication into the combustor section 106 and then expansion through the turbine section 108. Although depicted as a two-spool turbofan gas turbine engine in the disclosed non-limiting embodiment, it will be understood that the concepts described herein are not limited to use with two-spool turbofans, as the teachings may be applied to other types of gas turbine engines, including, for example, architectures having three or more spools or only a single spool.


The gas turbine engine 100 generally includes a low speed spool 112 and a high speed spool 114 mounted for rotation about an engine central longitudinal axis A relative to an engine static structure 116 via several bearing systems 118. It should be understood that various bearing systems at various locations may alternatively or additionally be provided and the location of the several bearing systems 118 may be varied as appropriate to the application. The low speed spool 112 generally includes an inner shaft 120 that interconnects a fan 122, a low pressure compressor 124 and a low pressure turbine 126. The inner shaft 120 may be directly connected to the fan 122 or through a speed change mechanism, such as, for example, a fan drive gear system configured to drive the fan 122 at a lower speed than that of the low speed spool 112. The high speed spool 114 generally includes an outer shaft 128 that interconnects a high pressure compressor 130 and a high pressure turbine 132. A combustor 134 is arranged in the gas turbine engine 100 between the high pressure compressor 130 and the high pressure turbine 132. The inner shaft 120 and the outer shaft 128 are concentric and rotate via the several bearing systems 118 about the engine central longitudinal axis A, which is collinear with longitudinal axes of the inner shaft 120 and the outer shaft 128.


The air in the core flow path C is compressed by the low pressure compressor 124 and then the high pressure compressor 130, mixed and burned with fuel in the combustor 134, and then expanded over the high pressure turbine 132 and the low pressure turbine 126. The low pressure turbine 126 and the high pressure turbine 132 rotationally drive the respective low speed spool 112 and the high speed spool 114 in response to the expansion. It will be appreciated that each of the positions of the fan section 102, the compressor section 104, the combustor section 106, the turbine section 108, and the fan drive gear system, if present, may be varied. For example, the fan drive gear system may be located aft of the combustor section 106 or even aft of the turbine section 108, and the fan section 102 may be positioned forward or aft of the location of the fan drive gear system.


Referring now to FIGS. 2A-2E, front views, a back view, and a cross section view of a turbine vane assembly 200 is schematically illustrated. FIG. 2A illustrates a front perspective view of turbine vane assembly 200. FIG. 2B illustrates a back perspective view of turbine vane assembly 200. FIG. 2C illustrates a front perspective view from a top portion of turbine vane assembly 200. FIG. 2D illustrates a front perspective view from a bottom portion of turbine vane assembly 200. FIG. 2E illustrates a top down cross section view of turbine vane assembly 200. The turbine vane assembly 200 is representative of the vanes present in either of the low pressure turbine 126 and the high pressure turbine 132 described above with reference to FIG. 1. While the present disclosure will be described with respect to its application to a turbine vane, the disclosure could also be utilized in a rotating structure such as a turbine blade (e.g., the turbine blades present in either of the low pressure turbine 126 and the high pressure turbine 132) or other static turbine components such as blade outer air seals, turbine exhaust cases, and struts. Additional uses of the cooling scheme may include combustor liners and flame holders as well as nozzle liners and flaps.


The turbine vane assembly 200 includes a right vane 202, a left vane 204, an outer platform end wall 206, an inner platform end wall 208, and a hole 210. As illustrated in FIGS. 2A-2E, right vane 202 is in the negative y direction and left vane 204 is in y direction. Right vane 202 includes several surfaces including a right leading edge 212, a right trailing edge 214, a right pressure side 216, and a right suction side 218. Right vane 202 further includes a right leading edge core 220 and a right trailing edge core 222 formed therein. Right leading edge 212, right trailing edge 214, right pressure side 216, and right suction side 218 forming an outer wall around right leading edge core 220 and right trailing edge core 222. Right leading edge core 220 and right trailing edge core 222 open into outer platform end wall 206 and inner platform end wall 208. Left vane 204 includes several surfaces including a left leading edge 224, a left trailing edge 226, a left pressure side 228, and a left suction side 230. Left vane 204 further includes a left leading edge core 232 and a left trailing edge core 234 formed therein. Left leading edge 224, left trailing edge 226, left pressure side 228, and left suction side 230 forming an outer wall around left leading edge core 232 and left trailing edge core 234. Left leading edge core 232 and left trailing edge core 234 open into outer platform end wall 206 and inner platform end wall 208. Outer platform end wall 206 defines an outer platform internal space 207 that is in fluid communication with right leading edge core 220, right trailing edge core 222, left leading edge core 232, and left trailing edge core 234. Inner platform end wall defines an inner platform internal space 209 that is in fluid communication with right leading edge core 220, right trailing edge core 222, left leading edge core 232, and left trailing edge core 234.


