FR3099463A1 - DEVICE FOR MOUNTING AN AXLE ON A SCREED FOR AN AIRCRAFT TURBOMACHINE - Google Patents

Abstract

The invention relates to a device (100) for mounting an axle (1) on a yoke (2) for an aircraft turbomachine, comprising a yoke (2) comprising two lugs (3, 4) comprising passage bores. (5, 6) of the axle (1), a first bush (7) fitted and slidably engaged in a first of the bores (5, 6), a second bush (8) fitted and slidably engaged in a second of the bores (5, 6), the axis (1) comprising a head (10) clamped axially against the first sleeve (7) and a nut tightened (11) axially against the second sleeve (8). According to the invention, the bores (5, 6) have different internal diameters (Di1, Di2) and the first bore (5) comprises an annular shoulder (15) having an internal diameter (Di15) less than the internal diameter (Di1) of this bore (5). The invention also relates to an aircraft turbomachine, comprising at least one such device (100). Figure for the abstract: Figure 1

Description

DEVICE FOR MOUNTING AN AXIS ON A Yoke FOR AN AIRCRAFT TURBOMACHINE

Technical field of the invention

The present invention relates to a device for mounting an axle on a yoke for an aircraft turbine engine.

Technical background

The present invention relates to a device for mounting an axle on a yoke, and in particular a device called an “axle-yoke assembly” for the suspension of an aircraft turbine engine.

Document FR-A1-2 923 460, in the name of the applicant, describes an example of mounting an axle on a yoke. Such an assembly allows a component, for example a connecting rod, to be mounted for rotation with respect to an axis which, once mounted, is secured to two lugs of a yoke.

The shaft passes through two bushings, each mounted in a separate lug and coming into contact with an element in order to lock it in translation along the shaft. In document FR-A1-2 923 460, the element locked in translation between the two sleeves is a ball joint, and a connecting rod is rotatably mounted on this ball joint. The pin is held on the yoke by the two bushings, as well as by means of a screw and a nut in helical engagement with the pin. This assembly provides good support for the parts between the two lugs of the yoke but has certain drawbacks, in particular when assembling the various elements together.

Indeed, during assembly, it may happen that one of the sleeves is mounted upside down or that one of the sleeves is mounted in the lug which was intended to receive the other sleeve. Mounting the bushings upside down or reversing the bushings no longer guarantees assembly play and can lead in particular to bending and plasticizing of the clevis ears.

The object of the present invention is in particular to solve all or part of the aforementioned problems.

The invention proposes for this purpose a device for mounting an axle on a yoke for an aircraft turbine engine, comprising:

- a yoke connected to a first turbomachine element and comprising two lugs comprising bores for the passage of an axis,

- a first sleeve engaged in an adjusted and sliding manner in a first of the bores,

- a second sleeve engaged in an adjusted and sliding manner in a second of the bores,

- a connecting element connected to a second turbomachine element and inserted between the first and second bushings,

- a shaft passing through said sleeves and said connecting element, this shaft comprising a head tightened axially against the first sleeve and a nut tightened axially against the second sleeve,

According to the invention, the bores have different internal diameters and the first bore comprises an annular shoulder having an internal diameter smaller than the internal diameter of this bore.

The annular shoulder thus offers a keying system which allows the assembly of the first sleeve in the bore only in one direction, entering from the side of the bore not having the annular shoulder, which prevents incorrect assembly of the first bushing in the first bore.

Furthermore, the internal diameters of the bores being different, the bushings must present different radial thicknesses in order to propose an equal internal diameter to be both in contact with the axis and their respective bore so that it is not possible to invert the positioning of the first sleeve with that of the second sleeve.

The mounting device according to the invention may comprise one or more of the characteristics below, taken separately with each other or in combination with each other:

• the bore of at least one of the ears is directly formed in this ear;
• the bore of at least one of the lugs is formed in an attached ring and shrunk in an orifice of this lug;
• the ring has an external annular bearing rim on one face of the corresponding ear;
• the edge rests on an outer face of the ear;
• the ring defining said first bore is engaged in the orifice of the lug over a length less than an axial thickness of this lug;
• the first bore has an internal diameter smaller than the internal diameter of the second bore;
• the second sleeve comprises at a first axial end an outer annular rim on which said nut bears directly or indirectly;
• the second sleeve comprises a second opposite axial end bearing on said connecting element, this second end being located at an axial distance from an internal face of the corresponding lug which is less than an axial thickness of the external rim of the second socket;
• said shoulder has an axial thickness which is less than 30% of an axial thickness of the corresponding ear;

The invention also relates to an aircraft turbomachine, comprising at least one device as defined above.

