FR3047776A1 - TURBOMACHINE AND METHOD OF MOUNTING - Google Patents

Abstract

This turbomachine comprises a rotor with an abutment disk (6) and at least one casing (24, 26, 28) in which the rotor is mounted on bearings so as to be able to pivot about a longitudinal axis of rotation (12), a fixed stop (34) cooperating with the stop disc (6) for maintaining in the longitudinal direction of the rotor in the housing (s) (24, 26, 28 ), at least one shim being removably mounted against the fixed stop (34) between the latter and a housing (26).

Description

The present invention relates to a turbomachine and its method of assembly.

A turbomachine, which may be a compressor and / or a turbine, has impeller or fin wheels for compressing and / or relaxing a gas, for example air. It is known to increase the rotational speed of a turbomachine to improve its performance and / or reduce its size and make it more compact. To limit losses and avoid the use of oil, air bearings are sometimes used. The turbomachine obtained is then a machine of high precision with reduced manufacturing tolerances.

For all turbomachines, and especially for such machines with high performance and high efficiency, it is important to perform a balancing of the rotating parts to avoid the presence of unbalance that induce premature wear of the bearings receiving these rotating parts.

The present invention therefore aims to provide a turbomachine structure for balancing the rotating parts of the machine without having to disassemble after balancing these rotating parts. Thus, the balancing can be performed under the conditions in which the rotating parts work in the turbomachine and this balancing is not altered by the transfer of the rotating assembly of the machine to be balanced to the turbomachine.

US2011 / 0038719 proposes a solution to avoid disassembly of the rotating assembly of a turbomachine after balancing. This solution provides for a casing for the two-part turbine engine which is mounted around the rotor after its balancing. The junction plane of the two parts here contains the axis of the rotor.

The solution proposed in this document of the prior art certainly avoids disassembly of the rotor after balancing but induces other mounting problems. Indeed, for the assembly of the two parts of the housing, it is necessary to perfectly align the two parts to avoid misalignment at the bearings and stops of the machine. It is also necessary to provide a good seal between the various channels of the machine. The assembly of the two parts of the casing must guarantee a good hold of them especially when the machine is subjected to vibrations.

The present invention therefore aims to provide a technical solution to, as mentioned above, to avoid disassembly of the rotor after balancing but without inducing the disadvantages indicated in the previous paragraph. For this purpose, the present invention provides a turbomachine comprising a rotor with a stop disk and at least one housing in which the rotor is mounted on bearings so as to be able to pivot about a longitudinal axis of rotation, a fixed abutment cooperating with the stop disc to maintain in the longitudinal direction of the rotor in the housing (s).

According to the present invention at least one shim is mounted removably against the fixed stop between the latter and a housing.

Providing at least one wedge between the fixed stop and the housing on which said fixed stop is mounted, allows to define two different axial sets. A first game makes it possible to obtain the necessary clearance for the balancing operation while the other game corresponds to the (reduced) clearance necessary for operation of the turbomachine (precharge of the stop). The abutment being static, one can act on it without having to intervene on the moving parts of the machine.

In a preferred embodiment, it is provided that the fixed stop is in the form of an annular piece and that the shim has two segments mounted between the annular piece and said casing, the two segments forming substantially an annular piece. In this way, it is possible to come up the shim after balancing coming disassemble the stop and then insert the shim between the stop and said housing.

To facilitate assembly operations, the fixed stop and the wedge are advantageously mounted on said housing by means of screws.

The present invention is particularly well suited to the case where the turbomachine concerned comprises at least one air bearing.

A preferred embodiment of the turbomachine provides that it comprises three separate casings, a first in which is taken place a motor for driving the rotor, a second carrying the fixed stop and a third forming a volute, the second casing being mounted between the first and the third. The housing bearing the fixed stop is preferably an intermediate element, that is to say sandwiched between two other housings.

The present invention also relates to a method of mounting a turbomachine comprising a rotor with a thrust disc and a housing inside which are provided bearings for receiving the rotor and a fixed stop cooperating with the disc of abutment, said method comprising a step of balancing the rotor and then mounting the rotor in the housing.

It is proposed by the present invention that during the balancing step, the rotor is mounted on the machine to be balanced with a second casing bearing the fixed stop and that the balancing is performed while the rotor is mounted. in said second housing, and that a subsequent step provides for the establishment of a shim adjacent to the fixed stop.

By performing such a mounting, it is possible not to have to disassemble the rotor after the balancing step and to insert a block in the turbomachine.

In this method, it is preferably provided that the shim is disposed between the fixed stop and the second casing carrying it.

According to a preferred embodiment, the fixed stop is screwed to the second casing, and the shim is advantageously fixed by means of the screws holding the fixed stop.

