A bearing includes a bearing sleeve with a first portion and a second portion adjacent to the first portion. A bump foil extends along an inner face of the first portion of the bearing sleeve and a metal mesh extends along an inner face of the second portion of the bearing sleeve. A top foil extends along an inner face of the bump foil of the first portion and the metal mesh of the second portion.
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8. A rotary machine comprising:
a shaft that is configured to rotate in the rotary machine;
a stationary component positioned outward from the shaft; and
a hybrid foil bearing positioned between the shaft and the stationary component, wherein the hybrid foil bearing has a first bump foil portion and a first metal mesh portion adjacent to the first bump foil portion.
1. A bearing comprising:
a bearing sleeve with a first portion and a second portion adjacent to the first portion;
a bump foil extending along an inner face of the first portion of the bearing sleeve;
a metal mesh extending along an inner face of the second portion of the bearing sleeve; and
a top foil extending along an inner face of the bump foil of the first portion and the metal mesh of the second portion.
2. The bearing of
a third portion in the bearing sleeve adjacent to the second portion; and
a bump foil extending along an inner face of the third portion of the bearing sleeve;
wherein the top foil extends along an inner face of the bump foil of the third portion.
3. The bearing of
4. The bearing of
a third portion in the bearing sleeve adjacent to the first portion; and
a metal mesh extending along an inner face of the third portion of the bearing sleeve;
wherein the top foil extends along an inner face of the metal mesh of the third portion.
5. The bearing of
6. The bearing of
7. The bearing of
a second bump foil extending along an inner face of the first bump foil, wherein the first bump foil and the second bump foil have different sized corrugations.
9. The rotary machine of
a bearing sleeve with the first bump foil portion and the first metal mesh portion;
a first bump foil positioned in the first bump foil portion of the bearing sleeve;
a first metal mesh positioned in the first metal mesh portion of the bearing sleeve; and
a top foil extending along an inner face of the first bump foil in the first bump foil portion and the first metal mesh in the first metal mesh portion.
10. The rotary machine of
a second bump foil portion in the bearing sleeve adjacent to the first metal mesh portion; and
a second bump foil extending along an inner face of the second bump foil portion of the bearing sleeve;
wherein the top foil extends along an inner face of the second bump foil of the second bump foil portion.
11. The rotary machine of
a second metal mesh portion in the bearing sleeve adjacent to the first bump foil portion; and
a second metal mesh extending along an inner face of the second metal mesh portion of the bearing sleeve;
wherein the top foil extends along an inner face of the second metal mesh of the second metal mesh portion.
12. The rotary machine of
13. The rotary machine of
a second bump foil extending along an inner face of the first bump foil, wherein the first bump foil and the second bump foil have different sized corrugations.
14. The rotary machine of
a tie rod extending along a central axis of the rotary machine, wherein the shaft is configured to rotate with the tie rod;
a compressor section including a compressor inlet, a compressor outlet, and a compressor rotor, wherein the compressor rotor is configured to rotate with the tie rod; and
a motor including a motor housing, a motor stator, and a motor rotor.
15. The rotary machine of
a tie rod extending along a central axis of the rotary machine, wherein the shaft is configured to rotate with the tie rod;
a fan section with a fan inlet, a fan outlet, and a fan rotor, wherein the fan rotor is configured to rotate with the tie rod;
a compressor section including a compressor inlet, a compressor outlet, and a compressor rotor, wherein the compressor rotor is configured to rotate with the tie rod;
a first turbine section including a first turbine inlet, a first turbine outlet, and a first turbine rotor, wherein the first turbine rotor is configured to rotate with the tie rod; and
a second turbine section including a second turbine inlet, a second turbine outlet, and a second turbine rotor, wherein the second turbine rotor is configured to rotate with the tie rod.
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The present invention relates to a bearing, and in particular, to a hybrid foil bearing.
Air cycle machines are used in environmental control systems in aircraft to condition air for delivery to an aircraft cabin. Conditioned air is air at a temperature, pressure, and humidity desirable for aircraft passenger comfort and safety. At or near ground level, the ambient air temperature and/or humidity is often sufficiently high that the air must be cooled as part of the conditioning process before being delivered to the aircraft cabin. At flight altitude, ambient air is often far cooler than desired, but at such a low pressure that it must be compressed to an acceptable pressure as part of the conditioning process. Compressing ambient air at flight altitude heats the resulting pressured air sufficiently that it must be cooled, even if the ambient air temperature is very low. Thus, under most conditions, heat must be removed from air by the air cycle machine before the air is delivered to the aircraft cabin. A cabin air compressor can be used to compress air for use in an environmental control system. The cabin air compressor includes a motor to drive a compressor section that in turn compresses air flowing through the cabin air compressor.
