The present disclosure relates generally to combustors used in gas turbine engines, and more specifically to a combustor including a metallic case and a heat shield.
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 heat shields that contain the burning fuel during operation of a gas turbine engine. The heat shield included in the combustor is designed and built to withstand high-temperatures induced during combustion. In some cases, heat shields may be made from metallic superalloys. In other cases, heat shields 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. The matrix and fibers can consist of any ceramic material, in which carbon and carbon fibers can also be considered a ceramic material.
Combustors and turbines made of metal alloys often require significant cooling to be maintained at or below their maximum use temperatures. The operational efficiencies of gas turbine engines are sometimes increased with the use of CMC materials that require less cooling and have operating temperatures that exceed the maximum use temperatures of most metal alloys. The reduced cooling required by CMC combustor heat shields when compared to metal alloy combustion heat shields can permit greater temperature uniformity and can lead to reduced undesirable emissions.
One challenge relating to the use of CMC heat shields is that they are sometimes secured to the surrounding metal shell via metal fasteners. Metal fasteners can lose their strength and may even melt at CMC operating temperatures. Since the allowable operating temperature of a metal fastener is typically 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 configurations may undermine the desired high temperature capability of the CMC. Accordingly, new techniques and configurations are needed for coupling components, such as CMC, to the walls of enclosures experiencing high-temperature environments.
The present disclosure may comprise one or more of the following features and combinations thereof.
According to a first aspect of the present disclosure, a combustor for use in a gas turbine engine includes a combustor shell, a heat shield, and a plurality of heat shield retainers. The combustor shell includes metallic materials adapted to be mounted in the gas turbine engine and is formed to define an internal cavity. The combustor shell includes an outer annular wall that extends circumferentially around a central reference axis. The combustor shell may further include an inner annular wall arranged radially inward from the outer annular wall to provide the internal cavity between the outer annular wall and the inner annular wall. The combustor shell may further include a dome panel that extends from an axially-forward end of the outer annular wall to the inner annular wall to form a forward wall. The dome panel may be shaped to include fuel nozzle apertures spaced circumferentially around the central reference axis that open into the internal cavity.
In some embodiments, the heat shield includes ceramic matrix composite materials. The heat shield may be coupled to the dome panel and arranged within the internal cavity to shield the dome panel from temperatures developed by burning fuel within a combustion chamber inside the internal cavity during use of the combustor in the gas turbine engine.
In some embodiments, the heat shield includes a shield panel, a first mount flange arranged along a first circumferential side of the shield panel, and a second mount flange arranged along a second circumferential side of the shield panel. The plurality of heat shield retainers are configured to retain the heat shield to the dome panel.
In some embodiments, the first and second mount flanges each include at least one attachment post that extends axially through an attachment aperture formed in the dome panel to engage a corresponding heat shield retainer arranged on an axially-forward side of the dome panel. The attachment aperture may be sized and shaped so that the dome panel moves relative to the heat shield due to different rates of thermal expansion without forming stresses in the heat shield as a result of binding between the heat shield and the combustor shell.
In some embodiments, the first mount flange includes an offset lip that extends along the first circumferential side from a radially outer edge of the shield panel to a radially inner edge of the shield panel and a first attachment post located about midway between the radially outer edge and the radially inner edge.
In some embodiments, the second mount flange includes an offset lip that extends along the second circumferential side from the radially outer edge of the shield panel to the radially inner edge of the shield panel and a first attachment post located closer to the radially outer edge than the radially inner edge and a second attachment post located closer to the radially inner edge than the radially outer edge. In some embodiments, the heat shield is bent at each circumferential side to provide the first mount flange and the second mount flange.
In some embodiments, the first attachment post of the first mount flange is positioned radially between attachment posts of a circumferentially neighboring heat shield. In some embodiments, the first attachment post of the second mount flange is positioned radially above an attachment post of a circumferentially neighboring heat shield and the second attachment post of the second mount flange is positioned radially below the attachment post of the circumferentially neighboring heat shield.
In some embodiments, the dome panel of the combustor shell is formed to include a plurality of attachment apertures including a first circular-shaped attachment aperture, a second elongated attachment aperture spaced apart circumferentially from the first attachment aperture, and a third elongated attachment aperture spaced apart circumferentially from the first attachment aperture and radially from the second attachment aperture.
In some embodiments, the second attachment aperture is elongated along a first axis and the third attachment aperture is elongated along a second axis and the first and second axes intersect at the first attachment aperture.
In some embodiments, the plurality of attachment apertures further comprises a fourth elongated attachment aperture spaced apart radially from the first attachment aperture and circumferentially from the second and third attachment apertures and the fourth attachment aperture is elongated along a third axis that intersects with the first and second axes at the first attachment aperture.
