The present disclosure relates generally to gas turbine engines, and more specifically to gas turbine engines that include tie bolts.
Gas turbine engines are used to power aircraft, watercraft, power generators, and the like. Gas turbine engines typically include a compressor, a combustor, and a turbine. The compressor compresses air drawn into the engine and delivers high pressure air to the combustor. In the combustor, fuel is mixed with the high pressure air and is ignited. Products of the combustion reaction in the combustor are directed into the turbine where work is extracted to drive the compressor and, sometimes, an output shaft. Left-over products of the combustion are exhausted out of the turbine and may provide thrust in some applications.
Compressors and turbines typically include alternating stages of static vane assemblies and rotating wheel assemblies. The rotating wheel assemblies include disks carrying blades around their outer edges. When the rotating wheel assemblies turn, tips of the blades move along blade tracks included in static shrouds that are arranged around the rotating wheel assemblies. Such static shrouds may be coupled with an engine case that surrounds the compressor, the combustor, and the turbine. In some engines, a tie bolt extends along an axis of the engine and applies a compressive force to the compressor and the turbine to locate them relative to each other.
The present disclosure may comprise one or more of the following features and combinations thereof.
A gas turbine engine includes an engine core, a tie bolt, and a fail-safe system. The engine core may include a compressor stage, a turbine stage, and a shaft. The compressor stage and the turbine stage are adapted to rotate about an axis. The shaft rotatably couples the compressor stage to the turbine stage to transmit torque from the turbine stage through the shaft to the compressor stage to drive the compressor stage during operation of the gas turbine engine. The tie bolt extends axially along the axis and locates axially the compressor stage relative to the turbine stage. The fail-safe system is configured to provide backup torque-transfer means for transmitting the torque from the turbine stage to the compressor stage through the tie bolt in response to a shaft disconnect event in which the shaft fails to transmit the torque from the turbine stage to the compressor stage during operation of the gas turbine engine so that the turbine stage is blocked from rotating about the axis faster than the compressor stage during the shaft disconnect event.
In some embodiments, the fail-safe system includes a fore-torque interface and an aft-torque interface. The fore-torque interface is configured to transmit the torque from the tie bolt to the compressor stage in response to the shaft disconnect event. The aft-torque interface is configured to transmit the torque from the turbine stage to the tie bolt in response to the shaft disconnect event.
In some embodiments, the fore-torque interface includes a lug slot formed in one of the tie bolt and the compressor stage and a fore-drive lug coupled to the other of the tie bolt and the compressor stage. The fore-drive lug may be located in the lug slot to rotatably couple the compressor stage to the tie bolt.
In some embodiments, the aft-torque interface includes an aft-drive lug and a coupler ring. The aft-drive lug may be rotatably coupled to the turbine stage. The coupler ring may be rotatably coupled to the tie bolt and the coupler ring is formed to include a driven lug. The aft-drive lug may be configured to transmit at least a portion of the torque to the driven lug in response to the shaft disconnect event so that the torque is transmitted from the turbine stage through the coupler ring and to the tie bolt during the shaft disconnect event.
In some embodiments, the aft-drive lug extends axially away from the turbine stage toward the coupler ring. The driven lug may extend axially away from the coupler ring toward the aft-drive lug. The driven lug may be circumferentially aligned with the aft-drive lug.
In some embodiments, the compressor stage includes a hub arranged around the axis and a plurality of airfoils that extend radially away from the hub. The lug slot may be formed in the hub of the compressor stage and the fore-drive lug may be coupled to the tie bolt and located in the lug slot.
In some embodiments, the fail-safe system includes a pin. The pin may extend at least partway into the compressor stage and at least partway into the tie bolt to rotatably couple the compressor stage to the tie bolt.
In some embodiments, the fail-safe system includes an aft-torque interface that includes an aft-drive lug and a coupler ring. The aft-drive lug may be rotatably coupled to the turbine stage. The coupler ring may be rotatably coupled to the tie bolt. The coupler ring may be formed to include a driven lug and the driven lug is aligned circumferentially with the aft-drive lug.
According to another aspect of the present disclosure, a gas turbine engine includes an engine core, a tie bolt, and a fail-safe system. The engine core includes a compressor stage adapted to rotate about an axis, a turbine stage adapted to rotate about the axis, and a shaft that rotatably couples the compressor stage with the turbine stage for rotation with the turbine stage. The tie bolt locates the compressor stage axially relative to the turbine stage. The fail-safe system is configured to rotatably couple the compressor stage and the turbine stage to the tie bolt in response to a shaft disconnect event.
In some embodiments, the fail-safe system includes a fore-torque interface that includes a lug slot and a fore-drive lug. The lug slot may be formed in one of the tie bolt and the compressor stage. The fore-drive lug may be coupled to the other of the tie bolt and the compressor stage. The fore-drive lug may be located in the lug slot to rotatably couple the compressor stage to the tie bolt.
In some embodiments, the compressor stage includes a hub arranged around the axis and a plurality of airfoils that extend radially away from the hub. The lug slot may be formed in the hub of the compressor stage. The fore-drive lug may be coupled to the tie bolt and located in the lug slot.
