FR3122493A1 - LEAK TEST DEVICE PROVIDED WITH A SYSTEM FOR CONTINUOUSLY ADJUSTING THE CLEARANCE BETWEEN TWO ELEMENTS OF A LABYRINTH SEAL - Google Patents

Abstract

The invention relates to a permeability machine (8) intended to carry out a permeability test of a labyrinth seal (1) comprising: - a cartridge (20) comprising a first element (2) of said labyrinth seal (1) provided with wipers called "wiper element", and - at least one support (21) carrying a second element (5) of said labyrinth seal (1) made of an abradable material, called "abradable element", and - a system ( 27) for adjusting a clearance between the wiper element (2) and the abradable element (5) configured in such a way that a rotational movement of an adjustment wheel (28) generates a following translational movement a first direction of a slider (38) which moves in translation a support (21) of the abradable element (5) in a second direction so as to be able to continuously vary the play between the abradable element (5) and the wiper element (2). Figure 4

Description

LEAK TEST DEVICE PROVIDED WITH A SYSTEM FOR CONTINUOUSLY ADJUSTING THE CLEARANCE BETWEEN TWO ELEMENTS OF A LABYRINTH SEAL

The present invention relates to a leak test device provided with a system for continuously adjusting the clearance between two elements of a labyrinth seal. The invention finds a particularly advantageous, but not exclusive, application with labyrinth seals used in aircraft engines.

As part of the development of new aircraft engines, partial permeability tests are carried out to optimize the ventilation circuits as well as the associated sealing devices placed at various locations in the engine between a rotor and a stator. These sealing devices generally take the form of labyrinth seals described in particular in the document FR3011608.

In a manner known per se, a labyrinth seal 1 shown in the comprises a first element 2 located on the side of the rotor provided with wipers 3, that is to say projecting circular ridges. In addition, a second element 5 made of an abradable material is intended to be placed on the side of the stator. The second element has a profile in the form of steps 6 arranged opposite the wipers 3. These elements 2 and 5 separate a surrounding volume into two enclosures which can be subjected to different pressures. A small clearance 7 separates the wipers 3 from the steps 6 of the abradable element 5.

Figures 1a to 1d show different configurations of single-stage type labyrinth seals. These figures show that the wipers 3 of the joint 1 can be stepped or not. The shape of the steps 6 arranged opposite the lips 3 is also variable from one figure to another. In a crocodile-like maze configuration shown on the , the element 2 has two rows of wipers 3 and two abradable elements 5 arranged on either side of the element 2. The arrows F correspond to an air flow.

There are tools for testing the permeability of different labyrinth profiles. The objective of the tests is to quantify the pressure drops of the system as a function of the clearance 7 between the wipers 3 and the abradable element 5. To this end, an air flow is measured upstream and downstream of the system of tightness to be tested.

The test vehicle used to perform the leak tests is called a "permeability machine". This machine comprises a duct in which the labyrinth profiles are arranged facing each other. These profiles are made in the form of two-dimensional profiles and not in the form of 360° parts as on the engines.

As illustrated by the , the permeability machine 8 is connected to an air inlet 9 via a stilling tank 12. For this purpose, the permeability machine 8 is mounted on a support plate 13 via a seal 14. The support plate 13 is hermetically fixed to one end of the tank 12 via another seal 15. The air inlet 9 opens on the side of an opposite end of the tank 12. The tank 12 can be mounted on a support 16 installed on a table 17.

Conventionally, a test assembly is used involving as many couples {labyrinth; game} as many configurations to test. As illustrated by the , the play 7 between the elements 2 and 5 of the seal 1 is created by means of wedges 19. However, the play 7 obtained during testing by such a system depends on the manufacturing tolerances of the parts. In addition, due to the discrete clearance configurations, it is necessary to manufacture as many wedges 19 as clearance configurations to be tested. Consequently, in the event of an additional clearance configuration to be tested, it is necessary to manufacture new shims 19.