In some embodiments, each heat shield retainer includes a first half and a second half arranged to combine with the first half and enclose a respective attachment post to block the attachment post from being removed from the attachment aperture. In some embodiments, the attachment post has a shape and the first half and the second half are formed to include a groove that matches the shape of the attachment post, each groove having a depth that is about half of a thickness of the attachment post. In some embodiments, the first half and the second half are retained together by a spring clip to block the attachment post from being removed from the attachment aperture.
In some embodiments, the first mount flange includes an offset lip that extends from a radially outer edge of the shield panel to a radially inner edge of the shield panel, a first attachment post located closer to the radially outer edge than the radially inner edge, and a second attachment post located closer to the radially inner edge than the radially outer edge.
In some embodiments, the second mount flange includes an offset lip that extends from the radially outer edge of the shield panel to the radially inner edge of the shield panel, a first attachment post located closer to the radially outer edge than the radially inner edge, and a second attachment post located closer to the radially inner edge than the radially outer edge.
In some embodiments, the first attachment post of the first mount flange is aligned radially with the first attachment post of the second mount flange and the second attachment post of the first mount flange is aligned radially with the second attachment post of the second mount flange.
In some embodiments, the heat shield is formed from a ceramic ply layup comprising a back-plate ply forming an axially aft surface of the shield panel, a front-plate ply forming a portion of an axially forward surface of the shield panel and a portion of the first and second mount flanges, a first edge ply forming a portion of the axially forward surface of the shield panel and a portion of the first mount flange, and a second edge ply forming a portion of the axially forward surface of the shield panel and a portion of the second mount flange.
According to another aspect of the present disclosure, a method of retaining a heat shield to a combustor in a gas turbine engine includes providing the combustor. The combustor may include at least one panel made from metallic materials.
In some embodiments, the method further includes forming the heat shield from ceramic matrix composite components. The heat shield includes a shield panel lining the panel of the combustor and providing a boundary for an interior combustion chamber.
In some embodiments, The heat shield further includes a first mount flange arranged along a first circumferential side of the shield panel and a second mount flange arranged along a second circumferential side of the shield panel. The first and second mount flange may each include at least one attachment post that extends away from the shield panel.
In some embodiments, the method may further include forming a plurality of attachment apertures in the panel of the combustor. In some embodiments, the method may further include inserting the attachment posts through respective attachment apertures. In some embodiments, the method may further include retaining each attachment post to the panel to block removal of the attachment posts from the attachment apertures.
In some embodiments, the attachment apertures are sized and shaped so that the panel is allowed to move relative to the heat shield due to different rates of thermal expansion without forming stresses in the heat shield as a result of binding between the heat shield and the panel.
In some embodiments, the step of retaining each attachment post includes providing a heat shield retainer for each attachment post. In some embodiments, the heat shield retainer includes a first half, a second half arranged to combine with the first half and enclose a respective attachment post to block the attachment post from being removed from the attachment aperture, and a spring clip configured to retain the first half to the second half enclosing the attachment post.
In some embodiments, the step of forming the heat shield includes forming the heat shield from at least one ceramic ply that is bent at each circumferential edge to provide the first mount flange and the second mount flange once infiltrated with ceramic matrix material so that the first mount flange and the second mount flange are made integral with the shield panel.
In some embodiments, the step of forming the heat shield includes forming the heat shield from a ceramic ply layup comprising a back-plate ply forming an axially aft surface of the shield panel, a front-plate ply forming a portion of an axially forward surface of the shield panel and a portion of the first and second mount flanges, a first edge ply forming a portion of the axially forward surface of the shield panel and a portion of the first mount flange, and a second edge ply forming a portion of the axially forward surface of the shield panel and a portion of the second mount flange.
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.
A gas turbine engine 10, in accordance with the present disclosure, is shown in
The combustor 20 operates at extremely high temperatures during operation of the gas turbine engine 10. The combustor 20 includes a combustor shell 26 made from metallic materials, a plurality of heat shields 28 made from ceramic matrix composite materials, and a plurality of heat shield retainers 30 as shown in
The plurality of heat shields 28 each extend partway around the central reference axis 25 and cooperate to provide a boundary of a combustion chamber 34 within the internal cavity 32. Combustion of fuel and gases occurs in the combustion chamber 34 and produces hot gases which, absent the plurality of heat shields 28, may damage portions of the combustor shell 26. The ceramic matrix composite materials forming the plurality of heat shields 28 are able to withstand much higher temperatures as compared to the metallic materials forming the combustor shell 26. As such, the plurality of heat shields 28 are arranged along inner surfaces of the combustor shell 26 defining the internal cavity 32 to define at least a portion of the combustion chamber 34 and block the hot gases from reaching the combustor shell 26.
