The application relates generally to gas turbine engines and, more particularly, to a new blade/disk fixing design for protecting predetermined regions of a blade root and/or disk from low speed rotation induced wear.
Turbofan blades are typically provided with blade dovetail which are loosely mounted in complementary-shaped dovetail slots defined in the outer periphery of the rotor hub of the fan rotor. At engine operating speeds, the blades are urged firmly in position by the centrifugal force, thereby locking the blade dovetails against movement in the associated dovetail slots. However, when the fan rotates at low speeds, such as during windmilling, the centrifugal force is not sufficient to prevent the blade dovetails from moving in the dovetail slots. Windmilling may occur when wind blows through the engine of a parked aircraft causing the fan rotor to slowly rotate. Windmilling can also occur when an aircraft crew shutdown a malfunctioning or damaged engine in flight. The continued forward motion of the aircraft forces ambient air through the fan blades causing the fan rotor to rotate at low speed.
The opposing gravitational forces on the blade during such low speed rotation cause the blade to chafe against the disk due to the play at the joint between the disk and the blades. This low load high cycle event causes wear of the contacting surfaces. Such low speed rotation or windmilling induced wear can result in wear in critical stress locations and, thus, lead to premature retirement of blades and disk from service.
It is know, therefore, to provide an insert or spacer between the rotor disk and the blade root, to force the blade to its outward operating position, thus, reducing blade root movement during windmilling, and thus wear. Theses inserts are extra parts requiring extra time to make and install. They contribute to the overall complexity of the engine.
Accordingly, there is a need to provide a new and simple protection against windmilling induced wear.
In one aspect, there is provided a fan rotor assembly of a gas turbine engine, comprising a disk mounted for rotation about a centerline of the engine, an array of circumferentially distributed dovetail slots defined in an outer periphery of the disk, a corresponding array of fan blades attachable to the disk, each fan blade having a blade dovetail engageable in a corresponding one of the dovetail slots, the blade dovetail having high stress regions and low stress regions, the low stress regions having a sacrificial bumper which will wear in preference to the high stress regions of the blade dovetail, the sacrificial bumper providing for a closer tolerance fit in the dovetail slots than the high stress regions, thereby shielding the high stress regions from rubbing against the disk when the rotational speed of the turbofan assembly is too low to centrifugally lock the fan blades in position on the disk.
In a second aspect, there is provided a gas turbine engine rotor assembly comprising a rotor disk mounted for rotation about an axis and having a plurality of blade mounting slots circumferentially distributed about a periphery of the rotor disk for receiving complementary blade fixing portions of a set of blades, wherein each blade fixing portion has low stress regions and high stress regions, and wherein bumper surfaces are provided in the low stress regions away from the high stress regions so that when the rotational speed of the rotor assembly is too low to centrifugally lock the blades in position on the disk, the bumper surfaces contact the disk and shield the high stress regions from contacting the disk, thereby protecting the high stress regions of the blade fixing portions from low speed rotation induced wear.
Reference is now made to the accompanying figures, in which:
The fan 12 includes a disk 20 (
The fan 12 further includes a circumferential array of fan blades 32 attachable to the fan disk 20. The fan blades 32 are axially received in the blade mounting slots 22 of the disk 20. Each blade 32 comprises an airfoil portion 34 (
During engine operation, the centrifugal force urges the bearing surfaces 46 of the blades 32 against the lug bearing surfaces 30, thereby firmly locking the blades 32 in position on the disk 20. However, when the rotational speeds are too low to urge the flanks of the blade dovetails 44 centrifugally against the bearing surfaces 30 of the lugs 28, such as when windmilling occurs, the blade dovetails 44 repeatedly rubs against the bounding surfaces of the blade mounting slots 22. This may lead to premature wear of the blade dovetails 44 and the disk 20.
Rubbing of high stress regions of the blade dovetail 44 and of the disk 20 particularly contributes to reduce the service-life of the blades 32 and of the disk 20 and should thus be avoided. An example of a high stress region is the neck portion 48 of the blade root 42. Another example of a high stress region is the bottom corner fillet region 31 of the blade mounting slots 22. It is desirable to protect such high stress regions from rubbing during slow or windmilling rotational speeds.
With reference to
The high stress bottom fillet region 31 of the disk slots 22 may be protected against windmilling induced wear by removing material or shaping the bottom corners 50 of the blade dovetails 44 so that the bottom corners 50 be somewhat recessed or spaced farther from the slot bottom fillet regions 31 than the adjacent low stress area of the blade dovetail 44. For instance, the blade root bottom corners can be rounded or chamfered to provide a play or gap 54 and thus avoid contact with the bottom fillet regions 31 during windmilling. The blade bottom corners 50 may be designed to have a smaller radius than that of the disk bottom fillet regions 31. The mated features adjacent to the fillet 31 act as bumpers in low stress region at the bottom of the blade/slot to shield the high stress bottom corner region of the slots 22.
The above description is meant to be exemplary only, and one skilled in the art will recognize that changes may be made to the embodiments described without departing from the scope of the invention disclosed. For example, it is understood that the above described dovetail details is not limited to fan rotor assembly but could also be applied to other types of rotor assembly, including compressor and turbine rotors. The general principals of the invention are not limited to straight dovetail designs and could also be applied to curved dovetail designs as for instance disclosed in U.S. Pat. No. 6,457,942. Still other modifications which fall within the scope of the present invention will be apparent to those skilled in the art, in light of a review of this disclosure, and such modifications are intended to fall within the appended claims.
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Number | Date | Country | |
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20110293429 A1 | Dec 2011 | US |