The present invention relates generally to gas turbine engines and, more particularly, to variable vane devices and methods for producing variable vane devices containing rotationally-driven translating vane structures.
By common design, a variable vane device contains a plurality of rotatable vanes, which are arranged in an annular array. An outer shroud member circumscribes the annular array of rotatable vanes, which, in turn, circumscribes an inner hub member. Collectively, the outer shroud member and the inner hub member define a static flow assembly through which an annular flow passage extends. The rotatable vanes are positioned within this annular flow passage and can be turned about individual rotation axes to adjust the flow rate through the flow passage. Variable vane devices of this type are commonly integrated into Gas Turbine Engines (GTEs). For example, a GTE platform may be equipped with an Inlet Guide Vane (IGV) system, which contains a variable vane device positioned immediately upstream of the GTE's compressor section. Additionally or alternatively, one or more variable vane devices may be integrated into the compressor section and/or turbine section of a given GTE platform. During engine operation, an actuator rotates the vanes through an angular Range of Motion (ROM) in accordance with commands received from a controller, such as a Full Authority Digital Engine Controller (FADEC). The FADEC may command the actuator to periodically or continually adjust vane angular position in accordance with a predetermined schedule, as a function of core engine speeds, or as a function of another operational parameter of the GTE.
While capable of boosting various measures of engine performance, conventional variable vane devices remain limited in certain respects. As a primary limitation, variable vane devices are prone to leakage at the interfaces between the rotatable vanes and the surrounding static flow assembly (referred to herein as “end gap leakage”). End gap leakage is due, at least in part, to the provision of radial gaps or endwall clearances between edges of the rotatable vanes, the inner circumferential surface or endwall of the outer shroud member, and the outer circumferential surface or endwall of the inner hub member. Variable vane devices are typically designed to minimize such endwall clearances to the extent possible, while ensuring that rubbing, binding, or other physically-restrictive contact does not occur between the vane edges, the shroud endwall, and the hub endwall. However, due to the relatively complex geometric relationship between the vane edges and the annular endwalls, the endwall clearances vary dynamically in conjunction with vane rotation with a corresponding leakage penalty. Such leakage may lower GTE efficiency and result in end gap leakage flow (e.g., vortices and wakes) creating excitation forces, which can result in increased strains on rotors and other components downstream of the variable vane device.
Variable vane devices containing rotationally-driven translating vane structures are provided. In one embodiment, the variable vane device includes a flow assembly having a centerline, an annular flow passage extending through the flow assembly, cam mechanisms, and rotationally-driven translating vane structures coupled to the flow assembly and rotatable relative thereto. The translating vane structures include vane bodies, which are positioned within the annular flow passage and angularly spaced about the centerline. During operation of the variable vane device, the cam mechanisms adjust translational positions of the vane bodies within the annular flow passage in conjunction with rotation of the translating vane structures relative to the flow assembly; e.g., the cam mechanisms may impart each of the vane bodies with a unique radial position corresponding to each unique rotational position of the corresponding translating vane structure. By virtue of the translational movement of the translating vane structures, a reduction in the clearances between the vane bodies and neighboring flow assembly surfaces can be realized to reduce end gap leakage and boost device performance levels. Although not restricted to any particular usage or application, embodiments of the variable vane devices may be advantageously utilized within Gas Turbine Engine (GTE) platforms to boost engine performance and/or to reduce downstream rotor excitation.
In another embodiment, the variable vane device includes a flow assembly through which a flow passage extends. A non-rotating ramped surface is coupled to the flow assembly in a rotationally-fixed relationship. A rotationally-driven translating vane structure is coupled to the flow assembly and rotatable relative thereto through an angular Range of Motion (ROM). The rotationally-driven translating vane structure includes a vane body positioned within the flow passage. A rotating ramped surface is further fixedly coupled to the rotationally-driven translating vane structure and rotates therewith. The rotating ramped surface slides along the non-rotating ramped surface as the rotationally-driven translating vane structure rotates through the angular ROM to adjust the translational position of the vane body within the flow passage. In some implementations, the variable vane device may also include a resilient preload member, such as a spring or wave washer, which exerts a translational force on the rotationally-driven translating vane structure urging contact between the non-rotating and rotating ramped surfaces.