Brief descriptions of figures

The invention will be better understood and other details, characteristics and advantages of the invention will appear more clearly on reading the following description given by way of non-limiting example and with reference to the appended drawings in which:

Figure 1 is a schematic view in axial section of the device according to the invention; And

Figure 2 is a schematic view in axial section of the device of Figure 1 according to a variant embodiment.

Detailed description of the invention

There is shown in Figures 1 and 2, a device 100 for mounting a shaft 1 on a yoke 2. Such a device 100 comprises the shaft 1 and the yoke 2. The latter is connected to a first element of turbomachine and comprises two lugs 3, 4 each comprising a bore 5, 6 for the passage of the axis 1. The assembly of the two lugs 4, 6 can for example be made in one piece.

Shaft 1 extends along a mounting shaft A corresponding to the mounting shaft of shaft 1 through lugs 3, 4. In the remainder of this description, axial is understood to mean any direction parallel to mounting axis A and radial any direction perpendicular to the axial direction. Unless otherwise specified, the adjectives internal/interior and external/external are used in reference to a radial direction so that the internal (i.e. radially internal) part of an element is closer to the axis of mounting A than the external (i.e. radially external) part of the same element. Finally, the diameters of the various elements are all measured in a radial direction.

The device 100 further comprises a first sleeve 7 engaged in an adjusted and sliding manner in a first 5 of the bores of the first ear 3 and a second sleeve 8 engaged in an adjusted and sliding manner in a second 6 of the bores of the second ear 4.

The device 100 also comprises a connecting element 9 connected to a second turbomachine element and inserted between the first 7 and second 8 sockets.

The sleeves 7, 8 each have a substantially equivalent internal diameter so that the pin 1 passes through the sleeves 7, 8 and the connecting element 9.

Shaft 1 is mounted tight on sleeves 7, 8 via a clamping means, in this case a head 10 located at a first axial end of the shaft and in particular clamped axially against first sleeve 7 and a nut 11 in particular tightened axially against the second sleeve 8. The pin 1 comprises for example for this a threaded part 30, located at a second axial end of the pin 1 and around which the nut 11 can be screwed.

The two bores 5, 6 are substantially circular and coaxial with each other relative to the mounting axis A. The first bore 5 has a first internal diameter Di1 and the second bore 6 has a second internal diameter Di2.

The two bores 5, 6 pass respectively through a first axial thickness E ₁ of the first lug 3 and a second axial thickness E ₂ of the second lug 4. In other words, the bores 5, 6 emerge on either side of their respective ear 3, 4. The first bore 5 and the second bore 6 thus extend respectively axially along the first thickness E ₁ and the second thickness E ₂ .

The axial thicknesses E ₁ and E ₂ can be equal or different. For example, in the two embodiments represented respectively in FIGS. 1 and 2, the first ear 3 of the yoke 2 is tightened axially by the screwing of the nut 11 and can therefore take up the axial forces in addition to the radial forces transmitted by the connecting element 9, while the second lug 4 does not take up any axial force. Provision may be made for the first thickness E ₁ to be greater than the second thickness E ₂ , to optimize the mass of the device without compromising the absorption of axial forces.

According to the invention the bores 5, 6 have different internal diameters Di1, Di2 and the first bore 5 comprises an annular shoulder 15 having an internal diameter Di15 smaller than the internal diameter Di1 of this bore 5. The internal diameter Di1 of the first bore 5 is also notably less than the internal diameter Di2 of the second bore 6.

The annular shoulder 15 extends radially inwards. It thus forms an internal projection with respect to the bore 15. It has an axial thickness l ₁₅ which is less than 30% of the axial thickness E _1, E ₂ of the corresponding lug 3, 4, i.e. that is to say here at the thickness E ₁ of the first lug 3. The annular shoulder 15 can only have a keying function to ensure that the first sleeve 7 can be mounted only in the right direction, c that is to say from inside the yoke 2, and therefore have no force recovery function. In particular, if, as in the embodiment of FIG. 1, a washer is interposed between the head 10 and an external face of the first lug 3 without bearing against the annular shoulder 15, the latter does not take up any forces. Its axial thickness l ₁₅ can be less than 20%, or even 10%, of the axial thickness E ₁ without compromising the solidity of the device.

