BLADE FOR A TURBOMACHINE FAN, COMPRISING AN IDENTIFICATION MEDIUM, AND METHOD FOR READING SUCH AN IDENTIFICATION MEDIUM

Abstract

A blade for a turbomachine fan, the blade being made from a composite material containing a plurality of longitudinal conductive fibres embedded in an electrically non-conductive matrix, the blade having at least one fastening region to which an identification medium for identifying the blade is fastened, the fastening region containing longitudinal fibres oriented along a preferred fibre axis, the identification medium contains an item of identification data for identifying the blade and at least one radio antenna having at least one communication lobe configured so as to receive a read request and transmit the item of identification data in return, the communication lobe being oriented along a radio axis that is angularly offset from the preferred fibre axis by less than 45°, preferably by less than 22.5°.

Claims

1-9. (canceled)

10. A vane for a fan of an aircraft turbomachine extending along an axis of the turbomachine, the vane being made of a composite material comprising a plurality of longitudinal conductive fibers embedded in an electrically non-conductive matrix, the vane comprising at least one fastening zone to which an identification medium for identifying the vane is fastened, the vane wherein the fastening zone comprises longitudinal fibers oriented along a favored fiber axis, the identification medium comprises at least one memory for storing an identification piece of data of the vane and at least one radio antenna comprising at least one communication lobe configured to receive a read request and transmit back the identification piece of data, the communication lobe being oriented along a radio axis which is angularly offset from the favored fiber axis by less than 45°.

11. The vane according to claim 10, successively comprising a mounting root configured to be axially mounted along the turbomachine axis, a platform and an air deflection blade, the at least one fastening zone belonging to the mounting root.

12. The vane according to claim 11 wherein the mounting root comprises at least one side wall, azimuthally defined in relation to the axis of the turbomachine when the vane is mounted to said turbomachine, the side wall comprising longitudinal fibers whose favored fiber axis extends substantially orthogonally to the axis of the turbomachine when the vane is mounted to said turbomachine, the at least one fastening zone belonging to the side wall.

13. The vane according to claim 11, wherein the mounting root comprises at least one upstream wall, axially defined in relation to the axis of the turbomachine when the vane is mounted to said turbomachine, an air flow circulating from upstream to downstream in the turbomachine, the upstream wall comprises longitudinal fibers whose favored fiber axis extends substantially orthogonally to the axis of the turbomachine when the vane is mounted to said turbomachine, the fastening zone belonging to the upstream wall.

14. The vane according to claim 10, successively comprising a mounting root configured to be axially mounted along the turbomachine axis, a platform and an air deflection blade, the at least one fastening zone belonging to the platform.

15. The vane according to claim 10, wherein the identification medium is of the radio frequency identification type.

16. The vane according to claim 15, wherein the identification medium is an identification medium for a metal fastening zone.

17. The vane according to claim 10, wherein the identification medium comprises an elongate shape body in which the storage memory and the radio antenna are mounted, the radio axis of the communication lobe extending along the length of the body.

18. A method for reading an identification medium of at least one fan vane according to claim 10, comprising: i. a step of receiving by radio a read request by the radio of the identification medium and ii. a step of transmitting by radio at least one identification piece of data from the storage memory by the radio antenna of the identification medium.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0031] The invention will be better understood upon reading the following description, which is given by way of example only, with reference to the appended drawings, which are given as non-limiting examples, in which identical references are given to similar objects and in which:

[0032] FIG. 1 is a schematic representation in a longitudinal cross-section view of a turbomachine according to prior art;

[0033] FIG. 2 is a schematic representation of a fan vane with an identification medium according to prior art;

[0034] FIG. 3 is a schematic representation of the identification medium of FIG. 2;

[0035] FIG. 4 is a schematic representation of a step of reading the identification data of a fan vane of a turbomachine according to the invention.

[0036] FIG. 5 is a schematic representation of a fan vane with an identification medium according to one embodiment of the invention;

[0037] FIG. 6 is a schematic representation in a longitudinal cross-section view of an identification medium according to one embodiment of the invention;

[0038] FIG. 7 is a schematic top representation of an identification medium comprising one radio lobe in the mounted position;

[0039] FIG. 8 is a schematic top representation of an identification medium comprising two radio lobes in the mounted position;

[0040] FIG. 9 is a schematic top representation of a square-shaped identification medium with one radio lobe in the mounted position;

[0041] FIG. 10 is a schematic representation of an identification medium according to the invention not comprising visual information;

[0042] FIG. 11 is a schematic representation of an identification medium according to the invention comprising visual information;

[0043] FIG. 12 is a schematic representation of a fan vane with an identification medium according to another embodiment of the invention.