Both air cycle machines and cabin air compressors have a shaft extending down a central axis that rotates. Bearings are positioned outward from the shaft to reduce friction between the rotating shaft and stationary components. Historically, ball bearings were used in air cycle machines and cabin air compressors. Ball bearings face limitations in that they wear out quickly and thus need to be replaced often. Further, ball bearings require oil for operation and the smell of the oil can seep into the air flowing through the air cycle machine and/or cabin air compressor before the air is delivered to the aircraft cabin.
To overcome the limitations of ball bearings, air bearings were later developed for use in air cycle machines and cabin air compressors. Air bearings create an air gap between a rotating part and the bearing components so that the air gap acts as the bearing. Examples of air bearings that can be used are bump foil bearings and metal mesh bearings. Bump foil bearings include a bump foil positioned between a top foil and a bearing sleeve. Metal mesh bearings include a metal mesh positioned between a top foil and a bearing sleeve. With both bump foil bearings and metal mesh bearings the top foil is positioned around the shaft. As air flows along the shaft, the top foil is pushed outward from the shaft to create an air gap between the rotating shaft and the top foil. Bump foil bearings have a high stiffness and can support high loads but have low dampening characteristics. The low dampening characteristics can lead to a phenomenon known as sub-synchronous whirl, which is the problem of uncontrolled vibration of the shaft. Metal mesh bearings have high dampening characteristics, but sag over time causing the shaft to become off centered.
A bearing includes a bearing sleeve with a first portion and a second portion adjacent to the first portion. A bump foil extends along an inner face of the first portion of the bearing sleeve and a metal mesh extends along an inner face of the second portion of the bearing sleeve. A top foil extends along an inner face of the bump foil of the first portion and the metal mesh of the second portion.
A rotary machine includes a shaft that is configured to rotate in the rotary machine, a stationary component positioned outward from the shaft, and a hybrid foil bearing positioned between the shaft and the stationary component. The hybrid foil bearing has a first bump foil portion and a first metal mesh portion adjacent to the first bump foil portion.
Fan section 12, compressor section 14, first turbine section 16, and second turbine section 18 are all mounted on tie rod 20. Tie rod 20 rotates about axis A. Fan and compressor housing 22 is connected to seal plate 24 and first turbine housing 26 with fasteners. Seal plate 24 separates flow paths in fan and compressor housing 22 from flow paths in first turbine housing 26. First turbine housing 26 is connected to second turbine housing 28 with fasteners. Fan and compressor housing 22, first turbine housing 26, and second turbine housing 28 together form an overall housing for air cycle machine 10. Fan and compressor housing 22 houses fan section 12 and compressor section 14, first turbine housing 26 housing first turbine section 16, and second turbine housing 28 houses second turbine section 18.
Fan section 12 includes fan inlet 30, fan duct 32, fan outlet 34, and fan rotor 36. Fan section 12 typically draws in ram air from a ram air scoop or alternatively from an associated gas turbine or other aircraft component. Air is drawn into fan inlet 30 and is ducted through fan duct 32 to fan outlet 34. Fan rotor 36 is positioned in fan duct 32 adjacent to fan inlet 30 and is mounted to and rotates with tie rod 20. Fan rotor 36 draws air into fan section 12 to be routed through air cycle machine 10.
Compressor section 14 includes compressor inlet 40, compressor duct 42, compressor outlet 44, compressor rotor 46, and diffuser 48. Air is routed into compressor inlet 40 and is ducted through compressor duct 42 to compressor outlet 44. Compressor rotor 46 and diffuser 48 are positioned in compressor duct 42. Compressor rotor 46 is mounted to and rotates with tie rod 20 to compress the air flowing through compressor duct 42. Diffuser 48 is a static structure through which the compressor air can flow after it has been compressed with compressor rotor 46. Air exiting diffuser 48 can then exit compressor duct 42 through compressor outlet 44.
First turbine section 16 includes first turbine inlet 50, first turbine duct 52, first turbine outlet 54, and first turbine rotor 56. Air is routed into first turbine inlet 50 and is ducted through first turbine duct 52 to first turbine outlet 54. First turbine rotor 56 is positioned in first turbine duct 52 and is mounted to and rotates with tie rod 20. First turbine rotor 56 will extract energy from the air passing through first turbine section 16 to drive rotation of tie rod 20.
