Patent Grant
10982852
This disclosure relates to gas turbine engines and, in particular, to gas turbine engine combustors.
A gas turbine engine may include a combustor section that receives gas and air for combustion. The flow of the compressed air within the combustor section may influence efficient operation of the gas turbine engine. The combustor section may include various components to guide the flow of compressed air and/or combustion. These components may be exposed to stresses caused by the flow of compressed air, heat generated by combustion, vibration from engine operation, and other stresses.
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.
By way of an introductory example, the combustor system many include an annular combustor dome arranged around a flow path for a gas turbine engine. The combustor dome may include a first outer surface and a second outer surface radially inward from the first outer surface, relative to the flow path. The annular combustor dome may further include a plurality of inlets in fluid communication with a combustion chamber downstream from the annular combustor dome.
The combustor system may further include a plurality of cassettes positioned on the first outer surface of the dome. At least one of the cassettes may include a cowl integral to a combustor wall. The combustor wall may extend in a downstream direction, relative to the flow path. The combustor wall may at least partially define the combustion chamber. The cowl may extend away from the combustor dome in an upstream direction, relative to the flow path. The cowl may convey fluid received from a diffusor in a radial inward direction to a space upstream of the combustor dome.
One technical advantage of the systems and methods described herein may be that the cowl may be integral to the combustor wall such that the cowl and the combustor wall are separate portions of the cassette. Integrating the cowl with the combustor wall may reduce a number of components in the combustor system and/or a number of coupling locations. Reducing the number of components may increase manufacturing time and/or decrease failures resulting from improper installation and defective components. In some examples, integrating the cowl to the combustor wall may result in less material, such as fasteners, welds, or molded sheet metal, resulting in a weight reduction.
Another technical advantage of the systems and methods described below may be that the cassette may include structures that increase the structural integrity of the cassette, optimize flows of compressed air into and around a combustion chamber, and/or provide other efficiencies related to manufacturing and operating a gas turbine engine. The structures may be integral to the cowl, thereby reducing the number of steps and components involved coupling the structures to the cowl. By way of ALM, structures designed to finely tune engine performance and/or improve structural integrity may be integrated in the cassette as a unitary structure. For example, the cassette may include stiffening structures configured to tune the dynamic response of the cowl and/or increase the impact resistance of the cowl. Additional or alternative technical advantages are made evident in the systems and methods described herein.
As described herein, a first component is integral to a second component when the first component and the second component are each a separate portions of a unitary structure. In the examples described herein, the cassette 102 may be a unitary structure. The cowl 104 and the combustor wall 106 may be separate respective portions of the cassette 102. The cowl 104 may be interchangeably referred to as a cowl portion of the cassette 102. The combustor wall 106 may be interchangeably referred to as a combustor wall portion of the cassette 102. The cassette 102 may be formed without attaching a separate cowl with a separate combustor wall. In some examples, the cassette 102 may be formed by Additive Layer Manufacturing (ALM).
ALM may include a manufacturing technique in which a three dimensional component is formed by successively solidifying new layers of material on top of previous layers of solidified material. For example, ALM may include powder bed fusion. Powder bed fusion may include a type of ALM in which an energy beam such as a laser or electron beam heats portions of a bed of powder. The heated powder is fused into place to form a solid layer. The three-dimensional component is formed by repeatedly heating and fusing additional layers of power on top of previously fused layers.
The cassette 102 may be formed through ALM by successively solidifying new layers of material on top of previous layers of solidified material. For example, the cassette 102 may formed by way of powder bed fusion. Powder may be added on top of a previously solidified layer of the cassette 102. Additional layers may be added to the cassette 102 be heating the power with an energy beam. At least one of the layers solidified by the energy beam may include a portion of the cowl 104 and a portion of the combustor wall 106. The energy beam may include a laser or an electron beam.
