The present disclosure relates generally to components used in a gas turbine engine, and more specifically to components that include ceramic matrix composite materials.
Gas turbine engines are used to power aircraft, watercraft, power generators, and the like. Gas turbine engines typically include a compressor, a combustor, and a turbine. The compressor compresses air drawn into the engine and delivers high pressure air to the combustor. In the combustor, fuel is mixed with the high pressure air and is ignited. Products of the combustion reaction in the combustor are directed into the turbine where work is extracted to drive the compressor and, sometimes, an output shaft. Left-over products of the combustion are exhausted out of the turbine and may provide thrust in some applications.
Compressors and turbines typically include alternating stages of static vane assemblies and rotating wheel assemblies. The rotating wheel assemblies include disks carrying blades around their outer edges. When the rotating wheel assemblies turn, tips of the blades move along blade tracks included in static shrouds that are arranged around the rotating wheel assemblies.
Some shrouds positioned in the turbine may be exposed to high temperatures from products of the combustion reaction in the combustor. Such shrouds sometimes include components made from ceramic matrix composite materials suited for use in high temperature environments.
The present disclosure may comprise one or more of the following features and combinations thereof.
According to the present disclosure, a blade track for use in a gas turbine engine includes a first segment comprising ceramic-matrix composite materials and a second segment comprising ceramic-matrix composite materials. The first segment includes a first band shaped to extend part-way around a central axis, a first finger support that extends partway around the central axis from a circumferential end of the first band, and a first attachment finger that extends from an end of the first finger support. The second segment includes a band shaped to extend part-way around the central axis a finger support that extends partway around the central axis from a circumferential end of the band, and a second attachment finger that extends from an end of the finger support.
In some embodiments, the first attachment finger extends from the first finger support in an axial direction and the second attachment finger extends from the second finger support in an axial direction opposite the first attachment finger. The first attachment finger and the second attachment finger combine to provide an interlocked joint between the first segment and the second segment.
In some embodiments, the first finger support extends from the circumferential end of the first band and the second finger support extends from the circumferential end of the second band opposite the first finger support. The first band, the first finger support, and the first finger form a first finger-receiving space between the circumferential end of the first band and the first finger.
In some embodiments, the second band, the second finger support, and the second finger form a second finger-receiving space between the circumferential end of the second band and the second finger. The first finger extends into the second finger-receiving space formed in the second segment and the second finger extends into the first finger-receiving space formed in the first segment. In some embodiments, the first band and the second band have a thickness that is about equal to a thickness of the first finger and the second finger.
In some embodiments, the first segment further includes a third attachment finger that extends from the first finger support in the axial direction and the first and third fingers cooperate with the first finger support to form a first finger-receiving space and a second finger-receiving space. The first attachment finger is positioned radially below the first finger-receiving space and is spaced apart circumferentially from the circumferential end of the first band and the third attachment finger is positioned radially above the third finger-receiving space and is adjacent the circumferential end of the first band. The second segment further includes a fourth attachment finger that extends from the second finger support in the axial direction and the second and fourth fingers cooperate with the second finger support to form a third finger-receiving space and a fourth finger-receiving space. The second attachment finger is positioned radially below the third finger-receiving space and is spaced apart circumferentially from the circumferential end of the second band and the fourth attachment finger is positioned radially above the fourth finger-receiving space and is adjacent the circumferential end of the second band.
In some embodiments, the first segment is configured to bond to the second segment such that the first attachment finger is extends into the fourth finger-receiving space, the second attachment extends into the second finger-receiving space, the third attachment finger extends into the third finger-receiving space, and the fourth attachment finger extends into the first finger-receiving space. The first band and the second band have a first thickness and each of the fingers has a second thickness and the second thickness may be less than the first thickness. The second thickness may be about half of the second thickness.
In some embodiments, the blade track includes at least one mount pin that extends through the first and second attachment fingers. The at least one mount pin may include a first mount pin that extends in the radial direction from the first attachment finger into the fourth attachment finger and a second mount pin that extends in the radial direction from the second attachment finger into the third attachment finger. The at least one mount pin may include a first mount pin that extends in the axial direction from the first finger support to the second finger support through one of the first and fourth attachment fingers and a second mount pin that extends in the axial direction from the first finger support to the second finger support through one of the second and the third attachment fingers.
In some embodiments, the ceramic matrix composite materials includes reinforcement-preform fibers suspended in a ceramics material matrix. The reinforcement-preform fibers may be oriented primarily in the circumferential and axial directions.
According to another aspect of the present disclosure, a method of making a blade track for a gas turbine engine is described. The method may include providing a first blade track segment having a band, a finger support and a finger and a second blade track segment having a band, a finger support and a finger. The method may also include chemical vapor infiltrating the first blade track segment and the second blade track segment to partially densify the first blade track segment and the second blade track segment.