Second turbine section 18 includes second turbine inlet 60, second turbine duct 62, second turbine outlet 64, and second turbine rotor 66. Air is routed into second turbine inlet 60 and is ducted through second turbine duct 62 to second turbine outlet 64. Second turbine rotor 66 is positioned in second turbine duct 62 and is mounted to and rotates with tie rod 20. Second turbine rotor 66 will extract energy from the air passing through second turbine section 18 to drive rotation of tie rod 20.
Air cycle machine 10 further includes first bearing 70, first rotating shaft 72, second bearing 74, and second rotating shaft 76. First bearing 70 is positioned in fan section 12 and is supported by fan and compressor housing 22. First rotating shaft 72 extends between and rotates with fan rotor 36 and compressor rotor 46. A radially outer surface of first rotating shaft 72 abuts a radially inner surface of first bearing 70. Second bearing 74 is positioned in first turbine section 16 and is supported by first turbine housing 26. Second rotating shaft 76 extends between and rotates with first turbine rotor 56 and second turbine rotor 66. A radially outer surface of second rotating shaft 76 abuts a radially inner surface of second bearing 74.
Motor 102 includes motor housing 110, motor rotor 112, and motor stator 114. Motor housing 110 surrounds motor rotor 112 and motor stator 114. Motor 102 is an electric motor with motor rotor 112 disposed within motor stator 114. Motor rotor 112 is rotatable about axis B. Motor rotor 102 is mounted to tie rod 106 to drive rotation of tie rod 106 in air compressor 100.
Compressor section 104 includes compressor housing 120, compressor inlet 122, compressor outlet 124, and compressor rotor 126. Compressor housing 120 includes a duct that forms compressor inlet 122 and a duct that forms compressor outlet 124. Compressor inlet 122 draws air into compressor section 104. Positioned in compressor housing 120 is compressor rotor 126. Compressor rotor 126 is driven with motor 102 and is mounted on tie rod 106 to rotate with tie rod 106 about axis B. Air that is drawn into compressor section 104 through compressor inlet 122 is compressed with compressor rotor 126 before exiting compressor section 104 through compressor outlet 124.
Air compressor 100 further includes first bearing 130, first rotating shaft 132, second bearing 134, and second rotating shaft 136. First bearing 130 is positioned in motor 102 and is supported by motor housing 110. First rotating shaft 132 is mounted on and rotates with tie rod 106. A radially outer surface of first rotating shaft 132 abuts a radially inner surface of first bearing 130. Second bearing 134 is positioned in motor 102 and is supported by motor housing 110. Second rotating shaft 136 extends between and rotates with motor rotor 112 and compressor rotor 126. A radially outer surface of second rotating shaft 136 abuts a radially inner surface of second bearing 134.
Hybrid foil bearing 200 includes three sections, including first foil portion 210, metal mesh portion 212, and second foil portion 214. Metal mesh portion 212 is positioned between first foil portion 210 and second foil portion 214. Bearing sleeve 220 has a cylindrical shape and forms a body portion of hybrid foil bearing 200. As seen in
First foil 222 is a cylindrical shape and is positioned in bearing sleeve 220 adjacent to an inner face of bearing sleeve 220 in first foil portion 210. Metal mesh 224 is a cylindrical shape and is positioned in bearing sleeve 220 adjacent to an inner face of bearing sleeve 220 in metal mesh portion 212. Second foil 226 is a cylindrical shape and is positioned in bearing sleeve 220 adjacent to an inner face of bearing sleeve 220 in second foil portion 214. Top foil 228 is a cylindrical shape and is positioned in bearing sleeve 220. Top foil 228 is adjacent to inner faces of first foil 222, metal mesh 224, and second foil 226.
Bearing sleeve 220 forms an outer body portion of metal mesh section 212 of hybrid foil bearing 200. Positioned along an inner face of bearing sleeve 220 in metal mesh section 212 is metal mesh 224. Metal mesh 224 includes a plurality of metal wires tangled together in a random manner. Metal mesh 224 can be made out of any suitable metal. Positioned along an inner face of metal mesh 224 is top foil 228. A first end of top foil 228 extends into metal mesh 224 to hold top foil 228 in position. In an alternate embodiment, the first of top foil 228 extends through metal mesh 224 and into bearing sleeve 220. There is a gap between the first end of top foil 228 and a second end of top foil 228 so that air can enter the space between shaft S and top foil 228. Shaft S is positioned adjacent to top foil 228 and extends through metal mesh section 212 of hybrid foil bearing 200.
