FR3134891A1 - AXIAL MOUNTED ROTOR TEST BENCH - Google Patents

Abstract

The invention relates to a test bench (10) for a rotor (12), in particular a turbomachine rotor, in which the rotor (12) comprises a journal (14) consisting of a part of revolution having grooves (16) on a radially external cylindrical face and the rotor (12) comprises a flange (20) located at a downstream axial end (22) of the journal (14), the test bench (10) comprising a main axis A, a fixed structure and a support shaft (28) consisting of a hollow element of revolution coaxial with the main axis A, which is mounted for rotation around the main axis A relative to the fixed structure, characterized in that the shaft of support (28) delimits a hollow housing (36) open towards the downstream in which the pin (14) is able to be inserted and fixed in a translational movement from downstream to upstream along the main axis A. Figure for abstract: Figure 1

Description

AXIAL MOUNTED ROTOR TEST BENCH

The invention relates to a fatigue test bench for a shaft, in particular a turbomachine shaft.

The invention relates more particularly to a test bench designed to allow easy assembly and disassembly of the shaft.

STATE OF PRIOR ART

When developing a turbomachine, it is known to carry out numerous tests to validate and certify a technical solution for the turbomachine.

Thus, many configurations must pass through a test tank and these can be modified so that the best technical solution can be put on the market.

This observation leads to the study of solutions to increase testing rates.

In an existing solution, a test bench for a turbomachine shaft comprises a set of flanges for fixing the shaft to the rest of the test bench. These flanges include a plurality of screws distributed in rings.

Thus, each time the shaft is changed, all the screws must be dismantled and then reassembled, which requires a significant amount of time which is not dedicated to carrying out the fatigue test.

To respond to this problem, it was put forward that it was necessary to leave on the bench an entire upstream module comprising the means for guiding and driving the rotating shaft and on which the shaft to be tested and found is fixed. a suitable fixing solution.

The aim of the invention is to provide a test bench which allows rapid assembly and disassembly of the rotor, or any other module to test several configurations.

The invention proposes a test bench for a rotor, in particular a turbomachine rotor, in which the rotor comprises a journal consisting of a part of revolution having grooves on a radially external cylindrical face and the rotor comprises a flange located at a downstream axial end of the journal, the test bench comprising a main axis A, a fixed structure and a support shaft consisting of a hollow element of revolution coaxial with the main axis A, which is mounted to rotate around the axis main A relative to the fixed structure, characterized in that the support shaft delimits a hollow housing open towards the downstream in which the pin is able to be inserted and fixed in a translational movement from downstream to upstream along the main axis A.

The axial insertion of the journal into the support shaft makes mounting the rotor in the test bench simpler than mounting using removable flanges.

Preferably, the pin is able to be fixed in the hollow housing of the support shaft by shrinking.

Preferably, the test bench comprises a tie rod which is able to cooperate with the support shaft and with the pin for the insertion and fixing of the pin in the hollow housing of the support shaft.

Preferably, the tie rod consists of an element of revolution coaxial with the main axis A, which is mounted in the hollow housing of the support shaft and in an interior volume of the journal, the tie rod comprising an upstream axial end which cooperates with an internal face of the support shaft and a downstream axial end which is intended to cooperate with the rotor.

Preferably, the downstream end of the tie rod comprises a threaded rod which is intended to pass through an associated orifice of the flange and which carries a nut intended to come to bear axially against a downstream face of the flange.

Preferably, the upstream end of the tie rod comprises a threaded portion which engages with a complementary threaded portion carried by said internal face of the support shaft.

Preferably, the downstream end of the tie rod comprises a downstream axial end face which is capable of bearing axially downstream against the flange and from which the threaded rod extends axially downstream.

Preferably, the test bench includes means for locking the tie rod in rotation relative to the rotor.

Preferably, said locking means comprise a locking pin which is intended to be received simultaneously in a first axial orifice formed in the downstream axial end of the tie rod and in a second axial orifice formed in the flange, in which the two axial orifices are able to be put into correspondence to be placed as an extension of one another.

Preferably, the locking pin has a head intended to be received in a complementary notch formed in the downstream face of the flange.

is a schematic perspective representation of part of a test bench according to the invention, comprising a support shaft and a tie rod to which a turbomachine rotor is fixed.

is a section of the test bench shown in , which is in configuration with the rotor mounted on the support shaft

, , , , ,

has

are views similar to that of the , showing different states of the test bench when mounting or dismounting the rotor.

is a detail on a larger scale of the means for blocking the rotation of the tie rod.

DETAILED DESCRIPTION OF THE INVENTION

We represented at the a test bench 10 which is used here to carry out tests on a turbomachine rotor 12. It will be understood that the invention is not limited to a test bench for a turbomachine rotor and that it can be used for any other element intended to be used in rotation around an axis.