In some embodiments, the method may include assembling the blade track by inserting the first finger formed on the first blade track segment into a first finger-receiving space formed in the second blade track segment and inserting the second finger formed on the second blade track segment into a second finger-receiving space formed in the first blade track segment to interlock the first blade track segment and the second blade track segment. The method may also include slurry melt infiltrating the first blade track segment and the second blade track segment to bond the first blade track segment and the second blade track segment.
In some embodiments, the method may include machining the finger supports and the fingers into the first blade track segment and the second blade track segment to form the finger-receiving spaces in the first and second blade track segments.
These and other features of the present disclosure will become more apparent from the following description of the illustrative embodiments.
For the purposes of promoting an understanding of the principles of the disclosure, reference will now be made to a number of illustrative embodiments illustrated in the drawings and specific language will be used to describe the same.
An illustrative aerospace gas turbine engine 10 includes a fan 12, a compressor 14, a combustor 16, and a turbine 18 as shown in
The turbine 18 includes at least one turbine wheel assembly 11 and a blade track 20 positioned to surround the turbine wheel assembly 11 as shown in
Blade track 20 extends around the turbine wheel assembly 11 to block combustion products from passing over the blades 13 through a gap without pushing the blades 13 to rotate. Blade track 20 is made from ceramic matrix composite materials, such as, for example silicon-carbide fibers suspended in a silicon-carbide matrix. However, any suitable ceramic-containing composition may be used depending on application.
A first embodiment of blade track 20, in accordance with the present disclosure is shown in
As shown in
The first segment and the second segment 28 interlock and form the interlocked joint 24 to block movement of the first segment 26 in circumferential and axial directions relative to the second segment 28. The first segment 26 includes a band 30, a finger support 32, and an attachment finger 34 as shown in
The second segment 28 includes a band 36, a finger support 38, and an attachment finger 40 as shown in
The first and second segments 26, 28 may be manufactured with respective bands 30, 36, finger supports 32, 38, and fingers 34, 40, or the bands 30, 36, finger supports 32, 38, and fingers 34, 40 may be machined into the first and second segments 26, 28. Each band 30, 36, finger support 32, 38, and finger 34, 40 has a thickness t that is continuous across the entire blade track 20 as shown in
The first segment 26 complements the second segment 28 so that the first and second segments 26, 28 combine and interlock to block movement of the first and second segments 26, 28 in the circumferential and axial directions relative to one another. The first segment 26 is formed to include a finger-receiving space 33 as shown in
Likewise, the second segment 28 is formed to include a complementary finger-receiving space 39 as shown in
The first segment 26 and the second segment 28 are constructed of ceramic matrix composite materials including reinforcement-preform fibers 42 suspended in a ceramics material matrix 44 as shown in
The reinforcement-preform fibers 42 are oriented in the circumferential and axial directions to align the reinforcement-preform fibers 42 along planes formed by the interlocked joint 24. The interlocked joint 24 may have a lower ultimate strength than the reinforcement-preform fibers 42 suspended in the ceramics material matrix 44. Any failures, such as cracks, for example, in the full-hoop blade track 20 may occur along the interlocked joint 24 and would have to pass though the reinforcement-preform fibers 42 and the ceramics material matrix 44 due to the arrangement of the interlocked joint 24. As such, the full-hoop blade track 20 may be strengthened by the arrangement of the interlocked joint 24.
Another embodiment of a full-hoop blade track 220, in accordance with the present disclosure, is shown in
As shown in
The first segment 226 and the second segment 228 interlock and form the interlocked joint 224 to block movement of the first segment 226 and the second segment 228 in circumferential, axial, and radial directions relative to one another. The first segment 226 includes a band 230, a finger support 232, a first attachment finger 234, and a second attachment finger 235 as shown in
The second segment 228 includes a band 236, a finger support 238, a first attachment finger 240, and a second attachment finger 241 as shown in
The first and second segments 226, 228 may be manufactured with respective bands 230, 236, finger supports 232, 238, and fingers 234, 235, 240, 241 or the bands 230, 236, finger supports 232, 238, and fingers 234, 235, 240, 241 may be machined into the first and second segments 226, 228. Each band 230, 236 and finger support 232, 238 has a thickness t1 that is continuous across the blade track 20 as shown in
The first segment 226 complements the second segment 228 so that the first and second segments 226, 228 combine and interlock to block movement of the first and second segments 226, 228 in the circumferential, axial, and radial directions relative to one another. The first segment 226 is formed to include a first finger-receiving space 242 and a second finger-receiving space 244 as shown in
Likewise, the second segment 228 is formed to include a complementary first finger-receiving space 246 and a complementary second finger-receiving space 248 as shown in
The first segment 226 and the second segment 228 are constructed of ceramic matrix composite materials including reinforcement-preform fibers 250 suspended in a ceramics material matrix 252 as shown in
The reinforcement-preform fibers 250 are oriented in the circumferential and axial directions to align the reinforcement-preform fibers 250 along planes formed by the interlocked joint 224. The interlocked joint 224 has a lower ultimate strength than the reinforcement-preform fibers 250 suspended in the ceramics material matrix 252. Any failures, such as cracks, for example, in the full-hoop blade track 220 may occur along the interlocked joint 224 and will have to pass though the reinforcement-preform fibers 250 and the ceramics material matrix 252 due to the arrangement of the interlocked joint 224. As such, the full-hoop blade track 220 is strengthened by the arrangement of the interlocked joint 224.