Each surface of turbine vane assembly 200 (e.g., right vane 202 surfaces, left vane 204 surface, outer platform end wall 206, and inner platform end wall 208) contains a plurality of cooling holes. Right vane 202 includes a plurality of right leading cooling holes 236 along right leading edge 212, a plurality of right pressure side cooling holes 237 along right pressure side 216, and a plurality of right suction cooling holes 239 along right suction side 218. Right vane 202 further includes right trailing cooling holes 238 along right trailing edge 214. Left vane 204 includes a plurality of left leading cooling holes 240 along left leading edge 224, a plurality of left pressure side cooling holes 241 along left pressure side 228, and a plurality of left suction side cooling holes 243 along left suction side 230. Left vane 204 further includes left trailing cooling holes 242 along left trailing edge 226. Outer platform end wall 206 includes a plurality of outer platform cooling holes 244. Inner platform end wall 208 includes a plurality of inner platform cooling holes 246. Each of the plurality of cooling holes (e.g., right leading cooling holes 236, left leading cooling holes 240, etc.) extends through a surface of turbine vane assembly 200 (e.g., right leading edge 212, left trailing edge 226, outer platform end wall 206, etc.) into a interior space (e.g., right leading edge core 220, left trailing edge core 234, outer platform internal space 207, etc.) and break out into an external gas path (e.g., right trailing edge 214, left trailing edge 226, etc.) For example, right leading cooling holes 236 are in fluid communication with right leading edge core 220 and right trailing edge core 222 which are in fluid communication with right trailing cooling holes 238. Gasses pass over right vane 202 and through right leading cooling holes 236, through right leading edge core 220 and/or right trailing edge core 222, and out through right trailing cooling holes 238. As another example, outer platform cooling holes 244 are in fluid communication with outer platform internal space 207 which is in fluid communication with right leading edge core 220, right trailing edge core 222, left leading edge core 232, and left trailing edge core 234. Gasses pass over outer platform end wall 206 and through outer platform cooling holes 244, through outer platform internal space 207, through right leading edge core 220, right trailing edge core 222, left leading edge core 232, and/or left trailing edge core 234, and out through right trailing cooling holes 238 and/or left trailing cooling holes 242. In various embodiments, the gasses may be a cooling fluid CF (e.g., a high-pressure flow of air bled from the compressor section 104 of the gas turbine engine 100 described above with reference to FIG. 1).


In various embodiments, right leading cooling holes 236, right trailing cooling holes 238, left leading cooling holes 240, left trailing cooling holes 242, outer platform cooling holes 244, and inner platform cooling holes 246 (collectively referred to as the cooling holes) may be arranged having different spacings and configurations. In various embodiments, right suction side cooling holes 239 located along right suction side 218 may be arranged in a herring bone pattern 250, as illustrated in FIG. 2C, for example. Herring bone pattern 250 may be symmetrical about a midpoint in the z-axis with an upper portion of the cooling holes above the midpoint pointing upward (e.g., the z-direction) and a lower portion of the cooling holes below the midpoint pointing downward (e.g., the negative z-direction). In various embodiments, herring bone 250 pattern may be duplicated as a second herring bone pattern 252. In various embodiments, a first plurality of right leading cooling holes 236 may be formed at an angle to the surface (e.g., right pressure side 216, right suction side 218, etc.). As a result of the design and arrangement of right leading cooling holes 236, right trailing cooling holes 238, left leading cooling holes 240, left trailing cooling holes 242, outer platform cooling holes 244, and inner platform cooling holes 246, turbine vane assembly 200 may provide improved durability and/or neutral performance changes as compared to current turbine vane designs. Additionally, the design and arrangement of the cooling holes reduces potential hots spots on turbine vane assembly 200 by promoting laminar flow across the uniformly distributed cooling holes. That is, while the cooling holes improve cooling of turbine vane assembly 200, the effect of the cooling holes is greater than other arrangements of cooling holes.


In various embodiments, right leading cooling holes 236, right trailing cooling holes 238, left leading cooling holes 240, left trailing cooling holes 242, outer platform cooling holes 244, and inner platform cooling holes 246 are arranged according to the cartesian coordinate values of X, Y, and Z as set forth in Tables 1-4. These values are reference dimensions from a designed point on a midpoint of hole 210. While the values in Tables 1-4 are unitless, in various embodiments the distances represented from the midpoint of hole 210 may be scaled as a ratio with respect to the size of turbine vane assembly 200. In various embodiments, the distances may be measured in inches. Table 1 includes hole IDs and cartesian coordinates (X, Y, Z) for each right leading cooling hole 236 and right trailing cooling hole 238 hole from the midpoint of hole 210. That is, hole IDs 1-196 correspond to right leading cooling holes 236 and right trailing cooling holes 238. For example, the cooling holes in herring bone pattern 250 may correspond to hole IDs 140-157. As another example, the cooling holes in herring bone pattern 252 may correspond to hole IDs 158-175. Table 2 includes hole IDs and cartesian coordinates (X, Y, Z) for each left leading cooling hole 240 and left trailing cooling hole 242 hole from the midpoint of hole 210. That is, hole IDs 197-379 correspond to left leading cooling holes 240 and left trailing cooling holes 242. Table 3 includes hole IDs and cartesian coordinates (X, Y, Z) for each outer platform cooling hole 244 from the midpoint of hole 210. That is, hole IDs 380-497 correspond to outer platform cooling holes 244. Table 4 includes hole IDs and cartesian coordinates (X, Y, Z) for each inner platform cooling hole 246 from the midpoint of hole 210. That is, hole IDs 498-550 correspond to inner platform cooling holes 246.