The first sleeve 7 is essentially tubular. The first sleeve 7 comprises a tubular part 7a extending axially and intended to be engaged in the first bore 5. At a first axial end of its tubular part 7a, the first sleeve 7 comprises an outer annular rim 7b or flange substantially perpendicular to the tubular part 7a. The outer annular rim 7b of the first sleeve 7 has an outer diameter strictly greater than the inner diameter Di1 of the first bore 5. Preferably, the first sleeve 7 is of circular section and the outer annular rim 7b has the shape of a ring. The outer annular rim 7b rests on the connecting element 9. The outer annular rim 7b can also rest on an inner face 3c of the first lug 3, that is to say a face of the first lug 3 facing the connecting element 9 so that the outer annular rim 7b is sandwiched between the connecting element 9 and the first lug 3. The internal diameter of the first sleeve 7 (i.e. i.e. the internal diameter of the tubular part 7a) is substantially equal to an external diameter of the shaft 1. The external diameter of the first sleeve 7 (that is to say the external diameter of the tubular part 7a) is substantially equal to the internal diameter Di1 of the bore 5 so that the first sleeve 7 is substantially in contact with the first bore 5. The external diameter of the first sleeve 7 is therefore greater than the internal diameter Di15 of the annular shoulder 15, this which prevents mounting the first sleeve 15 on the side where the annular shoulder 15 is located, that is to say here on the side of an outer face 3b of the first lug 3 and therefore requires mounting the first sleeve 7 of the other side, that is to say on the side of the internal face 3c of the first ear 3.

Like the first sleeve 7, the second sleeve 8 may comprise a tubular part 8a extending axially and intended to be engaged in the second bore 6. At a first axial end of its tubular part 8a, the second sleeve 8 comprises an outer annular flange 8b or flange substantially perpendicular to the tubular part 8a. The outer annular rim 8b of the second sleeve 8 has an outer diameter strictly greater than the inner diameter Di2 of the second bore 6. Preferably, the second sleeve 8 is of circular section and the outer annular rim 8b has the shape of a ring. The internal diameter of the second sleeve 8 (that is to say the internal diameter of the tubular part 8a) is substantially equal to the external diameter of the pin 1 and therefore substantially equal to the internal diameter of the first sleeve 7. The external diameter of the second sleeve 8 (that is to say the external diameter of the tubular part 8a) is substantially equal to the internal diameter Di2 of the bore 6 and therefore different from the external diameter of the first sleeve 7, so that the second sleeve 8 is substantially in contact with the second bore 6. The first sleeve 7 thus has a different radial thickness e ₁ (in particular less) than a radial thickness e ₂ of the second sleeve 8. Thus it is not possible to invert the positioning of the sleeves 7, 8 relative to the lugs 3, 4 when mounting the device 100.

The outer annular rim 8b can rest on an outer face 4b of the second lug 4, that is to say a face opposite to the connecting element 9, or even a face directed towards the nut 11. nut 11 can bear directly or indirectly on the outer annular rim 8b of the second sleeve 8. In the example illustrated, the device 100 comprises a second washer 42, in particular located between the nut 11 and the second sleeve 8, in particular at the level of the outer annular rim 8b of the second sleeve 8, so that the nut 11 bears on the outer annular rim 8b indirectly via the second washer 42.

The second sleeve 8 comprises a second axial end 8c opposite the outer annular rim 8b coming to bear on the connecting element 9. This second end 8c is located at an axial distance l ₀ from an inner face 4c of the ear corresponding, here the second ear 4, which is less than an axial thickness e of the outer annular rim 8b of the second sleeve 8. The internal face 4c of the second ear 4, faces the connecting element 9. The distance l ₀ being less than the thickness e, the assembly of the second sleeve 8 on the second lug 4 can only be done from the outside of the yoke 2, that is to say from the external face 4b towards the face internal 4c. Indeed assuming that the second sleeve 8 is mounted from inside the yoke 2, that is to say mounted in the wrong direction, from the internal face 4c to the external face 4b, this assembly must be carried out before to bring the connecting element 9 between the sleeves 7, 8. However, once the second sleeve 8 is mounted in the wrong direction, the axial thickness e of the outer annular rim 8b is too great to allow the element to link 9 to be positioned between the sockets 7, 8. It therefore becomes impossible to mount the connecting element 9 with the axis 1 if the second sleeve 8 is mounted in the wrong direction. In other words, a thickness e greater than the distance l ₀ performs keying to ensure that the second sleeve 8 is mounted in the correct direction.

