FR2729322A1 - Brazing carbon@ parts to each other or to metal or ceramic - Google Patents

Abstract

In a process for sealing by brazing carbon elements esp. to one another or to a metal or ceramic element, the novelty comprises (a) placing the two elements (2, 3) in contact or slightly spaced apart in the joint zone; (b) heating the joint-adjoining part of at least one of the elements (2) to an additive metal bonding temp in the range 400-800 deg C, depending on the additive metal and/or heated element type, in an inert atmos; (c) depositing liq additive metal onto at least the heated element in or near the zone of contact with the other element; and (d) slowly cooling the resulting assembly. Also claimed is an assembly obtained by the above process.

Description

METHOD OF SEALING BY BRAZING BASED ELEMENTS
OF CARBON AND ASSEMBLIES THUS OBTAINED
The present invention relates to the sealing by brazing of carbon-based elements and more precisely the sealing of a carbon-based element to a metallic, ceramic or other carbon-based element.

 The term “carbon-based element” is understood to mean a part or a structure the material of which is entirely of carbon such as polycrystalline graphites or pyrographites or a carbon-carbon composite.

 Sealing assemblies of carbon-based materials have so far been carried out either using organic resins, loaded or not, or using special adhesives, or by brazing.

 Brazing consists in assembling parts of the same type or not using a fusible filler metal at a temperature below the melting temperature of the assembled materials.

 The known methods of sealing by brazing carbonaceous materials, for example a carbon-carbon composite or a graphite, require heavy equipment which is difficult to handle and therefore impractical, since all of the parts treated must be heated by external heating means. and the pieces should be pressed against each other.

 These devices are expensive and, therefore, only allow the treatment of small parts which require only vacuum chambers of limited volume.

 The present invention seeks to overcome these drawbacks by proposing a technique of sealing by brazing which requires neither the submission of all of the elements to be assembled to temperature conditions, nor the application of contact pressure between said elements.

 More precisely still, the invention aims to obtain by such a method assemblies of parts, in particular of two parts made of carbon-carbon composite material or of a part based on carbon with a metallic part, capable of withstanding high temperatures. can reach or exceed 1400 OC while retaining some of the mechanical properties of carbon-based materials.

 The invention finally aims to propose a technique allowing the assembly of large parts, in particular parts on assemblies or subassemblies already made, impossible, by their dimensions and / or the fact that they incorporate elements or heat sensitive devices, to be placed in an autoclave to be treated by brazing according to known techniques.

To this end, the subject of the invention is a method of sealing by brazing of carbon-based elements, in particular from a carbon-based element to another carbon-based element, or to a metallic or ceramic element, using an appropriate filler metal, characterized in that it consists
- place two elements to be assembled in contact or
short distance from each other in the junction area,
- to carry the part contiguous to the junction of at least
one of the elements at a temperature, called attachment temperature
filler metal, in a range of the order of 400 to
8000C depending on the nature of said filler metal and / or
the partially heated element, the heat supply
being carried out in a neutral atmosphere,
- to deposit, upon reaching said temperature
attachment and maintaining said neutral atmosphere,
the filler metal in a liquid phase on at least
the heated element, in the area in contact with the other
element or immediately adjacent to it,
- and, finally, to slowly cool the assembly
thus realized.

 Advantageously, the elements to be assembled are prepared, before assembly, in the junction zone, by shaping, on either side of the junction plane, the periphery of at least one of the elements, so as to define between the two elements one or more wedge-shaped spaces facilitating the reception and retention of the filler metal in the liquid state.

 According to a preferred embodiment of the method, the heating to reach said attachment temperature and for the deposition in liquid form of the filler metal is carried out using an electric arc welding device with conventional type neutral gas sweep, the filler metal being in the form of a fly.

 The filler metal is a conventional refractory metal preferably chosen from the group comprising nickel-based alloys such as Ni-Fe, Ni-B and titanium or alloys thereof such as Ag-In-Cu- Ti.

 The method of the invention makes it possible to produce assemblies, for example of parts in the form of a thin plate, flat or not, end-to-end or one attached -on the side of the other, according to any incidence, or else elongated parts of curvilinear or polygonal contour section placed end to end, or parts of relatively small dimensions placed superimposed on other parts or parts of simple or complex assemblies or structures.