TABLE 1







Hole ID
X
Y
Z





















1
1.15002
1.43739
1.39073



2
1.14975
1.46908
1.53058



3
1.14968
1.49438
1.67189



4
1.14978
1.51381
1.81456



5
1.15006
1.52742
1.95856



6
1.15053
1.53486
2.10398



7
1.15121
1.53529
2.25102



8
1.15215
1.52739
2.39997



9
1.16036
1.57525
2.52167



10
1.12151
1.38854
1.44989



11
1.12317
1.42080
1.59005



12
1.12466
1.44677
1.73223



13
1.12594
1.46633
1.87474



14
1.12703
1.47965
2.01971



15
1.12789
1.48605
2.16516



16
1.12851
1.48478
2.31201



17
1.06626
1.26605
1.37967



18
1.06795
1.29903
1.52112



19
1.06914
1.32548
1.66341



20
1.06987
1.34601
1.80648



21
1.07017
1.36084
1.95029



22
1.07001
1.36978
2.09487



23
1.06936
1.37224
2.24030



24
1.06813
1.36721
2.38670



25
0.97083
1.11385
1.44149



26
0.97178
1.13725
1.58429



27
0.97242
1.15646
1.72689



28
0.97279
1.17216
1.86933



29
0.97292
1.18461
2.01163



30
0.97278
1.19367
2.15377



31
0.97235
1.19879
2.29573



32
0.97156
1.19906
2.43747



33
0.99576
1.26666
2.51994



34
0.93537
1.22954
2.61606



35
0.87164
0.95371
1.41528



36
0.86630
0.96103
1.55914



37
0.86035
0.96467
1.70299



38
0.85400
0.96595
1.84685



39
0.84743
0.96588
1.99070



40
0.84073
0.96503
2.13455



41
0.83392
0.96349
2.27841



42
0.82694
0.96091
2.42227



43
0.82592
0.99429
2.56617



44
0.78702
0.96426
2.61631



45
0.55807
1.42242
2.50121



46
0.55267
1.45070
2.56733



47
0.64508
0.66725
1.35005



48
0.66109
0.66725
1.51374



49
0.65850
0.66449
1.61381



50
0.65602
0.66221
1.71387



51
0.65373
0.66082
1.81391



52
0.65172
0.66069
1.91392



53
0.65004
0.66209
2.01390



54
0.64873
0.66519
2.11385



55
0.64783
0.67014
2.21376



56
0.64731
0.67685
2.31363



57
0.64714
0.68517
2.41346



58
0.69062
0.75667
2.49472



59
0.51886
0.58421
1.26978



60
0.53872
0.52258
1.43658



61
0.54489
0.52228
1.60204



62
0.54077
0.51462
1.69712



63
0.53699
0.50827
1.79219



64
0.53360
0.50347
1.88724



65
0.53068
0.50047
1.98226



66
0.52825
0.49940
2.07727



67
0.52637
0.50046
2.17224



68
0.52506
0.50375
2.26719



69
0.52436
0.50942
2.36212



70
0.52429
0.51752
2.45701



71
0.55475
0.59069
2.55128



72
0.40298
0.40701
1.36993



73
0.40474
0.39055
1.43704



74
0.40569
0.38425
1.51805



75
0.40643
0.38053
1.60261



76
0.40711
0.37765
1.68831



77
0.40773
0.37551
1.77504



78
0.40829
0.37406
1.86271



79
0.40440
0.36959
1.98593



80
0.40658
0.37096
2.07775



81
0.40873
0.37305
2.16867



82
0.41083
0.37593
2.25857



83
0.41289
0.37979
2.34723



84
0.41484
0.38584
2.43312



85
0.41915
0.40337
2.50000



86
0.42076
0.43009
2.56150



87
0.32422
0.27958
1.21427



88
0.32720
0.28359
1.31692



89
0.33136
0.28687
1.51209



90
0.33313
0.28697
1.65664



91
0.33539
0.28849
1.80202



92
0.33649
0.28939
1.87403



93
0.33839
0.29157
1.96333



94
0.34055
0.29396
2.10948



95
0.34174
0.29539
2.27545



96
0.34381
0.29931
2.43711



97
0.32138
0.31811
2.53866



98
0.25055
0.21075
1.24132



99
0.30169
0.20985
1.40305



100
0.30765
0.20722
1.57777



101
0.30786
0.20824
1.72121



102
0.30848
0.20998
1.86942



103
0.30915
0.21243
1.93724



104
0.31006
0.21517
2.02786



105
0.31152
0.21841
2.17006



106
0.31368
0.22395
2.31433



107
0.30337
0.23697
2.48603



108
0.21714
0.25695
2.67809



109
0.26265
0.12834
1.22147



110
0.30989
0.12667
1.37425



111
0.31104
0.12417
1.51295



112
0.31035
0.12459
1.65553



113
0.30987
0.12624
1.79841



114
0.30977
0.12829
1.93635



115
0.30944
0.13191
2.00643



116
0.30970
0.13374
2.09528



117
0.31017
0.13840
2.22945



118
0.31140
0.14132
2.36711



119
0.30348
0.14146
2.48649



120
0.27437
0.13407
2.58281



121
0.22384
0.11908
2.67218



122
0.29410
0.03760
1.21406



123
0.33069
0.04310
1.40662



124
0.33013
0.04495
1.56307



125
0.33023
0.04518
1.70649



126
0.33051
0.04551
1.85664



127
0.32998
0.04839
2.00666



128
0.32891
0.05170
2.06280



129
0.32872
0.05533
2.22021



130
0.32705
0.06369
2.36906



131
0.32170
0.06011
2.50375



132
0.28758
0.05226
2.60496



133
0.25347
0.03956
2.66336



134
0.36155
−0.01724
2.54140



135
0.32409
−0.02059
2.62288



136
