The present disclosure generally relates to gas turbine engines, and more particularly, to systems and methods for media-finishing airfoils of gas turbine engines.
Gas turbine engines are complex pieces of machinery which, generally speaking, have a compressor to compress and direct air to a combustor, where the air is then mixed with a fuel and ignited, and the resulting combustion gases are then passed through a turbine. To capture the moving air and turn same into rotational energy, the compressor and turbine have a plurality of airfoils in the form of radially outwardly extending blades, and radially inwardly extending vanes.
As engine designs have evolved, the materials from which those airfoils are manufactured, as well as their shape and curvature have become increasingly important. Not only must the airfoils be strong, but they must be able to withstand extreme temperature ranges and be as light weight as possible. They must also be aerodynamically smooth. In order to achieve such an aerodynamic surface, airfoils are typically processed through a vibratory media finishing procedure, such as a drag finishing procedure, to polish and remove metals from the surface of the airfoils. In particular, the a cluster of airfoils is often held by spindles or arms of a drag finishing mechanism and driven and/or spun through a bath of abrasive media at a rate sufficient to provide a finished surface thereon.
Current finishing processes, however, often result in inconsistent finishes among the airfoils, where the airfoils located at the outermost ends of the cluster exhibit a significantly higher rate of wear than the inner airfoils. This is due to the substantially free stream of abrasive media passing at the outermost ends of the cluster, in contrast to the more restricted stream of media passing through the inner airfoils of the cluster.
Such inconsistencies not only cause significant losses in engine efficiency and performance, but also weaken the integrity of the outermost airfoils making them more prone to damage over time. Accordingly, there is a need to provide improved and more consistent apparatus and method for media finishing sensitive metals, such as airfoils. The present disclosure aims to overcome one or more of the deficiencies set forth above.
In one aspect of the present disclosure, fixture for coupling a stator cluster having a plurality of airfoils to a media finishing mechanism is provided. The fixture may include a base having a first end and a second end, a receptacle disposed on the base and configured to receive the stator cluster, and at least one mock airfoil disposed at each of the first and second ends of the base in alignment with the airfoils of the stator cluster.
In a refinement, the receptacle may include a radial curvature corresponding to a radial curvature of the stator cluster, and each of the mock airfoils may include an axial curvature corresponding to an axial curvature of each of the airfoils of the stator cluster.
In another refinement, each mock airfoil may be sized and configured corresponding to a size and configuration of each airfoil of the stator cluster. The mock airfoils may be configured to reduce a wear rate of the endmost airfoils.
In another refinement, the base may include more than one mock airfoil on each end thereof. Each mock airfoil may have a thickness which approximates a thickness of each airfoil.
In another refinement, the base may include one mock airfoil on each end thereof. Each mock airfoil may have a thickness that is greater than a thickness of each airfoil.
In yet another refinement, the base may be attachable to a drag finishing mechanism.
In another aspect of the disclosure, a system for media finishing is provided. The system may include at least one stator cluster having a plurality of airfoils radially disposed thereon, a fixture having a first end, a second end, and a receptacle disposed between the first and second ends configured to receive the stator cluster, at least one mock airfoil disposed at each of the first and second ends of the fixture in radial alignment with and adjacent to the endmost airfoils of the stator cluster; and an abrasive media bath into which the fixture and airfoil cluster are placed and dragged
In a refinement, the airfoils may be radially inwardly disposed on the stator cluster and separated by a predefined distance. Each mock airfoil may be radially inwardly disposed on the fixture and separated from the adjacent endmost airfoil by the predefined distance.
In another refinement, the receptacle may include a radial curvature which corresponds to a radial curvature of the stator cluster, and each of the mock airfoils may include an axial curvature corresponding to an axial curvature of each of the airfoils of the stator cluster.
In another refinement, each mock airfoil may be sized and configured corresponding to a size and configuration of each airfoil of the stator cluster. The mock airfoils may be configured to reduce a wear rate of the endmost airfoils.
In another refinement, a thickness of each mock airfoil may be greater than a thickness of the airfoils.
In another refinement, more than one mock airfoil may be disposed at each end of the fixture.
In a related refinement, a thickness of each mock airfoil may be substantially equal to a thickness of the airfoils.
In yet another refinement, the airfoil cluster is one of a stator vane cluster and a rotor blade cluster.
In yet another aspect of the disclosure, a method for media finishing a stator cluster having a plurality of airfoils is provided. The method may determine a configuration of the airfoils, provide a fixture having at least one mock airfoil of substantially like configuration at each end thereof, attach the stator cluster onto the fixture such that each mock airfoil is positioned adjacent to and in alignment with an endmost airfoil of the stator cluster, and couple the fixture to a media finishing mechanism.