Other characteristics and advantages will emerge from the description which follows of embodiments of the method of the invention, description given by way of example only and with reference to the appended drawings in which
- Figure 1 is a diagram illustrating a setting
work of the method of the invention by welding
the electric arc of two plates end to end, and
- Figures 2 to 10 illustrate different types
assemblies achievable in accordance with
the invention.

 In Figure 1, there is shown very schematically an electric welding station equipped with an argon sweep comprising a work table 1 electrically conductive, grounded and carrying two thin flat plates 2 and 3 to be assembled.

 The plates 2 and 3 are for example plates of carbon-carbon composite material, placed edge to edge. The electrical welding generator, for example of the TIG (Tungsten Inert Gas) type, is symbolized at 4. The generator, which is grounded, is connected to a thoriated tungsten cathode 5.

 The generator 4 is capable of supplying a variable intensity, between 2 and 350 amperes in direct current and is moreover capable of supplying a high frequency current essential for striking the arc avoiding any contact between the electrode 5 and the plates 2 , 3. In addition, the generator 4 is programmable both for the ignition sequence and for the arc fading sequence at the end of the weld, as will be seen below.

 The generator 4 is finally provided with a scan of the pre-gas and post-gas type with neutral gas, argon in this case.

 The area located locally in a confined argon atmosphere during the implementation of the method of the invention has been represented symbolically at 6.

 The plates to be assembled 2 and 3, for example in carbon-carbon composite material of the high density woven thermo-structural type, have a thickness of a few millimeters and are placed side by side along one of their edges, this edge being of preferably prepared for assembly, by appropriate chamfering.

 The junction of the plates 2, 3 is of the type illustrated in FIG. 2, that is to say an edge-to-edge assembly, the two plates being in contact by a simple edge 7, the opposite edges of the plates being chamfered at 450 on both sides of the plates.

 The chamfers obtained on each side of the assembly 2, 3 define two channels, respectively 8 and 9, the sides of which are at 900.

 We will now describe an embodiment of the process of the invention applied to the assembly of plates 2 and 3 of FIGS. 1 and 2, with an alloy of nickel and iron (Ni 98%, Fe 2%) as filler metal in rod.

 After having placed on the table 1 the plates 2 and 3 as illustrated in FIG. 1, one of the plates is heated locally, which then acts as an anode, in the vicinity of the junction, using the welding device at the arc 4.5.

 To this end, prior to striking the arc, an argon sweep is carried out over the weld zone, namely, one of the channels produced by chamfering.

 The priming is carried out in high frequency mode of the generator 4, then the latter passes continuously to bring the local temperature of the heated plate, for example the plate 2, to the predetermined latching threshold, the argon sweep being of course continued during this time.

 The zone of the plate 2 which it is necessary to heat can be that reduced strictly to the extent covered by the chamfer concerned, that is to say the zone called to be in contact with the filler metal.

 Given the nature of this metal, a nickelfer alloy, said appropriate bonding temperature is of the order of 650 OC. As soon as approximately this local temperature is reached, such detection can be carried out by any appropriate means, including including visual assessment if the operator is an experienced welder, the filler metal rod is brought into the electric arc to obtain the fusion of the end of the rod.

 The droplets of molten filler metal fall into the channel 8 which is responsible, on the one hand, for channeling and retaining them and, on the other hand, for increasing the contact surface between the filler metal and the two plates to assemble.

 As soon as the droplets of filler metal come into contact with the material of the plates 2, 3 which is at at least said attachment temperature, they catch on the wall of the composite material and begin to solidify.

 The deposition of the filler metal naturally causes a local rise in temperature which can reach around 9000C at the end of welding.

 As soon as, locally, the desired quantity of filler metal is deposited, the arc is moved so as to gradually fill the channel 8 over its entire length, as during an assembly by ordinary welding, with or without bring.

