The disclosure relates generally to gas turbine engines and, more particularly, to a retaining assembly between rotating components in a gas turbine engine that includes an anti-rotation feature.
Retaining assemblies, including for instance threaded fasteners that are locked in place by key washers and retaining rings, are often employed in gas turbine engines to interconnect two rotating components. For instance, a fastener such as a nut is used to axially fasten the two components together while a key washer and retaining ring ensure the fastener remains in place and cannot rotate relative to the component(s) with which is it threadedly engaged. Key washers may provide both radial and axial retention forces for the retaining ring relative to a general rotational axis of the rotating components. To provide both such retention forces, the key washer requires adequate spacing within the gas turbine engine for its retention features. Modern gas turbine engines are typically quite compact, leading to tight spacing for the various components within. In addition, the retention features of a typical key washer often include overhanging parts, which may be subjected to high radial loads in gas turbine engines rotating at high operational speeds, for instance at or over 30,000 RPM.
In one aspect, there is provided a retention assembly for interconnecting rotating components in a gas turbine engine, comprising: a first rotating component defining a central rotation axis; a second rotating component rotatable about the central rotation axis, the second rotating component including an engagement portion defining protrusions circumferentially spaced apart and extending axially from the second rotating component; a threaded fastener axially retaining the second rotating component to the first rotating component, the threaded fastener having key-receiving slots circumferentially spaced apart and extending radially into an outer circumferential surface of the threaded fastener, and a groove extending circumferentially about the threaded fastener within the outer circumferential surface; a key washer mounted to the threaded fastener, the key washer being annular and defining a first axial surface and a second axial surface axially spaced apart from each other, the key washer having a first set of keys circumferentially spaced apart and extending radially inwardly from a radially inner surface of the key washer adjacent the first axial surface of the key washer, the key washer having a second set of keys circumferentially spaced apart and extending from the second axial surface of the key washer, the first set of keys received within the key-receiving slots in the threaded fastener; and a retaining ring disposed within the groove in the threaded fastener, the retaining ring radially retained by the protrusions extending axially from the second rotating component, the retaining ring axially retained between the second set of keys and the second axial surface of the key washer, the retaining ring radially spaced apart from the second set of keys of the key washer to define a radial gap between the second set of keys and the retaining ring.
The retention assembly as defined above and herein may further include, in whole or in part, and in any combination, one or more of the following features.
In certain embodiments, the key-receiving slots are proximate a first axial edge of the threaded fastener and the groove is proximate a second axial edge of the threaded fastener.
In certain embodiments, the second set of keys includes first portions projecting axially from the second axial surface of the key washer and second portions projecting radially inwardly from the first portions.
In certain embodiments, the key washer includes ninety-degree bends between the first portions and the second portions of the second set of keys.
In certain embodiments, the second rotating component includes slots defined between adjacent protrusions, the second set of keys received in said slots.
In certain embodiments, the first set of keys are arranged in adjacent pairs about the radially inner surface of the key washer, with slots separating respective first set of keys in each adjacent pair.
In certain embodiments, the second rotating components includes an annular flange including the protrusions, the annular flange further including cutouts arranged about an outer circumference of the annular flange.
In certain embodiments, the cutouts are scallop-shaped.
In another aspect, there is provided a retention assembly for interconnecting rotating components in a gas turbine engine, comprising: a first rotating component defining a central rotation axis; a second rotating component rotatable about the central rotation axis, the second rotating component including an engagement portion defining protrusions circumferentially spaced apart and extending axially from the second rotating component; a threaded fastener threaded to the first rotating component and axially retaining the second rotating component and the first rotating component together; and an anti-rotation feature for the threaded fastener, including: a key washer circumscribing an outer circumferential surface of the threaded fastener, the key washer having a first set of keys and a second set of keys, the first set of keys matingly engaging with corresponding key-receiving slots defined in the threaded fastener, the second set of keys matingly engaged with corresponding slots defined in the second rotating component, the key washer thereby preventing rotation of the threaded fastener relative to the first rotating component and the second rotating component; and a retaining ring retaining the key washer in place on the threaded fastener, the retaining ring received within axially aligned grooves defined in the threaded fastener and the key washer, the retaining ring being axially secured in place by the key washer, the retaining ring being radially spaced apart from the second set of keys of the key to define a radial gap between the second set of keys and the retaining ring, the retaining ring radially secured in place by the second rotating component.
The retention assembly as defined above and herein may further include, in whole or in part, and in any combination, one or more of the following features.
In certain embodiments, the first rotating component includes an engagement portion with slots circumferentially spaced about an outer circumference thereof, and wherein the engagement portion of the second rotating component includes retention tabs extending radially inwardly, the retention tabs received in the slots of the engagement portion of the first rotating component.