Embodiments of a method for producing a variable vane device, which includes rotationally-driven translating vane structures, are further provided. The variable vane devices may be produced pursuant to original manufacture or, instead, produced by modifying a pre-existing variable vane device initially lacking rotationally-driven translating vane structures. In an embodiment, the method includes the step or process of providing a non-rotating ramped surface coupled to a flow assembly in a rotationally-fixed relationship, as well as further providing a rotating ramped surface fixedly coupled to a rotationally-driven translating vane structure including a vane body positioned in a flow passage of the flow assembly. The non-rotating and rotating ramped surfaces are placed in contact such that the rotating ramped surface slides along the non-rotating ramped surface as the rotationally-driven translating vane structure rotates relative to the flow assembly to adjust a translational position of the vane body within the flow passage.
At least one example of the present invention will hereinafter be described in conjunction with the following figures, wherein like numerals denote like elements, and:
The following Detailed Description is merely exemplary in nature and is not intended to limit the invention or the application and uses of the invention. Furthermore, there is no intention to be bound by any theory presented in the preceding Background or the following Detailed Description. The term “exemplary,” as appearing throughout this document, is synonymous with the term “example” and is utilized repeatedly below to emphasize that the description appearing in the following section merely provides multiple non-limiting examples of the invention and should not be construed to restrict the scope of the invention, as set-out in the Claims, in any respect. Furthermore, terms such as “comprise,” “include,” “have,” and variations thereof are utilized herein to denote non-exclusive inclusions. Such terms may thus be utilized in describing processes, articles, apparatuses, and the like that include one or more named steps or elements, but may further include additional unnamed steps or elements. Finally, the term “bore,” as appearing herein, refers to a cavity having a generally cylindrical geometry and regardless of the particular manner in which the bore is formed.
The following sets-forth multiple exemplary embodiments of a variable vane device containing rotationally-driven translating vane structures. The translating vane structures are “rotationally-driven” in the sense that, as each vane structure is turned about its respective rotational axis, the rotating vane structure slides linearly or translates along its rotational axis. Such translational movement is imparted to the translating vane structures by cam mechanisms, which are further contained within the variable vane device. The cam mechanisms can assume various different forms for imparting translational movement to the vane structures in conjunction with rotation thereof. In an embodiment, the cam mechanism each include at least one pair of ramped surfaces between which relative rotation occurs when the translating vane structures rotate, as well as at least one resilient preload member urging contact between the ramped surfaces. The ramped surfaces can be machined or otherwise integrally formed in selected surfaces of a static flow assembly and the translating vane structures, formed on discrete pieces (e.g., annular spacers or ramped washers) rotationally affixed to the static flow assembly and to the translating vane structures, or a combination thereof. As the translating vane structures rotate, sliding movement between the ramped surfaces varies the axial heights of the cam mechanisms and, therefore, the translational positions of the vane bodies within the flow passage. By dimensioning the ramped surfaces appropriately, the translational positions of the vane bodies may vary dynamically in conjunction with vane rotation in a manner minimizing the radial gaps or endwall clearances, as taken over the angular Range of Motion (ROM) of the vane structures. End gap leakage across the interfaces between the vane bodies and the annular endwalls may be reduced as a result, with a corresponding improvement in device efficiency.
Embodiments of the variable vane device are advantageously utilized within Gas Turbine Engine (GTE) platforms and are consequently primarily described below in this exemplary context. In this regard, embodiments of the variable vane device are well-suited for usage within Inlet Guide Vane (IGV) systems of the type commonly included within GTE platforms, within variable compressor stages of a GTE, and/or within variable turbine stages of a GTE. Any practical number of variable vane devices can be incorporated into a given GTE, with larger GTE platforms often containing multiple variable vane devices distributed across different stages of the intake, compressor, and/or turbine sections. This notwithstanding, it is emphasized that embodiments of the variable vane device are not restricted to usage in conjunction with GTEs, but rather can be utilized within any fluid-conducting system or platform, including turbochargers, into which one or more low leakage variable vane devices are usefully integrated.