• au moins une molette de réglage montée rotative par rapport au bâti et bloquée en translation par rapport au bâti,
• au moins un coulisseau lié à la molette de réglage par l'intermédiaire d'une liaison hélicoïdale, ledit coulisseau étant apte à être guidé en translation par rapport au bâti,
• ledit coulisseau étant en appui plan incliné avec le support de l'élément abradable,
• de telle façon qu'un mouvement de rotation de la molette de réglage engendre un déplacement en translation suivant une première direction du coulisseau lequel déplace en translation le support de l'élément abradable suivant une deuxième direction de manière à pouvoir faire varier de façon continue le jeu entre l'élément abradable et l'élément à léchettes.

The invention aims in particular to effectively remedy the aforementioned drawbacks by proposing a permeability machine intended to carry out a permeability test of a labyrinth seal comprising:
- a frame,
- a cartridge comprising a first element of said labyrinth seal provided with wipers called "wiper element", and
- at least one support carrying a second element of said labyrinth seal made of an abradable material, called "abradable element",
- said permeability machine further comprises a system for continuously adjusting a clearance between the wiper element and the abradable element comprising:

• at least one adjustment knob rotatably mounted relative to the frame and locked in translation relative to the frame,
• at least one slider linked to the adjustment knob via a helical link, said slider being capable of being guided in translation relative to the frame,
• said slider resting on an inclined plane with the support of the abradable element,
• in such a way that a rotational movement of the adjustment knob generates a translational movement in a first direction of the slider which moves the support of the abradable element in translation in a second direction so as to be able to continuously vary the clearance between the abradable element and the wiper element.

The invention thus makes it possible to pass from a "discreet" adjustment with shims to a "continuous" type adjustment of the clearance between the wipers and the abradable element of the seal, which avoids having to establish in advance the list of game values to explore. It is thus possible to test without constraint a multitude of play values between the elements of the joint. The clearance can also be finely adjusted and no longer depends on the manufacturing tolerances of the components to be tested and the adjustment shims. Additional clearance configurations can therefore be implemented on the test bench without additional manufacturing time. The invention also makes it possible to reduce the number of parts to be manufactured as well as the duration of occupation of the test bench.

According to one embodiment of the invention, said permeability machine comprises a plate for blocking the adjustment knob in translation.

According to one embodiment of the invention, the frame comprises an air inlet duct opening into a test space where the wiper element and the abradable element of the labyrinth seal are arranged.

According to one embodiment of the invention, an assembly formed by the slider and the support carrying the abradable element is arranged inside a housing opening out towards the test space.

According to one embodiment of the invention, said permeability machine comprises a cover for closing the housing.

According to one embodiment of the invention, said permeability machine comprises a locking screw inserted in a through opening of the closure cover, said locking screw being provided with one end coming to bear against a face of the support of the abradable element .

According to one embodiment of the invention, said permeability machine comprises two supports each carrying an abradable element, said supports being arranged on either side of a wiper element provided with a double row of wipers in the case of a configuration of seal to be tested of the crocodile labyrinth type.

According to one embodiment of the invention, the wiper element and the abradable element are made in the form of two-dimensional profiles.

According to one embodiment of the invention, the first direction of translation and the second direction of translation are perpendicular to each other.

According to one embodiment of the invention, the first direction of translation is preferably a horizontal direction while the second direction of translation is a vertical direction.

The present invention will be better understood and other characteristics and advantages will become apparent on reading the following detailed description comprising 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, if necessary, contribute to its definition, on which:

Figures 1a to 1e, already described, are cross-sectional views of examples of labyrinth seal configurations;

There , already described, shows a permeability machine connected to a test bench for performing sealing tests on labyrinth seals;

There , already described, is a cross-sectional view of a conventional system for adjusting clearance between a wiper element and an abradable element of a labyrinth seal based on the use of discrete shims;

There is an exploded perspective view of a permeability machine according to the present invention provided with a system for continuously adjusting the clearance between a wiper element and an abradable element of a labyrinth seal;

There is a schematic representation of a kinematics of a continuous clearance adjustment system integrated into the permeability machine of the ;

There is a sectional view illustrating the mechanical connection of an adjustment wheel with a frame and a slider of the continuous clearance adjustment system;

There is a perspective view from above of a continuous clearance adjustment system integrated into the permeability machine according to the invention;

There is a cross-sectional view of a continuous clearance adjustment system used with a crocodile-type labyrinth seal configuration.

