This disclosure relates to combustors for gas turbine engines, and, in particular to combustor liners within combustors.
Combustors typically include combustor liners which surround the combustion chamber. Combustor liners may be intermittently exposed to high thermal stress over a long period of time. Failure to one portion of a combustor liner often requires complete replacement of the combustor liner.
The embodiments may be better understood with reference to the following drawings and description. The components in the figures are not necessarily to scale. Moreover, in the figures, like-referenced numerals designate corresponding parts throughout the different views.
Typically, the temperature of gases within a combustion chamber of a gas turbine engine are as high as possible to maximize efficiency of the gas turbine engine. Furthermore, thermal stress within the combustion chamber may not be uniform, causing increased wear on different portions of the combustor liner. Failure of any portion of the combustor liner may require replacement of the entire combustor liner. Therefore, it is desirable that components of the combustor liner may be easily changed to increase the life of the combustor and decrease maintenance costs associated with operation of the gas turbine engine.
The following description is merely exemplary in nature and is not intended to limit the present disclosure, application, or uses.
By way of an introductory example, a combustor liner assembly is provided including an inlet wall, an inner wall, an outer wall, and a plurality of fasteners. The inlet wall has an opening into a combustion chamber. The inner wall is coupled to the inlet wall at a first end of the combustor liner. The inner wall defines a radially inner end of the combustion chamber. The outer wall includes a plurality of segments. The plurality of segments define a radially outer end of the combustion chamber. A first portion of the plurality of fasteners couples each of the plurality of segments to another of the plurality of segments. A second portion of the plurality of fasteners couples at least one of the plurality of segments to the inlet wall at the first end of the combustor liner.
One interesting feature of the systems and methods described below may be that the segments may be easily interchangeable to repair worn or damaged areas of the combustor liner. Such replacements may increase the life of the combustor. Alternatively, or in addition, an interesting feature of the systems and methods described below may be that the segments may be similar or identical in design, reducing the maintenance cost for the combustor liner and may reduce the number of parts in the combustor liner. Alternatively, or in addition, an interesting feature of the systems and methods described below may be that the incorporation of the segments into the combustion liner may reduce the weight of the combustor liner. Alternatively, or in addition, an interesting feature of the systems and methods described below may be that a segmented combustor liner may still retain hoop integrity of the combustor liner while still eliminating forward and aft rings used in other combustor liner designs.
The shaft 76 may rotate around an axis of rotation, which may correspond to a centerline X in some examples. The centerline X may be a longitudinal axis which extends across the entire length of the shaft 76, along the axis of rotation. For the purposes of this application, the terms “radially outer” and “radially outward” may describe the position of an element with respect to its distance away from the centerline X of the gas turbine engine 64 or the center of the shaft 76. The terms “radially inner” and “radially inward” may describe the position of an element with respect to its distance toward the centerline X of the gas turbine engine 64 or the center of the shaft 76. A “downstream” direction may be any direction toward the exhaust section 68 of the gas turbine engine 64. An upstream direction may be any direction toward the intake section 66 of the gas turbine engine 64.
The inlet wall 12 may include an intake opening 22 which allows fluid from the compressor section 70 to enter the combustion chamber 34. Examples of the intake opening 22 may include a ringed slot, a circular opening, or a curved orifice such as a swirler. The inlet wall 12 may also include a fuel nozzle opening 24. The fuel nozzle opening 24 may be any opening through which a fuel nozzle (not shown) may extend to dispense fuel into the combustion chamber 34. Examples of the fuel nozzle opening 24 may include an orifice, a channel, or a circular passage.
The combustion chamber 34 may be any space within the combustor section 72 in which fluid from the compressor section 70 is ignited. Examples of the combustion chamber 34 may include a cavity, a space, or a passage. Fluid may enter the combustion chamber 34 from the intake opening 22 and may exit the combustion chamber 34 through an exhaust opening 26. The combustion chamber 34 may be surrounded by the combustor liner 10. The exhaust opening 26 may be any opening in the combustor liner 10 through which fluid may exit the combustion chamber 34. Example of the exhaust opening 26 may include an annular passage, a collection of spaced openings, or a directional passageway.
