The present invention relates to a method for manufacturing metal turbomachine parts, and in particular movable turbine wheel blades of an aircraft turbojet engine or turboprop engine.
It relates to a titanium-aluminium intermetallic compound alloy. TiAl 48-2-2 is specifically concerned.
It also relates to an assembly comprising a blank for a turbomachine part made from such an alloy based on TiAl and a machined part resulting from the machining of this blank.
An alloy forms an intermetallic compound with certain chemical compositions and under certain pressure and temperature conditions. Unlike a conventional alloy, where atoms of different natures may be distributed randomly on the same crystallographic site, an intermetallic compound consists of a periodic alternation of atoms. Thus, when an elementary mesh is looked at, a crystalline structure can be noticed.
The formation by founding (casting) of a part made from titanium-aluminium intermetallic alloy is extremely difficult at the present time and does not make it possible to cast sufficiently fine thicknesses to produce, by founding (casting), parts with finished cast regions.
Managing to efficiently machine a part made by founding (casting) is furthermore difficult.
Two categories of problems result therefrom:
In the prior art, there exist in particular the following solutions:
1) a solution providing for the obtaining of an over-thick rough form by lost-wax founding (casting), and then machining this rough form in order to obtain the final part, such as a blade,
2) a solution consisting of the casting of a blank to the almost final form of the part (referred to as “near net shape”), next allowing machining that is certainly minimal (with little loss of material) of the final part, but which remains necessary,
3) and a solution by founding (casting) in a centrifuged permanent mould, where it is possible to make provision for manufacturing a plurality of turbomachine parts, following steps consisting of:
Solutions by forging also exist, but are tricky to implement because of the fragility of TiAl alloys.
One drawback of founding (casting) for parts based on TiAl is the very rapid solidification of the molten material.
The result of this is a high risk of porosity of the parts, a failure to achieve suitable filling of the moulds and therefore a tricky finalisation of the external form of the as-cast rough form (blank).
Furthermore, a hot isostatic compression (HIC) is next typically necessary in order to close up any porosities, implying significant cost. In addition, this treatment is not always sufficient, in particular if the porosities of the rough form are opening out.
As drawbacks of loss-wax founding (casting) (non-permanent mould), the following can be noted:
Other points may also be mentioned:
One objective of the invention is to avoid or limit many of the problems mentioned above.
One solution for this is a method for manufacturing at least one metal turbomachine part, comprising steps consisting of:
a) keeping a TiAl (titanium-aluminium) intermetallic alloy melted by plasma torch in a retractable-bottom mould (or ring mould),
b) extracting therefrom an ingot, as cast, in a state cooled from molten,
c) cutting the ingot into at least one blank with an external shape that is simpler than the more complex one of the part to be manufactured,
d) and machining the blank in order to obtain the part with said more complex external shape.
The term “blank” must be understood here in a fairly broad sense. It designates a product that is not finished but the general form of which corresponds essentially to the appearance of the finished part. This means that a blank for a part as aforementioned is a metal product of the aforementioned type. This excludes neither the subsequent adaptation of the shape of this blank, for example by machining, nor the modification of this general appearance, for example by curving, bending or any other plastic deformation. It must rather be understood that a “blank” of a product of the aforementioned type is a part of this type that may undergo various shaping, machining or surface treatments in order to give rise to a finished product.
To supplement the aforementioned solution, it is advised that:
One objective sought is a machining aimed at reduced losses of material. In this context, and in a more general context of saving on material, it is moreover recommended that:
Typically, the “ring moulds” mentioned above are referred to as PAM (plasma arc melting) furnaces. These PAM furnaces are normally, in the prior art, used for casting material for remelting, that is to say, after melting of the material in the PAM furnace, this material solidifies, and is then remelted in order be cast. The cast bars, or ingots, then have very large diameters (especially >200 mm).
However, in order to comply with the requirements of a rough PAM bar or ingot, to be used with a view to direct machining, it has appeared useful to change the PAM method in order to make it more robust and better in a position to produce ingots without defects.
In this light, it is here proposed to cast PAM ingots of smaller diameters where the phenomena giving rise to defects are more easily controllable.
Thus it is in practice advised that, at step b), the extracted ingot should have a diameter of less than or equal to 200 mm or a cross section of less than approximately 32×103 mm2 within 5%.
Applying the aforementioned PAM production in particular to such small diameters of ingots will make it possible to avoid the shrinkage and chemical segregations that are the two main technical difficulties in casting in a centrifuged permanent mould, with solidification that will take place sequentially in a small volume that will be referred to as solidification wells.
By using such a PAM method, it will therefore be possible to obtain semifinished products with very little porosity and very homogeneous.
Moreover, by proceeding with a heat treatment in one of more operations, as advised below, the obtaining of the desired microstructure and mechanical properties will be encouraged even further.
This treatment, applied a priori to the blank, will favourably comprise:
As an alternative or in addition, it is however provided for the post-PAM treatment, on a blank consisting of a TiAl alloy with gamma grains having typically a composition containing between approximately (to within 5%) 47 and 49 percent aluminium (at %), to be as follows:
If the melting step and the step of obtaining the ingot are properly carried out it could be unnecessary to apply pressure during the second aforementioned heat treatment step.