The blade track 220 may further include at least one radial reinforcement pin 254 as shown in
Illustratively, the blade track 220 includes two radial reinforcement pins 256 that interconnect the first segment 226 and the second segment 228 as shown in
Illustratively, the blade track 220 includes two axial reinforcement pins 258 that interconnect the first segment 226 and the second segment 228 as shown in
Another embodiment of a blade-track 320, in accordance with the present disclosure, is shown in
The first segment 326 is similar to first segment 226 of blade track 220 and includes a band 330, a finger support 332, a first finger 334, and a second finger 335 as shown in
The locking feature 360 includes an attachment rib 362 coupled to the first finger 334 of the first segment 326 and an attachment slot 364 formed in the second finger 341 of the second segment 328 that complements the attachment rib 362. When the first segment 326 and the second segment 328 are interlocked, the attachment rib 362 extends into the attachment slot 364 to block axial movement of the first and second segments 326, 328 relative to one another.
Illustratively, the first segment 326 and the second segment 328 are made from ceramic matrix composite materials such as, for example, a ceramics-material matrix suspended in silicon-carbide fibers. The first and second segments 326, 328 are partially densified via chemical vapor infiltration (CVI) prior to being interlocked. Once interlocked, the first and second segments 326, 328 are slurry-melt infiltrated (SMI) to rigidify the blade track 320.
In illustrative embodiments, the single piece, full hoop, CMC, blade track embodied here may have a simple cross section that is cross keyed into the case. The single piece may eliminate all the intersegment gaps in the other configurations therefore eliminating potential leakage paths between the secondary air system and the hot flow path gases. This may also reduce the number of sealing components over the typical metallic configuration. The CMC lends itself to this configuration since it may not require the cooling air of a typical metallic component. Additionally, the lower thermal expansion characteristics of the ceramic matrix composites may be used to better match the rotor growth between specific conditions (namely cruise and max take off). In this way it can help control of the tip clearance to the blades.
In illustrative embodiments, scaling the hoop to the size of larger engine applications may present challenges to manufacturing. The size of hoop that may go into large engines may end up being large when compared to typical manufacturing equipment and may be a challenge to manufacture. The CMC manufacturing process may thus impose limits on the size of components. The different steps in the manufacturing process may have different limits. This disclosure may capture a way to make a single hoop by joining smaller arc segments with different joint geometries within the disclosed manufacturing process. The smaller arc segments may be at least partially densified (CVI). Then the arc segments may be tooled together and the full hoop component may be fully densified. The joining may be done with typical manufacturing methods (SMI).
Illustratively, the first embodiment may depict a mechanical interlock between the arc segments. Machining the edge of the arc segments may be reasonable with the geometry as shown. The arc segments in this embodiment may be made from multiple layup options including unidirectional plies, 2D woven, or 3D architecture. Allowing the laminate to have fibers oriented in the hoop direction and in the axial direction may put fibers in the typical crack plane. In other words, if a crack is generated in the joint gap along any straight edge of this geometry, the failure plane may require the crack to propagate through fibers with a higher ultimate strength than the matrix/joint material.
Illustratively, the second and third embodiments herein each have arc segments with multiple interlocking fingers that slide together. These joints may be configured such that the only direction which the joint can come apart without breaking fiber is opposite of how it was assembled. These joints may provide an extra degree of constraint relative to the first embodiment in that radial movement is no longer possible without breaking fibers. Additionally pins could be added to further strengthen the joint.
In illustrative embodiments, the system may snap together. Joints according to the present disclosure not be used on a hoop design but, when use in a hoop design, they may provide a built in locking feature that, once joined thru the SMI process may limit the part from coming apart in the direction it was assembled.
It is contemplated that joints according to the present disclosure may be incorporated into other ceramic matrix composite components. For example, joints like those described herein may be used to join tiles in a combustion liner and/or panels in an exhaust heat shield. Such other components may comprise ceramic matrix composite materials designed for high temperature use in combustors or exhaust systems.
While the disclosure has been illustrated and described in detail in the foregoing drawings and description, the same is to be considered as exemplary and not restrictive in character, it being understood that only illustrative embodiments thereof have been shown and described and that all changes and modifications that come within the spirit of the disclosure are desired to be protected.
This application claims priority to and the benefit of U.S. Provisional Patent Application No. 62/553,459, filed 1 Sep. 2017, the disclosure of which is now expressly incorporated herein by reference.
Number | Date | Country | |
---|---|---|---|
62553459 | Sep 2017 | US |