The system 100 may further include a combustor dome 108. The combustor dome may be arranged around a centerline C for a gas turbine engine. The centerline C may extend through a cross section defined by the combustor dome 108. The combustor dome 108 may include a plurality of inlets 110. The inlets 110 may fluidly communicate with a combustion chamber 112 downstream from the combustor dome 108. For example, the inlets 110 may receive air from a diffusor and convey the air to the combustion chamber 112 (a diffusor is shown in
The combustor dome 108 includes a dome wall 113. The dome wall 113 may at least partially define the combustion chamber 112. Alternatively or in addition, the dome wall 113 may separate the combustion chamber 112 from a compressor discharge cavity upstream from the combustion chamber 112. In some examples, the dome wall 113 may extend the distance between a first outer surface 120 and a second outer surface 122, which at least in part face each other. The first outer surface 120 may be positioned radially outward from the second outer surface 122, relative to the centerline C and/or a flow path for a gas turbine engine that extends along the centerline C. In some examples, the dome wall 113 may define the inlets 110. Alternatively or in addition, the dome wall 113 may include swirlers that respectively define the inlets 110
The cowl 104 may extend along an upstream direction U away from the combustor wall 106, the combustion chamber 112 and/or the dome wall 113. The cowl 104 may influence a pressure and/or a velocity of air flowing to the inlets 110. For example, the cowl 104 may redirect air from a diffusor to flow along an outer surface 116 of the cassette 102 along the upstream direction U. Alternatively or in addition, the air may flow along a radially inward direction I, relative to the centerline C. After reaching an edge 115 of the cowl 104, the air may flow back along the upstream direction U and into the combustion chamber 112.
The combustor wall 106 of the cassette 102 may at least partially define the combustion chamber 112. The combustor wall 106 may extend along a downstream direction D away from the dome wall 113 and/or the cowl 104. The combustor wall 106 may include a portion of the cassette 102 that is downstream from the combustor dome 108. An inner surface 118 of the cassette 102 along the combustor wall 106 may be a liner for the combustion chamber 112.
The combustor dome 108 may receive the cassette 102. For example, the cassette 102 may couple to the combustor dome 108. In some examples, the cassette 102 may fasten to the combustor dome 108 by way of one or more fasteners. Alternatively or in addition, the cassette 102 may couple to the combustor dome 108 by way of welding, brazing, or some other attachment. In some examples, the first outer surface 120 may receive the inner surface 118 of the cassette 102. For example, a fastener may extend through the outer surface 116 of the cassette 102, the inner surface 118 of the cassette 102, and/or the first outer surface 120 to couple the cassette 102 to the combustor dome 108.
Coupling the cassette 102 to the combustor dome 108 may support the combustor wall 106 and the cowl 104. For example, the cowl 104 and the combustor wall 106 may be separate portions of the cassette 102. In some examples, only the cowl 104 may be coupled to the combustor dome 108 by of way of a fastener or melted joint, such as weld or braising joint. The fastener and/or joint may couple the cowl 104 and the combustor wall 106 to the combustor dome 108. In some examples, the combustor wall 106 may not contact the combustor dome 108. Alternatively or in addition, the combustor wall 106 may not be affixed to the combustor dome 108 by any fasteners or by a melted joint. In other examples, the cowl 104 may not contact the combustor dome 108 and the combustor wall 106 may couple to the combustor dome 108.
The system 100 may further include an opposing cassette 124. The opposing cassette 124 may be positioned on the combustor dome 108 radially inward from the cassette 102, relative to the centerline C. The opposing cassette 124 may include an opposing cowl 126 and an opposing combustor wall 128. The opposing cowl 126 and the opposing combustor wall 128 may be separate portions of the opposing cassette 124. The opposing cowl 126 may be integral to the opposing combustor wall 128. For example, the opposing cassette 124 may be formed by ALM.
The opposing cowl 126 may extend along the upstream direction U and away from the combustion chamber 112, the opposing combustor wall 128, and/or the dome wall 113. For example, opposing cowl 126 of the cassette 102 may receive air along an outer surface 130 of the opposing cassette 124. The outer surface 130 of the opposing cassette 124 may face the centerline C.
The opposing combustor wall 128 may include portion of the opposing cassette 124 that at least partially defines the combustion chamber 112. For example, the combustion chamber 112 may be defined between the combustor wall 106 and the opposing combustor wall 128.
The opposing cassette 124 may include an inner surface 132. The inner surface 132 of the opposing cassette 124 may at least partially define the combustion chamber 112. For example, the opposing combustor wall 214 may include at least a portion of the inner surface 132 of the opposing cassette 124. The combustion chamber 112 may be defined between the inner surface 118 of the cassette 102 and the inner surface 132 of the opposing cassette 124.
The combustor dome 108 may receive the opposing cassette 124. For example, the second outer surface 122 of the combustor dome 108 may receive the inner surface 132 of the opposing cassette 124. Alternatively or in addition, opposing cassette 124 may couple to the combustor dome 108 by way of one or more fastener. In some examples, a faster may extend through the outer surface 130 of the opposing cassette 124, the inner surface 132 of the opposing cassette 124, and/or the second outer surface 122. Alternatively or in addition, the opposing cassette 124 may be joined with the combustor dome 108 by way of welding, or some other suitable attachment technique.