As shaft S rotates, air in hybrid foil bearing 200 will force top foil 228 radially outwards, pushing top foil 228 further into metal mesh 224. This forms air bearing gap 230 between shaft S and top foil 228. The utilization of metal mesh 224 in metal mesh portion 212 gives metal mesh portion 212 good dampening characteristics, as metal mesh 224 has a large number of surfaces contacting one another due to the plurality of wires tangled together that are capable of absorbing the vibrations. The good damping characteristics of metal mesh section 212 reduces vibrations caused by shaft S rotating in hybrid foil bearing 200.
Bearing sleeve 220 forms an outer body portion of foil section 210A of hybrid foil bearing 200. Positioned along an inner face of bearing sleeve 220 in foil section 210A is bump foil 222A. Bump foil 222A includes corrugations extending along the sheet. The corrugations can be sized for stiffness and load capacity. Positioned along an inner face of bump foil 222A is top foil 228. A first end of top foil 228 extends radially outward and abuts bump foil 222A to hold top foil 228 in place. There is a gap between the first end of top foil 228 and a second end of top foil 228 so that air can enter the space between shaft S and top foil 228. Shaft S is positioned adjacent to top foil 228 and extends through foil section 210A of hybrid foil bearing 200.
As shaft S rotates, air in hybrid foil bearing 200 will force top foil 228 radially outwards, pushing top foil 228 further into bump foil 222A to cause bump foil 222A to elastically deform. This forms air bearing gap 230 between shaft S and top foil 228. As seen in
Bearing sleeve 220 forms an outer body portion of foil section 210B of hybrid foil bearing 200. Positioned along an inner face of bearing sleeve 220 in foil section 210B is bump foil 222A. Foil 222B is a bump foil with three different sections, including first foil section 240, second foil section 242, and third foil section 244. First foil section 240, second foil section 242, and third foil section 244 are all bump foils with corrugations and they can have differently sized corrugations. In the embodiment shown in
As shaft S rotates, air in hybrid foil bearing 200 will force top foil 228 radially outwards, pushing top foil 228 further into foil 222B to cause foil 222B to elastically deform. This forms an air bearing gap between shaft S and top foil 228. As seen in
Bearing sleeve 220 forms an outer body portion of foil section 210C of hybrid foil bearing 200. Positioned along an inner face of bearing sleeve 220 in foil section 210C are foil 222C1 and foil 222C2. Foil 222C1 and foil 222C2 are bump foils. Foil 222C1 is adjacent to the inner face of bearing sleeve 220 and foil 222C2 is adjacent to the inner face of foil 222C1. In the embodiment shown in
As shaft S rotates, air in hybrid foil bearing 200 will force top foil 228 radially outwards, pushing top foil 228 further into foil 222C2 to cause foil 222C2 to elastically deform. This forms air bearing gap 230 between shaft S and top foil 228. As seen in
Bearing sleeve 220 forms an outer body portion of foil section 210D of hybrid foil bearing 200. Positioned along an inner face of bearing sleeve 220 in foil section 210D are plurality of leaf foils 222D and plurality of notches 246. Bearing sleeve 220 has plurality of notches 246 cut into it on an inner diameter of bearing sleeve 220. A first end of each leaf foil 222D is positioned in one of notches 246 in bearing sleeve 220. Each leaf foil 222D extends outward from one notch 246 and runs along an inner diameter of bearing sleeve 220. A second end of each leaf foil 222D overlaps an adjacent leaf foil 222D. In the embodiment shown in
Foil section 210D does not include a top foil, as plurality of leaf foils 222D extend around the entire inner diameter of bearing sleeve 220 and act as the top foil that abuts shaft S. When foil section 210D is used in hybrid foil bearing 200 shown in
Bearing sleeve 220 forms an outer body portion of foil section 210E of hybrid foil bearing 200. Positioned along an inner face of bearing sleeve 220 in foil section 210E are plurality of foils 222E and plurality of supports 248. There are three supports 248 in the embodiment shown in
As shaft S rotates, air in hybrid foil bearing 200 will force top foil 228 radially outwards, pushing top foil 228 further into plurality of foils 222E to cause plurality of foils 222E to elastically deform. This forms air bearing gap 230 between shaft S and top foil 228. Cantilevers C formed with plurality of foils 222E absorb stress from the deformation of plurality of foils 222E while helping plurality of foils 222E retain their strength. The utilization of plurality of foils 222E forming cantilevers C in foil portion 210E gives foil portion 210E high stiffness and high load bearing capacity.