As visible in Figure 1, the bore 5, 6 of at least one of the ears 3, 4, and in particular of the two ears 3, 4 is directly formed in this ear 3, 4. In this embodiment, the annular shoulder 15 is formed directly in one of the lugs 3, 4, in particular the first lug 3. The first lug 3 and the annular shoulder 15 then form, for example, a one-piece assembly. In this exemplary embodiment, the sleeves 7, 8 are positioned directly between the pin 1 and their respective lug 3, 4 so that they are in contact with the pin 1 and their respective lug.

According to a variant embodiment illustrated in FIG. 2, the device 100 comprises at least one ring 12, here a first ring 12, located in a first orifice 13 of the first lug 3. The device 100 can also comprise a second ring 19 located in a second orifice 14 of the second ear 4.

The orifices 13, 14 are in particular coaxial and in particular have an identical circular section. The two orifices 13, 14 pass respectively through the first axial thickness E ₁ of the first ear 3 and the second axial thickness E ₂ of the second ear 4.

In this embodiment, the bore 5, 6 of at least one of the ears 3, 4 is formed in one of the rings 12, 19. In the example illustrated, the first bore 5 is formed in the first ring 12 and the second bore 6 is formed in the second ring 19. Each of the rings 12, 19 is for example attached and shrunk in the orifice 13, 14 of the ear 3, 4 corresponding. In this embodiment, the annular shoulder 15 is therefore formed in one of the rings 12, 19, in particular the first ring 12.

The first ring 12 comprises a tubular part 12a intended to be engaged in the first orifice 13 of the first lug 3. At a first axial end of its tubular part 12a, the first ring 12 comprises an external annular flange 12b or external annular flange substantially perpendicular to the tubular part 12a. The outer annular rim 12b of the first ring 12 has an outer diameter strictly greater than the diameter of the first orifice 13. Preferably, the first ring 12 is of circular section and the outer annular rim 12b has the shape of a ring. The annular shoulder 15 is in particular located in an internal radial extension of the external annular rim 12b.

The outer annular rim 12b rests on a face of the first ear 3, in particular on the outer face 3b of the first ear 3, that is to say a face opposite the connecting element 9, or even a side facing the head 10 of the axis 1. In this embodiment, the internal diameter of the first ring 12 (that is to say the internal diameter of the tubular part 12a) defines the internal diameter Di1 of the first bore 5 and is substantially equal to the outer diameter of the first sleeve 7. The outer diameter of the first ring 12 (that is to say the outer diameter of the tubular part 12a) is substantially equal to the diameter of the first orifice 13 of the first lug 3. The first ring 12 is thus located directly between the first lug 3 and the first sleeve 7, the latter being in contact with the axis 1 as described previously.

According to one embodiment of the invention, the first ring 12 defining the first bore 5 is engaged in the first orifice 13 of the lug 3 over an axial length l ₁ less than the axial thickness E ₁ of this lug 3. The tubular part 12a of the first ring 12 can thus be inserted between the tubular part 7a of the first sleeve 7 and the first lug 3 without coming into contact with the outer annular rim 7b of the first sleeve 7. The first lug 3 can thus be clamped between the first sleeve 7 and the first ring 12, and in particular between the outer annular rim 7b of the first sleeve 7 and the outer annular rim 12b of the first ring 12.

Like the first ring 12, the second ring 19 may comprise a tubular part 19a intended to be engaged in the second orifice 14 of the second lug 4. At a first axial end of its tubular part 19a, the second ring 19 comprises an outer annular flange 19b or outer annular flange substantially perpendicular to the tubular part 19a. The outer annular rim 19b of the second ring 19 has an outer diameter strictly greater than the diameter of the orifice 19. Preferably, the second ring 19 is of circular section and the outer annular rim 19b has the shape of a ring. The outer annular rim 19b rests on one face of the second ear 4, in particular on the outer face 4b of the second ear 4. In this embodiment, the internal diameter of the second ring 19 (i.e. say the internal diameter of the tubular part 19a) defines the internal diameter Di2 of the second bore 6 and is substantially equal to the external diameter of the second sleeve 8. The external diameter of the second ring 19 (that is to say the diameter of the tubular part 19a) is substantially equal to the diameter of the second orifice 14 of the second lug 4. The second ring 12 is thus located directly between the second lug 4 and the second sleeve 8, the latter being in contact with the axis 1 as previously described.