In the above global context, it is anticipated that the ranges comprising the manufacture of bars or ingots with a view to direct machining, after cutting into a blank or blanks of simple shape during step c), must be designed so as to comply with the requirements of the final parts since they are in this case directly transferred onto the blanks. The main requirements are:
Concerning the assembly already mentioned including:
In correlation with the above, this assembly will favourably be such that the blank will have a diameter of less than or equal to 200 mm, preferably 120 mm, and a length of less than 300 mm, preferably between 220 mm and 240 mm.
This will assist a saving on material, particular in the context of the manufacture of a blade.
Before the aforementioned step a) of keeping the alloy molten, it will be possible to provide a series of plasma torches to melt the intermetallic compound and to keep it molten.
Other advantages and features of the invention will also emerge from a reading of the following description given by way of non-limitative example and with reference to the accompanying drawings, where
and
In the left-hand column in
In the central column the steps also involving remelting are listed, with moulding in a centrifuged mould (permanent mould), of a rough ingot issuing from melting (other than PAM), at the initial step.
And in the right-hand column the steps of the present invention are listed without moulding or necessarily remelting, after a rough ingot issuing from PAM melting has been obtained at the initial step.
Thus:
obtaining a rough ingot resulting from PAM melting, then cutting the remelted ingot obtained into a blank, and then heat treatment/optionally HIC and machining.
The solution in the favoured example in the right-hand column therefore consists of limiting the manufacture of this part to four steps making provision for:
a) initially casting a TiAl intermetallic compound in a ring mould (or PAM furnace), with melting by plasma torch,
b) extracting therefrom an as-cast ingot, in a state cooled from molten,
c) cutting the ingot into at least one blank with a simpler external shape than the more complex one of said part to be manufactured,
d) machining the blank in order to obtain the part with said more complex external shape.
As shown schematically in
A last plasma torch 70, placed above a final mould or vessel, keeps the top of the bath arriving from the tanks 11a and then 11b molten therein. This final vessel is in the form a ring mould 13. The ring mould 13 comprises a bottom 13a that is retractable or movable, for example axially, here with controlled vertical movement. The ring mould 13 is cold, typically cooled from outside, for example with water, via cooling means 15. Under its bottom opening 13b and here by lowering of the movable bottom 13a, the bottom of the bath flows, by gravity or other, then sufficiently cold to form an ingot 17, as cast, in this state cooled from molten. The ring mould 13 may be made from copper.
By using the various vessels 9, multiple refining hearths, such as here 11a, 11b, and then the ring mould 13, with plasma torches 7, 70 also multiple and placed above each of these receptacles, the travel of the material will be optimised, so as to completely melt it and to keep it therein at a substantially homogenous temperature. Reducing the number of inclusions or non-molten parts will also be possible by using, as illustrated, a plurality of overflow tanks. To guarantee an even greater quality, it will also be possible to make provision for carrying out successive meltings of the material.
Typically, the ingot 17 obtained will be substantially cylindrical or polyhedral.
In order to assist compliance with the requirements of a bar or ingot 17 intended for direct machining, and therefore with neither any intermediate moulding nor the conventional drawbacks of lost-wax founding (casting) (defects resulting from interactions with the mould, which is typically made from ceramic), or other defects characteristic of producing by casting in centrifugal permanent moulds (central shrinkage and chemical macrosegregation, in particular), it is here proposed to cast ingots of small sizes, in particular such that each ingot 17 extracted has a transverse dimension d (diameter or width for a square cross section) less than or equal to 200 mm, and preferably 120 mm, or, in cross section, less than approximately 32×103 mm2 and 12×103 mm2 within 5%, respectively.
It is next from such an as-cast ingot that one and preferably a plurality of blanks 21 will be directly cut (by basic tools), each with a simple shape, in particular once again substantially cylindrical or polyhedral and in any case with an external shape simpler than the more complex one of each of said parts to be manufactured, the result of the machining of each blank, such as the two blades 19a, 19b that can be seen by transparency in the blank 21 of
This objective and a search for optimisation of the manufacturing processes in particular of turbine blades, with shortening of the cycle times, has moreover led to preferring:
From a reading of the above table it will moreover have been clear that, between the step of cutting the ingot into blanks and the machining of each blank, preferably heat treatment (in a single sequence or multiple sequences) of each of these blanks will occur.
As already indicated, one aim will be to thereby assist the achieving of the expected mechanical and microstructure criteria.)
In fact, it is recommended carrying out:
One aim being therefore to obtain a duplex microstructure (intermetallic compound) consisting of gamma grains and lamellar grains (alpha2/gamma), and it is in practice advised to proceed as follows (with values supplied within 5%):
Between the two steps of this heat treatment, the material will also have been able to undergo hot isostatic compression (HIC) at a temperature of approximately 1200° C., preferably between 1185° C. and 1204° C.
Number | Date | Country | Kind |
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1552055 | Mar 2015 | FR | national |
Filing Document | Filing Date | Country | Kind |
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PCT/FR2016/050507 | 3/4/2016 | WO | 00 |