Method for separation of a metallic element glued to an element made of a composite material

Abstract

The invention relates to a method of separating at least one portion of a metallic part (3) glued to a composite material part (2) of the carbon-epoxy type, comprising a step to degrade the glued interface between the metallic part (3) and the composite material part (2). The metallic part (3) and the composite material part (2) are electrically connected to a dc electrical voltage generator so that an electrical potential difference can be applied to them to generate partial discharges in the glued interface to degrade the interface.

Claims

1. A method of separating at least one portion of a metallic leading edge glued to a blade body made of a composite material of the carbon-epoxy type, comprising a step to degrade the glued interface between the metallic leading edge and the blade body, in which the metallic leading edge and the blade body are electrically connected to a dc electrical voltage generator so that an electrical potential difference can be applied to the metallic leading edge and the blade body to generate partial discharges in the glued interface to degrade the interface, wherein the blade body comprises a root through which the blade body is electrically connected to the electrical voltage generator and assembling a guard made of electrically insulating material surrounding a portion of the root of the blade body to form an electrically insulating screen extending between the metallic leading edge and the root to prevent an appearance of an electric arc between the root and the metallic leading edge.

2. The method according to claim 1, wherein the guard is an electrically insulating elastomer part comprising a central opening arranged to hold the root by squeezing the root.

3. The method according to claim 2, wherein the guard comprises two complementary parts joined together to surround the root.

4. The method according to claim 1, comprising a prior metallisation operation of a face of the root to apply voltage to most of the fibres of the composite material from which the blade body is made.

5. The method according to claim 4, wherein metallisation is done by depositing a metallic layer of copper, aluminium, silver or gold by cold plasma.

6. The method according to claim 4, wherein metallisation is achieved by application of a copper or aluminium adhesive tape on the root to connect the root to the voltage generator.

7. The method according to claim 1, wherein the glued interface degradation step is implemented within an electrically insulating fluid.

8. The method according to claim 7, wherein the electrically insulating fluid is pressurized nitrogen.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a lateral view of a blade comprising a body made of composite material onto which a metallic leading edge is glued;

(2) FIG. 2 is a lateral view of a blade comprising a body made of composite material to which a metallic leading edge is glued using electrical means of connecting the root and the leading edge;

(3) FIG. 3 is a lateral view of a blade comprising a body made of composite material to which a metallic leading edge is glued using electrical means of connecting the root and the leading edge and a guard surrounding the root;

(4) FIG. 4 is a side view showing separation of a metallic leading edge from a blade body made of a composite material.

DETAILED PRESENTATION OF PARTICULAR EMBODIMENTS

(5) On FIG. 1, a turbojet fan blade 1 made of a composite material, comprises a body 2 actually made of a composite material such as a carbon-epoxy type composite, to which a metallic leading edge 3 is fixed by gluing, this leading edge in this case being made of a titanium based alloy.

(6) The body 2 comprises a root 4 or base through which it will be fixed to a rotor element of the motor, and at which composite material fibres of the blade body terminate with their ends flush with the surface.

(7) The basic concept of the invention is to set up a dc electrical potential difference between the metallic leading edge and the blade body made of a composite material so as to cause partial discharges between these two elements, in other words at the glue forming their interface to deteriorate this glue.

(8) To establish this potential difference, each of the metallic leading edge 2 and the blade root 4 are connected to a dc voltage generator not shown.

(9) To achieve this, the root 4 of the blade 1 is metallised to deposit a metallic layer 6 on its face on which the carbon fibres terminate, to apply a voltage to the vast majority of carbon fibres forming the blade body.

(10) This metallisation can be obtained by application of aluminium or copper adhesive tape available on the market, the necessary glue film only applying a negligible electrical resistance. This metallisation can also be obtained by the formation of a metallic deposit of copper, aluminium or gold added in the form of metallisation deposited by cold plasma.

(11) As can be seen on FIG. 2, an electrode 7 is then added on the metallised face 6 and being electrically connected to this face. Connection of this electrode 7 to a terminal of the voltage generator can thus bring the vast majority of carbon fibres of the blade body 2 to the same potential, by connecting the dc voltage generator to the negative terminal.

(12) Concerning the metallic leading edge 3, an electrode identified by the mark 8 on FIG. 2 is glued or brazed on this leading edge. This electrode can comprise a portion 9 that extends along the entire length of this leading edge and being glued or brazed to it, and that is prolonged by an end 11 oriented perpendicular to the leading edge, and that will be connected to the positive terminal of the voltage generator. Alternatively, a crocodile clip can be applied directly on the leading edge to squeeze it and be connected to the positive terminal of the dc voltage generator.