In certain embodiments, the key-receiving slots are proximate a first axial edge of the threaded fastener and the groove in the threaded fastener is proximate a second axial edge of the threaded fastener.
In certain embodiments, the second set of keys includes first portions projecting axially from an axial surface of the key washer and second portions projecting radially inwardly from the first portions.
In certain embodiments, the retaining ring is axially constrained between the second portions of the second set of keys and a body of the key washer.
In certain embodiments, the radial gap is defined by a radial distance between a radially inner surface of the protrusions and a radially inner surface of the first portions of the second set of keys.
In certain embodiments, the second rotating component has an annular flange including the protrusions, the annular flange further including cutouts arranged about an outer circumference of the annular flange.
In certain embodiments, the cutouts are scallop-shaped.
In certain embodiments, at least one of the cutouts is circumferentially located between pairs of the slots receiving the second set of keys.
In certain embodiments, the engagement portion of the second rotating component further includes slots between adjacent protrusions, the second set of keys received in said slots.
In certain embodiments, the first set of keys are arranged in adjacent pairs about the radially inner surface of the key washer, with slots separating respective first set of keys in each said adjacent pair.
In certain embodiments, the first rotating component is a rotor disc of a high pressure turbine of the gas turbine engine, and the second component is a rotor disc cover plate mounted to the rotor disc by the retention assembly.
In a further aspect, there is provided a method for assembling a retention assembly in a gas turbine engine, comprising: mounting a rotor disc cover plate to a rotor disc; positioning a retaining ring within a groove of a nut; mounting the nut to the rotor disc; torqueing the nut to fasten the rotor disc cover plate to the rotor disc; mounting a key washer over the nut; positioning a first set of keys of the key washer within a plurality of key-receiving slots in the nut; positioning a second set of keys of the key washer within a plurality of slots in the rotor disc cover plate; axially retaining the retaining ring relative to a central longitudinal axis of the gas turbine engine via the second set of keys; and radially retaining the retaining ring relative to the central longitudinal axis of the gas turbine engine via protrusions protruding from the rotor disc cover plate.
Reference is now made to the accompanying figures in which:
Referring to
The rotor assembly 22 includes a rotor disc 24 mounted around a drive shaft 20 (shown in
According to one or more embodiments, the rotor assembly 22 includes a plurality of circumferentially-disposed and radially extending blades 40 mounted in corresponding blade-receiving slots 42 provided in the outer periphery portion 38 for receiving roots of the blades 40. The number of blades 40 may vary, for instance based on the type of rotor assembly 22 or the type of engine 10. The slots 42 are designed to prevent the blades 40 from being ejected radially during rotation. Other components (not shown), such as fixing rivets, spring plates, etc., may be provided in the rotor assembly 22, depending on the design. In other cases, blades 40 that are made integral with the rotor, i.e. forming a monolithic assembly, may be contemplated as well.
In the depicted embodiment, the rotor disc cover plate 36 includes an inlet 44 (
As will be discussed in further detail below, the retention assembly 50 is operable to retain the rotor disc cover plate 36 to the rotor disc 24 while respecting the limited spacing provided within this section of the gas turbine engine 10, for instance due to the adjacent carbon seal runner 48. In addition, the retention assembly 50 may be operable to accommodate high rotational speeds of the rotating rotor disc 24, for instance speeds of 50,000 RPM or higher. While the shown retention assembly 50 is operable to retain the rotor disc cover plate 36 to the rotor disc 24 of the rotor assembly 22, it is understood that this is an exemplary embodiment. The retention assembly 50 according to the present disclosure may be used to retain various other rotating components within the gas turbine engine 10, for instance where spacing is limited and/or in cases where rotational speeds reach or exceed high values such as 30,000 RPM or more. As such, the retention assembly 50 as per the present disclosure may be used to interconnect a first rotating component (illustratively the rotor disc 24) with a second rotating component (illustratively the rotor disc cover plate 36) disposed about a central rotation axis (illustratively the central longitudinal axis 11 of the gas turbine engine 10). It is understood that other rotating components within the gas turbine engine rotating about other central rotational axes may benefit from the herein described retention assembly 50 as well.