0.37692
−0.06125
2.61855



137
0.32433
−0.07300
2.68242



138
0.43048
−0.10007
2.67136



139
0.50263
−0.09749
2.64646



140
0.45489
−0.08365
1.26842



141
0.45473
−0.08202
1.34302



142
0.45458
−0.08051
1.41772



143
0.45446
−0.07915
1.49255



144
0.45437
−0.07796
1.56752



145
0.45430
−0.07691
1.64262



146
0.45426
−0.07602
1.71784



147
0.45423
−0.07526
1.79318



148
0.45422
−0.07459
1.86861



149
0.45422
−0.07401
1.94410



150
0.45504
−0.07368
2.04274



151
0.45419
−0.07285
2.11945



152
0.45335
−0.07205
2.19615



153
0.45251
−0.07132
2.27277



154
0.45169
−0.07064
2.34936



155
0.45088
−0.07004
2.42587



156
0.45008
−0.06954
2.50231



157
0.44931
−0.06917
2.57863



158
0.67997
−0.03692
1.29260



159
0.68252
−0.03643
1.37057



160
0.68529
−0.03601
1.44854



161
0.68813
−0.03560
1.52651



162
0.69090
−0.03517
1.60447



163
0.69349
−0.03470
1.68244



164
0.69584
−0.03415
1.76041



165
0.69791
−0.03353
1.83838



166
0.69966
−0.03281
1.91636



167
0.70106
−0.03200
1.99435



168
0.70211
−0.03109
2.07234



169
0.70280
−0.03009
2.15033



170
0.70316
−0.02899
2.22832



171
0.70322
−0.02780
2.30632



172
0.70302
−0.02654
2.38433



173
0.70261
−0.02523
2.46234



174
0.70208
−0.02388
2.54035



175
0.70154
−0.02253
2.61835



176
0.84478
0.12722
1.32942



177
0.84209
0.12567
1.40738



178
0.84027
0.12448
1.48534



179
0.83911
0.12358
1.56332



180
0.83839
0.12284
1.64132



181
0.83796
0.12222
1.71932



182
0.83768
0.12168
1.79733



183
0.83743
0.12113
1.87533



184
0.83716
0.12058
1.95333



185
0.83679
0.12000
2.03133



186
0.83632
0.11936
2.10933



187
0.83573
0.11868
2.18732



188
0.83504
0.11796
2.26531



189
0.83432
0.11722
2.34331



190
0.83362
0.11651
2.42130



191
0.83307
0.11585
2.49930



192
0.78376
0.05261
2.55457



193
0.78414
0.05350
2.61845



194
1.17417
1.17362
2.55211



195
1.18717
1.21324
2.61570



196
1.22006
1.35817
2.55292






















TABLE 2







Hole ID
X
Y
Z





















197
1.15002
1.43739
1.39073



198
1.14975
1.46908
1.53058



199
1.14968
1.49438
1.67189



200
1.14978
1.51381
1.81456



201
1.15006
1.52742
1.95856



202
1.15053
1.53486
2.10398



203
1.15121
1.53529
2.25102



204
1.15215
1.52739
2.39997



205
1.12467
1.50245
2.53348



206
1.12151
1.38854
1.44989



207
1.12317
1.42080
1.59005



208
1.12466
1.44677
1.73223



209
1.12594
1.46633
1.87474



210
1.12703
1.47965
2.01971



211
1.12789
1.48605
2.16516



212
1.12851
1.48478
2.31201



213
1.06626
1.26605
1.37967



214
1.06795
1.29903
1.52112



215
1.06914
1.32548
1.66341



216
1.06987
1.34601
1.80648



217
1.07017
1.36084
1.95029



218
1.07001
1.36978
2.09487



219
1.06936
1.37224
2.24030



220
1.06813
1.36721
2.38670



221
0.99623
1.13391
1.25178



222
0.97083
1.11385
1.44149



223
0.97178
1.13725
1.58429



224
0.97242
1.15646
1.72689



225
0.97279
1.17216
1.86933



226
0.97292
1.18461
2.01163



227
0.97278
1.19367
2.15377



228
0.97235
1.19879
2.29573



229
0.97156
1.19906
2.43747



230
0.99576
1.26666
2.51994



231
0.87164
0.95371
1.41528



232
0.86630
0.96103
1.55914



233
0.86035
0.96467
1.70299



234
0.85400
0.96595
1.84685



235
0.84743
0.96588
1.99070



236
0.84073
0.96503
2.13455



237
0.83392
0.96349
2.27841



238
0.82694
0.96091
2.42227



239
0.64508
0.66725
1.35005



240
0.66109
0.66725
1.51374



241
0.65850
0.66450
1.61381



242
0.65602
0.66221
1.71387



243
0.65373
0.66081
1.81391



244
0.65172
0.66068
1.91392



245
0.65004
0.66208
2.01390



246
0.64873
0.66521
2.11385



247
0.64783
0.67014
2.21376



248
0.64731
0.67684
2.31363



249
0.64714
0.68516
2.41346



250
0.69062
0.75667
2.49472



251
0.48534
0.48602
2.53142



252
0.46877
0.51359
2.60548



253
0.51886
0.58421
1.26978



254
0.53872
0.52259
1.43658



255
0.54140
0.52141
1.51936



256
0.54489
0.52227
1.60204



257
0.54077
0.51462
1.69712



258
0.53699
0.50827
1.79219



259
0.53360
0.50348
1.88724



260
0.53068
0.50046
1.98226



261
0.52825
0.49940
2.07727



262
0.52637
0.50045
2.17224



263
0.52506
0.50375
2.26719



264
0.52436
0.50942
2.36212



265
0.52429
0.51752
2.45701