The inner wall 14 may be any structure which extends downstream from the inlet wall 12 and which defines a radially inner end of the combustion chamber 34. Examples of the inner wall 14 may include a cylinder, a conical tube, or a plate. The inner wall 14 may extend from a first end 30 of the combustor liner 10 to a second end 32 of the combustor liner 10. At the first end 30 of the combustor liner 10, the inner wall 14 may be coupled to the inlet wall 12. At the second end 32 of the combustor liner 10, the inner wall 14 may define a portion of the exhaust opening 26. The inner wall 14 may be made of any material which can provide structural support to the combustor liner 10 and contain combustion of fluid within the combustion chamber 34, such as a ceramic matrix composite material or a metal such as titanium or a nickel superalloy. The inner wall 14 may have an interior 80. The interior 80 of the inner wall 14 may be uniform or may have an internal architecture including, for example, advanced cooling systems.
The outer wall 16 may be any structure which extends downstream from the inlet wall 12 and which defines a radially outer end of the combustion chamber 34. Examples of the outer wall 16 may include a cylinder, a conical tube, or a plate. The outer wall 16 may extend from the first end 30 of the combustor liner 10 to the second end 32 of the combustor liner 10. At the first end 30 of the combustor liner 10, the outer wall 16 may be coupled to the inlet wall 12. At the second end 32 of the combustor liner 10, the outer wall 16 may define a portion of the exhaust opening 26. The outer wall 16 may be made of any material which can provide structural support to the combustor liner 10 and contain combustion of fluid within the combustion chamber 34, such as a ceramic matrix composite material or a metal such as titanium or a nickel superalloy. In some embodiments, the outer wall 16 may have a larger diameter and a larger circumference than the inner wall 14. The outer wall 16 may have an interior 78. The interior 78 of the outer wall 16 may be uniform or may have an internal architecture including, for example, advanced cooling systems.
The inner wall 14 and the outer wall 16 may both comprise one or more flanges 18. The flanges 18 may be any structure which extend radially from the inner wall 14 or outer wall 16. Examples of the flanges 18 may include protrusions, projections, or rims. The flanges 18 on the inner wall 14 may extend radially inward from a surface 92 of the inner wall 14 which is on the exterior of the combustion chamber 34. The flanges 18 on the outer wall 16 may extend radially outward from a surface 42 of the outer wall 16 which is on the exterior of the combustion chamber 34. The flanges 18 may also extend upstream to the first end 30 of the combustor liner 10 and may be aligned with the inlet wall 12. The flanges 18 may be integral to the inner wall 14 or outer wall 16 and may be made of the same material as the inner wall 14 or outer wall 16. The flanges 18 may include flange openings 20 which extend through the flange 18. Examples of the flange openings 20 may include channels, apertures, or passageways.
The inlet wall 12 may also include flanges 52 at the first end 30 of the combustor liner 10 which are associated with flanges 18 of the inner wall 14 and outer wall 16. In some embodiments, a first flange 52 of the inlet wall 12 may rest against the inner wall 14 and may be positioned such that the flange openings 20 of the inlet wall 12 flange 52 and the inner wall 14 flange 18 are aligned. Additionally, a second flange 52 of the inlet wall 12 may rest against the outer wall 16 and may be positioned such that the flange openings 20 of the inlet wall 12 flange 52 and the outer wall 16 flange 18 are aligned.
A fastener such as a bolt 36 may pass through the flange openings 20 of the flange 18 of the inner wall 14 and the flange 52 of the inlet wall 12. Similarly, another bolt 36 may pass through the flange openings 20 of the flange 18 of the outer wall 16 and the flange 52 of the inlet wall 12. Nuts 38 may be attached to the bolts 36 such that the flanges 18, 52 are coupled together between the bolt 36 and the nut 38. The bolts 36 and nuts 38 may be any device which passes through the flange openings 20 to couple flanges 18, 52 together. Examples of the bolts 36 may include carriage bolts, shoulder bolts, socket cap screws, or any other object which may pass through the flange opening 20 and secure one side of a flange 18, 52. Examples of the nuts 38 may include cap nuts, castle nuts, torque lock nuts, or any other object which, when attached to a bolt, can fasten the flanges 18, 52 between the bolt 36 and the nut 38.