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

Furthermore, in the rest of the description, the relative terms of the “horizontal”, “vertical”, “upper”, “lower” type are understood to refer to a permeability machine in the position of use on a bench of essay.

There shows a permeability machine 8 according to the invention intended to carry out a permeability test of a labyrinth seal 1. The labyrinth seal 1 comprises a first element 2 provided with wipers called "wiper element" and a second element 5 made in an abradable material, called "abradable element 5". The seal 1 may be chosen from those shown in Figures 1a to 1e.

In the context of carrying out a leak test, the wiper element 2 and the abradable element 5 are produced in the form of two-dimensional profiles and not in the form of 360° parts as on engines.

A cartridge 20 comprises the wiper element 2, while the abradable element 5 is carried by a support 21. A frame 22 of the permeability machine 8 comprises an air inlet duct 24 opening into a test space 25 where the wiper element 2 and the abradable element 5 are arranged.

In addition, a system 27 makes it possible to ensure continuous adjustment of a clearance 7 between the wiper element 2 and the abradable element 5.

This clearance adjustment system 27 comprises an adjustment wheel 28 rotatably mounted relative to the frame 22 and locked in translation relative to the frame 22. For this purpose, as can be seen in the , the adjustment knob 28 is extended by a rod 30 inserted inside a through opening 31 made in a wall of the frame 22. A seal 32 seals the assembly.

A plate 34 provides locking in translation of the adjustment wheel 28. This plate 34 is intended to retain a collar 35 coming from the rod 30 of the adjustment wheel 28. The collar 35 is arranged inside a cavity 36 of the frame 22 closed by the blocking plate 34. The blocking plate 34 is fixed to the frame 22 by means of fixing elements, such as screws, or rivets or any other fixing element suitable for the application. .

As can be seen in FIGS. 4 to 7, a slider 38 is linked to the adjusting wheel 28 via a helical link 39. For this purpose, as illustrated by the , the rod 30 connected to the adjustment knob 28 has a threaded end cooperating with a threaded hole 40 made in the slider 38 so as to create a screw-nut type connection. The slider 38 is guided in translation relative to the frame 22.

The slider 38 is in inclined plane support with the support 21 of the abradable element 5. For this purpose, the slider 38 has at least one inclined face 41 pressed against a corresponding inclined face 42 of the support 21. An angle of the inclined plane is of the order of 45 degrees with respect to a horizontal plane (cf. ). As can be seen in Figures 4 and 7, the slider 38 may include a groove 43 for receiving a rib 47 of the support 21 in order to facilitate guiding during relative movement of these two parts. The support 21 is capable of being guided in translation relative to the frame 22.

Thus, as can be seen in the , a rotational movement of the adjusting wheel 28 along the arrow 48 generates a translational movement of the slider 38 in a first direction 49 which moves the support 21 carrying the abradable element 5 in translation in a second direction 50 of translation so to be able to continuously vary the clearance 7 between the wiper element 2 and the abradable element 5. The first direction 49 of translation and the second direction 50 of translation are perpendicular with respect to each other. The first direction 49 of translation is preferably a horizontal direction while the second direction 50 of translation is a vertical direction.

A movement in one direction of rotation of the adjustment knob 28 makes it possible to bring the abradable element 5 closer to the wiper element 2 so as to reduce the clearance 7. While a movement in an opposite direction of rotation of the adjustment wheel 28 makes it possible to move the abradable element 5 away from the wiper element 2 so as to increase the clearance 7.

In the example shown in Figures 4 and 8, the permeability machine 8 comprises two sets 52.1, 52.2 each formed by a slider 38 and a support 21 carrying the abradable element 5.

A first assembly 52.1 is arranged inside an upper housing 53.1 opening out towards the test space 25. The upper housing 53.1 comprises two walls 54 providing guidance in translation of the slider 38 relative to the frame 22. The upper face of the housing 53.1 is closed by a closing cover 56.

A locking screw 57 inserted into an opening passes through the closure cover 56. The locking screw 57 is provided with one end bearing against a face of the support 21 so as to guarantee the inclined plane support between the slider 38 and support 21, as shown in figure .

A second assembly 52.2 is arranged inside a lower housing 53.2 opening out towards the test space 25. The underside of the housing 53.2 is closed by a closure cover 56.

