MODULE FOR ATTRACTING AND DETECTING DEBRIS

Abstract

Module (60) for attracting and detecting ferromagnetic debris in an oil flow from a turbomachine, the module (60) comprising: a permanent magnet (62); a bar (64), the bottom (66) of which extends radially and is wound around a coil (70). The coil (70) is able to detect the magnetic field generated by the magnet (62) and in particular its variations when a ferromagnetic particle comes into the vicinity of the magnet (62).

Claims

1.-15. (canceled)

16. A module for attracting and detecting ferromagnetic debris in an oil flow of a turbomachine, the module comprising: a permanent magnet of a cylindrical shape; a ferromagnetic bar composed of a foot rising radially from the magnet and a cap extending circumferentially from, or perpendicular to the foot; and a coil wound around the foot.

17. The module according to claim 16, wherein the coil is wound around a winding support threaded onto the foot.

18. The module according to claim 16, wherein the cap comprises two ends circumferentially opposite and each formed of a cylinder portion.

19. The module according to claim 18, wherein the two ends are spaced from each other by a distance substantially equivalent to the diameter of the magnet.

20. The module according to claim 18, wherein the portions of cylinders forming the two ends comprise a diameter which is approximately equal to a circumferential width of the foot, and is between 1.5 and 2.5 mm.

21. The module according to claim 16, wherein the foot comprises a circumferential width which is between 25% and 50% of a diameter of the magnet.

22. The module according to claim 16, wherein the foot comprises a radial height which is approximately 50% of a diameter of the magnet.

23. The module according to claim 16, wherein the ferromagnetic bar comprises an axial length which is equal to an axial length of the magnet.

24. The module according to claim 16, wherein the ferromagnetic bar is a first bar, the module comprising a second bar arranged diametrically opposite to the first bar.

25. The module according to claim 16, wherein the magnet comprises two diametrically opposed poles, the or each bar being arranged to the right of a pole.

26. The module according to claim 16, wherein said module further comprises a strainer describing at least one cylindrical portion and arranged coaxially with the magnet.

27. A system for detecting ferromagnetic debris in an oil flow of a turbomachine, the system comprising a passage intended to be traversed by the flow and a module for attracting and detecting the ferromagnetic debris present in the flow, wherein the module comprising: a permanent magnet of a cylindrical shape; a ferromagnetic bar composed of a foot rising radially from the magnet and a cap extending circumferentially from, or perpendicular to the foot; and a coil wound around the foot.

28. The system according to claim 27, wherein the module is positioned in the passage in such a way that an axis of the cylindrical shape is perpendicular to a direction of the oil flow in the passage, the cap being arranged upstream of the magnet.

29. An aircraft turbojet engine comprising a lubrication group made of a one-piece body receiving several pumps and filters, several oil inlets and outlets, and a system for detecting debris, wherein the system for detecting debris comprising a passage intended to be traversed by the flow and a module for attracting and detecting the ferromagnetic debris present in the flow, wherein the module comprising: a permanent magnet of a cylindrical shape; a ferromagnetic bar composed of a foot rising radially from the magnet and a cap extending circumferentially from, or perpendicular to the foot; and a coil wound around the foot; and said system for detecting debris is arranged in an oil inlet (40, 42) upstream of the pumps and filters.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0033] FIG. 1 represents an axial turbomachine according to the invention;

[0034] FIG. 2 illustrates an isometric view of the body of a lubrication group;

[0035] FIG. 3 shows an example of a debris detection system according to the invention;

[0036] FIG. 4 shows a debris attraction and detection module according to the invention;

[0037] FIG. 5 shows a sectional view of the module;

[0038] FIG. 6 shows the field lines in the section of FIG. 5;

[0039] FIG. 7 shows a variant of the attraction and detection module;

[0040] FIGS. 8 and 9 show a module comprising a strainer;

[0041] FIG. 10 illustrates an alternative with a parallelepiped cap.

DESCRIPTION OF EMBODIMENTS

[0042] In the description which follows, the term magnet refers to a permanent magnet. The flow of flux in the passage at the level of the magnet takes place in a main direction of flow which is transverse to the module (perpendicular or simply secant). Upstream and downstream are understood in relation to the direction of flow of the oil flow in the passage.

[0043] FIG. 1 represents an example of a double-flow turbojet. The turbojet 2 comprises a low-pressure compressor 4, a high-pressure compressor 6, a combustion chamber 8 and one or more levels of turbines 10. In operation, the mechanical power of the turbines 10 is transmitted via shafts to the rotor 12 and sets in motion the two compressors 4 and 6. The rotation of the rotor around its axis of rotation 14 makes it possible to generate an air flow and to progressively compress the latter until it enters the combustion chamber 8.

