The present disclosure relates generally combustors used in gas turbine engines; more particularly, the present disclosure relates to a combustor including a metallic shell and a liner made up of ceramic tiles.
Engines, and particularly 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. The combustor is a component or area of a gas turbine engine where combustion takes place. In a gas turbine engine, the combustor receives high pressure air and adds fuel to the air which is burned to produce hot, high-pressure gas. After burning the fuel, the hot, high-pressure gas is passed from the combustor to the turbine. The turbine extracts work from the hot, high-pressure gas to drive the compressor and residual energy is used for propulsion or sometimes to drive an output shaft.
Combustors include liners that contain the combustion process during operation of a gas turbine engine. The liner included in the combustor is designed and built to withstand high-temperature cycles induced during combustion. In some cases, liners may be made from metallic superalloys. In other cases, liners may be made from ceramic matrix composites (CMCs) which are a subgroup of composite materials as well as a subgroup of technical ceramics. CMCs may comprise ceramic fibers embedded in a ceramic matrix, thus forming a ceramic fiber reinforced ceramic (CFRC) material. The matrix and fibers can consist of any ceramic material, whereby carbon and carbon fibers can also be considered a ceramic material.
Combustors and turbines made of metal alloys require significant cooling to be maintained at or below their maximum use temperatures. The operational efficiencies of gas turbine engines are increased with the use of CMC materials that require less cooling and have operating temperatures that exceed the maximum use temperatures of metal alloys. The reduced cooling required by CMC combustor liners when compared to metal alloy combustion liners permits greater temperature uniformity and thereby leads to reduced NOx emmisions.
One challenge relating to the use of CMC tiles is that they are sometimes secured to the surrounding metal shell via metal fasteners. Metal fasteners lose their strength and may even melt at CMC operating temperatures. Since the allowable operating temperature of a metal fastener is lower than the allowable operating temperature of the CMC, metal fasteners, and/or the area surrounding it, is often cooled to allow it to maintain its strength. Such a configuration may undermine the desired high temperature capability of the CMC. Accordingly, new techniques and configurations are needed for securely fastening liner material, such as CMC tiles, to the walls of enclosures experiencing high-temperature environments.
The present disclosure may comprise one or more of the following features and combinations thereof.
A combustor adapted for use in a gas turbine engine is disclosed in this paper. The combustor includes a metallic shell forming a cavity and a ceramic liner arranged in the cavity of the metallic shell. The ceramic liner defines a combustion chamber in which fuel is burned during operation of a gas turbine engine. The ceramic liner includes a plurality of ceramic tiles coupled to the metallic shell and arranged to shield the metallic shell from heat generated in the combustion chamber.
In illustrative embodiments, the plurality of ceramic tiles are coupled to the metallic shell by metallic fasteners. Many of the metallic fasteners may be shielded from heat generated in the combustion chamber by portions of adjacent ceramic tiles coupled to the metallic shell. By shielding the metallic fasteners from the combustion chamber, the metallic fasteners can survive temperatures in the combustor.
In illustrative embodiments, the fasteners coupling an individual ceramic tile to the metallic shell may extend through preformed apertures in the ceramic tile. The preformed apertures may be sized to locate the ceramic tile while also allowing for expansion/contraction of the ceramic tile as the ceramic tile is heated/cooled during use of the combustor. In particular, a single round locator hole may receive a locator fastener locating a ceramic tile and a plurality of elongated securement slots may receive a plurality of securement fasteners so that the ceramic tile can expand and contract while the securement slots move around the securement fasteners.
In illustrative embodiments, the shell is formed to include a number of dimples that extend toward the combustion chamber and are received in corresponding hollows formed in the ceramic tiles. The dimples and hollows may be correspondingly sized so that a substantially uniform, predetermined distance is maintained between the dimples and the portion of the ceramic tiles forming the hollow. By maintaining a substantially uniform, predetermined distance, heat transfer from the ceramic tiles to the shell can be evenly distributed. In some embodiments, holes may be formed through the dimples to allow cooling air to be supplied to the ceramic tiles.
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.
