The invention relates to devices for performing anodizing treatment, preferably micro arc anodizing treatment, and it also relates to associated methods.
It is known to treat alloys based on magnesium, aluminum, or titanium by micro arc anodizing. That technique serves to make layers with very low porosity and of hardness that is much greater than the hardness of an amorphous oxide that could be obtained by conventional anodizing such as sulfuric anodic oxidation (SAO), chromic anodic oxidation (CAO), or phosphoric anodic oxidation (PAO). Specifically, in micro arc anodizing treatments, the oxide layer on the surface of the part is formed as a result of generating microelectric discharges leading to the formation of micro arcs that have the ability to raise the temperature of the surface of the part very locally so as to crystallize the amorphous oxide that forms during the anodizing step. In micro arc anodizing treatment, the parts may be immersed in an aqueous electrolyte and they are exposed to oscillating pulses of electrical energy by a specific electronic generator, and if necessary by a counter-electrode of shape matching the parts. Microscopic light-emitting discharges are then visible at the surfaces of such parts, which discharges are due to dielectric breakdowns in the hydroxide layer, and they can be considered as being microplasmas.
The main parameters of the treatment (frequency of the electrical signal, current density, duration for which the parts are immersed in the bath, temperature, . . . ) can be modulated and controlled as a function of the material of the treated part, of its shape, and of the properties desired for the layer of anodizing.
Nevertheless, making a coating by the present micro arc anodizing technique in a large vessel (vessel having a volume of about 0.5 cubic meters (m3)) can present several limits.
Firstly, that technique can involve using a generator delivering high value bipolar currents, given the large surface area of the part(s) for treatment, which can lead to high levels of electricity consumption. Furthermore, it can be difficult to obtain a coating by micro arc anodizing on a part of large area because of the high currents needed for anodizing.
Furthermore, since micro arc anodizing treatment consumes a large amount of energy, the temperature of the electrolyte in prior art bath treatments can be difficult to control. Nevertheless, it is necessary to control the temperature of the bath in order to ensure that the coating is properly made. The desire to regulate the temperature of the bath can lead to using an installation that is relatively complex, thereby significantly increasing the cost of performing the treatment.
Another disadvantage of prior art micro arc anodizing methods is that it can be difficult to measure reliably certain parameters of the electrolyte in the bath while the anodizing treatment is being performed. Reliable measurements of such parameters are nevertheless desirable, e.g. in order to be able to modify the anodizing treatment being performed as a function of the information determined from such measurements.
Finally, in order to perform micro arc anodizing on a part in a well-specified zone, it is possible to use resists that may be of organic type, e.g. a varnish, or of inorganic type, e.g. resulting from conventional anodizing, for the purpose of preventing the micro arc anodizing layer being formed over the entire surface of the part. Resists serve in particular to insulate the surface of the underlying part electrically from the electrolyte, thereby preventing that surface being anodized. Nevertheless, putting resists into place can be relatively expensive and can make the organization of fabrication significantly more complex. Furthermore, the masking step may be difficult to perform and can thus make the treatment significantly more expensive.
There thus exists a need to provide devices that enable anodizing treatment to be performed in simple and inexpensive manner, and in particular micro arc anodizing treatment.
There also exists a need to provide devices that enable the temperature of the electrolyte during anodizing treatment to be controlled effectively, and in particular during micro arc anodizing treatment.
There also exists a need to provide novel devices suitable for performing treatments in addition to anodizing and making it possible in particular to monitor reliably the parameters of the electrolyte in use during the anodizing treatment.
To this end, in a first aspect, the invention provides a device for performing anodizing treatment on a part, the device comprising:
The invention relies on the principle of using a treatment chamber that is “remote” from the electrolyte storage vessel, the part to be treated forming a wall of the treatment chamber. Unlike anodizing devices known in the prior art, the part to be treated is not immersed in the electrolyte, but only the surface of the part that is to be treated is in contact with the electrolyte during the anodizing treatment. Naturally, the surface of the part to be treated is electrically conductive, the part being constituted for example by a metal, e.g. aluminum, magnesium, and/or titanium.
The invention advantageously enables the anodizing treatment to be “concentrated” in a limited volume in the treatment chamber and makes it possible to use a treatment chamber of volume that is significantly smaller than that of a vessel used in prior art anodizing methods in which the part to be treated is immersed. Thus, in the invention, a treatment chamber is used that has a volume that matches the dimensions of the surface to be treated, and this presents several advantages.