[0044] A fan 16 is coupled to the rotor 12 and generates an air flow which is divided into a primary flow 18 passing through the different aforementioned levels of the turbomachine, and a secondary flow 20 passing through an annular duct. Reduction means 22 can reduce the rotational speed of the fan 16 and/or the low-pressure compressor 4 relative to the speed of the associated turbine 10.

[0045] The rotor 12 comprises several coaxial shafts 24 supported by bearings 26. The cooling and/or lubrication of the bearings 26 and the optional reduction gear 22 are ensured by a lubrication circuit 28. The lubrication circuit 28 may include a heat exchanger. heat 30 to cool the oil whose temperature can exceed 200? C.

[0046] The lubrication circuit 28 may include oil recovery lines 32 collecting the oil in the lubrication enclosures of the bearings 26 and conveying it to the reservoir 34. It may also include a line 32 for recovering the lubricating oil the reducer 22 and returning this oil to the tank 34.

[0047] In order to force the circulation of the oil during its recovery, the lubrication circuit 28 can include a lubrication group 36. The lubrication group 36 is a unit composed of a one-piece body which accommodates several hydraulic functions such as for example several pumps and filters. It pressurizes the oil taken from the tank and distributes it to the engine components which need to be lubricated. Then, the lubrication group 36 reconditions the oil (cooling, filtration, monitoring) and returns it to the tank 34.

[0048] FIG. 2 illustrates an example in isometric view of a body 38 of lubrication group 36.

[0049] The body 38 can be manufactured by additive manufacturing and be of particularly complex shape. The body 38 can be in one piece. It may include several oil inlets 40, 42 to suck the oil from the reservoir or from the components of the turbomachine and several oil outlets 41, 43 to discharge the oil towards the reservoir or towards the components of the turbomachine. Respective passages connect the entrances to the exits. Some passages may be completely independent of other passages.

[0050] Group 36 can be equipped with numerous functions and contain several pumps and several filters. According to the invention, group 36 can also contain a ferromagnetic debris detection system.

[0051] FIG. 3 schematically shows a debris detection system 45 according to the invention. A passage 50, for example in the vicinity of the entrance 42, accommodates an attraction and detection module 60 of ferromagnetic particles. This protrudes into passage 50. It can occupy the entire height/width of the passage or less. Its projecting length and orientation can be adjusted mechanically by appropriate means (electric motor, screw, piston, etc.).

[0052] The detection system 45 makes it possible to detect the presence and/or circulation of ferromagnetic debris, or ferromagnetic particles, contained in the oil. This debris can in particular result from wear of a bearing or wear of a gear tooth of the reducer 22. Module 60 can be connected to a signal processing unit (not shown). The processing unit manages to identify the presence of debris at each pipe. Detectable debris can be between 50 ?m and 1000 ?m in size, or between 150 ?m and 750 ?m.

[0053] FIG. 4 shows an example of a detection module 60. The module 60 comprises a magnet 62 of cylindrical shape and axis A. The magnet can be of the NdFeB type and preferably SmCo (Samarium-Cobalt), retaining its properties at a temperature of 350? C.

[0054] The magnet is chosen not to be too powerful, so as not to capture all the particles and saturate the detection module. The main objective remains statistical detection and monitoring of the increase in the number of particles. For example, the magnet could be chosen according to the oil flow it encounters. A magnet with a coercivity of around 800 kA/m could be chosen to target particles with a size of around 500 microns.

[0055] In the following, the references axial, radial and circumferential relate to the magnet 62, axial being understood as parallel to the axis A, radial being understood as perpendicular to the axis A and circumferential being such that the axial, radial and circumferential directions form a cylindrical coordinate system (A, R, T).

[0056] The module 60 further comprises a ferromagnetic bar 64 (for example made of M50 steel) attached to the magnet 62. The bar 64 can extend over the entire axial length L of the magnet 62.

[0057] The bar 64 comprises a foot 66 rising radially from the magnet 62 and a cap 68 extending circumferentially on either side of the foot 66.

[0058] A coil 70 is wound around the foot 66. The coil 70 can include several tens or hundreds of turns. The coil 70 detects variations in the magnetic field: when a ferromagnetic particle attracted by the bar 64 passes near the magnet 62, the magnetic field generated by the magnet 62 is disturbed and these disturbances are measured by the coil 70.

[0059] The magnet 62 has the dual role of attracting the ferromagnetic debris found in the oil flow (attraction amplified by the bar 66) and of generating a magnetic field detectable by the coil 70.

[0060] Generally speaking, the detection technology used is similar, for example, to the technology disclosed in document WO 2017/157855 A1 or in document EP 3 363 518 A1.