The combustion chamber 112 may receive a mixture of fuel and air for combustion in a gas turbine engine. The cassette 102, the opposing cassette 124, and/or the dome wall 113 may at partially or completely define the combustion chamber 112. For example, the combustion chamber 112 may be defined between the inner surface 118 of the cassette 102 and the inner surface 132 of the opposing cassette 124.
In some examples, the cowl 104 may extend along the upstream direction U further than the opposing cowl 126. In other examples, the cowl 104 and the opposing cowl 126 may extend a same proximate distance from the dome wall 113. In other examples, the system may include the cowl 104 without the opposing cowl. Alternatively or in addition, the system may include the opposing cowl without the cowl 104. In some examples, the cowl 104 and the opposing cowl may include mirrored features but are oriented on separate outer surfaces of the combustor dome 108, such as the first outer surface 120 and the second outer surface 122.
During manufacturing and assembly, multiple cowls and/or opposing cowls may be formed by way of ALM. The cowls and/or opposing cowls may be positioned around the combustor dome 108.
The system 100 may include a plurality of cassettes 202. Each of the cassettes 202 may include the cassette 102 described in reference to
The cowls of the cassettes 202 may join together to define an annular cowl 206 around a first side of the combustor dome 108. The annular cowl 206 may extend away from the dome wall 113 along the upstream direction U. Alternatively or in addition, the annular cowl 206 may tapper radially inward toward a centerline C of the gas turbine engine. For example, the annular cowl 206 may curve radially inward toward the centerline C.
The combustor walls of the cassettes 202 may join together to define a annular combustor wall 208. The annular combustor wall 208 may at least partially define the combustion chamber 112 for the gas turbine engine.
Alternatively or in addition, the system 100 may include a plurality of opposing cassettes 210. Each of the opposing cassettes 210 may include the opposing cassette 124 described in reference to
The cowls of the opposing cassettes 210 may join together to define an opposing annular cowl 212 around the first side of the combustor dome 108. The opposing annular cowl 212 may extend away from the combustor dome wall 113 along the upstream direction U. Alternatively or in addition, the opposing annular cowl 212 may tapper radially outward and away a centerline C of the gas turbine engine. For example, the opposing annular cowl 212 may curve radially outward and away from the centerline C.
The combustor walls of the cassettes 302 may join together to define an opposing annular combustor wall 214. The opposing annular combustor wall 214 may at least partially define the combustion chamber 112 for the gas turbine engine. For example, the combustion chamber 112 may be defined between the annular combustor wall 208 and the opposing annular combustor wall 214.
In some examples, a space S may be defined between the annular cowl 206 and the opposing annular cowl 212. The inlets 110 of the combustor dome 108 may receive air conveyed to the space S by annular cowl 206 and/or the opposing annular cowl 212.
The cassette 102 may include a first adjoining end 306 and a second adjoining end 308. The cassette 102 may be circumferentially defined between the first adjoining end 306 and the second adjoining end 308. For example, the first adjoining end 306 may be circumferentially offset from the second adjoining end 308, with respect to the centerline C. In some examples, the cassette 102, or portions of the cassette 102, may include an accurate sheet that curves between the first adjoining end 306 and the second adjoining end 308. For example, the inner surface 118 of the cowl 104 may curve so that the cowl 104 may be received by an annular or semi-annular combustor dome that is annular with respect to the centerline C.
The cowl 104 may include a portion of the cassette 102 along the first axial side 302. The cowl 104 may extend from the first axial side 302 toward the second axial side 304. Alternately or addition, the cowl 104 may extend along the first axial side 302 of the cassette 102, from the first adjoining end 306 to the second adjoining end 308.
The cowl 104 may include a lip 310 along the first axial side 302 of the cassette 102. For example, the lip 310 may include a portion of the cassette 102 along the edge 115 of the cowl 104. The lip 310 may be positioned on the combustor dome 108 such that the lip 310 is upstream from the dome wall 113 (See
Depending on implementation, the thickness of the lip 310 may vary to improve a dynamic response of the cowl 104 during engine operation, a structural integrity of the cowl 104, and other design considerations. The lip 310 may be formed by way of ALM such that the lip is integral to the cowl 104. The tapering of the lip may include a curve that is formed layer by layer through ALM.
