The present disclosure relates to rotor disks, and more particularly, to rotor disk bosses.
Gas turbine engines typically include a compressor section, a combustor section, and a turbine section, disposed about an axial centerline and arranged in flow series with an upstream inlet at the combustor section and a downstream exhaust at the turbine section. The compressor section typically includes stacked rotors across and between which air flows as it is compressed.
Compressor sections may also include various inter-disk devices or features attached interstitially between stacked rotor disks. Inter-disk devices or features may become detached from a rotor disk during operation of the engine. Such detachment may impede the proper functioning of the gas turbine engine, may cause damage to an adjacent rotor disk, and may decrease the cycle life of rotor disks.
The present disclosure provides devices related to rotor disk bosses. A rotor disk assembly comprises a first rotor disk, wherein the first rotor disk comprises a web, disposed between a rim and a bore. The rotor disk assembly further comprises a second rotor disk operatively coupled to the first rotor disk, an inter-disk device disposed on the second rotor disk and extending axially toward the first rotor disk, and a boss disposed on the first rotor disk, wherein the boss protrudes axially from the web toward the inter-disk device.
A rotor disk assembly comprises a first rotor disk operatively coupled to a second rotor disk, and a bore cavity defined by, and disposed between, the first rotor disk and the second rotor disk. The second rotor disk comprises a spacer arm disposed in the bore cavity and extending axially toward the first rotor disk. The first rotor disk comprises a boss disposed in the bore cavity and protruding axially from the first rotor disk toward the second rotor disk, whereby the boss forms a buffer between the spacer arm and the first rotor disk.
In various embodiments, the present disclosure provides methods for designing a rotor disk boss. Such methods may be used to determine a probable point of contact on a rotor disk in response to an inter-disk device failure, and to redesign a rotor disk to include a rotor disk boss.
The accompanying drawings are included to provide a further understanding of the present disclosure and are incorporated in, and constitute a part of, this specification, illustrate various embodiments, and together with the description, serve to explain the principles of the disclosure.
Referring to
The forward-aft positions of gas turbine engine 100 lie along axis of rotation 120. For example, fan 140 is forward of turbine section 190 and turbine section 190 is aft of fan 140. During operation of gas turbine engine 100, air flows from forward to aft, from fan 140 to turbine section 190. As air flows from fan 140 to the more aft components of gas turbine engine 100, the axis of rotation 120 defines the direction of the air stream flow.
The compressor sections 150, 160 comprise a rotor disk assembly 159 and a stator assembly 157, operatively coupled to one another to create alternating rows of rotary airfoils or blades 156 and static airfoils or vanes 158. The rotor disk assembly 159 comprises a series of stacked rotor disks operatively coupled to one another and oriented about an axis of rotation 120.
A rotor disk comprises a web disposed between a rim and a bore. The rotor disk is oriented about an axis of rotation, and the bore is disposed radially inward of the web and the rim. Because rotor disks operate at high rotational speeds and high temperatures, the web is thinner than both the rim and the bore, and connects the rim and the bore with a smooth and continuous curved surface. The rotor disk is coupled to a plurality of blades. Each blade is disposed on the rim of the rotor disk and extends radially outward therefrom.
Various inter-disk devices are attached to a rotor disk and suspended or hung in a bore cavity defined by and disposed between stacked rotor disks. For example, a plurality of air transport tubes is attached to the aft side of a forward rotor disk such that it is suspended in the bore cavity defined by the forward rotor disk and an aft rotor disk. During operation, an inter-disk device may become detached from the forward rotor disk and contact the aft rotor disk. Such contact may result in contact damage, galling, gouging, and the like, thereby decreasing the cycle life of the rotor disk.
With reference to
The first rotor disk 210 further comprises a boss 250 that engages an axially extending spacer arm 281 (discussed below) secured to the second rotor disk 260. The boss 250 is disposed between the rim 211 and the bore 212 on a forward surface of the first rotor disk 210. The boss 250 is axially closer to the spacer arm 281 than the rest of the web 213 is to the spacer arm 281. The boss 250 extends toward the spacer arm 281 in a forward axial direction from the forward surface of the first rotor disk 210. In various embodiments, the boss 250 can be generally planar and/or pitched relative to the web 213. In further embodiments, the boss 250 can comprise at least one arcuate surface.
As illustrated in
In further embodiments, the boss 250 can be disposed on the web 213 not immediately adjacent to the web foot 215. The boss 250 can protrude axially from the web 213 at the radial outer edge of the boss 250 and can connect to the web at the radial outer edge via a first arcuate filleted edge. The boss 250 can protrude axially from the web 213 at the radial inner edge of the boss 250 and can connect to the web at the radial inner edge via a second arcuate filleted edge.
The radial-direction span of the boss 250 can be limited to the area in which the spacer arm 281 can contact the web 213. Various portions of the first rotor disk 210, including without limitation, the web 213 and the web foot 215, can be sensitive to contact by the spacer arm 281. Contact between the first rotor disk 210 and the spacer arm 281 can decrease the cycle life of the first rotor disk 210. The boss 250 serves as a buffer between the spacer arm 281 the web 213, and/or between the spacer arm 281 and the web foot 215. The boss 250 can increase the thickness of a portion of the rotor disk 210. The boss 250 decreases the linear distance between the spacer arm 281 and the boss 250.
With reference to
The inter-disk device 280 can comprise a plurality of air transport tubes coupled to a rotor disk by a hoop. The air transport tubes can be disposed in the bore cavity 270 such that air flowing radially inward from the blades will be smoothly directed toward the bores. The inter-disk device 280 can comprise any device disposed at least partially between rotor disks of a rotor disk assembly, and/or any means of directing air toward the bore including, without limitation, paddles or vanes.
The inter-disk device 280 can be coupled to the second rotor disk 360 such that it is disposed in the bore cavity 270. A spacer arm 281 of an inter-disk device 280—that is, the portion of the inter-disk device 280 extending farthest in an aft direction into the bore cavity 270—is disposed adjacent to, and forward of, the boss 250. The boss 250 is disposed adjacent to, and aft of, the spacer arm 281. As already described and with reference to
Methods of designing a rotor disk are provided. Inter-disk devices or features may become detached from a rotor disk during operation of the engine. Detachment of an inter-disk device and/or spacer arm from a rotor disk constitutes a failure. Upon detachment, an inter-disk device will contact a rotor disk aft of the inter-disk device at a point of contact. The point of contact is the portion of the web contacted by the spacer arm in the event of an inter-disk device failure. The point of contact may be determined experimentally, experientially, predictively, or by any other appropriate means.
Prior to detachment, a point of contact is calculated. With reference to
With reference to
The redesigning step further comprises adding material at the point of contact to create a boss (Step 404). The adding step causes the boss to protrude from the surface of the rotor disk in an axial direction. The adding step moves the point of contact in an axial direction. In various embodiments, a method of designing a rotor disk further comprises improving the manufacturability of the rotor disk (Step 405). The improving step comprises at least one of creating a filleted transition between the boss and an adjacent web, bore or rim, decreasing the size of the boss, or decreasing the weight of the rotor disk.
No element, component, or method step in the present disclosure is intended to be dedicated to the public regardless of whether the element, component, or method step is explicitly recited in the claims. As used herein, the terms “comprises”, “comprising”, or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.
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20160208612 A1 | Jul 2016 | US |