 When the channel 8 is filled, and if only this one has to be filled, the arc is extinguished, but following a gradual fading in the known manner, to avoid thermal shocks and the scanning of argon from the welded zone is maintained sufficient time for the temperature to drop below the threshold, of the order of 5000C, oxidation or degradation of the mechanical qualities of the composite material. This threshold is assessed under the same conditions as those set out above with regard to the attachment temperature.

 From the stopping of the electric arc, begins the cooling phase of the sealing. According to the invention, this cooling is carried out in a controlled and regular manner, namely at a slow speed, of the order of 15 to 25 OC per minute. To this end, the assembly can for example be buried in a particulate refractory insulating material such as vermiculite.

 The cooling time is for example of the order of 15 to 25 min.

 If we also want to deposit filler metal in the other channel, when the channel 8 is filled and before entering the cooling phase of the filler metal which has just been deposited there, the assembly plates 2, 3 is returned to immediately fill the other channel 9.

 The composite material of the walls of the channel 9 is already at a temperature above said attachment temperature, the filler metal is directly deposited.

 It is only after the filling of the channel 9 that the arc will be extinguished and the cooling will be carried out, in accordance with the explanations given above.

 The final assembly has the appearance of a usual brazing assembly, the channels 8 and 9 being filled with a brazing bead symbolized at B in FIG. 2.

 FIG. 3 illustrates a variant of preparation of the interface of the elements to be assembled.

 The two plates shown, 12 and 13, are butted and chamfered so as to retain a flat 14 of greater or lesser width and which will delimit a cormraine contact surface between the two plates 12 and 13, if the latter are brought into contact, because it is of course possible to leave between the two plates, as illustrated in FIG. 3, a slight gap during the sealing operation, this gap being filled with the filler metal. The chamfers made on the plates 12, 13 on their opposite edges are for example 450.

 FIG. 4 illustrates the sealing of two tubular parts 22, 23, for example made of carbon-carbon composite material. The two pieces, of the same dimensions, are abutted.

Chamfers, for example at 450, made on either side of the junction plane in the opposite ends of the parts determine a peripheral circular channel 24 which will receive the filler metal.

 FIG. 5 illustrates the assembly of a plate 32 by its edge against one of the faces of a second plate 33. In this case, the plate 32 is chamfered, for example like one of the plates 12, 13 and placed against plate 33 at right angles.

 The chamfers define on either side of the plate 32 a channel 34 for receiving the filler metal.

 FIG. 6 illustrates an assembly of the same type as that of FIG. 5, with plates 42, 43, but forming between them an angle different from 900, for example an angle of 450. At the level of the junction plane, the plate 42 may, like the plates 32, 33 moreover, not be chamfered on its edges as illustrated in FIG. 6. The filler metal is deposited directly in the angle of the dihedral formed by the two concerned faces of the plates.

 In FIG. 7, the plates 52, 53 are placed edge to edge, forming a right angle between them. The edges of the two plates are bevelled at 54 and 55 to define a channel 56 for receiving the filler metal.

 FIG. 8 illustrates a jointing of two plates 62, 63, the facing edges of which are bevelled in a complementary U-shape, a slight gap 64 being preserved between the plates to receive the filler metal.

 The two plates or elements to be assembled in FIGS. 1 to 8 are made of the same carbon-carbon composite material or not.

 One may be made of carbon-carbon composite and the other of metal, copper or stainless steel for example, or graphite or ceramic.

 Both can be made of graphite, provided however that its electrical conductivity is sufficient, for example graphite having a density at least equal to 1.8.

 The filler metal depends on the nature of the elements to be assembled and the mechanical and temperature resistance expected from the assembly.

In addition to the nickel-iron alloy, titanium can be used, the so-called bonding temperature is of the order of 5000 ° C., which is slightly lower than that of the alloy.
Nickel-iron. Titanium has the particularity of wetting well but, in the case of carbon-based material, oxidation can occur beyond 500 to 6000C with the formation of derivatives such as titanium carbide.

The filler metal can also be a titanium-based alloy, in particular the alloy Silver 62, 25% - Indium 9.5%
Copper 27% - Titanium 1.25%, whose bonding temperature is even lower, of the order of 500 OC or below.

 Such a metal will be preferred in the presence in particular of carbon-carbon composite material, because the lower the temperatures used during the sealing will be and the less the mechanical qualities of the composite material will be degraded.