One or both of the inner wall 14 and outer wall 16 may be coupled to the inlet wall 12 in alternative configurations, such as welding or brazing. In some embodiments, one or both of the inner wall 14 and outer wall 16 may be formed integrally to the inlet wall 12. In some embodiments, only the inner wall 14 may be fastened to the inlet wall 12 through the flanges 18, 52. In other embodiments, only the outer wall 16 may be fastened to the inlet wall 12 through the flanges 18, 52. The inner wall 14 and outer wall 16 may also be coupled to the inlet wall 12 using other fasteners such as clamps, rivets, anchors, panel fasteners, or screws. In some embodiments, washers (not shown) may be placed between the bolt 36 and the nut 38.
In some embodiments, as illustrated in
In some embodiments, one or both of the inner wall 14 and the outer wall 16 may include an interfacing feature 28 which extends radially at the second end 32 of the combustor liner 10. The interfacing feature 28 may be any object which is shaped to be coupled to the turbine section 74 of the gas turbine engine 64. Examples of the interfacing feature 28 may include a projection, a tab, or a cylindrical shaped rim. The interfacing feature 28 may be integral to the inner wall 14 or the outer wall 16 and may be made of the same material as the inner wall 14 and the outer wall 16. The interfacing feature 28 may be shaped to direct the flow of fluid from the exhaust opening 26 to the turbine section 74. The interfacing feature 28 may also act as a fluid seal, preventing fluid from leaking as it flows toward the turbine section 74.
In some embodiments, the cooling channel 82 may be formed into the interior 78 of the outer wall 16 through machining. Alternatively, more complex and more extensive cooling channels 82 may be formed as the outer wall 16 is being formed through additive layer manufacturing. If the cooling channel 82 is designed to effectively cool the portions of the outer wall 16 under the most thermal stress, more cost effective materials, such as metals, may be used for the outer wall 16 over more complicated designs involving ceramics and ceramic-plated metals. Similar processes may be used to form a cooling channel 82 in the interior 80 of the inner wall 14.
Each outer wall segment 46 may be identical and easily separable from the combustor liner 10. Such a configuration may reduce the cost of maintaining the combustor liner 10, as outer wall segments 46 may be simply replaced when worn or damaged. Particularly where complex cooling channels 82 have been created in the outer wall segment 46, manufacturing identical outer wall segment 46 may be cost effective. Additionally, in some embodiments, the outer wall segments 46 may be removed and replaced without separating the combustor section 72 from the compressor section 70 and the turbine section 74.
As shown in
Each inner wall segment 48 may be identical and easily separable from the combustor liner 10. Such a configuration may reduce the cost of maintaining the combustor liner 10, as inner wall segments 48 may be simply replaced when worn or damaged. Particularly where complex cooling channels 82 have been created in the inner wall segment 48, manufacturing identical inner wall segments 48 may be cost effective.
As shown in
Additionally, as illustrated in
Each inlet wall segment 54 may be identical and easily separable from the combustor liner 10. Such a configuration may reduce the cost of maintaining the combustor liner 10, as inlet wall segments 54 may be simply replaced when worn or damaged. Particularly where complex cooling channels 82 have been created in the inlet wall segment 54, manufacturing identical inlet wall segments 54 may be cost effective.
Other similar fasteners may be used instead of bolts 36 and nuts 38. For example, a rivet may be advanced through the flange openings 20 and expanded to couple the flanges 18. Alternatively, as illustrated in
The method (100) includes coupling the inner wall 14 to the inlet wall 12 (102). The inner wall 14 may be coupled to the inlet wall 12 through a variety of methods including welding, integrally forming the two components, and coupling using fasteners. The method (100) also includes coupling one of the outer wall segments 46 to the inlet wall 12 by coupling a fastener to the inlet wall 12 and to the outer wall segment 46 (104). In some embodiments, every outer wall segment 46 may be coupled to the inlet wall 12. Each of the outer wall segments 46 may extend from the first end 30 to the second end 32 of the combustor liner 10. The method (100) also includes coupling an outer wall segment 46 to another outer wall segment 45 (106). Each of the outer wall segments 46 may be coupled to adjacent outer wall segments 46 by fasteners about the entire circumference of the combustor liner 10 to form the outer wall 16. The annular combustion chamber 34 is defined within the inlet wall 12, the inner wall 14, and the outer wall 16 formed by the outer wall segments 46.
