FR3137941A1 - DEVICE FOR FIXING A TURBOMACHINE INLET CONE - Google Patents

Abstract

The present invention relates to an inlet cone (7) for a test turbomachine comprising: - a cone cover (9), - a cone body (10), and - at least one fixing device (11) comprising : - a clamping screw (13) arranged inside a threaded through opening (15) made in the cone cover (9), - a retaining flange (14) carried by the clamping screw (13) , and - a clamping groove (24) made in the cone body (10), - such that rotation of the clamping screw (13) in a tightening direction causes a movement of the retaining flange ( 14) in the direction of the clamping groove (24), until said retaining flange (14) comes to bear against said clamping groove (24) to mechanically connect the cone cover (9) to the cone body (10). Figure 2

Description

DEVICE FOR FIXING A TURBOMACHINE INLET CONE

The present invention relates to a device for fixing a turbomachine inlet cone. The invention finds a particularly advantageous, but not exclusive, application with an aircraft turbomachine used in a wind tunnel during a test campaign.

In a manner known per se, a turbomachine fan compresses the air which enters the engine. A large part of this air constitutes the secondary flow, and the other part constitutes the primary flow. The latter passes through a low pressure compressor attached to the fan, then a high pressure compressor, the combustion chamber, the high pressure turbine and, finally, the low pressure turbine before being ejected.

There shows a test machine 1 for a test bench comprising, from upstream to downstream, an upstream aerodynamic stream 2, a fan 3 having a rotor module 4 with movable blades and a rectifier module 5 with fixed blades, as well as a stream downstream aerodynamics 6. The rotor module 4 provides acceleration to the air particles, by deflecting them relative to the axis X1 of the engine. The rectifier module 5 slows down the air particles and transforms part of their speed into pressure. The rectifier module 5 brings back the flow of air, accelerated by the rotor module 4, in the axis X1 of the motor.

An inlet cone 7 is mounted at the upstream end of the test machine 1 to divert part of the air flow which enters the interior of the turbojet towards the blades of the fan 3. The inlet cone 7 is regularly dismantled by removing the cover 9 relative to the body 10 in order to access an angular adjustment device for the blades of the fan 3. Once the angular positioning of the blades has been modified, the inlet cone 7 can then be reinstalled before to carry out a new test. A test campaign can for example aim to verify and optimize the aero-acoustic performance of the fan 3. Particular care must therefore be taken with the aerodynamic vein so as not to impact the aerodynamic flows of the test machine 1.

However, the fixing devices 11 of the inlet cone 7 are left visible on existing testing machines. The countersinks present can be filled with a filling material, such as Scotch (registered trademark) or silicone. However, this operation requires cleaning and drying time each time it is dismantled. In addition, the plugging material used is likely to come off during wind tunnel tests.

The invention aims to effectively remedy these drawbacks by proposing an inlet cone for a test turbomachine comprising:

- a cone cover,

- a cone body, and

- at least one fixing device for fixing the cone cover to the cone body,

- said fixing device comprising:

- a clamping screw placed inside a threaded through opening made in the cone cover,

- a retaining flange carried by the clamping screw, said retaining flange being guided in translation relative to the cone cover, and

- a clamping groove made in the cone body,

- in such a way that a rotation of the tightening screw in a tightening direction causes a movement of the retaining flange towards the tightening groove, until said retaining flange comes to bear against said said groove clamping to mechanically bond the cone cover to the cone body.

The invention thus makes it possible to integrate a device for fixing the inlet cone on the test machine while minimizing interference with the aerodynamic vein. Furthermore, when dismantling the inlet cone, the invention has the advantage of not requiring specific intervention, such as the addition of a plugging material inducing cleaning operations and a drying time.

According to one embodiment of the invention, the cone body comprises a centering surface intended to cooperate with a centering face made in the cone cover.

According to one embodiment of the invention, said inlet cone comprises an abutment zone produced on the cone body against which the retaining flange bears to prevent the assembly formed by the clamping screw and the retaining flange from separates from the cone cover when the clamp screw is loosened.

According to one embodiment of the invention, said inlet cone comprises a device for indexing the cone cover in rotation relative to the cone body.

According to one embodiment of the invention, the indexing device comprises a pin belonging to one of the elements among the cone cover and the cone body intended to cooperate with a housing of corresponding shape made in the other of the elements among the cone cover and the cone body.

According to one embodiment of the invention, the clamping screw has a head disposed inside the tapped through opening.

According to one embodiment of the invention, the clamping screw extends perpendicular to an aerodynamic vein.

According to one embodiment of the invention, said inlet cone comprises a plurality of fixing devices distributed angularly in a regular manner along a circumference of the cone cover.

According to one embodiment of the invention, the retaining flange abuts against an end flange of the clamping screw.

The invention also relates to a test turbomachine comprising an inlet cone as previously defined.

