Field of the Invention
The present invention relates to a method for depositing an aluminizing coating on a substrate.
Description of the Related Art
Aluminum-based coatings, called “aluminizing coatings,” are used to protect the surface of parts operating at high temperatures and in oxidizing environments. Such a coating may also serve as a fastening layer for attaching to another protective coating, said protective coating being more able to adhere to such an aluminizing coating than to the surface of the part itself.
For example, such parts are found in aeronautic turbojet engines, such as airplane engines. These parts are in particular turbine vanes or nozzles.
These parts are for example made from nickel-based superalloys.
To perform an aluminizing coating on such a superalloy, a layer of platinum 20 is first deposited on the surface 11 of said superalloy that is the substrate 10. This step is illustrated in
A thermal diffusion treatment is then done intended to diffuse the nickel of the superalloy 10 in the layer of platinum 20, and the platinum in the superalloy 10. This step is illustrated in
A thermochemical aluminizing treatment is then done that leads to the deposition of a layer of aluminum 40 on the layer of platinum 20. This step is illustrated in
The drawback of this currently used method is that the diffusion treatment of the layer of platinum is long and costly.
The present invention aims to resolve this drawback.
The invention aims to propose a method for depositing an aluminizing coating on a substrate, the cost and duration of which are decreased relative to the current method.
This aim is achieved owing to the fact that the method includes the following steps:
Owing to these arrangements, the total duration of the method for depositing the aluminizing coating is reduced, since there is no longer any diffusion step. Furthermore, the total cost of the deposition method for the aluminizing coating is decreased, since the deposition of a coating containing platinum and nickel can be done using known and inexpensive methods.
The invention will be better understood, and its advantages will appear more clearly, upon reading the following detailed description of one embodiment shown as a non-limiting example. The description refers to the appended drawings, in which:
As shown diagrammatically in
The layer 23 containing platinum and at least 35% of nickel is deposited on the surface 11 of the substrate 10. This deposition may be done by electrolysis, for example by soaking the substrate 10 in an electrolytic bath containing platinum salts and nickel salts.
Below, the particular embodiment is described wherein the layer 23 is made up of a first layer 20 containing platinum and a second layer 30 containing nickel.
First, in a known manner, for example by electrolysis, a layer of platinum 20 (first layer) is deposited on the surface 11 of the substrate 10 (step (a),
The thickness of this layer of platinum is for example approximately 5 μm to 10 μm.
Beforehand, it is possible to prepare the surface 11 so as to obtain better attachment of the layer of platinum 20 on said surface 11. This preparation for example consists of making the surface rougher, the raised portions thus formed serving as catches for the layer of platinum 20.
The surface preparation may also be done in the more general case of a deposition of the layer 23 (made up of a layer of platinum 20 and a layer of nickel 30) on the surface 11.
No diffusion treatment of this platinum layer 20 is done.
As shown diagrammatically in
The deposition of this layer of nickel 30 is for example done using the known electrolysis method. The part to be covered is soaked in an electrolytic bath containing nickel salts, said part serving as an electrode (cathode), and a current is passed between said electrode and another electrode (anode) made from nickel. The nickel is then gradually deposited on the part.
The advantage of the method according to the invention is that the deposition of the layer of platinum 20, then the layer of nickel 30 can be done consecutively in the same facility. This therefore saves time. Furthermore, these depositions may be done at a low temperature and ambient pressure, which is less expensive than the diffusion treatment used in the prior art (step illustrated in
A layer of aluminum 40 is next deposited on the layer of nickel 30 (step (c),
Advantageously, a vacuum is established beforehand in said enclosure, for example at 400 mbar and 1100 mbar.
This vacuum makes it possible to improve the quality of the aluminum deposition, in particular the uniformity of said deposition.
Owing to the presence of the layer of nickel 30, the nickel atoms diffuse directly from said layer of nickel 30 in the layer of aluminum 40, where it forms NiAl compounds 60, which reduces the formation of PtAl2 compounds 50, and therefore the risk of the formation of PtAl2 plates on the surface of the layer of aluminum 40.
Furthermore, the reduction of this PtAl2 formation is more effective than in the method according to the prior art, as more nickel atoms diffuse in the layer of aluminum 40. In fact, the layer of nickel 30, which is in contact with a layer of aluminum 40, is made up of nearly 100% of nickel in the case of a deposition by electrolysis.
In general, the layer of nickel 30 contains enough nickel such that the layer 23 that is made up of the layer of platinum 20 and the layer of nickel 30 (or a single layer containing platinum and nickel) contains at least 35% of nickel.
On the contrary, in the prior art, the layer in contact with the layer of aluminum 40 comprises both platinum atoms and nickel atoms. However, the Ni—Pt—Al phase diagrams show that the NiAl compounds form to the detriment of the PtAl2 even more easily inasmuch as the surface on which said layer of aluminum 40 is deposited comprises more than 35 at.% of nickel.
Furthermore, unlike the method according to the prior art, it is not necessary for the substrate 10 to contain nickel, since the contribution of nickel intended to diffuse in the layer of aluminum 40 comes from the layer of nickel 30 that is deposited on the layer of platinum 20 that has been deposited on said substrate 10. The method according to the invention can therefore be used on any substrate 10, and not only nickel-based superalloys. For example, the method according to the invention may be used on any superalloy.
After deposition of the layer of aluminum 40, it is possible to deposit another material on that layer, for example a ceramic thermal barrier when the part thus coated is designed for high temperature applications.
Number | Date | Country | Kind |
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10 54850 | Jun 2010 | FR | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/FR2011/051330 | 6/10/2011 | WO | 00 | 3/1/2013 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2011/157935 | 12/22/2011 | WO | A |
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Number | Date | Country | |
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20130175178 A1 | Jul 2013 | US |