Dynamic Stability and Mid Axial Preload Control for a Tie Shaft Coupled Axial High Pressure Rotor

Abstract

A middle support member is used to provide axial support and control to the tie shaft. The middle support member includes a high pressure compressor coupling nut that applies a preload that allows the high pressure compressor stack to be installed separately from the high pressure turbine rotor through a kickstand.

Description

BACKGROUND

This application relates to a method of assembling a gas turbine engine, wherein both a compressor rotors and the turbine rotors are assembled using a tie shaft connection.

Gas turbine engines are known, and typically include a compressor, which compresses air and delivers it downstream into a combustion section. The air is mixed with fuel in the combustion section and combusted. Products of this combustion pass downstream over turbine rotors, driving the turbine rotors to rotate.

Typically, the compressor section is provided with a plurality of rotor serial stages, or rotor sections. Traditionally, these stages were joined sequentially one to another into an inseparable assembly by welding or separable assembly by bolting using bolt flanges, or other structure to receive the attachment bolts.

More recently, it has been proposed to eliminate the welded or bolted joints with a single coupling which applies an axial force through the compressor rotors stack to hold them together and create the friction necessary to transmit torque.

SUMMARY

A gas turbine engine has a compressor section carrying a plurality of compressor rotors and a turbine section carrying a plurality of turbine rotors. The compressor rotors and the turbine rotors are constrained to rotate together with a tie shaft. An upstream hub provides an upstream abutment face for the compressor rotors stack. A downstream hub bounds the upstream end of the compressor rotor and abuts the compressor rotor stack against the upstream hub.

The downstream hub creates a middle support used to provide radial support for a high pressure rotor and control to the tie shaft preload. The middle support also includes a high pressure compressor coupling nut that applies a preload that allows the high pressure compressor stack to be installed separately from the high pressure turbine rotor. The middle support is essential to control the dynamic stability of the long high pressure rotor spanning the distance between its forward and aft supports. The aft support includes a multiple layer interference fit between the shaft and the most downstream turbine rotor. The multi-layer fit accomplishes simultaneously radial support for the rotors stack and dynamic stability for the high pressure spool

These and other features of the present invention can be best understood from the following specification and drawings, the following of which is a brief description.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a partial sectional perspective view of a turbine engine according to the claims;

FIG. 2 is an enlarged view of the engine with the middle support member; and

FIG. 3 is an enlarged view of the HP Rotor AFT end support member according to the claims.

DESCRIPTION

FIG. 1 illustrates a turbofan gas turbine engine 10 of a type preferably provided for use in subsonic flight, generally including a fan 12 through which ambient air is propelled, a multistage compressor 14 for pressurizing the air, a combustor 16 in which the compressed air is mixed with fuel and ignited for generating an annular stream of hot combustion gases, and a turbine section 18 for extracting energy from the combustion gases. In the illustrated arrangement, by-pass air flows longitudinally around the engine core through a by-pass duct 20 provided within the nacelle. The compressor 14 and turbine 18 may be connected in a variety of ways, such as through a shaft, through one or more tie shafts, through a transmission, etc.

Referring to FIG. 2, a long span between supporting bearings 350 and 330 creates rotor dynamic problems for bearing preload and rotor stability. Bearings apart from being mounted on the shafts and housings have to be preloaded properly for their proper functioning. Preloading is the methodology by which the internal clearance in the bearing is removed by applying a permanent thrust load to it. In other terms, the bearing is pushed to such an extent that it has to move only in the groove (raceway) and cannot move axially in either direction. Preloading may be needed for several reasons such as to eliminate the radial and axial play in the bearing which would be inherently present even after a bearing is mounted radially on a shaft, eliminate all the unnecessary clearances, which may induce a rigidity to the bearings and thus to the system the bearing supports and by reducing the clearances, the rotational accuracy of the bearing may be controlled. Thus, it helps to reduce the non-repetitive run out that could occur because of the clearances.