 The filler metal can also be a nickel-boron alloy, the bonding temperature of which is however appreciably higher, of the order of 800 OC.

 In the case of assembly of carbon-based material and stainless steel, it suffices to heat the carbonaceous material because the stainless steel catches the filler metal at any temperature.

 The parts or elements to be assembled do not require, beforehand, any particular chemical or physical preparation, if not, possibly, the production of conical chamfers as we have seen above.

 The method of the invention applies to relatively thin plates of the order of a few millimeters, flat or not and of simple or complex shapes. A thin plate can be assembled to a solid piece. it is also possible to assemble massive parts, subject however to being able to bring the whole mass of the sealing zone to the required temperatures and, this, relatively homogeneously.

 For progressive filling from one end to the other of the channels for receiving the filler metal, it is advantageous to use conventional automatic welding machines.

 Other localized heating means than the electric arc can be envisaged.

 For example, an argon plasma torch could be used for preheating as well as for melting the filler metal, this heating means being as localized as the electric arc and also making it possible to carry out the process. on poorly conductive graphites.

 When the parts to be assembled are small, the preheating time will be very short.

 On the other hand, in the case of massive parts or structures to be assembled, where relatively large masses must be brought to said said attachment temperature, it will be possible to use a preheating means of a different nature from that ensuring the melting of the metal. of input.

 Thus, in such a case, said preheating can be ensured by electromagnetic induction or by infrared emission, using a mobile electric oven.

 A mobile induction coil can be used to obtain the desired temperatures locally and in depth, the coil progressively following, with the filler metal rod, the layout of the channel to be filled.

 In the case of infrared preheating, the parts brought to the desired temperature will be gradually extracted from the hot zone of the mobile oven in order to be assembled.

 The elements to be assembled, or one of them, can be a part already produced, the dimensions and complexity of which can be greater or less. The method thus makes it possible to repair or mount a structure in situ, that is to say without being obliged to bring it to a particular place. This is currently unthinkable with known brazing techniques which require placing all of the parts to be assembled in a heating chamber.

 The technique of the invention allows the assembly to retain its electrical conductivity and its resistance to high temperatures, the mechanical resistance however being substantially reduced compared to the intrinsic qualities, in particular of carbon-carbon type composite materials.

 FIG. 9 illustrates an exemplary embodiment of an assembly comprising a superimposed copper plate 72 of dimensions 14 mm × 14 Tin × 4 mm, on a block 73 of carbon-carbon composite material of the high density woven thermo-structural type, of dimensions 14 UKEL x 14 mm x 22 mm.

A peripheral channel 74 is formed by chamfering at 450, at the height of the junction plane between the two superimposed elements 72, 73. The filler metal was a rod of
Ni 98% - Fe 2%.

 The rise in temperature of the pre-heating was preferably carried out on the copper element 72, up to 700 ° C., before putting the filler metal.

 When the arc was extinguished, the argon flow was maintained on the metal cord in the channel 74 for a few seconds, then the assembly was buried immediately in vermiculite shavings.

 The cooling lasted about twenty minutes.

 The temperature during the operations of depositing the filler metal oscillated between 700 OC and 900 C approximately.

 FIG. 10 illustrates a second example of edge-to-edge assembly produced using a wafer 82 made of carbon-carbon composite material similar to that of element 72 and of dimensions 20 mm × 10 mm × 3 mm and d '' a plate 83 in stainless steel type 18-10 of dimensions 20 un x 10 mm x 2mm.

 The filler metal was identical to that of the example in FIG. 9.

 A peripheral channel 84 has been formed by chamfering 450 of the elements 82, 83 at their junction.

 Preheating was carried out only on the composite element 82 up to a temperature between 600 and 7000C. The scanning of argon after depositing the filler metal and the cooling were carried out under the same conditions as in the previous example.

 In accordance with the method of the invention, test pieces were produced by assembling the type of FIG. 2 between two flat elements of the same material as that of FIG. 2, the test pieces having a thickness of three millimeters, a length between heels of 38 millimeters and a width of 14 millimeters, the filler metal being an alloy Ni 98 g - Fe 2 W.