Additionally, the fasteners may be uncoupled from any of the outer wall segments 46 in order to remove and replace the outer wall segments 46. Similar steps may be taken to replace inner wall segments 48 and the inlet wall segments 54.
Each component may include additional, different, or fewer components. For example, the ports 44 and cooling channels 82 may not be included in some embodiments of the combustor liner 10. Additionally, in some embodiments, the inner wall 14 may not be divided into multiple inner wall segments 48, and the inlet wall 12 may not be divided into multiple inlet wall segments 54.
The method (100) may be implemented with additional, different, or fewer components. For example, in some embodiments of the method (100) the inner wall segments 48 may be coupled to other adjacent inner wall segments 48. This may be particularly relevant in embodiments wherein the inner wall 14 includes many inner wall segments 48.
The logic illustrated in the flow diagrams may include additional, different, or fewer operations than illustrated. The operations illustrated may be performed in an order different than illustrated.
To clarify the use of and to hereby provide notice to the public, the phrases “at least one of <A>, <B>, . . . and <N>” or “at least one of <A>, <B>, . . . <N>, or combinations thereof” or “<A>, <B>, . . . and/or <N>” are defined by the Applicant in the broadest sense, superseding any other implied definitions hereinbefore or hereinafter unless expressly asserted by the Applicant to the contrary, to mean one or more elements selected from the group comprising A, B, . . . and N. In other words, the phrases mean any combination of one or more of the elements A, B, . . . or N including any one element alone or the one element in combination with one or more of the other elements which may also include, in combination, additional elements not listed.
While various embodiments have been described, it will be apparent to those of ordinary skill in the art that many more embodiments and implementations are possible. Accordingly, the embodiments described herein are examples, not the only possible embodiments and implementations.
The subject-matter of the disclosure may also relate, among others, to the following aspects:
an inlet wall having an opening into a combustion chamber;
an inner wall;
an outer wall, wherein the inner wall and the outer wall define the combustion chamber, the inner wall radially inward from the outer wall, the inner wall coupled to the inlet wall at a first end of the combustor liner, the outer wall comprising a plurality of segments, wherein the plurality of segments; and
a plurality of fasteners, wherein a first portion of the plurality of fasteners couples each of the plurality of segments to another of the plurality of segments, and a second portion of the plurality of fasteners couples at least one of the plurality of segments to the inlet wall at the first end of the combustor liner.
a combustor section comprising a combustor liner comprising an inlet wall arranged at a first end of the combustor liner, an inner wall extending from the first end to a second end of the combustor liner, and an outer wall extending from the first end to the second end of the combustor liner, wherein an annular combustion chamber is defined within the inlet wall, the inner wall, and the outer wall, wherein the outer wall comprises a plurality of segments, wherein each of the plurality of segments is coupled to another of the plurality of segments by a first portion of a plurality of fasteners, wherein each of the plurality of segments extends from the first end to the second end of the combustor liner, and wherein each of the plurality of segments is coupled to the inlet wall by a second portion of the plurality of fasteners, wherein the combustor section is configured to be coupled to a turbine section.
coupling an inner wall to an inlet wall;
coupling a first outer wall segment of a plurality of outer wall segments to the inlet wall by coupling a first fastener to the inlet wall and the first outer wall segment, wherein each of the plurality of outer wall segments extends from a first end to a second end of the combustor liner; and
coupling a second outer wall segment of the plurality of outer wall segments to the first outer wall segment by coupling a second fastener to the first outer wall segment and the second outer wall segment, wherein an annular combustion chamber is defined within the inlet wall, the inner wall, and an outer wall formed by the plurality of outer wall segments.
uncoupling the fasteners from one of the plurality of outer wall segments; and
after uncoupling the fasteners, removing the one of the plurality of outer wall segments.
after removing the one of the plurality of outer wall segments, coupling a replacement outer wall segment to the inlet wall by coupling the first fastener to the inlet wall and the replacement outer wall segment, and coupling the replacement outer wall segment to another of the plurality of outer wall segments, wherein while coupling the replacement outer wall segment, the combustor is coupled to a compressor section at a first end, and a turbine section at a second end.
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