The present invention relates to a gas turbine engine, in particular in the aviation field, and has as its object the installation of a rotor shaft inside the engine.
The operations of installing and removing a turbine engine are awkward, because of the number of parts that they comprise and the small clearances between them while the dimensions may be considerable. The cost of the working on the engine comprising such operations is therefore always high. The aim is therefore constantly to simplify them. In a front, double-bodied turbofan engine, such as the cfm56 engine, access to the bearing supporting the high pressure compressor shaft is particularly difficult because it is installed, on the intermediate casing, behind the fan and the first two bearings supporting respectively the low pressure compressor shaft and that of the fan. The intermediate casing is the portion of the casing of the machine that supports in particular the front rotor bearings. In order to avoid dismantling the whole front portion of the engine and the fan in particular, the elements of this bearing are currently arranged so as to allow installation from the rear. Such a solution is advantageous, but still has some disadvantages that it would be desirable to eliminate.
To keep the shaft 4 in the bearing 3, according to the teaching of the prior art, a nut 6 is provided that is held inside the pinion 5, upstream by a segment or retaining ring 6′. The nut comprises a thread on its outer surface by which it is screwed into the upstream end of the shaft 4, provided with an appropriate thread. A nut-lock 6″ keeps the nut in place in the shaft 4. Furthermore, the axial splines on the inner wall of the coupling of the pinion 5 interact with splines on the outer surface of the shaft 4 to prevent any rotation of one relative to the other. This assembly incorporates the function of auto-extraction of the HP compressor. The function is performed by the segment which axially fixedly attaches the bearing nut to the bevel gear. Thus, by tightening the nut in the thread of the HP compressor shaft, the compressor is docked with the bearing; conversely, by unscrewing the nut, the compressor is pushed rearward because the nut is immobilized axially by the segment.
The applicant has set itself the objective of preventing the problems associated with this installation.
More particularly, the problem to be solved relates to a type of connection between the HP compressor and the engine IGB making it possible to install and remove the HP compressor with sole access by the tools via the rear of the engine.
According to the invention, the system for attaching the end of a gas turbine engine shaft engaged inside a coupling supported by a bearing, by means of a nut, is characterized in that the nut comprises a first thread, by which it is screwed into said shaft comprising a thread, and a second thread by which it is screwed to said coupling comprising a thread. More particularly, the two screw pitches of the nut are reversed relative to one another so as to form an adjusting nut.
The solution of the invention is therefore suitable for installing the HP compressor shaft of a double-bodied engine whose power offtake to drive the machines' gearbox is provided by a bevel pinion fixedly attached to the latter, the coupling belonging to this drive bevel pinion.
The use of an adjusting nut allows the HP compressor to be removed simply, by working only from the rear of the engine, and is not compromised by the tools and installation means currently used.
Installation/removal via the rear of the engine is a very major advantage for this type of engine and greatly reduces the cost of such an operation.
In addition, the solution is compact; it fits into the available space and does not interfere with the air circulation between the IGB and the LP shaft. The present application also relates to a compressor and a turbine engine incorporating the system of the invention.
The invention will now be described in greater detail, with reference to the appended drawings in which:
A description will now be given of the front installation of the HP compressor shaft in the bearing 3, with reference to
The bearing is assembled with the bevel gear 15 shrink-fitted into the race 3i of the bearing. The first step consists in heating the bearing 3 by placing a heater under the race 3i. The advantage of the solution of the invention is already seen because, in the absence of a nut, no superfluous heating damages the surrounding parts.
In parallel, the nut 16 is placed on the shaft as shown in
With reference to
The nut 16 may be called an adjusting nut because a tractile tension is applied to the shaft 14. The nut is rotated by known tools across the shaft from the rear in particular. To prevent forces from passing through the bearing, the bevel gear may be axially strapped by means of an appropriate tool that is placed, for example, in an axial strapping zone made between tenons 157 made at the front of the gear to prevent any rotation during the installation and a shoulder 158.
Number | Date | Country | Kind |
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06 50293 | Jan 2006 | FR | national |
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3622185 | Rosan et al. | Nov 1971 | A |
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1 087 410 | Aug 1960 | DE |
0 987 457 | Mar 2000 | EP |
2 633 023 | Dec 1989 | FR |
Number | Date | Country | |
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20070177935 A1 | Aug 2007 | US |