266
0.54210
0.57689
2.55753



267
0.61531
0.65317
2.50560



268
0.62168
0.69360
2.57267



269
0.40298
0.40701
1.36993



270
0.40474
0.39055
1.43704



271
0.40569
0.38425
1.51805



272
0.40643
0.38053
1.60261



273
0.40711
0.37765
1.68831



274
0.40773
0.37551
1.77504



275
0.40829
0.37406
1.86271



276
0.40440
0.36959
1.98593



277
0.40658
0.37096
2.07775



278
0.40873
0.37305
2.16867



279
0.41083
0.37593
2.25857



280
0.41289
0.37979
2.34723



281
0.41484
0.38584
2.43312



282
0.25905
0.29639
1.24564



283
0.30956
0.29280
1.36502



284
0.32681
0.28865
1.52291



285
0.32865
0.28898
1.66609



286
0.33112
0.29096
1.81046



287
0.33194
0.29159
1.86700



288
0.33410
0.29422
1.95621



289
0.33622
0.29652
2.10105



290
0.33744
0.29795
2.26614



291
0.33644
0.30293
2.41973



292
0.31841
0.31919
2.53209



293
0.24610
0.21037
1.24357



294
0.29805
0.20953
1.41300



295
0.30261
0.20730
1.58977



296
0.30286
0.20851
1.73149



297
0.30352
0.21040
1.87805



298
0.30409
0.21271
1.92915



299
0.30500
0.21552
2.01968



300
0.30642
0.21873
2.16054



301
0.30861
0.22453
2.30255



302
0.30007
0.23709
2.47757



303
0.19856
0.25908
2.67766



304
0.24865
0.12402
1.22592



305
0.30566
0.12581
1.38414



306
0.30608
0.12312
1.52516



307
0.30540
0.12373
1.66630



308
0.30492
0.12554
1.80738



309
0.30483
0.12769
1.94532



310
0.30446
0.13116
1.99849



311
0.30471
0.13290
2.08652



312
0.30509
0.13793
2.21974



313
0.30634
0.14041
2.35740



314
0.29990
0.13995
2.47959



315
0.27072
0.13259
2.57924



316
0.21892
0.11692
2.67089



317
0.28468
0.03469
1.21678



318
0.33069
0.04310
1.40662



319
0.33013
0.04495
1.56307



320
0.33023
0.04518
1.70649



321
0.33051
0.04551
1.85664



322
0.32998
0.04839
2.00665



323
0.32891
0.05170
2.06280



324
0.32872
0.05533
2.22021



325
0.32705
0.06369
2.36906



326
0.32170
0.06011
2.50375



327
0.28757
0.05226
2.60496



328
0.21388
0.01457
2.70061



329
0.45724
−0.09924
1.28177



330
0.45545
−0.08734
1.35673



331
0.45520
−0.08571
1.44049



332
0.45498
−0.08425
1.52439



333
0.45479
−0.08298
1.60845



334
0.45463
−0.08189
1.69267



335
0.45449
−0.08096
1.77702



336
0.45437
−0.08015
1.86147



337
0.45426
−0.07945
1.94602



338
0.45599
−0.07936
2.06400



339
0.45515
−0.07851
2.14785



340
0.45431
−0.07771
2.23162



341
0.45349
−0.07698
2.31534



342
0.45267
−0.07632
2.39899



343
0.45188
−0.07577
2.48255



344
0.45119
−0.07591
2.56552



345
0.45290
−0.09138
2.64202



346
0.68623
−0.03856
1.27010



347
0.68631
−0.03970
1.35825



348
0.68681
−0.04100
1.44680



349
0.68744
−0.04234
1.53550



350
0.68800
−0.04367
1.62412



351
0.68835
−0.04491
1.71254



352
0.68840
−0.04603
1.80065



353
0.68807
−0.04702
1.88838



354
0.68734
−0.04784
1.97571



355
0.68671
−0.04798
2.09932



356
0.68601
−0.04772
2.18563



357
0.68491
−0.04732
2.27231



358
0.68344
−0.04678
2.35931



359
0.68167
−0.04613
2.44660



360
0.67966
−0.04539
2.53409



361
0.67888
−0.04510
2.62047



362
0.85332
0.13074
1.32957



363
0.85058
0.12917
1.40753



364
0.84870
0.12796
1.48549



365
0.84748
0.12702
1.56348



366
0.84670
0.12626
1.64147



367
0.84621
0.12562
1.71947



368
0.84589
0.12506
1.79747



369
0.84561
0.12450
1.87548



370
0.84532
0.12395
1.95348



371
0.84495
0.12336
2.03148



372
0.84449
0.12273
2.10948



373
0.84392
0.12206
2.18747



374
0.84328
0.12135
2.26547



375
0.84261
0.12064
2.34346



376
0.84198
0.11995
2.42146



377
0.84150
0.11932
2.49946



378
0.79153
0.05392
2.55424



379
0.79277
0.05511
2.61666






















TABLE 3







Hole ID
X
Y
Z





















380
0.10836
1.68534
2.73083



381
0.10601
1.48181
2.75402



382
0.09613
1.26502
2.76260



383
0.10072
1.02619
2.77576



384
0.10651
0.74412
2.80069



385
0.11122
0.42613
2.80254



386
0.10610
0.24686
2.80037



387
0.09341
−0.09759
2.78766



388
0.09964
−0.28371
2.77295



389
0.09596
−0.54589
2.74321



390
0.08507
−0.80623
2.70556



391
0.09956
−1.02104
2.68387



392
0.09965
−1.26353
2.64229



393
0.09965
−1.50592
2.59405



394
0.31037
1.55118
2.70887



395
0.24973
1.42980