The combustor shell 26 includes an outer wall 36, an inner wall 38 spaced apart from the outer wall 36, and a dome panel 40 as shown in
The dome panel 40 is formed to include a plurality of fuel nozzle apertures 46 that open into the internal cavity 32. Fuel nozzles (not shown) extend through the fuel nozzle apertures 46 and into or adjacent to the combustion chamber 34 and are configured to spray and ignite fuel flowing therethrough. The hot gases produced by the combustion reaction flow aft through the combustion chamber 34 until they exit the combustion chamber 34 toward the turbine 22 where the hot gases are used to drive rotation of components in the turbine 22.
Although the combustor includes a plurality of heat shields 28 in the illustrative embodiment, each of the heat shields 28 are substantially similar. Accordingly, only one heat shield 28 is described below. In the illustrative embodiment, the heat shield 28 is coupled to an axially-aft surface of the dome panel 40 and is arranged within the internal cavity 32 as shown in
The heat shield 28 is formed into a one-piece CMC and includes a shield panel 50, a first mount flange 52, and a second mount flange 54 as shown in
The heat shield 28 is formed from a single ceramic ply that is shaped to provide the first mount flange 52 and the second mount flange 54. The first and second mount flanges 52, 54 extend away from the shield panel 50 toward the dome panel 40 of the combustor shell 26 as shown in
The second mount flange 54 includes an offset lip 68, and a pair of attachment posts 70, 72 coupled to the offset lip 68 as shown in
Each of the attachment posts 62, 70, 72 extends axially through a corresponding attachment aperture 74, 76, 78 formed in the dome panel 40 to mount the heat shield 28 to the dome panel 40 as shown in
The attachment apertures 74, 76, 78 cooperate to locate the heat shield 28 relative to the first attachment aperture 74 while allowing movement of the second and third attachment apertures 76, 78 relative to the heat shield 28 as the dome panel 40 expands. The first attachment post 62 is received in the first attachment aperture 74 and is generally fixed relative to the dome panel 40 as shown in
In the illustrative embodiment, the heat shield 28 cooperates with neighboring heat shields 29, 31 to line the combustor shell 26. The first attachment post 62 of the first mount flange 52 is positioned radially between attachment posts 71, 73 of circumferentially neighboring heat shield 29. The first attachment post 70 of the second mount flange 54 is located radially above an attachment post 63 of circumferentially neighboring heat shield 31. The second attachment post 72 of the second mount flange 54 is located radially below the attachment post 63 of circumferentially neighboring heat shield 31. This same arrangement is provided for all of the heat shields 28 of the combustor 20 circumferentially around the central reference axis 25.
Once the attachment posts 62, 70, 72 are positioned in their respective attachment apertures 74, 76, 78, a corresponding heat shield retainer 30 is configured to engage each attachment post 62, 70, 72 along an outer surface 84 of the dome panel 40 as shown in
Each heat shield retainer 30 includes a first half 86, a second half 88, and a clip 90 as shown in
Attachment post 62 is shown in detail in
Another embodiment of an attachment post 262 is shown in detail in
Another embodiment of an attachment post 362 is shown in detail in
Another embodiment of a combustor 420 for use in the gas turbine engine 10 is shown in
The combustor 420 includes a combustor shell 426 made from metallic materials, a heat shield 428 made from ceramic matrix composite materials, and a plurality of heat shield retainers 430 as shown in
The first and second mount flanges 452, 454 extend away from the shield panel 450 toward the dome panel 440 of the combustor shell 426 as shown in
The first mount flange 452 includes an offset lip 460, a first attachment post 462 coupled to the offset lip 460, and a second attachment post 463 coupled to the offset lip 460 as shown in
The second mount flange 454 includes an offset lip 468 and a pair of attachment posts 470, 472 coupled to the offset lip 468 as shown in
Each of the attachment posts 462, 463, 470, 472 extends axially through a corresponding attachment aperture 474, 476, 478, 479 formed in the dome panel 440 to mount the heat shield 428 to the dome panel 440 as shown in
The plurality of attachment apertures includes a first circular-shaped attachment aperture 474, a second elongated attachment aperture 476, a third elongated attachment aperture 478 and a fourth elongated attachment aperture 479. The first and fourth attachment apertures 474, 479 are generally aligned circumferentially and are spaced apart radially from one another. The first and fourth attachment apertures 474, 479 are located on an opposite circumferential side of fuel nozzle aperture 446 from the second and third attachment apertures 476, 478. The second and third attachment apertures 476, 478 are generally aligned circumferentially and are spaced apart radially from one another.