To address these requirements, it may be necessary to provide a support #3 between supports #1 and #2, and for the rotors 313324 to retain a tight radial fit with the tie shaft 322 at support locations throughout the mission envelope. Axial preload in the compressor and turbine rotor stacks 313 and 324 may be required to generate the friction between adjoining rotor faces for torque transmission. The downstream hub 341 acts as a middle support member to address these requirements. The middle support member 341 may allow the compressor stack 313 to be assembled separately with a temporary preload applied by the HPC coupling nut 332. It may be necessary for the coupling nut 332 axial interface to retain a minimum axial preload throughout the mission envelope to satisfy dynamic stability requirements and prevent an axially loose nut from whirling.

FIG. 2 schematically illustrates a gas turbine engine 10 incorporating a combustion section 311, shown schematically, a compressor section 313 having a plurality of compressor rotors 338, and a turbine section 324 having a plurality of turbine rotors 325. As shown, an upstream hub 334 may be threadably secured to the tie shaft 322 at the upstream side of the compressor section 313. A downstream hub/middle support member 341 may be positioned at a downstream side of the compressor stack 313, and contacting a downstream-most compressor rotor 315. The stack of compressor rotors 313 may be sandwiched between the downstream hub 341 and upstream hub 334, and secured by a HPC lock nut 332. The downstream hub/middle support member 341 may abut the stack of turbine rotors 324 that are secured with the high pressure turbine (HPT) lock nut 327 (FIG. 3). Lock Nut 401 may bias a plurality of seals and bearings against the turbine rotors. The two lock nuts 327 and 401 may be threadably engaged to the same tie shaft 322. The high pressure turbine coupling nut 327 applies the primary preload to HPC stack 313 and HPT stack 324. As shown in FIG. 3, the nut 327 may be threadably received on threads 458 on the tie shaft 322. FIG. 3 illustrates the nuts 401 and 327 threadably engaged to tie shaft 322. Initially, the upstream hub 334 (FIG. 2) may be threadably assembled to the tie shaft 322 while the compressor rotors 338 and 315 and downstream hub/middle support member 341 may be stacked together using lock nut 332 to secure all of them by applying a axial preload force holding the rotors against the kickstand 343 of the upstream hub 334. An internal compression load may be created in the rotors stack to react the tension load in the tie shaft 322.

The kickstand 343 of the downstream hub/middle support member 341 is designed as a soft spring to enable the secondary load path from the HPC Coupling Nut 332 through the kickstand 343, downstream hub/middle support member 341 and compressor rotors stack 313. The secondary load path may prevent rolling and may ensure self alignment with the mating face of the HPC coupling nut 332. The kickstand 343 of the arrangement may also generate radial and axial reactions at the downstream hub/middle support member 341 interface with the last compressor rotor 315. The secondary load path applies a preload that is mostly temporary as it decreases significantly after the HPT Nut 327 is tightened—the residual secondary preload may also create loaded contact between the kickstand 343 of the downstream hub/middle support member 341 and the HPC coupling nut 332 even for conditions when the HPC coupling nut tends to separate.

For the HP Rotor downstream end, the radial preload may be realized through a multi-layered fit arrangement (Fits A 420, B 430 and C 440 in FIG. 3) between bearing 330, intermediary sleeve 465, HPT rotor arm 467 and the tie shaft 322.

The turbine rotors 325 may be axially preloaded using lock nut 327 to secure the new assembly by applying an axial preload force holding the compressor 313 and turbine rotors 324 together and ensuring the necessary friction to transmit torque. As soon as the HPT Nut 327 is tightened, the primary load path is transferred from the kickstand 343 to the cylindrical portion of the downstream hub/middle support member 341 and HPT stack 324 with internal compression load in the compressor rotors stack and 313 and turbine rotors stack 324, and tension load in the downstream end of the tie shaft 322.