The present invention will be better understood and other characteristics and advantages will appear further on reading the detailed description which follows including embodiments given by way of illustration with reference to the appended figures, presented by way of non-limiting examples, which may be used to complete the understanding of the present invention and the presentation of its realization and, where appropriate, contribute to its definition, on which:

There , already described, is a schematic view in longitudinal section of a test turbomachine on which an inlet cone according to the invention is intended to be installed;

There is a detailed sectional view of a fixing device according to the invention for fixing a cone cover to a cone body;

There is a front view of an inlet cone of a test turbomachine provided with a plurality of fixing devices distributed along a circumference of the cone cover;

There is a sectional view illustrating the translational guidance of the retaining flange of the cone cover fixing device;

Figures 5a, 5b, and 5c illustrate the operation of a fixing device according to the invention making it possible to fix a cone cover on a cone body.

It should be noted that, in the figures, the structural and/or functional elements common to the different embodiments have the same references. Thus, unless otherwise stated, such elements have identical structural, dimensional and material properties.

There shows a longitudinal sectional view of an inlet cone 7 for a test turbomachine comprising a cone cover 9 and a cone body 10 also visible on the . The inlet cone 7 has an axis X2 corresponding to the axis regularly along a circumference of the cone cover 9 to fix the cone cover 9 on the cone body 10, as illustrated by the . This makes it possible to distribute the tightening forces evenly along the circumference of the entry cone 7. In the example shown, three fixing devices 11 are provided. However, as a variant, it is of course possible to provide more or less three fixing devices 11 ensuring the fixing of the cone cover 9 on the cone body 10.

Each fixing device 11 comprises a clamping screw 13 disposed inside a threaded through opening 15 made in the cone cover 9 as well as a retaining flange 14 carried by the clamping screw 13.

The clamping screw 13 has a thread cooperating with a tapping of the through opening 15. The clamping screw 13 also includes a head 16 provided with a recess to allow its tightening and loosening by a tool. Advantageously, the tightening screw 13 extends perpendicular to the aerodynamic vein 2.

The screw head 16 is arranged inside the through opening 15. The screw head 16 is flush with or is located slightly set back from the emerging end of the through opening 15 towards the aerodynamic vein 2. such a configuration makes it possible to avoid any interference of the screw head 16 with the aerodynamic flow of the vein 2.

The retaining flange 14 extends transversely relative to the clamping screw 13, that is to say that the retaining flange 14 has a direction of longitudinal elongation extending perpendicular to the direction of extension longitudinal of the tightening screw 13.

The retaining flange 14 is guided in translation relative to the cone cover 9, while being blocked in rotation relative to the cone cover 9, as illustrated by the . For this purpose, the retaining flange 14 may for example have a parallelepiped shape, two opposite faces 18 of which are guided by faces of a housing 19 of corresponding shape made in the cover 9.

The retaining flange 14 has a through hole 21 for the clamping screw 13. The through hole 21 of the retaining flange 14 is smooth. Thus, the retaining flange 14 is not linked to the clamping screw 13 by a helical connection of the screw-nut type but only by a connection of the pivot type.

As can be seen on the , the retaining flange 14 abuts against an end flange 22 of the clamping screw 13 located on the opposite side of the screw head 16. The retaining flange 14 is arranged inside a delimited internal volume through the cone cover 9.

The retaining flange 14 is intended to cooperate with a clamping groove 24 made in the cone body 10. The end portion 25 of the retaining flange 14 in contact with the clamping groove 24 may have a flared shape to optimize the support zone between these two elements 14, 24. The contact face between the two elements 14, 24 preferably forms a non-zero angle with respect to a radial direction. This radial direction is considered in relation to the axis X2 of the inlet cone 7.

Furthermore, the cone body 10 comprises a centering surface 27 intended to cooperate with a centering face 28 produced in the cone cover 9. The centering surface 27 of the cone body 10 and the centering face 28 of the cone cover cone 9 each have an annular face of axial orientation relative to the axis cone cover 9 relative to the cone body 10 when tightening the retaining flange 14.

The clamping groove 24 is made on the opposite side of the centering surface 27. In other words, the centering surface 27 is made on a radially external face while the clamping groove 24 is made on a radially internal face of the cone body 10.

The cone body 10 further comprises a stop zone 30 produced on the cone body 10 against which the retaining flange 14 bears to prevent the assembly formed by the clamping screw 13 and the retaining flange 14 from becoming separates from the cone cover 9 when the tightening screw 13 is loosened. The abutment zone 30 is constituted by a recess made in the cone body 10.

Furthermore, the inlet cone 7 includes a device 31 for indexing the rotation of the cone cover 9 relative to the cone body 10. This makes it possible to guarantee correct angular positioning of the cone cover 9 relative to the cone body. 10 according to which a retaining flange 14 is located axially aligned with a corresponding clamping groove 24.