The test bench 10 comprises a main axis A around which the rotor 12 is intended to be rotated to carry out the test.

In the description which follows, we will use the upstream and downstream sides arbitrarily as being the left and right sides respectively.

Here, only an upstream part of the rotor 12 has been shown and comprises a pin 14 consisting of a hollow part of revolution, that is to say that the pin 14 is generally cylindrical, and which has grooves 16 on its cylindrical face external 18. The rotor 12 also includes a circular flange 20 which is fixed to a downstream axial end 22 of the pin 14.

The upstream axial end 24 of the pin 14 opens out axially.

The test bench 10 comprises a fixed structure 26, a support shaft 28 on which the rotor 12 is intended to be mounted and means 30 for guiding the support shaft 28 in rotation around the main axis A.

The support shaft 28 also consists of a hollow element of revolution coaxial with the main axis A. The external cylindrical wall 32 of the support shaft 28 cooperates with the guide means 30 in rotation.

The support shaft 28 has an upstream axial end (not shown) by which it is connected to rotational drive means and it has a downstream axial end 34 which is intended to cooperate with the rotor 12.

The support shaft 28 delimits a housing 36 in which the pin 14 is intended to be inserted and to be fixed for the connection of the rotor 12 to the support shaft 28.

For this, the support shaft 28 has a radially internal face 38 which radially delimits the housing 36 and with which the pin 14 cooperates for its connection with the support shaft 28.

According to a preferred embodiment, the pin 14 is fixed to the support shaft 28 by shrinking. For this, the dimensions of the radially internal face 38 are defined as a function of the dimensions of the pin 14, in particular as a function of the external diameter of the grooves 16.

The radially internal face 38 of the support shaft 28 further comprises internal splines 40 which are complementary to the splines 16 of the pin 14. The two sets of splines 16, 40 cooperate with one another when the rotor 12 is mounted on the support shaft 28.

Finally, the downstream axial end 34 of the support shaft 28 has a radial end face 42 against which the circular flange 20 is intended to bear axially upstream.

Thus, when the rotor 12 is mounted on the test bench, the pin 14 is coupled with the support shaft 28 both by the shrink fit and by the cooperation of the splines 16, 40. In addition, the rotor 12 is positioned axially by the support of the circular flange 20 against the radial end face 42 of the support shaft 28.

The rotor 12 is placed in the test bench 10 by introducing the pin 14 into the housing 36 of the support shaft 28 in an axial translation movement from downstream to upstream.

Such a movement of the rotor 12 relative to the support shaft 28 and relative to the entire test bench 10 is relatively easy to implement. In addition, it does not require assembling a large number of components necessary for fixing the rotor to the support shaft 28.

The rotor 12 is driven in axial translation relative to the support shaft 28 by means of a tie rod 44 which cooperates both with the support shaft 28 and with the rotor 12.

The tie rod 44 consists of an element extending in the axial direction, which is arranged in the housing 36 delimited by the second axial end 34 of the support shaft 28 and it is capable of being received in the cylindrical volume delimited by the pin 14.

The tie rod 44 has an upstream axial end 46 which is connected to the radially internal face 38 of the support shaft 28 by screwing. For this, the radially internal face 38 of the support shaft 28 comprises a threaded portion 48 and the upstream axial end 46 of the tie rod 44 comprises a complementary threaded portion 50.

The tie rod 44 has a downstream axial end 52 which is intended to cooperate with the rotor 12. In particular, the downstream axial end 52 of the tie rod 44 cooperates with the circular flange 20 of the rotor.

The downstream axial end 52 of the tie rod 44 comprises a circular radial body 54 which is delimited axially by a downstream axial end face 56 opposite the upstream axial end 46 of the tie rod 44. The downstream axial end 52 of the tie rod 44 comprises also a threaded rod 58 which extends coaxially to the main axis A while projecting downstream relative to the downstream axial end face 56 of the circular radial body 54.

A nut 64 is engaged on the threaded rod 58.

The free downstream end 60 of the threaded rod 58 comprises flats 62 intended to cooperate with a tool (not shown) to maneuver the tie rod in rotation around the main axis A, in order to screw, unscrew or keep the tie rod 44 stationary relative to the support shaft 28.

As can be seen in Figures 1 and 7, when the rotor 12 is mounted on the support shaft 28 via the tie rod 44, the downstream axial end 34 of the support shaft 28 is supported axially towards downstream against a circular plate 82 mounted on the upstream face 66 of the circular flange 20. The threaded rod 58 passes through a central orifice 68 formed in the circular flange 20. Finally, the nut 64 is supported axially towards the upstream against a downstream face 70 of the circular flange 20.