In some examples, a recess 312 may be defined in the cowl 104 along the first axial side of the cassette. The recess 312 may extend toward the second axial side of the cowl 104. Alternatively or in addition, the cowl 104 may include a collar 314 that defines the recess 312. The collar 314 may include a portion of the cassette 102 that extends radially away from or toward the centerline C. The collar 314 may include an outer surface 316 that intersects the outer surface 111 of the cassette 102. Alternatively or in addition, the cassette 102 may include a fillet 318 where the outer surface 111 of the cassette 102 and the outer surface of the collar 314 meet. For example, the fillet 318 may be a curved region along an intersection of the outer surface 111 of the cassette 102 and the outer surface 316 of the collar 314. The fillet 318 may be tapered thereby directing cooling fluid away from the outer surface 116 of the cassette 102 and/or around the recess 312. For example, the fillet 318 may be rounded along the intersection.
The collar 314 and/or the fillet 318 may be integral to the cassette and formed by way of ALM. For example, the collar 314 and/or the fillet 318 may be formed layer by layer via ALM. ALM may enable the fillet 318 and/or collar 314 to be tapered at various angles or curves. The fillet 318 and/or collar 314 may be integrated into the cowl 104, thereby removing the steps of fastening or joining separate components to the cowl 104. Alternatively or in addition, the recess 312 may be defined in layers successively added to the cassette 102 during formation, thereby eliminating additional steps of removing material to form the recess 312.
In some examples, the cowl 104 defines a fastener hole 309 or multiple fastener holes. The fastener hole 309 may receive a fastener for coupling the cowl 104 to the combustor dome 108. The fastener hole 309 may extend through the cassette 102, between an inner surface 118 and outer surface 116 of the cassette 102. The fastener hole 309 may receive a fastener to affix both the cowl 104 and the combustor wall 106 to the combustor dome 108. The fastener hole 309 may be defined by layers successively added to the cassette 102 during formation, thereby eliminating additional steps of removing material to form the fastener hole 309.
During assembly, the first adjoining end may be positioned along a second adjoining end of an adjacent cassette. The cassette 102 may include a groove 320 along the first adjoining end and/or the second adjoining end. For example, the groove may include a recess that extends toward the second adjoining end 308. In some examples, at least a portion of the cowl 104 and at least a portion of the combustor wall 105 may include the groove 320. The groove may be formed by successively creating layers by way of ALM. The layers may define the groove 320 thereby removing additional steps of removing material to form the groove 320 or coupling components together to define the groove 320.
The tongue may be integrated into the cassette as a portion of the cassette. The tongue may be included in at least one layer solidified to form the cassette 102 by way of ALM. One or more layers may be added to the cassette 102 to define the tongue 402 on the cassette 102 with removing material from the cassette and/or without coupling components to the cassette to from the tongue 402.
In the example illustrated in
The rib 502 may be integral to the cassette 102. For example, the rib 502 may be integrated into the cassette 102 by way of ALM. For example, the rib 502 may be formed layer by layer via ALM. The rib 502 may be integrated into the cowl 104, thereby removing the steps of joining separate components to the cowl 104 and/or removing material from the cowl 104.
In some examples, the stiffener 602 may include an elongated rib. For example, a first end 604 of the stiffener 602 may be positioned at or proximate to the first side 302 of the cassette. The stiffener 602 may extend away from the edge 115 of the cowl 104. For example, stiffener 602 may extend along the upstream direction U and/or toward the second side of the cassette 102. A second end 606 of the stiffener 602 may be downstream from the first end 604 of the stiffener 602.
In some examples, the stiffener 602 may be tapered such that the first end 604 is further from the inner surface 118 of the cassette 102 than the second end 606. Alternatively or in addition, for example, the first end 604 may extend away from the inner surface 118 of the cassette 102 and the second end of the stiffener may be flush or approximately flush with the inner surface 118 of the cassette. Alternatively, the stiffener may curve from the first end 604 of the cassette 102 to the second end 606.
The stiffener 602 may be integral to the cassette 102. For example, the stiffener 602 may be integrated into the cassette 102 by way of ALM. The stiffener 602 may be formed layer by layer via ALM. The stiffener 602 may be integrated into the cowl 104 as a portion of the cowl 104, thereby removing the steps of joining separate components to the cowl 104 and/or removing material from the cowl 104 to define the stiffener 602.