Bearing sleeve 220 forms an outer body portion of foil section 210F of hybrid foil bearing 200. Positioned along an inner face of bearing sleeve 220 in foil section 210F are plurality of foils 222F and plurality of projections 249. Plurality of projections 249 extend radially inwards from bearing sleeve 220 and a lip is formed on either side of each projection 249. There are three projections 249 in the embodiment shown in
As shaft S rotates, air in hybrid foil bearing 200 will force plurality of top foils 228 radially outwards, pushing plurality of top foils 228 further into plurality of foils 222F to cause plurality of foils 222F to elastically deform. This forms air bearing gap 230 between shaft S and plurality of top foils 228. As seen in
Hybrid foil bearing 200 utilizes first foil section 210, metal mesh section 212, and second foil section 214. First foil section 210 and second foil section 214 have high stiffness and high load bearing capabilities. Metal mesh section 212 has good dampening characteristics. Utilizing first foil section 210, metal mesh section 212, and second foil section 214 creates hybrid foil bearing 200 that has high stiffness and high load bearing capabilities while also having good dampening characteristics.
Hybrid foil bearing 250 includes three sections, including first metal mesh portion 260, foil portion 262, and second metal mesh portion 264. Foil portion 262 is positioned between first metal mesh portion 260 and second metal mesh portion 264. Bearing sleeve 270 has a cylindrical shape and forms a body portion of hybrid foil bearing 250. As seen in
First metal mesh 272 is a cylindrical shape and is positioned in bearing sleeve 270 adjacent to an inner face of bearing sleeve 270 in first metal mesh portion 260. Foil 274 is a cylindrical shape and is positioned in bearing sleeve 270 adjacent to an inner face of bearing sleeve 270 in foil portion 262. Second metal mesh 276 is a cylindrical shape and is positioned in bearing sleeve 270 adjacent to an inner face of bearing sleeve 270 in second metal mesh portion 264. Top foil 278 is a cylindrical shape and is positioned in bearing sleeve 270. Top foil 278 is adjacent to inner faces of first metal mesh 272, foil 274, and second metal mesh 276.
Hybrid foil bearing 300 includes four sections, including first metal mesh portion 310, first foil portion 312, second foil portion 314, and second metal mesh portion 316. First foil portion 312 is positioned between first metal mesh portion 310 and second foil portion 314. Second foil portion 314 is positioned between first foil portion 312 and second metal mesh portion 316. Bearing sleeve 320 has a cylindrical shape and forms a body portion of hybrid foil bearing 300. As seen in
First metal mesh 322 is a cylindrical shape and is positioned in bearing sleeve 320 adjacent to an inner face of bearing sleeve 320 in first metal mesh section 310. First foil 324 is a cylindrical shape and is positioned in bearing sleeve 320 adjacent to an inner face of bearing sleeve 320 in first foil portion 312. Second foil 326 is a cylindrical shape and is positioned in bearing sleeve 320 adjacent to an inner face of bearing sleeve 320 in second foil portion 314. Second metal mesh 328 if a cylindrical shape and is positioned in bearing sleeve 320 adjacent to an inner face of bearing sleeve 320 in second metal mesh portion 316. Top foil 330 is a cylindrical shape and is positioned in bearing sleeve 320. Top foil 330 is adjacent to inner faces of first metal mesh 322, first foil 324, second foil 326, and second metal mesh 328.
Hybrid foil bearing 350 includes two sections, including metal mesh portion 360 and foil portion 362. Metal mesh portion 360 is positioned adjacent to foil portion 362. Bearing sleeve 370 has a cylindrical shape and forms a body portion of hybrid foil bearing 350. As seen in
Metal mesh 372 is a cylindrical shape and is positioned in bearing sleeve 370 adjacent to an inner face of bearing sleeve 370 in metal mesh portion 360. Foil 374 is a cylindrical shape and is positioned in bearing sleeve 370 adjacent to an inner face of bearing sleeve 370 in foil portion 362. Top foil 376 is a cylindrical shape and is positioned in bearing sleeve 370. Top foil 376 is adjacent to inner faces of metal mesh 372 and foil 374.