This results in the circular flange 20 being clamped axially between the downstream axial end 34 of the support shaft 28 and the nut 64. The rotor 12 is thus also blocked in axial translation via the tie rod 44.

As said above, when the rotor 12 is mounted on the support shaft 28, the splines 16 of the pin 14 cooperate with the internal splines 40 of the support shaft 28. The rotor 12 is thus immobilized in rotation relative to the support shaft 28.

The tie rod 44 is immobilized in rotation relative to the support shaft 28 by means of the rotor 12, which is itself immobilized in rotation relative to the support shaft 28.

As can be seen in more detail in , this immobilization in rotation of the tie rod 44 is implemented by the use of a locking pin 72 which extends parallel to the main axis A and which is capable of being received simultaneously in a first axial orifice 74 formed in the circular radial body 54 of the tie rod 44 and in a second axial orifice 76 formed in the circular flange 20.

The first axial orifice 74 and the second axial orifice 76 are located at the same radial distance from the main axis A and they are placed in correspondence with each other when the rotor 12 is placed on the shaft support 28, by rotating the tie rod 44 relative to the rotor 12 and relative to the support shaft 28. When the rotor 12 is placed on the support shaft 28, an axial play is present between the face downstream axial end 56 of the tie rod 44 and the upstream face 66 of the circular flange 20, allowing axial movement of the tie rod relative to the rotor during this matching of the axial orifices 74, 76

The locking pin 72 comprises a head 78 located at the downstream end of the locking pin 72 which is capable of being received in a complementary notch 80 formed in the downstream face 70 of the circular flange 20.

The first axial orifice 74, the second axial orifice 76 and the notch 80 are positioned such that when the rotor 12 is mounted on the support shaft 28 via the tie rod 44, the nut 64 presses on the head 78 of the locking pin 72, preventing the locking pin 72 from leaving the axial orifices 74, 76.

In the description which follows, we will describe the different stages of assembly and disassembly of the rotor 12 on the test bench 10 with reference to Figures 2 and following.

There represents the test bench 10 in its initial configuration, not including the tie rod 44.

In this configuration, the support shaft 28 is only connected to the fixed structure 26 by the guide means 30, its interior housing 36 is empty.

In a first step represented in , the tie rod 44 is assembled in the interior housing 36 of the support shaft 28. This assembly consists of screwing the tie rod 44 into the support shaft 28 via the threaded portions 48, 50. The operation of the tie rod 44 is carried out by the use of a tool (not shown) which is engaged on the flats 62 formed at the free downstream end 60 of the threaded rod 58.

In a second step represented in , the rotor 12 is presented opposite the support shaft 28 then the pin 14 is introduced into the interior housing 36 of the support shaft 28. Finally, the rotor 12 is docked to engage the splines 16 of the pin 14 with the splines 40 of the support shaft 28.

During this introduction of the pin 14 into the interior housing 36, the threaded rod 58 of the tie rod 44 is introduced through the central orifice 68 of the circular flange 20.

At the end of this step, the splines 16 of the pin 14 and the splines 40 of the support shaft 28 are not completely engaged and the pin 14 is not linked to the support shaft 28 by shrink fit. In addition, circular plate 82 is at a distance from the downstream end face 42 of the downstream axial end 34 of the support shaft 28.

In a third step represented in , the nut 64 is screwed onto the threaded rod 58 until it comes into contact with the downstream face 70 of the circular flange 20. The nut 64 is then screwed even further to exert a thrust force on the circular flange 20, causing the entire rotor 12 to move upstream to a predetermined final position for which the splines 40 of the support shaft 28 are completely engaged and the pin 14 is connected to the support shaft 28 by shrink fit .

Furthermore, in this final position, the circular flange 20 bears axially upstream against the radial end face 42 of the downstream axial end 34 of the support shaft 28, via the plate circular 82.

To enable the nut 64 to be screwed in, the tie rod 44 is locked in rotation by using a tool which cooperates with the flats 62 of the free downstream end 60 of the threaded rod 58.

In a fourth step represented in , the nut 64 is partially unscrewed to move it away from the downstream face 70 of the circular flange 20. This distancing of the nut 64 from the circular flange 20 makes it possible to release the notch 80 formed in the downstream face 70.

Then, the locking pin 72 is introduced into the first axial orifice 74 and into the second axial orifice 76, its head 78 is positioned in the notch 80.

Then, according to a fifth step represented in , the nut 64 is screwed again to rest against the downstream face 70 of the circular flange 20, thus tightening the circular flange 20, the rotor 12 is then securely fixed to the support shaft 28, it can then be subjected to the required tests.