2.70368



396
0.20497
1.30700
2.69286



397
0.18179
1.18043
2.68842



398
0.19440
1.03198
2.70033



399
0.24080
0.91315
2.71796



400
0.30890
−0.38659
2.71196



401
0.24429
−0.48995
2.68373



402
0.19509
−0.60133
2.66086



403
0.17207
−0.71905
2.64243



404
0.18578
−0.86414
2.63102



405
0.22951
−0.97350
2.62447



406
0.30352
−1.06850
2.63119



407
0.39535
−1.14270
2.66018



408
1.39569
2.63987
2.41795



409
1.39502
2.40679
2.46836



410
1.39487
2.17357
2.51285



411
1.39481
1.93931
2.55154



412
1.39486
1.70413
2.58441



413
1.39517
1.46826
2.61150



414
1.39541
1.23178
2.63283



415
1.39541
0.99487
2.64806



416
1.39520
0.75756
2.65718



417
1.39495
0.48705
2.66042



418
1.39653
0.20713
2.65574



419
1.39858
−0.11715
2.64008



420
1.40113
−0.38507
2.61900



421
1.39811
−0.62855
2.59337



422
0.40430
0.44817
2.83012



423
0.31154
0.22156
2.80351



424
0.35268
0.04589
2.78855



425
0.40275
−0.12533
2.76260



426
0.45102
−0.28072
2.68595



427
0.49575
0.62228
2.82919



428
0.51499
0.45038
2.82592



429
0.55656
0.28373
2.80601



430
0.60106
0.12344
2.78317



431
0.66977
0.00941
2.73452



432
0.76956
0.76183
2.76363



433
0.82448
0.61455
2.76447



434
0.88565
0.52149
2.74129



435
0.95914
0.45537
2.70554



436
1.06855
1.30772
2.68215



437
1.10763
1.11852
2.69949



438
1.09354
0.88438
2.70153



439
1.11496
0.73441
2.68344



440
1.32731
1.61536
2.60629



441
1.32208
1.43979
2.62315



442
1.32363
1.16071
2.62745



443
0.98341
−0.75621
2.64335



444
1.02275
−0.90586
2.62780



445
1.11623
−0.36437
2.65950



446
1.18157
−0.56935
2.64887



447
1.26577
−0.78285
2.57315



448
1.24869
−0.10476
2.66739



449
1.25745
−0.30183
2.65570



450
1.27175
−0.49852
2.63156



451
1.33401
−0.67879
2.57716



452
0.42063
2.05018
2.68571



453
0.41858
1.85860
2.69608



454
0.44533
1.64300
2.67089



455
0.57857
2.14946
2.66171



456
0.59046
1.96678
2.67727



457
0.73587
2.23322
2.61888



458
0.82632
2.10181
2.58921



459
0.86293
2.38475
2.56286



460
1.02863
2.50487
2.49298



461
1.16412
2.57230
2.40791



462
−0.01566
0.82305
2.84091



463
−0.01566
0.92893
2.83685



464
−0.01567
1.03476
2.83163



465
−0.01566
1.14052
2.82525



466
−0.01567
1.24621
2.81772



467
−0.01566
1.35181
2.80904



468
−0.01566
1.45730
2.79921



469
−0.01566
−0.97242
2.73344



470
−0.01566
−0.86760
2.74896



471
−0.01566
−0.76263
2.76335



472
−0.01566
−0.65751
2.77658



473
−0.01566
−0.55223
2.78867



474
−0.01567
−0.44685
2.79961



475
−0.01566
−0.34134
2.80940



476
0.28374
−1.65244
2.61529



477
0.20108
−1.71473
2.59788



478
1.00064
−1.11222
2.64514



479
0.94604
−1.15336
2.64620



480
0.72231
−1.32195
2.64675



481
0.82200
−1.24683
2.65272



482
1.21107
−0.95365
2.62015



483
1.12721
−1.01684
2.63383



484
1.46238
−0.62487
2.66179



485
1.47007
−0.48246
2.67521



486
1.47007
0.72303
2.72018



487
1.47007
0.97395
2.71134



488
1.47007
1.22412
2.69938



489
1.47007
2.65487
2.48796



490
1.38154
−0.82519
2.62151



491
1.29835
−0.88788
2.59570



492
1.33953
2.84276
2.40694



493
1.25480
2.77778
2.41692



494
1.16431
2.72417
2.46568



495
1.08519
2.67437
2.50126



496
0.25191
2.09023
2.73185



497
0.16615
2.02326
2.73905






















TABLE 4







Hole ID
X
Y
Z





















498
0.28920
1.40537
1.05181



499
0.20020
1.29508
1.05270



500
0.13753
1.17280
1.05976



501
0.10755
1.03961
1.06143



502
0.13264
0.86933
1.07250



503
0.15827
0.74774
1.06681



504
0.21818
0.62348
1.07599



505
0.31775
0.53230
1.12265



506
0.21665
−0.19761
1.04984



507
0.15796
−0.30704
1.03929



508
0.11805
−0.42112
1.02581



509
0.10194
−0.58123
0.99999



510
0.13386
−0.69230
0.98974



511
0.18470
−0.80822
0.97592



512
0.26082
−0.90786
0.97654



513
0.35343
−1.02096
0.99459



514
0.50447
−0.03108
1.14419



515
0.48392
0.11384
1.09839



516
0.50467
0.37173
1.11895



517
0.51238
0.57807
1.17478



518
0.75908
0.21331
1.16557



519
0.78926
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1.15180



520
0.79089
0.59786
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521
0.80036
0.76413
1.19580