In some embodiments, the fail-safe system includes an aft-torque interface that includes an aft-drive lug and a coupler ring. The aft-drive lug may be rotatably coupled to the turbine stage. The coupler ring may be rotatably coupled to the tie bolt and the coupler ring is formed to include a driven lug. The driven lug may be aligned circumferentially with the aft-drive lug.
In some embodiments, the aft-drive lug extends axially away from the turbine stage toward the coupler ring. The driven lug may extend axially away from the coupler ring toward the aft-drive lug. The driven lug may be circumferentially aligned with the aft-drive lug.
In some embodiments, the fail-safe system includes an aft-torque interface. The aft-torque interface may rotatably couple the turbine stage to the tie bolt in response to the shaft disconnect event.
In some embodiments, the fail-safe system includes a fore-torque interface. The fore-torque interface may include a pin that extends at least partway into the compressor stage and at least partway into the tie bolt to rotatably couple the compressor stage to the tie bolt.
In some embodiments, the fail-safe system includes an aft-torque interface that includes a coupler ring and a pin. The coupler ring may be configured to rotatably couple to the turbine stage. The pin may extend at least partway into the coupler ring and at least partway into the tie bolt to rotatably couple the coupler ring to the tie bolt.
According to another aspect of the present disclosure, a method may include a number of steps. The method may include applying a compressive force to a compressor stage and a turbine stage with a tie bolt, rotating the turbine stage about an axis, transmitting torque from the turbine stage through a shaft to the compressor stage to rotate the compressor stage about the axis, and transmitting the torque from the turbine stage through the tie bolt to the compressor stage to rotate the compressor stage about the axis in response to a shaft disconnect event in which the shaft no longer transmits the torque from the turbine stage to the compressor stage while the turbine stage is rotating.
In some embodiments, transmitting the torque from the turbine stage through the shaft to the compressor stage to rotate the compressor stage about the axis is performed without transmitting the torque from the turbine stage through the tie bolt to the compressor stage. In some embodiments, the method may include rotating the turbine stage relative to the tie bolt until the turbine stage is rotatably coupled to the tie bolt in response to the shaft disconnect event. In some embodiments, the method may include rotating the turbine stage at the same speed as the compressor stage during the shaft disconnect event.
These and other features of the present disclosure will become more apparent from the following description of the illustrative embodiments.
For the purposes of promoting an understanding of the principles of the disclosure, reference will now be made to a number of illustrative embodiments illustrated in the drawings and specific language will be used to describe the same.
A gas turbine engine 10 in accordance with the present disclosure is shown in
The engine core 12 includes the compressor 18, a combustor 20, the turbine 22, and the shaft 24 as shown in
The tie bolt 14 applies an axial compressive load to the compressor 18, the turbine 22, and the shaft 24 to couple together those components as suggested in
The fail-safe system 16 is configured to provide backup torque-transfer means for transmitting the torque from the turbine 22 to the compressor 18 through the tie bolt 14 in response to a shaft disconnect event in which the shaft 24 fails to transmit the torque from the turbine 22 to the compressor 18 during operation of the gas turbine engine 10 so that the turbine 22 is blocked from rotating faster than the compressor 18 during the shaft disconnect event. A shaft disconnect event may be detected, for example, by changes in vibration of the shaft 24 and engine core 12. The engine core 12 may be shut down in response to the shaft disconnect event and the fail-safe system 16 transmits the torque during the shut down.
The illustrative compressor 18 includes a plurality of compressor stages 26A, 26B, 26C, 26D, 26E that are rotatably coupled together as shown in
Each compressor stage 26A-26E includes features for rotatably coupling adjacent stages so that the torque is transmitted between the compressor stages 26A-26E through the features during operation of the gas turbine engine 10. In the illustrative embodiment, the fore and aft faces of the compressor stages 26A-26E are splined and interlock with adjacent stages 26A-26E to form joints. The tie bolt 14 applies a compressive force to the compressor stages 26A-26E to maintain engagement of the interlocked joints between compressor stages 26A-26E. In other embodiments, the compressor stages 26A-26E may be bolted, pinned, fastened, meshed with teeth or tabs, or coupled for rotation to another compressor stage 26A-26E by any other suitable alternative means.
The turbine 22 includes a plurality of turbine stages 28A, 28B as shown in
Each turbine stage 28A, 28B includes features for rotatably coupling adjacent stages so that the torque is transmitted between the turbine stages 28A, 28B through the features during operation of the gas turbine engine 10. In the illustrative embodiment, the fore and aft faces of the turbine stages 28A, 28B are splined and interlock with each other to form joints. The tie bolt 14 applies a compressive force to the turbine stages 28A, 28B to maintain engagement of the interlocked joints between the turbine stages 28A, 28B. In other embodiments, the turbine stages 28A, 28B may be bolted, pinned, fastened, meshed with teeth or tabs, or coupled for rotation to each other by any other suitable alternative means.