The second ring 19 defining the second bore 6 is engaged in the second orifice 14 of the second lug 4 over an axial length l ₂ for example slightly less than the axial thickness E ₂ of this lug 4. Alternatively, the axial length l ₂ may be equal to or slightly greater than the axial thickness E ₂ .

A first axial functional clearance J1 between the outer annular rim 8b of the second sleeve 8 and the outer annular rim 19b of the second ring 19 (FIG. 2) or the outer face 4b of the second lug 4 (FIG. 1) is left so to allow the second sleeve 8, at its second axial end 8c to press on the connecting element 9 by tightening the nut 11.

The device 100 can also comprise a first washer 41, in particular located between the head 10 and the external face 3b of the first lug 3 (FIG. 1) or between the head 10 and the first ring 12, in particular at the level of the external annular rim 12b of the first ring 12 (Figure 2).

The first lug 3 is then clamped between the first sleeve 7, in particular at the level of the outer annular rim 7b and the first washer 41 (FIG. 1) or the first ring 12, in particular at the level of the outer annular rim 12b of the first ring 12 (figure 2).

In the examples illustrated, there is therefore a tightening by axial support of the nut 11 on the second washer 42, of the second washer 42 on the second sleeve 8, of the second sleeve 8 on the connecting element and of the other side of the device 100 of the head 10 on the first washer 41, of the first washer on the first lug 3 (FIG. 1) or on the first ring (FIG. 2), in which case the first ring 12 is in radial support on the first lug 3, of the first lug 3 on the first sleeve 7 and of the first sleeve 7 on the connecting element 9. The parts of the device 100 are thus held together axially when the nut 11 is screwed onto the shaft 1 and the tightening of the first lug 3 is in particular ensured.

Claims (11)

Device (100) for mounting an axle (1) on a yoke (2) for an aircraft turbine engine, comprising:
- a yoke (2) connected to a first turbomachine element and comprising two lugs (3, 4) comprising passage bores (5, 6) for a shaft (1),
- a first sleeve (7) engaged in an adjusted and sliding manner in a first of the bores (5, 6),
- a second sleeve (8) engaged in an adjusted and sliding manner in a second of the bores (5, 6),
- a connecting element (9) connected to a second turbomachine element and inserted between the first (7) and second bushings (8),
- a shaft (1) passing through said sleeves (7, 8) and said connecting element (9), this shaft (1) comprising a head (10) tightened axially against the first sleeve (7) and a tightened nut (11) axially against the second sleeve (8),
characterized in that the bores (5, 6) have different internal diameters (Di1, Di2) and in that the first bore (5) comprises an annular shoulder (15) having an internal diameter (Di15) smaller than the internal diameter ( Di1) of this bore (5). Device (100) according to Claim 1, in which the bore (5, 6) of at least one of the ears (3, 4) is directly formed in this ear (3, 4). Device (100) according to claim 1 or 2, in which the bore (5, 6) of at least one of the lugs (3, 4) is formed in a ring (12, 19) attached and shrunk in an orifice ( 13, 14) of this ear (3, 4). Device (100) according to Claim 3, in which the ring (12, 19) has an outer annular rim (12b, 19b) bearing on a face (3b, 4b) of the corresponding lug (3, 4). Device (100) according to Claim 4, in which the flange (12b, 19b) bears against an outer face (3b, 4b) of the ear (3, 4). Device (100) according to one of Claims 3 to 5, in which the ring (12) defining the said first bore (5) is engaged in the orifice (13) of the lug (3) over a lower length (l ₁ ) to an axial thickness (E ₁ ) of this lug (3). Device (100) according to one of the preceding claims, in which the first bore (5) has an internal diameter (Di1) smaller than the internal diameter (Di2) of the second bore (6). Device (100) according to one of the preceding claims, in which the second sleeve (8) comprises at a first axial end an external annular rim (8b) on which the said nut (11) bears directly or indirectly. Device (100) according to Claim 8, in which the second sleeve (8) comprises a second opposite axial end (8c) for bearing on the said connecting element (9), this second end (8c) being located at an axial distance (L ₀ ) of an inner face (4c) of the ear (3, 4) corresponding which is less than an axial thickness (e) of the outer rim (8b) of the second sleeve (8). Device (100) according to one of the preceding claims, in which the said shoulder (15) has an axial thickness (l ₁₅ ) which is less than 30% of an axial thickness (E ₁ ) of the corresponding lug (3, 4). Aircraft turbomachine, comprising at least one device (100) according to one of the preceding claims.