Advantageously, the indexing device 31 comprises a pin 32 belonging to one of the elements among the cone cover 9 and the cone body 10 intended to cooperate with a housing 33 of corresponding shape made in the other of the elements among the cone cover 9 and the cone body 10. In this case, the pin 32 is carried by the cone cover 9 while the housing 33 is made in the cone body 10. Alternatively, the structure could be reversed, that is to say that the pin 32 is carried by the cone body 10 while the housing 33 is made in the cone cover 9.

We describe below, with reference to Figures 5a, 5b, and 5c, the operation of the fixing device 11 making it possible to ensure the fixing of the cone cover 9 on the cone body 10.

As is illustrated by the , the clamping screw 13 being loosened, the pre-assembled assembly "cone cover 9-tightening screw 13-retaining flange 14" is engaged on the centering surface 27 of the cone body 10. The cone body 10 can then slide along the arrow F1 until the end of the cone cover 9 comes to bear against a face of radial orientation 35 relative to the axis X2 made in the cone body 10 The angular indexing of the cone cover 9 relative to the cone body 10 is obtained by bringing the pin 32 into cooperation with the corresponding housing 33.

As is illustrated by the , a rotation of the clamping screw 13 in a tightening direction following the arrow F2 causes, thanks to the translation guidance of the faces 18 on the faces 19, a movement of the retaining flange 14 in the direction of the clamping groove 24 following the arrow F3, until said retaining flange 14 comes to bear against said clamping groove 24 to mechanically connect the cone cover 9 to the cone body 10. It should be noted that if the operator makes a mistake in the direction of rotation by rotating the tightening screw 13 in a loosening direction, the retaining flange 14 could not fall inside the cone cover 9 because the "tightening screw 13-retaining flange 14" assembly would come abutting on the cone body 10 at the location of the abutment zone 30.

As is illustrated by the , the stressing of the retaining flange 14 engaged inside the clamping groove 24 causes an axial thrust of the cone cover 9 along the arrow F4. This ensures continuity of the aerodynamic vein 2 between the cone cover 9 and the cone body 10.

The invention thus makes it possible to integrate a fixing device 11 of the inlet cone on the test machine while minimizing interference with the aerodynamic vein. Furthermore, when dismantling the inlet cone 7, the invention has the advantage of not requiring specific intervention, such as the addition of a plugging material inducing cleaning operations and a drying time. .

Of course, the different features, variants and/or embodiments of the present invention can be associated with each other in various combinations as long as they are not incompatible or exclusive of each other.

Furthermore, the invention is not limited to the embodiments described above and provided solely by way of example. It encompasses various modifications, alternative forms and other variants that those skilled in the art may consider in the context of the present invention and in particular all combinations of the different modes of operation described above, which can be taken separately or in combination.

Claims (10)

Inlet cone (7) for a test turbomachine comprising:
- a cone cover (9),
- a cone body (10), and
- at least one fixing device (11) for fixing the cone cover (9) to the cone body (10),
characterized in that said fixing device (11) comprises:
- a clamping screw (13) arranged inside a threaded through opening (15) made in the cone cover (9),
- a retaining flange (14) carried by the clamping screw (13), said retaining flange (14) being guided in translation relative to the cone cover, and
- a clamping groove (24) made in the cone body (10),
- in such a way that rotation of the clamping screw (13) in a tightening direction causes a movement of the retaining flange (14) in the direction of the clamping groove (24), until said flange retainer (14) comes to bear against said clamping groove (24) to mechanically connect the cone cover (9) to the cone body (10). Inlet cone according to claim 1, characterized in that the cone body (10) comprises a centering surface (27) intended to cooperate with a centering face (28) produced in the cone cover (9). Inlet cone according to claim 1 or 2, characterized in that it comprises a stop zone (30) produced on the cone body (10) against which the retaining flange (14) comes to bear to prevent the The assembly formed by the clamping screw (13) and the retaining flange (14) separates from the cone cover (9) when the clamping screw (13) is loosened. Inlet cone according to any one of claims 1 to 3, characterized in that it comprises a device (31) for indexing the rotation of the cone cover (9) relative to the cone body (10). Cone according to claim 4, characterized in that the indexing device (31) comprises a pin (32) belonging to one of the elements among the cone cover (9) and the cone body (10) intended to cooperate with a correspondingly shaped housing (33) made in the other of the cone cover (9) and the cone body (10). Inlet cone according to any one of Claims 1 to 5, characterized in that the clamping screw (13) has a head (16) arranged inside the threaded through opening (15). Inlet cone according to any one of Claims 1 to 6, characterized in that the clamping screw (13) extends perpendicular to an aerodynamic vein (2). Inlet cone according to any one of claims 1 to 7, characterized in that it comprises a plurality of fixing devices (11) distributed angularly in a regular manner along a circumference of the cone cover (9). Inlet cone according to any one of Claims 1 to 8, characterized in that the retaining flange (14) abuts against an end flange (22) of the clamping screw (13). Test turbomachine comprising an inlet cone (7) defined according to any one of the preceding claims.