[0061] Thus, when a ferromagnetic particle arrives near the magnet 62, it modifies the magnetic field and creates discontinuities in the intensity of the coil 70. When the variations exceed a given threshold, the module 60 recognizes that a ferromagnetic particle has passed.

[0062] FIG. 5 shows a section of the module 60 in a plane perpendicular to the axis A. It can be seen that the bar 64 can have a mushroom shaped section.

[0063] The magnet 62 can have a diameter D of approximately 5 mm.

[0064] The foot 66 has a circumferential width e and a radial height h. The width e characterizes the concentration of the field lines. The height h materializes the radial distance between the cap 68 and the magnet 62.

[0065] The width e can be between 25% and 50% of the diameter D of the magnet 62, and be worth for example approximately 2.5 mm. The cap 68 extends radially with a width E approximately equal to the diameter D.

[0066] The radial height h can be approximately 50% of the diameter D of the magnet 62, the cap thus being distant from the center of the magnet by 4 to 6 mm, and in particular by 4.6 mm.

[0067] In a preferred embodiment, the ends 68.1 and 68.2 of the cap 68 have the shape of a cylinder portion of diameter d.

[0068] In one embodiment, the value of d may be approximately equal to e. The values of d and e can for example be between 1.5 and 2.5 mm, and are preferably worth around 1.75 mm or around 2 mm.

[0069] In a variant, the distance between the two centers of the cylinder portions 68.1, 68.2 is between 5 and 7 mm, preferably 6.5 mm.

[0070] The coil 70 can be housed in grooves provided in the foot 66 or alternatively, as shown in FIG. 5, a cage 72 of non-magnetic material can confine the coil 70. The cage 72 can thus be a support for the coil, threaded around foot 66.

[0071] In an embodiment not illustrated, the module includes an additional coil, called Built-in test making it possible to generate a magnetic field and check the response of the coil 70, for example before starting up a turbojet.

[0072] The radially external surface 68.3 of the cap 68 as well as the cylinder portions 68.1, 68.2 constitute the debris attraction surfaces. They are particularly advantageous for attracting particles because they have a large surface area with a small footprint.

[0073] The surface 68.3 can be generally cylindrical with a diameter twice that of the magnet, for example 10 mm.

[0074] FIG. 6 shows the field lines of the magnetic field generated by the magnet. This figure highlights in particular the concentration of the field lines across the foot 66.

[0075] FIG. 7 illustrates an alternative where two bars 64 are arranged diametrically on each side of the magnet 62. The bars 64 can be positioned to the right of the N/S poles of the magnet.

[0076] FIG. 8 shows an implementation of the module 60 with a strainer 80. The strainer comprises a filtration mesh 82 extending from a base 84 towards a ceiling 86. The base 84 and the ceiling 86 can correspond to an orifice made in a pipe 51 delimiting the passage 50. Alternatively, the strainer may occupy only part of the passage 50. Suitable joints and mounting means (not shown) may be provided.

[0077] The magnet 62 and the bar 64 can be welded to the base 84 of the strainer 80.

[0078] Alternatively, a tight or crimped assembly can be used. The mesh 82 can take the form of a cylinder or a portion of a cylinder, for example extending over 180? around the axis A. The mesh 82 and the magnet 62 are advantageously coaxial.

[0079] The mesh size of the mesh 82 can be greater than or equal to 500 ?m, to prevent the largest particles (greater than a size of the order of 500 to 1000 ?m) from damaging the pumps. Filtration elements placed downstream of the pumps can be provided to protect the motor components (injectors, enclosures) with filtration of the order of 10 to 150 ?m.

[0080] The strainer 80 can be made entirely, including with its mesh 82, by additive manufacturing.

[0081] The axis A intersects the main direction of the flow F, preferably perpendicular.

[0082] The magnet 62 and the bar 64 extend over all or part of the height of the strainer 80.

[0083] FIG. 9 illustrates these aspects in a sectional view along the axis IX:IX of FIG. 8.

[0084] In this example, the flow F first encounters the bar 64, then the magnet 62, then the mesh 82. Alternatively, another orientation around the axis A can be favored for the bar 64 and the magnet 62.

[0085] FIG. 9 also shows the order of magnitude of the ratio between the diameter of the magnet 62 and that of the mesh 82 which can be of the order of 3.

[0086] In an embodiment not illustrated, the module 60 is arranged in an elbow of a pipe such that the axis A is substantially parallel to the flow.

[0087] FIG. 10 illustrates an alternative in which the hat is of parallelepiped shape. Such a design has substantially the same advantages as the shape described in FIGS. 4 to 9.

[0088] The different aspects presented in FIGS. 4 to 9 can be applied to such a magnet, in particular semi-cylindrical ends and ends of such a magnet can be planar or semi-cylindrical, the dimension ratios, the presence of two magnets at 180?, integration into a strainer, etc.