The stiffener 602, or similar type features, may add stiffness to the cowl 104. Alternatively or in addition, the stiffener 602, or similar features, may be arranged on the cowl 104 to alter/tune the dynamic response of the cowl 104 to prevent damaging vibration in the engine during operation.
In some examples, the collar 314 may divert the compressed air around the fuel injector assembly 704. For example, the recess of the cowl 104 may receive a stem 706 of the fuel injector assembly 704. The collar 314 may cause air to flow around stem of the fuel injector assembly and over the edge 115.
The opposing cassette 124 may be positioned radially inward from the cassette 102. The opposing cowl 126 may receive air from the diffusor and guide the air in a radial inward direction I. For example, opposing cowl 126 may tapper toward the cowl 104. Alternatively or in addition, the cowl 104 may tapper toward the opposing cowl 126. The combustion chamber 112 may be defined between the cassette 102 and the opposing cassette 124.
The gas turbine engine 800 may take a variety of forms in various embodiments. Though depicted as an axial flow engine, in some forms the gas turbine engine 800 may have multiple spools and/or may be a centrifugal or mixed centrifugal/axial flow engine. In some forms, the gas turbine engine 800 may be a turboprop, a turbofan, or a turboshaft engine. Furthermore, the gas turbine engine 800 may be an adaptive cycle and/or variable cycle engine. Other variations are also contemplated.
The gas turbine engine 800 may include an intake section 820, a compressor section 860, a combustion section 830, a turbine section 810, and an exhaust section 850. During operation of the gas turbine engine 800, fluid received from the intake section 820, such as air, travels along the direction D1 and may be compressed within the compressor section 860. The compressed fluid may then be mixed with fuel and the mixture may be burned in the combustion section 830. The combustion section 830 may include any suitable fuel injection and combustion mechanisms. The combustion section 830 may include the cowl 104 and/or the opposing cowl 126. For example, the cowl 104 may influence the pressure of the air around the fuel injection and combustion mechanisms. The hot, high pressure fluid may then pass through the turbine section 880 to extract energy from the fluid and cause a turbine shaft of a turbine 814 in the turbine section 810 to rotate, which in turn drives the compressor section 860. Discharge fluid may exit the exhaust section 850.
As noted above, the hot, high pressure fluid passes through the turbine section 810 during operation of the gas turbine engine 800. As the fluid flows through the turbine section 810, the fluid passes between adjacent blades 812 of the turbine 814 causing the turbine 814 to rotate. The rotating turbine 814 may turn a shaft 840 in a rotational direction D2, for example. The blades 812 may rotate around an axis of rotation, which may correspond to a centerline C of the turbine 814 in some examples.
For example, ALM may form the cassettes 202. The cassettes 202 may be formed by applying a laser to a powder bed to define successive layers fused together by the laser. Each of the layers comprises various portions of the cassette 102 and/or the opposing cassette 124. For example, at least one of the layers of the cassette 102 may include a portion of the cowl 104 and a portion of the combustor wall 106. Alternately or in addition, at least one of the layers may include at least one of the cowl lip 310, the collar 314, the tongue 402 the rib 502, and/or the stiffener 602. In some examples, the layer formed by fusing the power may define, or partially define, the recess 312, the groove 320, and/or the fastener hole 309. In other examples, other methods of additive layer manufacturing may be employed to form the cassette 102 and/or the opposing cassette.
Manufacturing the combustor system 100 may further include positioning the cassette 102 on the combustor dome 108 (904). The cassette 102 may be positioned such that the combustor wall 106 of the cassette 102 at least partially defines the combustion chamber 112. For example, the inner surface 118 of the cassette 102 may be positioned on the first outer surface 120 of the combustor dome 108. The combustor wall 106 may be positioned downstream from the dome wall 113. At least a portion of the cowl 104 may extend away from the dome wall 113 and the combustion chamber 112.
Manufacturing the combustor system 100 may further include coupling the cassette 102 to the combustor dome 108. For example, a fastener may couple the cassette 102 to the combustor dome 108. Multiple cassettes may be positioned on the combustor dome 108 and fastened to the combustor dome 108. In other examples, the cassettes may be braised or welded to the combustor dome 108.
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. Unless otherwise indicated or the context suggests otherwise, as used herein, “a” or “an” means “at least one” or “one or more.”