Details and advantages of the present invention will become more apparent from the description which follows, given with reference to the appended schematic drawing in which:

FIG. 1 is a longitudinal sectional view of a turbomachine rotor to be balanced,

FIG. 2 shows the rotor of FIG. 1 mounted in a turbine engine in longitudinal section,

FIG. 3 shows in a section corresponding to FIGS. 1 and 2 of the rotor of FIG. 1 with a housing forming a thrust flange,

FIG. 4 is a perspective view of the rotor positioned on a tooling allowing a pre-hold on a machine to be balanced, and

FIG. 5A is an exploded view of the assembly illustrated in FIG. 3, and

Figures 5B and 5C illustrate the mounting of a shim after a balancing operation.

FIG. 1 shows an assembly comprising a shaft 2, a permanent magnet 4, a stop disk 6 and a wheel 8. The illustrated shaft 2 is a cylindrical tubular shaft of longitudinal axis 12 whose outer surface is machined at least at level of a first zone 14 and a second zone 16 so as to form two non-contact bearing bearings such as magnetic or gas bearings. The shaft 2 grips the magnet 4 so that the two parts are integral with each other. Magnet 4 is a conventional magnet used as a permanent magnet in an electric motor. It is advantageously of solid cylindrical shape.

The stop disk 6 protrudes radially from the outer surface of the shaft 2. This stop disk 6 is disposed at the end of the shaft 2 in the embodiment shown and is adjacent to the second bearing zone 16. This stop disk 6 is extended, on the opposite side to the shaft 2, by a half-tie 18 which is used for mounting the wheel 8. The latter is held on the half-tie 18 with the help of a nut system 20.

Figure 2 illustrates the rotor of Figure 1 mounted in a motorized compressor assembly. The shaft 2 with the permanent magnet 4 here forms the rotor of an electric motor 22. The assembly formed by the electric motor 22 and the rotor of FIG. 1 is arranged in a housing made of several parts of the housing type. Thus, the housing here comprises a motor housing 24, a second casing 26 forming an intermediate flange and a third casing 28 forming a volute.

The crankcase 24 houses the motor 22 and has a first support 30 to form a bearing with the first zone 14 and a second support 32 to form another bearing with the second zone 16. The bearings thus formed here are air bearings, which corresponds to a preferred embodiment (but not limiting) for the motorized compressor described here. Substantially all the shaft 2 is housed in the crankcase 24. The thrust disk 6 is outside the crankcase 24, close to the latter.

The stop disk 6 and the first wheel 8 are housed in the second housing 26. The latter then performs several functions. Vis-à-vis the wheel 8, the second casing 26 is shaped so as to integrate the diffuser of this wheel. The intermediate flange formed by the second housing 26 also serves to support the fixed stop 34 which cooperates with the stop disc 6. It is mounted for example by screwing, or by any other reversible mounting means, on the crankcase 24.

The volute formed by the third casing 28 is mounted by screwing, or other equivalent reversible assembly, on the second casing 26. It should be noted in FIG. 2 that the embodiment of the volute illustrated here comprises an air inlet and an outlet of air connected by a control bypass 36.

In an original way, it is proposed to carry out the balancing of the rotor illustrated in FIG. 1 when it is mounted in the second housing 26. As explained below, this makes it possible subsequently to be able to insert the rotor of a block into the turbomachine. FIG. 4 illustrates the positioning of this rotor / flange assembly on a machine maintenance tooling 38 to be balanced. Indeed, a specific tool is expected to allow the assembly of this assembly on the balancing machine. For example, it is possible to fix the second casing 26 on the machine to be balanced in the same manner as that provided for fixing the second casing 26 on the crankcase 24 by adapting, for example, the tooling 38 of the machine to be balanced. The solution proposed in FIG. 4 provides for it to be clamped against the tooling 38 by means of clamping fingers 40, the correct positioning of the second casing 26 being provided for example by at least two positioning pins 42 (a single being visible in Figure 4).

To balance the rotor, it should be rotated about its longitudinal axis 12 to measure the unbalance of the rotor and its positioning before correcting it. During balancing, the speed of rotational drive does not allow the creation of a film on the stop. It is then necessary to ensure an axial clearance between the stop disk 6 and the fixed stop 34 which is greater than the axial play in operation of the compressor (very reduced). It is proposed here an original way to modify this game without having to intervene on the rotor.

FIG. 5A illustrates in exploded perspective the rotor of FIG. 1 (without a wheel), the fixed stop 34 and a shim made up of two segments 44.

Figure 5A shows in more detail the fixed stop 34 which comprises a plate 34a forming another shim and a stop 34b, these two parts being fixed on the second casing 26 by screws 34c. This figure is an exploded view making it possible to clearly visualize the various components at the level of the rotating stop disc 6 and the fixed stop 34.