[0044] It should be noted that the figures set out the invention in detail for implementing the invention, said figures can of course be used to better define the invention where appropriate.

DETAILED DESCRIPTION

[0045] With reference to FIG. 4, there is represented a turbomachine 100 extending along a turbomachine axis X and for moving the aircraft from an air flow entering the turbomachine 100 and circulating from upstream to downstream. Hereafter, the terms “upstream” and “downstream” are defined in relation to the turbomachine axis X oriented from upstream to downstream. Similarly, the terms “internal” and “external” are defined along a radial direction R defined in relation to the axis X. In a known manner, the turbomachine 100 comprises a compressor, a combustion chamber and a turbine for rotatably driving the compressor. Upstream, the turbomachine 100 comprises a fan 110 for accelerating the air flow from upstream to downstream in the turbomachine 100.

[0046] The fan 110 comprises a disc 111, rotatably integral with a shaft of the compressor, comprising housings, distributed around the periphery of the disc 111, in which vanes 1 are respectively mounted by axial insertion along the turbomachine axis X from upstream to downstream. The vanes 1 extend in a same plane transverse to the turbomachine axis X. For the sake of clarity and brevity, only one vane 1 will now be set forth. In this example, the turbomachine 100 comprises a cone 112 which is mounted upstream of the disc 111.

[0047] With reference to FIG. 5, each vane 1 extends along a radial axis R and successively comprises a mounting root 11 configured to be axially mounted along a turbomachine axis X in a housing of the disc 111 of the fan 110, a platform 12 and an air deflection blade 13 radially extending along the radial axis R in relation to the turbomachine axis X. The vane 1 radially extends in the mounted position. The mounting root 11 is thus referred to as radially internal while the air deflection blade 13 is referred to as radially external.

[0048] As illustrated in FIG. 5, the platform 12 comprises a radially external face 12A which is in the air flow, and a radially internal face 12B which is opposite to the radially external face 12A. The mounting root 11 comprises two side walls 11L, also called azimuthal walls, an upstream wall 11F and a downstream wall 11B. The walls 11L, 11B, 11F extend substantially radially along the radial axis R as illustrated in FIG. 5. The walls of the mounting root 11 are defined in relation to the way they are mounted in the turbomachine.

[0049] The vane 1 is made of a composite material comprising a plurality of longitudinal fibers F embedded in a matrix. According to the invention, the longitudinal fibers F are electrically conductive while the matrix is not electrically conductive. Preferably, the longitudinal fibers F are, in particular metallic, reinforcing fibers. In this example, the longitudinal fibers F are made of carbon, but it goes without saying that other materials could be suitable, for example aluminum or copper. The matrix is in this example thermosetting but it could be of a different kind. A vane 1 of composite material is known to the skilled person and will not be set forth in more detail.

[0050] In a known manner, in a local zone of the vane 1, the longitudinal fibers F are oriented along a favored fiber axis XF. In other words, the longitudinal fibers F are locally parallel and oriented along a favored fiber axis XF. By favored fiber axis XF, it is meant the axis to which most of the fibers F are parallel in said local zone.

[0051] In practice, the fibers F are woven in several directions, in particular in a 3D weave, of which one direction is preferred which is hereinafter referred to as “favored fiber axis XF” and which is perfectly identified during weaving.

[0052] In this example, still with reference to FIG. 5, the side wall 11L of the mounting root 11 comprises longitudinal fibers F which are oriented along a favored fiber axis XF which is substantially radial, that is orthogonal to the axis X of the turbomachine. Similarly, the upstream wall 11L of the mounting root 11 comprises longitudinal fibers F which are oriented along a favored fiber axis XF which is substantially radial, that is, orthogonal to the axis X of the turbomachine. Similarly, the platform 12 and the air deflection blade 13 comprise longitudinal fibers F.

[0053] According to the invention, with reference to FIG. 5, the vane 1 comprises at least one fastening zone to which an identification medium 3 comprising at least one identification piece of data ID1, ID2 of the vane 1, is fastened. A fastening zone is a local zone for which a favored fiber axis XF is determined.

[0054] With reference to FIG. 6, there is represented an identification medium 3 according to one embodiment of the invention.