After having subjected the rotor 12 to various tests, the rotor 12 is dismantled from the test bench 10, and more particularly the rotor 12 is separated from the support shaft 28.

As we can see in the , the nut 64 is unscrewed completely from the threaded rod 58. The rotor 12 is then no longer blocked in axial movement downstream relative to the support shaft by the tie rod 44, as is the pin of locking which is no longer blocked in axial movement towards the downstream in the axial orifices 74, 76 of the circular flange 20 and of the circular radial body 54.

The locking pin 72 is then dismantled.

Then, the rotor 12 is separated from the support shaft 28 by a translation of the rotor 12 downstream.

For this, and according to another aspect of the invention, the rotor 12 is driven downstream in movement by the tie rod 44.

As said previously, the tie rod 44 is connected to the support shaft 28 at its upstream axial end 46 by screwing.

Thus, by unscrewing the tie rod 44 from the support shaft 28, the tie rod 44 is moved axially downstream.

By this movement towards the downstream, the downstream axial end face 56 of the tie rod 44 comes to bear axially towards the downstream against the upstream face 66 of the circular flange 20.

The tie rod 44 then pushes the rotor 12 moving downstream relative to the support shaft 28, thus allowing the separation of the rotor 12 from the support shaft 28, in a manner opposite to the mounting of the rotor 12 on the support shaft 28 which was described previously.

The rotation of the tie rod 44 relative to the support shaft 28 is achieved by immobilizing the support shaft 28 and causing the tie rod 44 to rotate using a tool (not shown) which is engaged on the flats 62 formed at the free downstream end 60 of the threaded rod 58.

At the end of this step, the tie rod 44 and the rotor 12 are separated from the support shaft 28, the test bench 10 then finds itself in its configuration shown in .

Claims (10)

Test bench (10) for a rotor (12), in particular a turbomachine rotor,
in which the rotor (12) comprises a journal (14) consisting of a part of revolution having grooves (16) on a radially external cylindrical face and the rotor (12) comprises a flange (20) located at a downstream axial end ( 22) of the pin (14),
the test bench (10) comprising a main axis A, a fixed structure and a support shaft (28) consisting of a hollow element of revolution coaxial with the main axis A, which is mounted to rotate around the axis main A in relation to the fixed structure,
characterized in that the support shaft (28) delimits a hollow housing (36) open towards the downstream in which the pin (14) is able to be inserted and fixed in a translational movement from downstream to upstream along the main axis A. Test bench (10) according to the preceding claim, characterized in that the pin (14) is capable of being fixed in the hollow housing of the support shaft (28) by shrinking. Test bench (10) according to the preceding claim, characterized in that it comprises a tie rod (44) which is able to cooperate with the support shaft (28) and with the pin (14) for insertion and fixing the pin (14) in the hollow housing of the support shaft (28). Test bench (10) according to the preceding claim, characterized in that the tie rod (44) consists of an element of revolution coaxial with the main axis A, which is mounted in the hollow housing of the support shaft (28). ) and in an interior volume of the journal (14), the tie rod (44) comprising an upstream axial end (46) which cooperates with an internal face (38) of the support shaft (28) and a downstream axial end (52 ) which is intended to cooperate with the rotor (12). Test bench (10) according to the preceding claim, characterized in that the downstream end (52) of the tie rod (44) comprises a threaded rod (58) which is intended to pass through an associated orifice (68) of the flange ( 20) and which carries a nut (64) intended to come to bear axially against a downstream face (70) of the flange (20). Test bench (10) according to the preceding claim, characterized in that the upstream end (46) of the tie rod (44) comprises a threaded portion (50) which engages with a complementary threaded portion (48) carried by said internal face (38) of the support shaft (28). Test bench (10) according to the preceding claim, characterized in that the downstream end (52) of the tie rod (44) comprises a downstream axial end face (56) which is able to come to bear axially towards the downstream against the flange (20) and from which the threaded rod (58) extends axially downstream. Test bench (10) according to any one of claims 3 to 7, characterized in that it comprises means for locking the tie rod (44) in rotation relative to the rotor (12). Test bench (10) according to the preceding claim, in combination with claim 4, characterized in that said locking means comprise a locking pin (72) which is intended to be received simultaneously in a first axial orifice (74) formed in the downstream axial end (52) of the tie rod and in a second axial orifice (76) formed in the flange (20), in which the two axial orifices (74, 76) are capable of being matched to be placed as an extension of each other. Test bench (10) according to the preceding claim, in combination with claim 5, characterized in that the locking pin comprises a head (78) intended to be received in a complementary notch (80) formed in the downstream face ( 70) of the flange (20).