Once the rotor is balanced, the shim is put in place. To do this, the screws 34c are removed and the segments 44, each forming a half wedge, are positioned between the plate 34a and the second casing 26. The shim generally has the shape of a washer, that is to say it has an annular shape of small thickness having two parallel flat front faces. This washer is cut diametrically into two parts, each of these parts then forms a half block here called segment 44. In this way two half shims of exactly the same thickness are obtained. The outer diameter of the wedge (segments 44) is preferably at least equal to the outer diameter of the plate 34a and / or the stop 34b. The inner diameter of the shim (segments 44) is chosen so as to allow the mounting of the segments 44 without having to intervene on the rotor.

FIG. 5B illustrates the positioning of the segments 44 behind the abutment 34, that is to say between the abutment 34 formed of the abutment 34b proper and the plate 34a, and its support, the second casing 26. The 5C illustrates the final assembly: the two segments 44 are in place and the screws 34c are used for fixing the stop 34 and segments 44 on the intermediate flange formed by the second housing 26. Holes are advantageously provided in the segments 44 for the passage of the screws 34c so as to allow a perfect maintenance of these segments 44.

Once the segments 44 (the shim) have been put in place, the subassembly illustrated in FIG. 3 and comprising the shaft 2 is mounted in the crankcase 24, the second casing 26 is fixed on the crankcase 24 and the third casing 28 (volute) is mounted.

Note that when mounting the motorized compressor of Figure 2, it is not necessary to act on the rotor after balancing. The rotor is introduced as balanced in the final assembly.

The foregoing description thus presents a turbomachine rotor assembly principle, and a turbomachine structure, which allow insertion of the rotor into the turbomachine without disassembly (at the rotor) after balancing of the rotor.

The solution proposed is, in short, to balance the rotating parts forming the rotor with certain static parts by mounting these rotating and static parts using a specific tool on the machine to be balanced. This solution also makes it possible to act on the axial clearance between the static parts and the dynamic parts so that this clearance is sufficient to allow balancing of the rotating parts and the stop is preloaded in operation of the turbomachine for a machine with gas bearings (air). A shim, or removable wedge, is here put in place at the fixed abutment so as to intervene only on the static parts of the machine to perform the precharge of the stop. The shim is not in place to perform the balancing and is positioned after this balancing. It is made in two pieces (or possibly more) called higher segments, to allow this assembly after balancing.

It is therefore proposed here to complicate the structure of the machine since complementary parts (removable wedge or segments) are added compared to a conventional structure, but this complexification finally makes it possible to simplify the assembly of the rotor in the machine and especially to ensure better final balancing quality and therefore better operation.

Of course, the present invention is not limited to the machine and the method presented above by way of non-limiting examples and the variants mentioned but also relates to any variant of embodiment within the reach of the skilled person in the context of the claims below.

Claims (8)

1. Turbomachine comprising a rotor with a stop disc (6) and at least one housing (24, 26, 28) in which the rotor is mounted on bearings so as to be pivotable around a longitudinal axis of rotation (12), a fixed stop (34) cooperating with the stop disk (6) for maintaining in the longitudinal direction of the rotor in the housing (s) (24, 26, 28), characterized in that at least one shim (44) is removably mounted against the fixed stop (34) between the latter and a housing (26). 2. The turbomachine according to claim 1, characterized in that the fixed stop is in the form of an annular piece (34) and the shim has two segments (44) mounted between the annular piece (34) and said housing ( 26), the two segments (44) forming substantially an annular piece. 3. The turbomachine according to one of claims 1 or 2, characterized in that the fixed stop (34) and the shim (44) are mounted on said housing by means of screws (34c). 4. Turbomachine according to one of claims 1 to 3, characterized in that it comprises at least one air bearing. 5. Turbomachine according to one of claims 1 to 4, characterized in that it comprises three separate housings, a first (24) in which is taken place a motor for driving the rotor, a second (26) bearing the fixed stop and a third (28) forming a volute, the second casing being mounted between the first and the third. 6. A method of manufacturing a turbomachine according to claim 1, characterized in that said method comprises a step of balancing the rotor and then mounting the rotor in the housing (24), in that during the step balancing device, the rotor is mounted on the machine to be balanced with a second housing (26) carrying the fixed stop (34) and the balancing is carried out while the rotor is mounted in said housing (26), and in that a subsequent step provides for the establishment of at least one shim (44) adjacent to the fixed stop (34). 7. Method according to claim 6, characterized in that the shim (44) is disposed between the fixed stop (34) and the second casing (26) carrying it. 8. Method according to one of claims 6 or 7, characterized in that the fixed stop (34) is screwed on the second housing, and in that the wedge (44) is fixed with screws (34c). now the fixed stop (34).