(13) Furthermore, a guard made of an electrically insulating material identified by the mark 12 on FIG. 3 is added onto the blade root so as to surround it. This guard 12 is arrange to form an insulating screen designed to prevent the formation of an electric arc between the metallised face 6 of the blade root 4, and the end 13 of the leading edge that is closest to this root.

(14) This guard 12 that is advantageously fabricated from a flexible material such as a silicone elastomer or polyurethane forms a wall arranged to increase the distance to be travelled by an electric arc from the blade root 4 to an end 13 of the leading edge 3. This guard can also be fabricated from a cycloaliphatic epoxy, or mica/silicone or mica/epoxy material or any other appropriate material.

(15) In the example in FIG. 3, this guard 12 comprises a bottom wall 14 with a generally oval contour comprising a central opening designed so that the blade root 4 can pass through it. When this guard is in place as in FIG. 3, it forms an electrically insulating partition interposed between the metallised face 6 and the end 13 of the metallic leading edge 3.

(16) The choice of a flexible material for this guard makes it possible to apply pressure around the blade root so as to squeeze it and provide electrical insulation between the blade root and the leading edge.

(17) Due to this guard, the shortest path so that an arc is formed between the metallised face 6 and the leading edge 3 that is shown in dashed lines on FIG. 3, being identified by Ch, necessarily bypasses the wall 14. This path Ch is thus significantly longer than the distance separating the metallised wall 6 from the metallic end 13 of the leading edge.

(18) As can be seen on FIG. 3, the top face of the bottom wall 14 of the guard 12 supports two concentric circumferential walls identified by marks 16 and 17 each of which surrounds the blade root 4. Similarly, the bottom face of the guard 12 supports two other walls of the same type identified by marks 18 and 19, that are also concentric and surround the metallised face 6 and the electrode 7, projecting from this metallised face 6.

(19) The wall 16 is shaped like a closed ribbon surrounding the root 4 and extending perpendicular to the top face of the bottom wall 14 that supports it. The wall 17 has the same shape as the wall 16 that it surrounds. The walls 18 and 19 are symmetric with walls 18 and 19 respectively about the plane of the bottom wall 14 that is generally plane, they can even further lengthen the path separating the blade root and the leading edge.

(20) This guard 12 can be formed from two complementary parts nesting into each other so as to squeeze it and form an electrically insulating screen around this root.

(21) When the blade 1 to be treated has been prepared, in other words when the bottom face 6 of its root has been metallised and an electrode 7 has been fixed to it, and an electrode 8 has also been fixed to the leading edge 3 to be electrically connected to it, the guard 12 is mounted around the root 4 before applying the treatment itself.

(22) The electrode 8 of the leading edge 3 is then connected to a positive terminal of the voltage generator, and the electrode 7 of the blade body is connected to the negative terminal of the voltage generator, for example using crocodile type clips.

(23) The generator is then manipulated to increase the applied voltage up to a voltage value that causes partial discharges at the interface between the leading edge and the blade body, in other words in the glue layer fixing these two elements to each other, which is typically a structural epoxy glue.

(24) Specifically, the partial discharges are micro-electric discharges initiating in structural irregularities of an element placed in an electric field with an appropriate intensity. In the framework of the invention, these micro-discharges are provoked in the glue layer bonding the leading edge to the blade body made of a composite material.

(25) In practice, by deteriorating the glue layer, the micro-discharges facilitate separation of the leading edge, this separation possibly being achieved by mechanical tension after application of the treatment, and possibly after also applying another treatment to degrade this glue layer.

(26) In general, the voltage to be applied is between a minimum value of 300 volts and a maximum value corresponding to the maximum value allowable by the composite material of the blade body. This maximum voltage allowable by the blade body can be determined by tests to evaluate the threshold voltage causing damage to the material of the blade body.

(27) These tests can consist of applying different voltages to different blade bodies, to identify the value starting at which micro-discharges appear within the composite material, and/or causing damage or degradation to the composite material. Similarly, tests can be performed to determine the minimum voltage necessary to obtain micro-discharges in the glue layer.

(28) Identification of these threshold values then provides a means of determining the voltage to be applied between the leading edge and the blade body to cause separation.

(29) In general, the invention can be used to modify defective gluing during fabrication of the blades, and to replace a damaged leading edge without needing to replace the entire blade that supports it, and possibly to recycle damaged leading edges made of titanium after they have been removed.

(30) In the example described, the invention is applied to separation of a metallic leading edge glued to a blade body made of a composite material, but the invention is more generally applicable to separation of an electrically conducting material that is glued to an electrically insulating material.

(31) In order to improve the method, the separation operation is used within an insulating material such as air, for example such as gaseous nitrogen under pressure equal for example to 30 bars or under a dielectric fluid such as a mineral or silicone oil. The choice of such a medium to implement the separation operation can limit or even extinguish any electric arcs in the process.