1. Technical Field
This disclosure relates generally to a turbine engine and, more particularly, to a lug for preventing rotation of a stator vane arrangement relative to a turbine engine case.
2. Background Information
A stator vane arrangement for a typical turbine engine includes a plurality of stator vane airfoils circumferentially arranged around an axial centerline. The airfoils may extend radially between a radial inner platform and a radial outer platform. The outer platform may include a plurality of hooks that are mated with corresponding annular grooves in a turbine engine case. These hooks prevent the stator vane arrangement from moving radially and/or axially relative to the turbine engine case. A plurality of anti-rotation locks are provided to prevent the stator vane arrangement from rotating relative to the turbine engine case.
Various types of anti-rotation locks are known in the art. One such anti-rotation lock includes a rectangular lug that is connected to the turbine engine case with a plurality of fasteners. The rectangular lug is mated with a corresponding slot in the outer platform and, thereby, prevents the stator vane arrangement from rotating relative to the turbine engine case.
There is a need in the art for an improved anti-rotation lock.
According to an aspect of the invention, an assembly is provided for a turbine engine wherein the assembly includes a stator vane arrangement and an anti-rotation lug that is rotatably connected to a turbine engine case. The stator vane arrangement includes a platform, an airfoil and an anti-rotation slot. The platform extends circumferentially around an axial centerline and is engaged with the case. The airfoil extends radially from the platform and is arranged circumferentially around the centerline. The slot extends radially into the platform, and is mated with the lug, which is configured with a substantially equilateral polygonal geometry.
According to another aspect of the invention, a turbine engine is provided that includes a core, a casing, a stator vane arrangement and an anti-rotation lug. The core includes a compressor section, a combustor section and a turbine section. The casing houses at least a portion of the core. The stator vane arrangement includes a platform, a plurality of airfoils and an anti-rotation slot. The platform extends circumferentially around an axial centerline and is engaged with the case. The airfoils extend radially from the platform and are arranged circumferentially around the centerline. The slot extends radially into the platform and is mated with the lug, which has a substantially equilateral polygonal geometry.
The substantially equilateral polygonal geometry may be a substantially square geometry with or without one or more chamfered corners.
The lug may have an axial lug width and a lateral lug width, which is substantially equal to the axial lug width.
The lug may include a plurality of platform engagement surfaces. One of the platform engagement surfaces may laterally engage (e.g., contact) a side surface of the slot.
A fastener may rotatably connect the lug to the case. The fastener may be axially and laterally centered to the lug.
The slot may also extend axially into the platform. The slot, for example, may extend axially into the platform through a hook of the platform. The hook may mate with an annular groove that extends axially into the case.
The slot may be one of a plurality of anti-rotation slots that are arranged circumferentially around the centerline. The lug may be one of a plurality of anti-rotation lugs that are respectively mated with the slots. The platform may include a plurality of arcuate platform segments. One or more of the platform segments may each be arranged with one or more of the airfoils and/or one of the slots.
The airfoils may extend radially inwards from the platform. Alternatively, the airfoils may extend radially outwards from the platform.
The stator vane arrangement may be arranged with the compressor section. Alternatively, the stator vane arrangement may be arranged with the turbine section.
The foregoing features and the operation of the invention will become more apparent in light of the following description and the accompanying drawings.
The turbine engine 10 also includes one or more stator assemblies (e.g., 26 and 28). At least one of the stator assemblies may be configured to guide gas between two of the turbine engine sections 18-23. The stator assembly 26, for example, is configured to guide core gas from a rotor stage 29 of the compressor section 19 to an axially adjacent rotor stage 30 of the compressor section 20. At least one of the stator assemblies may also or alternatively be configured to guide gas between adjacent rotor stages of a respective one of the turbine engine sections 18-23. The stator assembly 28, for example, is configured to guide core gas between adjacent rotor stages 31 and 32 of the compressor section 20.
Referring to
The platform 40 extends axially between a first (e.g., upstream) platform end 46 and a second (e.g., downstream) platform end 48. The platform 40 extends radially between a first platform surface 50 (e.g., a radial inner gaspath surface) and a second platform surface 52 (e.g., a radial outer surface). The platform 40 also extends circumferentially around the centerline 12 (see
One or more of the airfoils 42 extend radially (e.g., inwards) from the respective platform segment 54, and are arranged circumferentially about the centerline 12 (see
Each of the slots 44 extends axially into a respective one of the platform segments 54 and through the second hook 58 to a distal end surface 64. Each of the slots 44 extends radially into the respective platform segment 54 from the second platform surface 52 to a distal end surface 66. Each of the slots 44 extends laterally between a first side surface 68 and a second side surface 70, which defines a lateral slot width 72 as illustrated in
Referring to
Referring to
The equilateral polygonal geometry of the lugs 36 may reduce the complexity and/or cost of manufacturing the turbine engine 10. The equilateral polygonal geometry, for example, enables the lugs 36 to be connected to the case 38 without concern for which ones of the platform engagement surfaces 73-76 are adjacent to the side surfaces 68 and 70. In addition, a misalignment between the platform engagement surface 73 and the first side surface 68 may be self-corrected when the respective lug 36 initially engages the platform 40 since the lug 36 may rotate about the fastener 86. The equilateral polygonal geometry of the lugs 36 may also or alternatively reduce the complexity and/or cost of maintaining the turbine engine 10. Instead of replacing the lug 36 when the platform engagement surface 73 has become worn, for example, the lug 36 may be rotated about the fastener 86 a quarter, a half or three-quarters of a turn, for example, such that another one of the platform engagement surfaces 74-76 engages the first side surface 68. The equilateral polygonal geometry therefore may increase the service life of the lug 36 by four times.
In some embodiments, the stator vane arrangement may also include an annular inner vane arrangement platform. The airfoils may extend radially between the inner and outer vane arrangement platforms. The present invention, however, is not limited to any particular stator vane arrangement configuration.
While various embodiments of the present invention have been disclosed, it will be apparent to those of ordinary skill in the art that many more embodiments and implementations are possible within the scope of the invention. For example, the present invention as described herein includes several aspects and embodiments that include particular features. Although these features may be described individually, it is within the scope of the present invention that some or all of these features may be combined within any one of the aspects and remain within the scope of the invention. Accordingly, the present invention is not to be restricted except in light of the attached claims and their equivalents.
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