A flow passage 20 is provided through flow assembly 12, 14 and may extend substantially parallel to centerline 16. In the embodiment shown in
Variable vane device 10 further contains a plurality of rotationally-driven translating vane structures 28. Only a few of translating vane structures 28 (and many of the other repeating components and features of variable vane device 10) are labeled in
Inboard stem portions 34 are matingly received in a number of bores 38, which are formed in inner hub member 14, which are angularly spaced about centerline 16, and which penetrate hub endwall 26. Similarly, outboard stem portions 32 are received through a like number of bores 36, which are provided in outer shroud member 12 and which are angularly spaced about centerline 16. Bores 36 penetrate or intersect shroud endwall 24 and extend into a plurality of cylindrical extensions or bosses 48, which project radially outward from shroud member 12. Outboard stem portions 32 extend fully through bores 36 and bosses 48 for connection to an annular array of drive arms 40. The opposing ends of drive arms 40 are rotatably joined to a drive ring assembly 42. During operation of variable vane device 10, a non-illustrated actuator rotates drive ring assembly 42 to swivel drive arms 40 about their respective rotational axes or pivot points. Rotation of drive ring assembly 42 turns rotationally-driven translating vane structures 28 about their respective rotational axes in a synchronized manner. Adjustments in the angular positioning of translating vane structures 28 may be implemented in accordance with a predetermined schedule, as a function of core engine speeds, or as a function of another operational parameter of the GTE. To facilitate rotation of translating vane structures 28, a number of flanged tubular bushings or sleeves 44 may be received within bores 36 and positioned around outboard stem portions 32. Although hidden from view in
Rotationally-driven translating vane structure 28 further contains first and second spacers 60, 62. When variable vane device 10 is assembled, spacers 60, 62 are received within bore 36 provided in outer shroud member 12. Spacers 60, 62 are thus hidden from view in
The illustrated portion of variable vane device 10 shown in
Relative rotation between spacers 60, 62 occurs in conjunction with rotation of rotationally-driven translating vane structure 28 relative to outer shroud member 12 and, more generally, relative to static flow structure 12, 14. As relative rotation occurs between spacers 60, 62, ramped surface 66 slides along ramped surface 64 to adjust the axial height of spacer pair 60, 62. Stated differently, the width of the gap or gaps that separate the regions of surfaces 64, 66 that rotate out of contact increases in conjunction with relative rotation of spacers 6062. As the axial height across spacer pairs 60, 62 increases, spacer pair 60, 62 urges translating vane structure 28 to slide radially inward (downward in
The geometry (e.g., pitch, dimensions, periodicity, etc.) of ramped surfaces 64, 66 can be adjusted, by design, to translate vane body 30 through any desired range of linear positions in conjunction with rotation of translating vane structure 28. In the illustrated example, a single ramped surface 64, 66 is provided on each of spacers 60, 62 and extends fully around rotational/translational axis 58 (
In the embodiment shown in
Turning now to
As further plotted in graph 84 (
In the embodiment shown in
In certain embodiments, variable vane device 10 may be further designed such that the hub endwall clearance (trace 86) and the shroud endwall clearance (trace 88) are maintained at substantially constant values across the angular ROM of translating vane structure 28, whether measured adjacent trailing edge 56 or leading edge 54 of vane body 30; the term “substantially constant,” as appearing herein, indicating that the maximum value of a given radial clearance or gap width is less than twice the minimum value of the radial clearance, as taken across the angular ROM of the translating vane structure. Additionally, in embodiments, the difference between the maximum and minimum values of the clearance width for the hub endwall clearance (trace 86) and/or for the shroud endwall clearance (trace 88) may be less than 2% the chord length of vane body 30 (
There has thus been provided an exemplary embodiment of a variable vane device containing rotationally-driven translating vane structures and a number of cam mechanisms, which adjust the translational position of the vane bodies in conjunction with rotational movement of the translating vane structures. In the above-described example, each cam mechanism contains a pair of ramped surfaces between which relative rotation occurs in conjunction with vane structure rotation. The physical characteristics of ramped surfaces 64, 66 (e.g., slope, amplitude, and phase) can be tailored, as desired, to control the rate, amount, and timing respectively of the clearances through the angular ROM of the rotationally-driven translating vane structures. While the ramped surfaces were provided on discrete pieces (e.g., ramped spacers) in the foregoing exemplary embodiment, this need not be the case in all embodiments. Instead, in further embodiments, the ramped surfaces can be provided on other surfaces of the variable vane device and, perhaps, integrally formed with the static flow assembly and/or the rotationally-driven translating vane structures. A further exemplary embodiment of the variable vane device will now be described in conjunction with
The foregoing has thus provided multiple exemplary embodiments of a variable vane devices containing rotationally-driven translating vane structures. By virtue of the controlled translational movement of the translating vane structures, a reduction in the clearances between the vane bodies and neighboring flow assembly surfaces is achieved to reduce end gap leakage and boost device performance levels. The controlled translational movement may be imparted to the translating vane structures utilizing cam mechanism, which are further integrated into the variable vane device. In embodiments wherein the flow assembly has an annular endwall (e.g., a hub or shroud endwall) partially bounding the annular flow passage and wherein the vane bodies are separated or radially offset from the annular endwall by radial clearances, the cam mechanisms may be configured to adjust the translational positions of the vane bodies such that an average value of the radial clearances is decreased due to the translational movement imparted to the rotationally-driven translating vane structures by the cam mechanisms. In such embodiments, the radial clearances vary from a maximum value to a minimum value over an angular ROM of the translating vane structures, and wherein the cam mechanisms are configured to adjust the translational positions of the vane bodies within the annular flow passage such that the difference between the maximum and minimum values is less than 2% a chord length of the vane body.