522
1.05899
0.57465
1.18420



523
1.01907
0.83798
1.16602



524
1.01906
1.11495
1.17575



525
0.54076
1.55496
1.10233



526
0.49001
1.69509
1.01539



527
0.84319
1.86333
1.05729



528
0.78045
1.98494
1.01029



529
0.89693
2.00292
1.02404



530
0.93274
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531
1.14741
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1.11873



532
1.25302
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1.13576



533
1.38010
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1.12834



534
1.18168
1.77412
1.10381



535
1.40178
1.71679
1.07747



536
1.38590
1.88934
1.04949



537
1.23368
−0.05962
1.16337



538
1.40006
0.10895
1.15525



539
1.16707
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540
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541
1.33353
0.63949
1.18725



542
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1.05671
1.17563



543
1.35381
2.27675
0.98205



544
1.00217
1.94686
1.12082



545
1.15774
0.77766
1.19278



546
1.18335
0.91919
1.17476



547
1.22604
1.17512
1.15499



548
1.24450
1.44341
1.12886



549
0.10590
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550
1.38741
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1.00726










Benefits, other advantages, and solutions to problems have been described herein with regard to specific embodiments. Furthermore, the connecting lines shown in the various figures contained herein are intended to represent exemplary functional relationships and/or physical couplings between the various elements. It should be noted that many alternative or additional functional relationships or physical connections may be present in a practical system. However, the benefits, advantages, solutions to problems, and any elements that may cause any benefit, advantage, or solution to occur or become more pronounced are not to be construed as critical, required, or essential features or elements of the disclosure. The scope of the disclosure is accordingly to be limited by nothing other than the appended claims, in which reference to an element in the singular is not intended to mean “one and only one” unless explicitly so stated, but rather “one or more.” Moreover, where a phrase similar to “at least one of A, B, or C” is used in the claims, it is intended that the phrase be interpreted to mean that A alone may be present in an embodiment, B alone may be present in an embodiment, C alone may be present in an embodiment, or that any combination of the elements A, B and C may be present in a single embodiment; for example, A and B. A and C, B and C, or A and B and C. Different cross-hatching is used throughout the figures to denote different parts but not necessarily to denote the same or different materials.


Systems, methods and apparatus are provided herein. In the detailed description herein, references to “one embodiment,” “an embodiment,” “various embodiments,” etc., indicate that the embodiment described may include a particular feature, structure, or characteristic, but every embodiment may not necessarily include the particular feature, structure, or characteristic. Moreover, such phrases are not necessarily referring to the same embodiment. Further, when a particular feature, structure, or characteristic is described in connection with an embodiment, it is submitted that it is within the knowledge of one skilled in the art to affect such feature, structure, or characteristic in connection with other embodiments whether or not explicitly described. After reading the description, it will be apparent to one skilled in the relevant art(s) how to implement the disclosure in alternative embodiments.


Numbers, percentages, or other values stated herein are intended to include that value, and also other values that are about or approximately equal to the stated value, as would be appreciated by one of ordinary skill in the art encompassed by various embodiments of the present disclosure. A stated value should therefore be interpreted broadly enough to encompass values that are at least close enough to the stated value to perform a desired function or achieve a desired result. The stated values include at least the variation to be expected in a suitable industrial process, and may include values that are within 10%, within 5%, within 1%, within 0.1%, or within 0.01% of a stated value. Additionally, the terms “substantially,” “about” or “approximately” as used herein represent an amount close to the stated amount that still performs a desired function or achieves a desired result. For example, the term “substantially,” “about” or “approximately” may refer to an amount that is within 10% of, within 5% of, within 1% of, within 0.1% of, and within 0.01% of a stated amount or value.


Furthermore, no element, component, or method step in the present disclosure is intended to be dedicated to the public regardless of whether the element, component, or method step is explicitly recited in the claims. No claim element herein is to be construed under the provisions of 35 U.S.C. 112(f) unless the element is expressly recited using the phrase “means for.” As used herein, the terms “comprises,” “comprising,” or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.


Finally, it should be understood that any of the above-described concepts can be used alone or in combination with any or all of the other above-described concepts. Although various embodiments have been disclosed and described, one of ordinary skill in this art would recognize that certain modifications would come within the scope of this disclosure. Accordingly, the description is not intended to be exhaustive or to limit the principles described or illustrated herein to any precise form. Many modifications and variations are possible in light of the above teaching.