 Tensile tests on such specimens have revealed tensile strengths of up to 12 to 19 MPa at l0000C and from 5 to 8 MPa between 1300 and 14000C. As a reminder, the NI-Fe alloy melts at 1440 C.

 Finally, the invention is obviously not limited to the embodiments described above but on the contrary covers all variants thereof, both as regards the nature, shape and dimensions of the elements to be assembled and the nature filler metal, and as regards the methods, in particular of the pre-heating of one of the elements to be sealed, or of both, of depositing the filler metal and of cooling.

Claims (13)

R E V E N D I C A T I O N S  1. A method of sealing by brazing of carbon-based elements, in particular from a carbon-based element to another carbon-based element, or to a metallic or ceramic element, using a filler metal suitable, characterized in that it consists  - placing two elements to be assembled (2,3) in contact or  close to each other in the area of  junction,  - to carry the part contiguous to the junction of at least  one of the elements (2) at a temperature, called  of attachment of the filler metal, in a range of the order  from 400 to 8000C depending on the nature of said filler metal  and / or the partially heated element, the contribution of  heat being carried out in a neutral atmosphere,  - to deposit, upon reaching said temperature  attachment and maintaining said neutral atmosphere,  the filler metal in a liquid phase on at least  the heated element, in the area in contact with the other  element or immediately adjacent to it,  - and, finally, to slowly cool the assembly  thus realized.  2. Method according to claim 1, characterized in that the elements to be assembled (2,3) are prepared, before assembly, in the junction zone, by shaping, on either side of the junction plane, the periphery of at least one of the elements, so as to define between the two elements one or more wedge-shaped spaces facilitating the reception and retention of the filler metal in the liquid state.  3. Method according to claim 1 or 2, characterized in that the heating to reach said bonding temperature and for the deposition in liquid form of the filler metal is carried out using a welding device with the electric arc with neutral gas sweep (4, 5, 6) of conventional type, the filler metal being in the form of rod  4. Method according to claim 3, characterized in that an argon sweep is carried out on the assembly zone prior to said heating to reach said attachment temperature, in that at the end of the deposition of the metal input, the electric arc is extinguished according to a determined fading process and in that after the extinction of the arc the argon sweep is maintained until the temperature of the carbon-based material is lowered below a determined threshold.  5. Method according to one of claims 1 to 4, characterized in that the filler metal is a refractory metal chosen from the group comprising nickel-based alloys such as Ni-Fe, Ni-Bo and titanium or alloys thereof such as Ag-In-Cu-Ti.  6. Method according to one of claims 1 to 5, characterized in that said cooling of the assembly is carried out at a speed of the order of 15 to 25 OC per minute.  7. Method according to claim 1 or 2, characterized in that the heating to reach said bonding temperature and for said deposit in liquid form of the filler metal is carried out using an argon plasma torch .  8. Method according to claim 1 or 2, characterized in that the heating to reach said attachment temperature is carried out using an electromagnetic induction coil or by infrared emission.  9. Method according to one of claims 1 or 2 and claim 8, characterized in that, upon reaching said bonding temperature, the filler metal is deposited using a welding device to the electric arc with neutral gas sweep or an argon plasma torch.  10. Assembly obtained in accordance with the method according to any one of claims 1 to 9.  11. The assembly of claim 10, comprising two plates (2, 3; 12, 13) relatively thin, planar or not, at least one of which is made of carbon-carbon composite material, sealed end to end, the filler metal being deposited in channels (8, 9) formed by chamfering the edges of said plates, the latter being in contact or at a short distance from each other.  12. The assembly of claim 10, comprising two plates (32, 33; 42, 43; 52, 53) relatively thin, planar or not, at least one of which is made of carbon-carbon composite material, sealed in the form of a moon by relative to the other an angle, right or not, chamfers possibly being made on at least one of the plates to receive the filler metal.  13. The assembly of claim 10, comprising two tubular elements (22, 23) at least one of which is made of carbon-carbon composite material, sealed end to end, said elements being in contact or at a short distance one of 1 other and provided with an external peripheral chamfer defining a channel (24) for receiving the filler metal.