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:
1. A system comprising:
a cassette configured to couple to an annular combustor dome arranged around a flow path for a gas turbine engine, the annular combustor dome comprising a dome wall comprising a plurality of inlets configured to receive compressed air for a combustion chamber located downstream, relative to the flow path, from the annular combustor dome the cassette comprising:
an annular combustor dome arranged around a flow path for the gas turbine engine, the annular combustor dome comprising a first outer surface and a second outer surface radially inward from the first outer surface, relative to the flow path, the annular combustor dome comprising a dome wall defined between the first outer surface and a second outer surface, the dome wall including a plurality of inlets in fluid communication with a combustion chamber downstream from the combustor dome, relative to the flow path; and
a plurality of cassettes joined together and positioned on the first outer surface of the dome, at least one of the cassettes including a cowl integral to a combustor wall, wherein the combustor wall extends along a downstream direction, relative to the flow path, and at least partially defines the combustion chamber, wherein the cowl extends away from the combustor dome in an upstream direction, relative to the flow path, and is configured to convey air received from a diffusor in a radial inward direction to a space upstream of the combustor dome.
9. The combustor of aspect 8, wherein each of the cassettes comprises a plurality of layers successively fused together by an energy beam, wherein each of the layers comprise a portion of the cowl and the combustor wall.
10. The combustor of any of aspects 8 to 9, wherein the dome wall at least partially defines the combustion chamber, wherein combustor wall extends away from the dome wall.
11. The combustor of any of aspects 8 to 10, the cowl comprises a stiffener integral to the cowl, the stiffener comprising a raised portion of the cowl extended along a surface of the cowl away from an edge of the cowl.
12. The combustor of any of aspects 8 to 11, further comprising:
a plurality of opposing cassettes joined together and positioned on the second outer surface of the dome, the plurality of opposing cassettes positioned radially inward from the first plurality of cassettes, relative to the flow path, at least one of the opposing cassettes including an opposing cowl integral to an opposing combustor wall, wherein the opposing combustor wall extends in the downstream direction and the combustion chamber is at least partially defined between the opposing combustor wall and the combustor wall, wherein the opposing cowl extends away from the combustor dome in the upstream direction.
13. The combustor of any of aspects 8 to 12, wherein the cassettes comprises a first cassette and a second cassette, the first cassette adjacent to the second cassette on the combustor dome, wherein the first cassette comprises a tongue positioned in a groove defined by an adjoining edge of the second cassette.
14. The combustor of aspect 13, wherein the cassette comprises a first axial side and a second axial side, the cowl further comprising a collar and a lip, the collar and the lip being integral to the cowl, wherein the collar defines a recess along the first axial side and the lip comprises a portion of the cowl along an edge of the cowl and adjacent to the recess, wherein the collar extends along a radial inward direction, and the lip extends along a radial outward direction, wherein the collar is configured to divert air around a fuel injector assembly positioned at least partially in the recess and the lip is configured to guide air toward a space upstream from the dome wall and radially inward from the cowl.
15. A method comprising
forming, by additive layer manufacturing, a plurality of cassettes for a gas turbine engine, each of the cassettes comprising a cowl integral to a combustor wall;
positioning at least one of the cassettes on an outer surface of an annular combustor dome so that the combustor wall at least partially defines a combustion chamber downstream from the dome and at least a portion of the cowl is positioned upstream from the combustor dome, relative to a flow path that extends through a cross section of the combustor dome; and
coupling the at least one of the cassettes to the annular dome.
16. The method of aspect 15, wherein the step of positioning further comprises:
joining a groove in a first cassette with a tongue of a second cassette.
17. The method of any of aspects 15 to 16, further comprising:
forming, by additive layer manufacturing, a plurality of opposing cassettes, each of the opposing cassettes comprising an opposing cowl integral to an opposing combustor wall; and
positioning at least one of the opposing cassette on a second outer surface of the annular combustor dome so that and at least a portion of the opposing cowl is positioned opposite the cowl, and the combustion chamber is defined between the opposing combustor wall and the combustor wall.
18. The method of any of aspects 15 to 17, wherein the step of forming the plurality of cassettes further comprises:
applying metallic powder to a previously solidified layer of the cassette; and
directing an energy beam to the metallic powder to solidify the power and generate a new layer of the cassette, the new layer comprising at least a portion of the cowl and at least a portion of the outer combustor wall.
19. The method of aspect 18, wherein the new layer further comprises a rib configured to be positioned along an edge of the cowl.
20. The method of aspect 18, wherein the new layer further comprises at least a portion of a collar configured to define a recess along an edge of the cowl.
This invention was made with government support under contract DTFAWA-14-R-73573 awarded by the Federal Aviation Administration. The government has certain rights in the invention.
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