Referring to
Referring additionally to
Referring additionally to
The cover plate engagement portion 70 further includes an annular flange 73 disposed about the outer circumference of the cover plate engagement portion 70. The annular flange 73 includes a plurality of protrusions 74 spaced apart an outer circumference of the annular flange 73 and protruding or extending axially from an axial surface of the annular flange 73 relative to the longitudinal axis 11. In the depicted embodiment, adjacent pairs of protrusions 74 define cover plate slots 75 therebetween. As will be discussed in further detail below, once the retention assembly 50 is assembled, the cover plate slots 75 are operable to engage with elements of the key washer 90 to prevent rotation of the various components. The size and shape of the cover plate slots 75 may vary, for instance based on the geometry of the corresponding elements of the key washer 90. In the depicted embodiment, between said adjacent pairs of protrusions 74 are defined scalloped cutouts 76, for instance to reduce stresses within the rotor disc cover plate 36 and/or to provide access to the retaining ring 100 once the retention assembly 50 is assembled. Other cutout shapes may be contemplated as well. As will be discussed in further detail below, once the retention assembly 50 is assembled, the protrusions 74 are operable to engage with the retaining ring 100 to retain the retaining ring 100 in place in a radial direction relative to the longitudinal axis 11. Other numbers, sizes, geometries and positions of the various retention tabs 72, protrusions 74, cover plate slots 75 and scalloped cutouts 76 may be contemplated as well.
Referring additionally to
The shown nut 80 further incudes a plurality of key-receiving slots 86 circumferentially spaced apart about the radially outer surface 82 of the nut 80 towards the first axial edge 83 of the nut 80. As will be discussed in further detail below, upon assembly of the retention assembly 50 with the nut 80 suitably fastened, the key-receiving slots 86 are engageable with elements of the key washer 90 to prevent rotation, i.e. unfastening, of the nut 80. As such, the key-receiving slots 86 in the nut 80 are open towards the first axial edge 83 to facilitate such engagement. The number, size, position and shape of the key-receiving slots 86 may vary, for instance based on the geometry of the key washer 90. The nut 80 further incudes a groove 87 extending circumferentially about the outer circumferential surface 82 of the nut 80 towards the second axial edge of the nut 80. As will be discussed in further detail below, upon assembly of the retention assembly 50, the retaining ring 100 is insertable in the groove 87 of the nut 80. The size, position and shape of the groove 87 may vary, for instance based on the geometry of the retaining ring 100.
Referring additionally to
The key washer 90 further includes a plurality of second set of keys 97 circumferentially spaced apart and extending axially from the second axial surface 94 of the key washer 90. In the depicted embodiment, the second set of keys 97, also referred to as ‘lugs’, are hook-shaped, i.e. they include a first portion 97a projecting axially from second axial surface 94 relative to the longitudinal axis 11 and a second portion 97b projecting radially inwardly from the first portion 97a relative to the longitudinal axis 11. In the depicted embodiment, each of the second set of keys 97 includes a ninety-degree bend 97c between the first portion 97a and second portion 97b. Other angles between the first portions 97a and second portions 97b or types or joining members may be contemplated as well, for instance curved joining members. As will be discussed in further detail below, when the retention assembly 50 is in an assembled configuration, the key washer 90 is operable to retain or support the retaining ring 100 in an axial direction relative to the longitudinal axis 11. As shown in
Referring additionally to
After the retaining ring 100 is installed into the groove 87, it may rise or pop radially outwardly from the groove 87 relative to the longitudinal axis 11, as shown in
In an exemplary assembly procedure of the illustrated retention assembly 50, the rotor disc cover plate 36 is first mounted to the rotor disc 24. The opening 71 of the rotor disc cover plate 36 is aligned with the longitudinal axis 11 and the rotor disc cover plate 36 is slid over the hub portion 26 until the cover plate engagement portion 70 is aligned with the rotor disc engagement portion 60. The rotor disc cover plate 36 may be rotated until the retention tabs 72 are aligned with and are received within corresponding cover plate-receiving slots 62. Then, the retaining ring 100 may be positioned in the groove 87 of the nut 80, for instance via pliers (not shown) engaging the notches 103 to widen the gap 104. Then, the nut 80 is positioned on the rotor disc 24 with the second set of threads 85 engaging with the first set of threads 64. The nut 80 is torqued, thus locking or retaining the rotor disc cover plate 36 to the rotor disc 24. The key washer 90 is then slipped over the nut 80 and positioned so that the first set of keys 95 engage with the key-receiving slots 86 in the nut 80 to lock the nut 80, i.e. to prevent the nut 80 from unwinding. The pliers may be used to narrow or collapse the gap 104 at this stage, causing the retaining ring 100 to sit deeper within the groove 87 so that the key washer 90 can slide over the retaining ring 100. The retaining ring 100 may then pop or rise radially outwardly relatively (relative to the longitudinal axis 11) in the groove 87 and abut against the protrusions 74, the protrusions 74 thus radially retaining the retaining ring 100. The key washer is concurrently positioned so that the second set of keys 97 are disposed in the cover plate slots 75. As shown in
As shown in
The embodiments described in this document provide non-limiting examples of possible implementations of the present technology. Upon review of the present disclosure, a person of ordinary skill in the art will recognize that changes may be made to the embodiments described herein without departing from the scope of the present technology. Yet further modifications could be implemented by a person of ordinary skill in the art in view of the present disclosure, which modifications would be within the scope of the present technology.
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