In a refinement, each mock airfoil may be sized and configured corresponding to a size and configuration of each airfoil of the stator cluster. The mock airfoils may be configured to reduce a wear rate of the endmost airfoils.
In another refinement, the fixture may further be provided with a receptacle for receiving the stator cluster thereon. The receptacle may be provided with a radial curvature corresponding to a radial curvature of the stator cluster.
In another refinement, more than one mock airfoil may be provided on each end of the fixture. Each mock airfoil may have substantially the same thickness as each airfoil of the stator cluster.
In another refinement, each mock airfoil may be configured such that an axial curvature thereof substantially corresponds to an axial curvature of the stator cluster airfoils.
In yet another refinement, the fixture may be coupled to a drag finishing mechanism.
These and other aspects and features of the present disclosure will be more readily understood when read in light of the accompanying drawings.
Referring now to
As shown, the gas turbine engine 20 includes a fan 22, compressor 24, combustor 26, and turbine 28 axially aligned along axis 30. As the fan 22 rotates, ambient air is directed into the compressor 24. That air is compressed by the compressor 24 and in turn directed to the combustor 26 where it is mixed with fuel and ignited. The resulting combustion gases are then passed through the turbine 28 causing the rotor 32 of the turbine 28 to rotate. As the rotor 32 is mounted to a shaft 34 extending along the axis 30, rotation of the turbine 28 also causes the compressor 24 to rotate to thus continue the cycle. Many different gas turbine engine designs exist, including dual spool engines with high and low pressure compressors and turbines mounted on concentric shafts, but again such details are widely known in the industry and need not be repeated herein.
In order to capitalize on the movement of the air through the engine, and both align that moving air as desired and transform it into rotational energy in the shaft 34, the compressor 24 and turbine 28 include a plurality of specifically shaped airfoils 36. More specifically, the compressor 24 and turbine 28 include airfoils 36, which may be provided in the form of radially outwardly extending rotor blades 38, and radially inwardly extending stator vanes 40. The blades 38 are curved and movable so as to capture the moving air and cause the compressor 24 and/or turbine 28 to rotate, while the vanes 40 are fixed so as to reorient and align the incoming moving air as desired before being communicated to the next blade.
During the assembly of such compressors 24 and turbines 28, groups of airfoils 36 are joined together in clusters 42, one of which is shown in
Referring again to
Referring now to
The fixture 102 of
Still referring to
In particular, the mock airfoils 118, 120 may be provided with a general thickness 126, width 128 and/or height 130 configured to appropriately obstruct the flow of abrasive media against the endmost airfoils 122, 124 and to correct for any excess wear thereon. For example, if only one mock airfoil 118, 120 is provided at each end 108, 110 of the base 106 as in
With the cluster 42 so mounted into the fixture 102, both can then be lowered into a bath 140 filled with abrasive media 142, as shown in
Significantly, not only does such motion result in the desired aerodynamically smooth surfaces 46, but through the provision of the mock airfoils 118, 120, the sacrificial material of the mock airfoils 118, 120 absorbs the brunt of the interaction, allowing the actual airfoils 36 therebetween to be more uniformly engaged by the abrasive bath 140. This results in more uniformly produced airfoils 36 that are better able to withstand actual use and to do so with a more predictable, and long-lasting, life span.
Turning now to
Once the fixture 102 with appropriate mock airfoils 118, 120 is provided, the cluster 42 may be removably attached to the fixture 102 in a step 204. More specifically, as shown in
In general, the foregoing disclosure finds utility in various industrial applications relating to surface finishing of airfoils of gas turbine engines, such as blades and vanes of compressors and turbines of gas turbine engines. More specifically, the systems and methods disclosed may be used to provide improved and more consistent means of finishing, polishing and removing metals from the surfaces of airfoils disposed along a stator vane or rotor blade cluster of a compressor or turbine.
By providing a fixture for holding a cluster of airfoils which incorporates sacrificial mock airfoils positioned at each end of the fixture, the present disclosure corrects the flow of abrasive media applied to the endmost airfoils, such that the overall wear rate is more consistent throughout a given cluster regardless of the relative positions of the airfoils.
From the foregoing, it will be appreciated that while only certain embodiments have been set forth for the purposes of illustration, alternatives and modifications will be apparent from the above description to those skilled in the art. These and other alternatives are considered equivalents and within the spirit and scope of this disclosure and the appended claims.
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