Claims
  • 1. A turbine vane assembly for a gas turbine engine, comprising: a turbine vane including a leading edge, a pressure edge, a suction edge, and a trailing edge;a core defined by the turbine vane;an outer platform end wall connected to the turbine vane, the outer platform end wall defining an interior space, the interior space being in fluid communication with the core; anda plurality of cooling holes formed in the turbine vane, the plurality of cooling holes being in fluid communication with the core, wherein the plurality of cooling holes are located in the vane according to coordinates of Table 1, wherein the coordinates of Table 1 are distances from a point of origin on the turbine vane assembly.
  • 2. The turbine vane assembly of claim 1, wherein the turbine vane assembly is a first stage turbine vane assembly of a high pressure turbine of the gas turbine engine.
  • 3. The turbine vane assembly of claim 1, further comprising: a second turbine vane including a second leading edge, a second pressure edge, a second suction edge, and a second trailing edge, the second turbine vane connected to the outer platform end wall;a second core defined by the second turbine vane, the second core in being fluid communication with the interior space; anda second plurality of cooling holes formed in the second turbine vane, the second plurality of cooling holes in being fluid communication with the second core.
  • 4. The turbine vane assembly of claim 3, further comprising: an inner platform end wall connected to the turbine vane and the second turbine vane opposite the outer platform end wall, the inner platform end wall defining a second interior space, wherein the second interior space is in fluid communication with the core and the second core.
  • 5. The turbine vane assembly of claim 4, further comprising: a third plurality of cooling holes formed in the outer platform end wall, the third plurality of cooling holes being in fluid communication with the interior space.
  • 6. The turbine vane assembly of claim 5, further comprising: a fourth plurality of cooling holes formed in the inner platform end wall, the fourth plurality of cooling holes being in fluid communication with the second interior space.
  • 7. The turbine vane assembly of claim 6, wherein the fourth plurality of cooling holes are located in the inner platform end wall according to coordinates of Table 4, wherein the coordinates of Table 4 are distances from a point of origin on the turbine vane assembly.
  • 8. The turbine vane assembly of claim 5, wherein the third plurality of cooling holes are located in the outer platform according to coordinates of Table 3, wherein the coordinates of Table 3 are distances from a point of origin on the turbine vane assembly.
  • 9. The turbine vane assembly of claim 3, wherein the second plurality of cooling holes are located in the second turbine vane according to coordinates of Table 2, wherein the coordinates of Table 2 are distances from a point of origin on the turbine vane assembly.
  • 10. A component for a gas turbine engine, comprising: a first turbine vane including first outer walls and a first core, the first core being partially defined by the first outer walls;a second turbine vane including second outer walls and a second core, the second core being partially defined by the second outer walls;an outer platform end wall connected to the first turbine vane and the second turbine vane;an inner platform end wall connected to the first turbine vane and the second turbine vane opposite the outer platform end wall;a first plurality of cooling holes extending through the first outer walls into the first core, wherein the first plurality of cooling holes are located in the first turbine vane according to coordinates of Table 1, wherein the coordinates of Table 1 are distances from a point of origin on the component; anda second plurality of cooling holes extending through the second outer walls into the second core.
  • 11. The component of claim 10, wherein the outer platform end wall further comprises: a first interior space, the first interior space being in fluid communication with the first core and the second core; anda third plurality of cooling holes extending through the outer platform end wall and into the first interior space.
  • 12. The component of claim 11, wherein the third plurality of cooling holes are located in the outer platform end wall according to coordinates of Table 3, wherein the coordinates of Table 3 are distances from a point of origin on the component.
  • 13. The component of claim 11, wherein the inner platform end wall further comprises: a second interior space, the second interior space being in fluid communication with the first core and the second core; anda fourth plurality of cooling holes extending through the inner platform end wall and into the first interior space.
  • 14. The component of claim 13, wherein the fourth plurality of cooling holes are located in the inner platform end wall according to coordinates of Table 4, wherein the coordinates of Table 4 are distances from a point of origin on the component.
  • 15. The component of claim 10, wherein the second plurality of cooling holes are located in the second turbine vane according to coordinates of Table 2, wherein the coordinates of Table 2 are distances from a point of origin on the turbine vane assembly.
  • 16. A method of cooling a turbine vane assembly of a gas turbine engine, comprising: receiving a turbine vane assembly including a first turbine vane, a second turbine vane, an outer platform end wall, and an inner platform end wall, the first turbine vane disposed adjacent the second turbine vane, the outer platform end wall connected to the first turbine vane and the second turbine vane, and the inner platform end wall connected to the first turbine vane and the second turbine vane opposite the outer platform end wall;forming a first plurality of cooling holes in a first turbine vane, wherein the first plurality of cooling holes are located in the first turbine vane according to coordinates of Table 1, wherein the coordinates of Table 1 are distances from a point of origin in the turbine vane assembly; andforming a second plurality of cooling holes in a second turbine vane that is adjacent the first turbine vane, wherein the second plurality of cooling holes are located in the first turbine vane according to coordinates of Table 2, wherein the coordinates of Table 2 are distances from a point of origin in the turbine vane assembly.
  • 17. The method of claim 16, further comprising: forming a third plurality of cooling holes in the outer platform end wall, wherein the third plurality of cooling holes are located in the outer end wall according to coordinates of Table 3, wherein the coordinates of Table 3 are distances from a point of origin in the turbine vane assembly.
  • 18. The method of claim 16, further comprising: forming a fourth plurality of cooling holes in the inner platform end wall, wherein the fourth plurality of cooling holes are located in the inner platform end wall according to coordinates of Table 4, wherein the coordinates of Table 4 are distances from a point of origin in the turbine vane assembly.
CROSS REFERENCE TO RELATED APPLICATIONS

This application claims priority to, and the benefit of, U.S. Provisional Application No. 63/421,059 filed on Oct. 31, 2022, and titled “High Pressure Turbine Vane Cooling Configuration,” which is incorporated by reference herein in its entirety for all purposes.

US Referenced Citations (8)
Number Name Date Kind
9322279 Spangler Apr 2016 B2
9957894 Deibel et al. May 2018 B2
10107140 Ennacer et al. Oct 2018 B2
10648363 McMahon et al. May 2020 B2
20130164116 Tardif et al. Jun 2013 A1
20140010632 Spangler Jan 2014 A1
20150211376 Riley et al. Jul 2015 A1
20180106156 LoRicco Apr 2018 A1
Non-Patent Literature Citations (1)
Entry
International Searching Authority; International Search Report and Written Opinion filed in PCT/US23/36237 dated Feb. 13, 2024.
Related Publications (1)
Number Date Country
20240218796 A1 Jul 2024 US
Provisional Applications (1)
Number Date Country
63421059 Oct 2022 US