The arrangement of an illustrative high-temperature combustor 10 in a gas turbine engine 110 is shown in
The combustor 10 includes a shell 12, a liner 14, fuel nozzles 16, and a heat shield 18 as shown, for example, in
The shell 12 illustratively includes an outer shell member 30 and an inner shell member 34 that is generally concentric with and nested inside the outer shell member 30. To expand the size of the cavity 15, the outer shell member 30 is formed to include a plurality of radially offset steps (or joggles) 31, 32 and the inner shell member 34 is formed to include a plurality of radially offset steps (or joggles) 35, 36, 37 as shown in
The liner 14 is illustratively assembled from a plurality of ceramic tiles 21-25 secured to the shell 12 by a plurality of metallic fasteners 28 as shown in
The heat shield 18 is arranged at the axially forward end 12F of the shell 12 as shown in
The ceramic tiles 21-25 are illustratively arranged so that fasteners 28 securing axially-aft ceramic tiles 23, 24, 25 are shielded from heat generated in the combustion chamber by axially-adjacent ceramic tiles 21, 22, 24 as shown in
As a result of the overlapped arrangement of the ceramic tiles 21-25, the fasteners 28 experience lower temperatures than are presented in the combustion chamber 45 as suggested in
Moreover, in the illustrative embodiment, the fasteners 28 are spaced a predetermined distance 95 from the uncovered portion of the tile 21-25 through which they extend as shown in
In the illustrative embodiment shown in
The fasteners 28 are illustratively made from a metallic material which may provide greater tensile strength and preload capability suitable for the vibratory environment inside the gas turbine engine 110. The illustrative fasteners 28 are configured to receive cooling air from the compressor 112 of the gas turbine engine 110 as suggested by arrows 29 in
In other embodiments, full hoop tiles may be used rather than a number of circumferentially-adjacent tiles while still being arranged so that the metallic fasteners 28 are shielded from the heat of combustion. In still other embodiments, a single wall liner
Upon securing the ceramic tiles 21-24 included in the liner 14 to the metallic shell 12, the combustor 10 may be mounted to the case 120 of the gas turbine engine 110 as suggested in
Another illustrative combustor 210 adapted for use in the gas turbine engine 110 is shown in
Unlike the combustor 10, the combustor 210 includes a shell 212 having outer and inner shell members 230, 234 that do not have joggles as shown in
Further, unlike the combustor 10, the combustor 210 includes ceramic tiles 221-224 that each include a body 250, a plurality of axially-extending tabs 252 arranged along an axially-forward side of a corresponding body 250, and a plurality of circumferentially-extending tabs 254 arranged along a circumferential side of a corresponding body 250 as shown in
The body 250 of each ceramic tile 221-224 extends around a portion of the combustion chamber 245 and defines a portion of the combustion chamber 245 as shown in
The axially-extending tabs 252 of each ceramic tile 221-224 extend from the body 250 of a corresponding ceramic tile 221-224 as shown in
The circumferentially-extending tabs 254 of each ceramic tile 221-224 extend from the body 250 of a corresponding ceramic tile 221-224 as shown in
The locating hole 258′ included in a radially-extending tab 254′ of a ceramic tile 221-224 (and the locating fastener that extends therethrough) locates the corresponding ceramic tile 221-224 relative to the shell 212. The securement slots 258 included in radially-extending tab 254 of a ceramic tile 221-224 are elongated in the axial direction to allow expansion/contraction of the ceramic tiles 221-224 in the axial direction on account of heating/cooling during operation of the combustor 210.
By arranging the fasteners 228 through the tabs 252, 254 the fasteners 28 are spaced a predetermined distance from the uncovered body 250 of the tiles 221-224 as shown in
Another illustrative combustor 310 adapted for use in the gas turbine engine 110 is shown in
Unlike the combustor 10, the combustor 310 includes a shell 212 having outer and inner shell members 330, 334 that do not have radial steps as shown in
Further, unlike the combustor 10, the combustor 310 includes ceramic tiles 321-326 that each include a body 350, a plurality of axially-extending tabs 352 arranged along an axially-forward side of a corresponding body 350, and a plurality of circumferentially-extending tabs 354 arranged along a circumferential side of a corresponding body 350 as shown in
The body 350 of each ceramic tile 321-326 extends around a portion of the combustion chamber 345 and defines a portion of the combustion chamber 345 as shown in
In the illustrative embodiment, the body 350 of axially-forward and axially-intermediate ceramic tiles 321-324 has a generally U-shaped cross-section and is formed to include a hollow 351 as shown in
Another illustrative combustor 410 adapted for use in the gas turbine engine 110 is shown in
Unlike the combustor 210, the combustor 410 includes a shell 410 having contoured outer and inner shell members 430, 432 as shown in
Also, unlike the combustor 210, the combustor 410 includes ceramic tiles 421-424 that do not include circumferentially-extending tabs as shown in
In addition to axially-extending tabs 454 that are arranged along the forward side of the axially-forward ceramic tiles 421, 422, the axially-forward ceramic tiles 421, 422 include axially-extending tabs 455 arranged along an aft side of the axially-forward ceramic tiles 421, 422 as shown in
In addition to axially-extending tabs 454 that are arranged along the forward side of the axially-aft ceramic tiles 423, 424, the axially-aft ceramic tiles 423, 424 include porpoise seals 465 arranged along an aft side of the axially-aft ceramic tiles 423, 424 as shown in
In the illustrative embodiment, circumferentially-adjacent tiles 421, 421′ are interlocked using interlocking tabs 481, 483 received in slots 482, 484 as shown in
In the illustrative embodiment, the overlapping shelves 470, 472 include a cold-side shelf 470 and a hot-side shelf 472 as shown in
Ceramic combustor liners such as CMC liners often require less cooling than metal alloys typically used combustors and turbines, and the reduction in liner cooling permits a flattening of the combustor profile to be achieved. In turn, higher turbine inlet temperatures and flatter combustor profiles lead to reduced NOx emissions. Furthermore, reduced liner cooling allows a greater fraction of airflow in the gas turbine engine to be dedicated to the combustion process. As a result, in a “lean” burn application, greater airflow for combustion provides a reduction in emissions and/or provides a greater temperature increase for a given emissions level. In a “rich” burn application, greater airflow for combustion allows more air used to be used for quenching and provides reduced NOx emissions.
With regard to fabrication, one driving cost of a CMC combustor liner fabrication process is furnace time, which may be approximately three weeks. Given the high temperatures that must be maintained to properly cure CMC combustor liner components, the cost of the CMC combustor liner fabrication process may be high. For a single wall integrated (monolithic/annular) CMC combustor liner, the design and shape of the liner may allow for only one combustor to be cured at a time in a furnace. However, using a tiled CMC liner design as described herein allows tiles for several combustors to be cured at the same time which provides a dramatic cost savings. For example, the overall cost of a fabrication process for a CMC tiled liner design may be one half of the cost of the single wall CMC liner design for an annular wall liner of the same size.
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 is a continuation of U.S. patent application Ser. No. 14/135,350, which claims the benefit of and priority to U.S. Provisional Patent Application Ser. No. 61/798,253, filed Mar. 15, 2013, which are both incorporated by reference in their entirety herein.
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Child | 15218668 | US |