In the above-described exemplary embodiments, the cam mechanisms each include a rotating ramped surface and a non-rotating ramped surface, which engage the rotating ramped surface along a sliding interface. In the exemplary embodiment discussed above in conjunction with
The foregoing has further provided methods for producing a variable vane device containing rotationally-driven translating vane structures. The variable vane devices may be fabricated pursuant to original manufacture. Alternatively, the variable vane device may be produced by modifying a pre-existing variable vane device containing vane structures initially designed for rotational, but not translational movement. In the latter case, a pre-existing variable vane device lacking translating vane structures may be obtained and modified to include those features creating the desired translational movement of the vane structures. As one possibility, ramped surfaces can be machined into selected surfaces of the pre-existing variable vane device, such as the interior surfaces of the bores provided in the static flow assembly and/or into the button portions of the vane structures. Discrete members having ramped surfaces can be added to the pre-existing variable vane device by retrofit installation. For example, a first set of ramped spacers can be inserted into the bores of the static flow assembly and rotationally affixed thereto in different manners, while a second set of ramped spacers can be inserted around the stem portions of the vane structures as previously described. Similarly, resilient preload members can be installed by retrofit in various different locations as appropriate to exert a convergent preload force urging contact of mating pairs of the ramped surfaces. Material can be removed from the interior of the bores and/or other structural modifications can be made to the pre-existing variable vane device to accommodate the addition of any such ramped spacers and resilient preload members.
While at least one exemplary embodiment has been presented in the foregoing Detailed Description, it should be appreciated that a vast number of variations exist. It should also be appreciated that the exemplary embodiment or exemplary embodiments are only examples, and are not intended to limit the scope, applicability, or configuration of the invention in any way. Rather, the foregoing Detailed Description will provide those skilled in the art with a convenient road map for implementing an exemplary embodiment of the invention. It being understood that various changes may be made in the function and arrangement of elements described in an exemplary embodiment without departing from the scope of the invention as set-forth in the appended claims.
This application is a continuation of Application Ser. No. 15/420,717, filed Jan. 31, 2017, now U.S. Pat. No. 10,495,108.
Number | Name | Date | Kind |
---|---|---|---|
4278398 | Hull | Jul 1981 | A |
6887035 | Bruce | May 2005 | B2 |
7922445 | Pankey et al. | Apr 2011 | B1 |
9333603 | Christophel | May 2016 | B1 |
20150016946 | Ottow | Jan 2015 | A1 |
20160024959 | Do | Jan 2016 | A1 |
20160108821 | Robertson, Jr. | Apr 2016 | A1 |
20160251980 | Slavens | Sep 2016 | A1 |
20170254266 | Milani | Sep 2017 | A1 |
20170268357 | Torres | Sep 2017 | A1 |
20180163543 | Morton | Jun 2018 | A1 |
Number | Date | Country |
---|---|---|
2116694 | Nov 2009 | EP |
2573363 | Mar 2013 | EP |
Entry |
---|
Extended EP Search Report for Application No. 18154007.1 dated Jun. 19, 2018. |
Number | Date | Country | |
---|---|---|---|
20200049163 A1 | Feb 2020 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 15420717 | Jan 2017 | US |
Child | 16656211 | US |