The three fit 420430440 arrangement may ensure that the compressor and turbine sections are reliably held together, will be capable to resist the forces to be encountered during use, transmit the necessary torque and satisfy dynamic stability requirements. All these functions may be accomplished within a minimal radial envelope and with a low-profile locking ring 458

As a result of the arrangement, axial preload may be achieved with a single fastener (tie shaft) 322. The preload may be distributed between the primary path (backbone) and the secondary path (kickstand 343) in a balanced manner such that there is a minimum loss in clamping capability while the dynamic stability is maintained for a long-span, high speed rotor (>20,000 RPM). The multi-layer snap illustrated in FIG. 4 accomplishes simultaneously radial support for the rotors stack, dynamic stability for the high pressure spool and a leak-proof joint for the secondary air system.

Although embodiments of this invention have been disclosed, a worker of ordinary skill in this art would recognize that certain modifications would come within the scope of this invention. For that reason, the following claims should be studied to determine the true scope and content of this invention. In accordance with the provisions of the patent statutes and jurisprudence, exemplary configurations described above are considered to represent a preferred embodiment of the invention. However, it should be noted that the invention can be practiced otherwise than as specifically illustrated and described without departing from its spirit or scope.

Claims

1. A high pressure spool of a turbine engine comprising: a first hub on a first end of a tie shaft;a second hub on a second end of the tie shaft; anda middle support member between the FWD and AFT ends of the HP Rotor wherein the middle support member further comprises:a high pressure compressor coupling nut which couples a kickstand in communication with the HPC stack to the tie shaft; andAn AFT support comprising: a high pressure turbine coupling nut;a lock ring; anda multiple layer interference fit between the shaft, the high pressure turbine disk and a bearing stack.

2. The high pressure spool of a turbine engine of claim 1 wherein the kickstand of the middle support member provides a support between the FWD and AFT ends of the HP Rotor and accepts a secondary load.

3. The high pressure spool of a turbine engine of claim 1, wherein the kickstand of the middle support member provides positive axial and radial reactions in the middle support member.

4. The high pressure spool of a turbine engine of claim 1, wherein the high pressure compressor coupling nut applies a preload to the compressor rotors stack.

5. The high pressure spool of a turbine engine of claim 4, wherein the high pressure compressor nut allows the high pressure compressor stack to be installed separately from the high pressure turbine rotor.

6. The high pressure spool of a turbine engine of claim 1, wherein the turbine end of the tie shaft comprises a turbine coupling nut that applies a preload to the compressor and turbine rotors stacks.

7. The high pressure spool of a turbine engine of claim 1, further comprising a multi-layered fit arrangement for the HP Rotor AFT end which creates a radial preload.

8. The high pressure spool of a turbine engine of claim 7, wherein the HP coupling nut is secured against unlocking by using the locking ring wherein the locking ring is a low-profile locking ring which provides a minimal radial envelope.

9. A turbine engine with a tie shaft and a HP rotor comprising: a fan rotatable about an axis, the fan including a plurality of radially-extending fan bladesa combustor which exhaust high speed air into a turbine,the turbine comprising a HP rotor wherein the rotor is rotatable about an axis,an upstream hub on a first end of a tie shaft; anda middle HP rotor support member between the FWD and AFT ends of the HP Rotor wherein the middle support member further comprises: a high pressure compressor coupling nut which couples a kickstand in communication with the HPC stack to the tie shaft; andAn AFT HP rotor support comprising: a high pressure turbine coupling nut;a low profile lock ring; anda multiple layer interference fit between the shaft, the high pressure turbine disk and a bearing stack.

10. The turbine engine of claim 9, wherein the kickstand of the middle support member provides a support between the FWD and AFT ends of the HP Rotor and accepts a secondary load.

11. The turbine engine of claim 9, wherein the kickstand of the middle support member provides positive axial and radial reactions in the middle support member.

12. The turbine engine of claim 9, wherein the high pressure compressor coupling nut applies a preload to the compressor rotors stack.

13. The turbine engine of claim 12, wherein the high pressure compressor nut allows the high pressure compressor stack to be installed separately from the high pressure turbine rotor.

14. The turbine engine of claim 9, wherein the turbine end of the tie shaft comprises a turbine coupling nut that applies a preload to the compressor and turbine rotors stack.

15. The turbine engine of claim 14, further comprising a multi-layered fit arrangement for the HP Rotor AFT end which creates a radial preload.