The translational guidance of the slider 38 relative to the frame 22 is ensured by means of a first wall 58 of the housing 53.2 and of a second wall 59 made in the closure cover 56.

The cartridge 20 comprising the wiper element 2 is arranged between the two housings 53.1 and 53.2. The cartridge 20 may have the shape of a drawer inserted inside the test space 25.

In the case of a labyrinth seal configuration 1 crocodile, it is thus possible to provide two supports 21 each carrying an abradable element 5 and arranged on either side of a wiper element 2 provided with a double row of wipers 3, namely a row 60.1 of upper wipers 3 and a row 60.2 of lower wipers 3.

In this case, a portion of an injected air flow 61 passes through the space 7 extending between the upper abradable element 5 and the row 60.1 of upper wipers, then is deflected by a deflector 62 towards the space between the lower abradable element 5 and a row of lower wipers 60.2 before being evacuated through a through hole 63 made in the cover 56 of the lower housing 53.2.

The two adjustment knobs 28 make it possible to independently adjust the clearance 7 between the upper abradable element 5 and the row of upper wipers 60.1 and the clearance 7 between the lower abradable element 5 and the lower row of wipers 60.2.

As a variant, the permeability machine 8 could of course comprise a single housing containing a single "slider-abradable element support" assembly in the case where the seal is of the single-stage type.

Of course, the different features, variants and/or embodiments of the present invention can be associated with each other in various combinations insofar 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 a person skilled in the art may consider in the context of the present invention and in particular all combinations of the various modes of operation described previously, which may be taken separately or in combination.

Claims (10)

Permeability machine (8) intended to carry out a permeability test of a labyrinth seal (1) comprising:
- a frame (22),
- a cartridge (20) comprising a first element (2) of said labyrinth seal (1) provided with wipers called "wiper element", and
- at least one support (21) carrying a second element (5) of said labyrinth seal (1) made of an abradable material, called "abradable element",
characterized in that said permeability machine (8) further comprises a system (27) for continuously adjusting a clearance (7) between the wiper element (2) and the abradable element (5) comprising:
- at least one adjustment knob (28) rotatably mounted relative to the frame (22) and locked in translation relative to the frame (22),
- at least one slider (38) connected to the adjustment knob (28) via a helical connection (39), said slider (38) being able to be guided in translation relative to the frame (22),
- said slider (38) resting on an inclined plane with the support (21) of the abradable element (5),
- in such a way that a rotational movement of the adjusting wheel (28) generates a translational movement in a first direction (49) of the slider (38) which moves the support (21) of the abradable element ( 5) in a second direction (50) so as to be able to continuously vary the clearance (7) between the abradable element (5) and the wiper element (2). Permeability machine according to Claim 1, characterized in that it comprises a plate (34) for blocking the adjustment knob (28) in translation. Permeability machine according to Claim 1 or 2, characterized in that the frame (22) comprises an air inlet duct (24) opening out into a test space (25) where the wiper element (2 ) and the abradable element (5) of the labyrinth seal (1). Permeability machine according to Claim 3, characterized in that an assembly (52.1, 52.2) formed by the slider (38) and the support (21) carrying the abradable element (5) is arranged inside a housing (53.1, 53.2) leading to the test space (25). Permeability machine according to Claim 4, characterized in that it comprises a cover (56) for closing the housing. Permeability machine according to Claim 5, characterized in that it comprises a locking screw (57) inserted in a through opening of the closure cover (56), said locking screw (57) being provided with an end coming bearing against a face of the support (21) of the abradable element (5). Permeability machine according to any one of Claims 1 to 6, characterized in that it comprises two supports (21) each carrying an abradable element (5), the said supports (21) being arranged on either side of a wiper element (2) provided with a double row of wipers in the case of a configuration of seal to be tested of the crocodile labyrinth type. Permeability machine according to any one of Claims 1 to 7, characterized in that the wiper element (2) and the abradable element (5) are produced in the form of two-dimensional profiles. Permeability machine according to any one of Claims 1 to 8, characterized in that the first direction (49) of translation and the second direction (50) of translation are perpendicular to each other. Permeability machine according to Claim 9, characterized in that the first direction (49) of translation is preferably a horizontal direction while the second direction (50) of translation is a vertical direction.