Hybrid foil bearing 200 shown in
The following are non-exclusive descriptions of possible embodiments of the present invention.
A bearing includes a bearing sleeve with a first portion and a second portion adjacent to the first portion. A bump foil extends along an inner face of the first portion of the bearing sleeve and a metal mesh extends along an inner face of the second portion of the bearing sleeve. A top foil extends along an inner face of the bump foil of the first portion and the metal mesh of the second portion.
The bearing of the preceding paragraph can optionally include, additionally and/or alternatively, any one or more of the following features, configurations and/or additional components:
The bearing can include a third portion in the bearing sleeve adjacent to the second portion, and a bump foil extending along an inner face of the third portion of the bearing sleeve, wherein the top foil extends along an inner face of the bump foil of the third portion.
The bearing sleeve has a first wall thickness at the first portion and the third portion that is greater than a second wall thickness at the second portion.
The bearing can include a third portion in the bearing sleeve adjacent to the first portion, and a metal mesh extending along an inner face of the third portion of the bearing sleeve, wherein the top foil extends along an inner face of the metal mesh of the third portion.
The bearing sleeve has a first wall thickness at the first portion and the third portion that is lesser than a second wall thickness at the second portion.
The bump foil has a first section having corrugations with a first size and a second section having corrugations with a second size, wherein the first size is larger than the second size.
The bump foil is a first bump foil and the bearing further includes a second bump foil extending along an inner face of the first bump foil, wherein the first bump foil and the second bump foil have different sized corrugations.
A rotary machine includes a shaft that is configured to rotate in the rotary machine, a stationary component positioned outward from the shaft, and a hybrid foil bearing positioned between the shaft and the stationary component. The hybrid foil bearing has a first bump foil portion and a first metal mesh portion adjacent to the first bump foil portion.
The rotary machine of the preceding paragraph can optionally include, additionally and/or alternatively, any one or more of the following features, configurations and/or additional components:
The hybrid foil bearing further includes a bearing sleeve with the first bump foil portion and the first metal mesh portion, a first bump foil positioned in the first bump foil portion of the bearing sleeve, a first metal mesh positioned in the first metal mesh portion of the bearing sleeve, and a top foil extending along an inner face of the first bump foil in the first bump foil portion and the first metal mesh in the first metal mesh portion.
The hybrid foil bearing further includes a second bump foil portion in the bearing sleeve adjacent to the first metal mesh portion, and a second bump foil extending along an inner face of the second bump foil portion of the bearing sleeve, wherein the top foil extends along an inner face of the second bump foil of the second bump foil portion.
The hybrid foil bearing further includes a second metal mesh portion in the bearing sleeve adjacent to the first bump foil portion, and a second metal mesh extending along an inner face of the second metal mesh portion of the bearing sleeve, wherein the top foil extends along an inner face of the second metal mesh of the second metal mesh portion.
The first bump foil has a first section having corrugations with a first size and a second section having corrugations with a second size, wherein the first size is larger than the second size.
The hybrid foil bearing further includes a second bump foil extending along an inner face of the first bump foil, wherein the first bump foil and the second bump foil have different sized corrugations.
The rotary machine can include a tie rod extending along a central axis of the rotary machine, wherein the shaft is configured to rotate with the tie rod; compressor section including a compressor inlet, a compressor outlet, and a compressor rotor, wherein the compressor rotor is configured to rotate with the tie rod; and a motor including a motor housing, a motor stator, and a motor rotor.
The rotary machine can include a tie rod extending along a central axis of the rotary machine, wherein the shaft is configured to rotate with the tie rod; a fan section with a fan inlet, a fan outlet, and a fan rotor, wherein the fan rotor is configured to rotate with the tie rod; a compressor section including a compressor inlet, a compressor outlet, and a compressor rotor, wherein the compressor rotor is configured to rotate with the tie rod; a first turbine section including a first turbine inlet, a first turbine outlet, and a first turbine rotor, wherein the first turbine rotor is configured to rotate with the tie rod; and a second turbine section including a second turbine inlet, a second turbine outlet, and a second turbine rotor, wherein the second turbine rotor is configured to rotate with the tie rod.
While the invention has been described with reference to an exemplary embodiment(s), it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from the essential scope thereof. Therefore, it is intended that the invention not be limited to the particular embodiment(s) disclosed, but that the invention will include all embodiments falling within the scope of the appended claims.
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