The shaft 24 rotatably couples the turbine stage 28A with the compressor stage 26E to rotatably couple the turbine 22 with the compressor 18 as shown in
The shaft 24 may directly couple the turbine 22 to the compressor 18 as shown in
The tie bolt 14 is coupled with the compressor stage 26A and the turbine stage 28B as shown in
The compressive force applied to the compressor stages 26A-26E and the turbine stages 28A, 28B by the tie bolt 14 is not sufficient to generate a friction force that would allow the torque to be transmitted from the turbine stage 28B to the compressor stage 26A through the tie bolt 14. That is, without the fail-safe system 16, the turbine stage 28A and/or the compressor stage 26A would slip relative to the tie bolt 14 if attempting to transmit the torque through the friction connection of the tie bolt 14.
The fail-safe system 16 is configured to provide backup torque-transfer means for transmitting the torque from the turbine stage 28B to the compressor stage 26A through the tie bolt 14 in response to a shaft disconnect event in which the shaft 24 fails to transmit the torque from the turbine stage 28B to the compressor stage 26A during operation of the gas turbine engine 10 so that the turbine stage 28B is blocked from rotating about the axis 11 faster than the compressor stage 26A during the shaft disconnect event. The fail-safe system 16 is configured to transmit the torque via an alternative path 34. The alternative path 34 includes transmitting the torque from the first turbine stage 28A to the second turbine stage 28B, from the second turbine stage 28B to the tie bolt 14 via a coupler ring 58, and from the tie bolt 14 to the compressor stage 26A as shown in
The fail-safe system 16 includes a fore-torque interface 44 and an aft-torque interface 46 as shown in
The fore-torque interface 44 includes fore-drive lugs 48 coupled to the tie bolt 14 and lug slots 50 formed in the compressor stage 26A as shown in the exploded view of
The fore-drive lugs 48 transmit the torque from the tie bolt 14 to the compressor hub 36 during a shaft disconnect event as suggested in
The fore-drive lugs 48 include a plurality of lugs 48 as shown in
In other embodiments, the fore-torque interface 44 rotatably couples the tie bolt 14 to the compressor stage 26A via other suitable means such as, for example, lugs formed on the compressor stage 26A and pins that are located in the compressor stage 26A and tie bolt 14 as shown in
The aft-torque interface 46 includes aft-drive lugs 56 coupled to the turbine stage 28B, the coupler ring 58, and slots 60 formed in the tie bolt 14 as shown in
The turbine stage 28B includes a turbine hub 62 and a plurality of turbine blades 64 that extend radially away from the turbine hub 62 as shown in
The coupler ring 58 includes an annular body 68 arranged around the axis 11, driven lugs 70 that extend axially away from the annular body 68 and toward the turbine stage 28B, and ribs 72 that extend radially away from the annular body 68 and interlock with the tie bolt 14 as shown in
Each driven lug 70 is spaced apart circumferentially from a neighboring driven lug 70 as shown in
The aft-drive lugs 56 and the driven lugs 70 are shown as being spaced apart circumferentially during normal operation as shown in
The rib slots 60 are formed in the tie bolt 14 as shown in
In other embodiments, the aft-torque interface 46 rotatably couples the tie bolt 14 to the turbine stage 28B via other suitable means such as, for example, lugs or ribs coupled to one of the turbine stage 28B and the tie bolt 14 and slots or lugs formed in the other of the turbine stage 28B and the tie bolt 14 or pins that are located in the turbine stage 28B or coupler ring 58 and the tie bolt 14 as shown in
During normal operation, the tie bolt 14 applies the compressive force to the compressor 18 and the turbine 22 as suggested in
In response to a shaft disconnect event, the torque is transmitted from the turbine 22 to the compressor 18 via the alternative path 34 as suggested in
The present disclosure relates to the mechanical features and arrangement that allow power from the turbine 22 to be conveyed to the compressor 18 of the gas turbine engine 10 via an alternate torque path in the event of failure of the primary path 32 as suggested in
The rotor arrangement and the torque path from the turbine 22 to the compressor 18 under typical circumstances are shown in
The alternate torque path 34 is configured to prevent the unloading and subsequent potential overspeed burst of the turbine 22 in the event of a shaft disconnect. A shaft break which uncouples the turbine 22 from the compressor 18, but do not dislocate the turbine rotors 28A, 28B (i.e., rotating to static clashing may not occur between the turbine rotors and static components such as turbine vanes) may result in turbine overspeed. Acceleration of the uncoupled, free-spinning turbine 22 may be too great for an overspeed control system to mitigate. The present disclosure is configured to prevent this from happening.
One embodiment of the mechanical features that create the alternate torque path 34 is shown in
Rotatably coupled components are mechanically connected to rotate with one another at the same rotational speed about the axis 11. The components may be directly rotatably coupled with one another or intermediate components may interconnect the components for rotation with one another. The mechanical connection between components may include tabs, slots, grooves, splines, ribs, pins, fasteners, a bond layer, integrally formed components, or any other suitable alternative connection.
While the disclosure has been illustrated and described in detail in the foregoing drawings and description, the same is to be considered as exemplary and not restrictive in character, it being understood that only illustrative embodiments thereof have been shown and described and that all changes and modifications that come within the spirit of the disclosure are desired to be protected.