[0055] The identification medium 3 comprises a storage memory 30 in which two identification pieces of data ID1, ID2 are stored, in particular, a serial number ID1 known as “serial number SN” and a part number ID2 known as “part number PN”. Preferably, the storage memory 30 is of the computer type and the identification data ID1, ID2 are computer data. It goes without saying that the storage memory 30 could store a single identification piece of data such as a single identifier which would make it possible to identify in a particular way a part or more than two identification pieces of data such as a manufacturer's identifier (CAGE code, etc.), a date of manufacture, a degree of sensitivity to specific fluids, an operating authorization reference, data related to the maintenance or logistical operations of the part such as the operational status, operations carried out, etc.

[0056] The identification medium 3 further comprises a radio antenna 31 configured to receive a read request REQ and to transmit back the identification data ID1, ID2. Preferably, the identification medium 3 is of the radio frequency identification type, better known as its acronym RFID. The identification medium 3 may comprise a battery or be remotely powered. Such an identification medium 3 is known to the person skilled in the art.

[0057] In a known manner, identification media of the radio frequency identification type are divided into those intended for “non-metallic” use, those intended for “metallic” use and those intended for “mixed” use. Preferably, the identification medium 3 is intended for “metallic” use. Such an identification medium 3 has a higher performance by interaction with the longitudinal fibers F of the vane 1 which are electrically conductive as will be set forth later. With reference to FIG. 6, an identification medium 3 intended for “metallic” use has a thickness E3 which is greater than 1 mm, preferably greater than 2 mm. In comparison, an identification medium 3 intended for “non-metallic” use has a thickness of less than 1 mm.

[0058] According to the invention, the radio antenna 31 comprises at least one communication lobe L1 oriented along a radio axis XR to receive a read request REQ and transmit back the identification data ID1, ID2. With reference to FIGS. 6 and 7, the radio antenna 31 comprises a single communication lobe L1, also referred to as the primary lobe, but it goes without saying that it could comprise more than one, in particular two thereof. As illustrated in FIG. 8, the radio antenna 31 may in particular comprise two communication lobes L1 aligned along a same radio axis XR. Such an identification medium 3 can thus be used along two opposite senses, along a same direction.

[0059] In this example, with reference to FIG. 6, the identification medium 3 comprises a body 32, which is in particular non-conductive, such as a polymer or ceramic material, in which the memory 30 and the radio antenna 31 are mounted. With reference to FIGS. 6 and 7, the body 32 has a rectangular shape but it goes without saying that it could be any shape, in particular a square shape or a round or wire shape.

[0060] Preferably, in the case of an elongate shape body 32, the radio axis XR extends along the length of said body 32 as illustrated in FIGS. 6 to 8. With reference to FIG. 9, when the body 32 is not elongate, the body 32 advantageously comprises a visual orientation indicator 5 of the radio axis XR as illustrated in FIGS. 9 and 10 in order to allow optimal orientation of the identification medium 3 on a fastening zone of the vane 1 by an operator as will be set forth hereafter.

[0061] As illustrated in FIG. 11, the identification medium 3 comprises the identification data ID1, ID2 as computer data but also visual identification indicators ID1V, ID2V in order to allow the identification data to be read both by radio and visually. In this example, the visual identification indicators ID1V, ID2V are printed on the body 32 of the identification medium 3. Preferably, when the dimensions of the identification medium 3 are too narrow in relation to the visual identification indicators ID1V, ID2V, the identification medium 3 only comprises the identification data ID1, ID2 as computer data as illustrated in FIG. 10.

[0062] According to the invention, with reference to FIG. 5, the identification medium 3 is fastened to a fastening zone of the vane 1 comprising longitudinal fibers F oriented along a favored fiber axis XF. Advantageously, the communication lobe L1 is oriented along a radio axis XR which is angularly offset from the favored fiber axis XF by less than 45°, preferably by less than 22.5°. Preferably, the radio axis XR is parallel to the favored fiber axis XF. Preferably, the radio axis XR and the favored fiber axis XF are aligned.

[0063] When a radio antenna 31 comprises several communication lobes L1, it is preferred that the main communication lobe L1 is aligned in accordance with the defined alignment with the favored fiber axis XF.