The attachment apertures 474, 476, 478, 479 cooperate to locate the heat shield 428 relative to the first attachment aperture 474 while allowing movement of the second, third, and fourth attachment apertures 476, 478, 479 relative to the heat shield 428 as the dome panel 440 expands and contracts. The first attachment post 462 is received in the first attachment aperture 474 and is generally fixed relative to the dome panel 440 as shown in
The second attachment aperture 476 is elongated along a first axis 480. The third attachment aperture 478 is elongated along a second axis 482. The fourth attachment aperture 479 is elongated along a third axis 483. The first, second, and third axes 480, 482, 483 intersect at the first attachment aperture 474. The dome panel 440 moves relative to the second and third attachment posts 463, 470, 472 such that the attachment posts 463, 470, 472 slide along axes 480, 482, 483 through the attachment apertures 476, 478, 479 as the dome panel 440 expands and contracts.
Once the attachment posts 462, 463, 470, 472 are positioned in their respective attachment apertures 474, 476, 478, 479, a corresponding heat shield retainer 430 is configured to engage each attachment post 462, 463, 470, 472 along an outer surface 484 of the dome panel 440 as shown in
The ceramic matrix composite materials in the illustrative embodiments described herein may comprise silicon carbide fibers suspended in a silicon carbide matrix (SiC—SiC CMC), however, any suitable ceramic matrix composite composition may be used. The heat shields are made from silicon carbide fiber preforms that are infiltrated with ceramic matrix material. The fiber preforms may be a two-dimensional ply preform or a three-dimensionally woven or braided preform. Prior to infiltration, the preforms may be molded into a desired shape, as shown in
In some embodiments, when compared to metallic combustor heat shields, the implementation of CMC heat shields in a combustion system may result in a decrease in cooling air requirements within the system. This could allow for either more air to be used to cool other components, or for air to be routed directly back to the core. This could allow for improved operation at higher temperatures, as well as for an increase in power output without an increase to the air intake. Additionally, the implementation of CMCs into the combustor system may result in weight reductions.
In some embodiments, one of the functions of a heat shield is shielding the combustor dome panel from the intense heat within the combustion chamber. Thus, the heat shield comes into direct contact with and often fixtures to the dome panel. Due to the high discrepancies between the coefficients of thermal expansion (CTEs) of the CMC and the metallic dome panel, management of thermal stresses and rates of thermal expansion may be required when considering how to attach the CMC heat shield to the dome panel.
In some embodiments, in order to minimize the stresses exerted on the CMC heat shield fixture, the locating features of the dome panel which relate its position to that of the heat shield may be designed such that the heat shield remains fixed in all directions, but allows for the dome panel to expand freely relative to the heat shield. The present disclosure discusses CMC heat shields in a combustion system and the construction of the heat shield and how it attaches to the dome panel.
In some embodiments, a single laminate or ply forms the entirety of the heat shield body, with the circumferential edges of the laminate creating two axially protruding flanges on the forward side of the laminate. Attachment features would be machined from these flanges. One edge flange includes a single attachment while the other includes two attachments. Clam-shell collars are mated around the attachment flanges and a retaining ring or clip is placed around both clam-shells to fix the assembly axially and block the collars from separating. A second retaining ring may be added to the clam-shells to block any separation caused by pinching from the first retaining ring.
In some embodiments, basic through holes on the dome panel are used to position the heatshield dowels; however, for CMC applications, this arrangement may cause stresses on the heat shield attachment geometry due to the dome panel expanding at a faster rate than the CMC. To counteract this, only one clam shell collar subassembly is positioned with a basic (circular) through hole on the dome panel, the remaining subassemblies are positioned within slotted hole cutouts on the dome panel. This arrangement fixes the heatshield both radially and circumferentially, and, since the retaining rings do not apply any clamping force on the dome panel and heat shield, the dome panel is allowed to expand freely along the direction of the slots as temperatures increase during operation.
In some embodiments, the CMC heat shield may include an extrusion on the forward side of the heat shield that is used to position and fix the heat shield relative to the dome panel. The CMC heat shield may be constructed from 4 sub-laminates or plys with one flat ‘chamber-side’ laminate defining the entire aft section of the heatshield, two L-shaped laminates, and a U-shaped laminate defining the forward section as shown in
In some embodiments, the geometry associated with the machined attachment features may vary between a dovetail, bulb, and fir tree shape. The inner machined face of the clam-shell collars would also vary, respective to the geometry found on the heat shield flanges. The attachment subassembly comprising of the heatshield flanges, the clam-shell collars, and the retaining rings block axial movement of the heat shield caused by pressure differences between either sides of the dome panel/heat shield assembly.
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.
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