[0064] Advantageously, the use of an identification medium 3 intended for “metallic” use enhances interactions between the longitudinal conductive fibers F which are conductive and the radio antenna 30, thereby improving amplification. The identification data ID1, ID2 can be read from a greater distance. Preferably, a metallic interface member is positioned between the identification medium 3 and the fastening zone to improve communication performance. The metallic interface member is preferably electrically conductive (for example Al, Ti, Cu, Pt, Au, Fe, Pb, Sn, Ni or the like and combinations thereof). Preferably, the metal interface member has a thickness between 0.001 mm and 20 mm. According to one aspect of the invention, the metal interface member is mounted to the composite by bonding for an easier installation.

[0065] According to a first embodiment, with reference to FIG. 5, a side wall 11L of the mounting root 11 comprises the fastening zone of the identification medium 3. The side wall 11L has a large surface area for fastening the identification medium 3. In this example, the longitudinal fibers F of the side wall 11L of the mounting root 11 radially extend along the axis R and the identification medium 3 is oriented so that the radio axis XR is radially oriented along the axis R outwardly so as to benefit from the best communication conditions. Preferably, the identification medium 3 is fastened to a downstream portion of the side wall 11L since it has a greater radial height and many radial fibers F.

[0066] In this embodiment, since the available space is large, the identification medium 3 has an elongate shape and comprises visual identification indicators ID1V, ID2V (FIG. 11) in order to allow the identification data to be read by radio and visually.

[0067] According to a second embodiment, with reference to FIG. 12, an upstream wall 11F of the mounting root 11 comprises the fastening zone of the identification medium 3. The upstream wall 11F, also known as the scaffold pole, has a reduced surface area which nevertheless allows the identification medium 3 to be fastened. In this example, the longitudinal fibers F of the upstream wall 11F of the mounting root 11 radially extend and the identification medium 3 is oriented in such a way that the radio axis XR is radially oriented along the axis R outwardly in order to benefit from the best communication conditions.

[0068] In this example, given that the space available is small, the identification medium 3 has a reduced shape and does not comprise visual identification indicators ID1V, ID2V (FIG. 11) but only a visual orientation indicator 5 of the radio axis XR (FIG. 10).

[0069] Preferably, the identification medium 3 is fastened to the vane 1 on a zone that is not in contact with the air flow to be accelerated, that is an aerodynamic zone. Thereby, the identification medium 3 is preferably fastened to the mounting root 11 or to an internal surface 12B of the platform 12 of the vane 1. In this example, the identification medium 3 is fastened to the surface of the vane 1 but it goes without saying that it could be mounted in the composite material of the vane 1.

[0070] With reference to FIG. 4, a method for individually and collectively reading the identification data ID1, ID2 of the vanes 1 of a fan 110 of a turbomachine 100, in particular, an aircraft turbine engine, will now be set forth.

[0071] In this example, an operator P uses a radio frequency identification reading device 4, known per se to the person skilled in the art, and places himself/herself at a distance from the turbomachine 100, in particular, upstream of the latter so as to be close to the fan 110.

[0072] Using a radio frequency identification reading device 4, the operator P radio transmits a read request REQ which is radio received by the radio antenna 30 of the identification medium 3. In particular, the read request REQ is received by the communication lobe L1 of the radio antenna 30 which is amplified due to its positioning on a fastening zone whose longitudinal fibers F are aligned along a favored fiber axis XF which is substantially aligned with the radio axis XR of said communication lobe L1.

[0073] In response to the read request REQ, the radio antenna 30 of the identification medium 3 radio transmits identification data ID1, ID2 which are read by the radio frequency identification reading apparatus 4. In particular, the identification data ID1, ID2 are transmitted by the communication lobe L1 of the radio antenna 30 which is amplified as explained previously. The read identification data ID1, ID2 are stored in a computerized manner in the radio frequency identification reading device 4.

[0074] By virtue of the invention, an operator P can conveniently, quickly and without risk of error obtain the identification data ID1, ID2 of a vane 1. Furthermore, there is no need to disassemble the upstream portion of the turbomachine 100 as in prior art.

[0075] Advantageously, amplification of the communication lobe L1 makes it possible to get rid of the electromagnetic shielding induced by the disc housings 111 and by the cone 112 and to communicate to the outside optimally.

[0076] Depending on the transmitting power of the radio frequency identification reading apparatus 4 and the distance between the radio frequency identification reading apparatus 4 and the identification medium 3, an operator can read an identification medium 3 of a vane 1 individually (low power and small distance) or collectively a plurality of identification media 3 of the vanes 1 of a fan 110 (high power and large distance). In practice, reading is made at a distance of between 50 cm and 1200 cm.