Specifically, the invention makes it possible to achieve savings in terms of energy consumption compared with prior art methods since, while using the device of the invention, the power delivered by the generator is specifically proportional to the dimensions of the surface area to be treated. In addition, a part of large dimensions of the kind frequently encountered in the field of aviation, e.g. a part made of aluminum, can advantageously be anodized without having recourse to a vessel in which it can be totally immersed, as is required in known prior art methods, thus making it possible to achieve a saving in terms of the quantity of electrolyte that is used during the anodizing treatment.
It is thus possible to use a current and a quantity of electrolyte that match the dimensions of the surface area to be treated, as a result of using a treatment chamber of volume and of shape matching the surface to be treated. In addition, the use of such a treatment chamber advantageously makes expensive steps of installing resists or masks superfluous.
The invention thus provides devices enabling anodizing treatment to be performed in simple and inexpensive manner, and preferably micro arc oxidation treatment.
The device of the invention is preferably for use in performing micro arc oxidation treatment.
Devices of the invention also make it possible to have better control over the effects of heat being produced in the treated zone by enabling the electrolyte to be renewed effectively in the treatment chamber and by maintaining the treatment chamber under good mixture conditions. This renewal is made possible by the system for storing and circulating the electrolyte that enables the electrolyte to flow from the storage vessel to the treatment chamber and the electrolyte to return from the treatment chamber to the storage vessel. Such a system contributes to having better control over the anodizing treatment and leads to coatings that are easier to make so that they comply with the required specifications.
Advantageously, the system for storing and circulating the electrolyte may further include a pump for driving circulation of the electrolyte through said system.
In an embodiment, the device may be such that the circuit for circulating the electrolyte comprises:
Advantageously, the treatment chamber may have a volume that is less than the volume of the storage vessel. The volume of the storage vessel and the volume of the treatment chamber correspond respectively to the inside volumes of said storage vessel and of said treatment chamber (i.e. not including the volumes of the walls). In particular, the ratio (volume of the treatment chamber)/(volume of the storage vessel) is less than or equal to 1, preferably less than or equal to 0.2.
In an embodiment, the device may include at least one sealing gasket constituting a second wall of the treatment chamber, the second wall being different from the first wall. In particular, the device advantageously includes two sealing gaskets situated facing each other and constituting two distinct walls of the treatment chamber.
In an embodiment, the treatment chamber may define a single compartment.
The present invention also provides a method of anodizing a part, the method comprising the following steps:
The anodizing treatments of the invention present the advantages as described above.
Preferably, the anodizing treatment is micro arc oxidation treatment.
In an implementation, the electrolyte may flow in the electrolyte circulation circuit at a flow rate lying in the range 0.1 times to 10 times the volume of the treatment chamber, per minute.
Advantageously, the electrolyte present in the treatment chamber is continuously renewed during the anodizing treatment.
In an implementation, during the anodizing treatment:
In an implementation, the method may also further include a step of filtering the electrolyte flowing in the second channel prior to its return into the storage vessel.
In an implementation, the method may also further include the following steps:
Other characteristics and advantages of the invention appear from the following description of particular embodiments of the invention, given as non-limiting examples, and with reference to the accompanying drawings, in which:
The counter-electrode 7 is preferably made of stainless steel. More generally, it is possible to use any electrically-conductive material for the counter-electrode 7 providing it is compatible with performing anodizing treatment.
The device 1 has a treatment chamber 10 in which the anodizing treatment is to be performed, the part 3 to be treated constituting a first wall of the treatment chamber 10 and the counter-electrode 7 constituting a wall of the treatment chamber that is situated facing the first wall. An electrolyte 11 is present in the treatment chamber 10 between the part 3 and the counter-electrode 7. The electrolyte 11 has a chemical composition that enables the part 3 to be subjected to anodizing treatment. As shown, the counter-electrode 7 is not immersed in the electrolyte 11. The counter-electrode 7 forms a wall of the treatment chamber 10.
Thus, as shown, the part 3 to be treated is not immersed in the electrolyte 11 present in the treatment chamber 10. The part 3 constitutes a wall of the treatment chamber 10 so that only the surface S to be treated of the part 3 is in contact with the electrolyte 11. In the example shown, the part 3 is treated over its entire length, i.e. over its entire longest dimension. Naturally, it would not be beyond the ambit of the present invention for the part to be treated over a fraction only of its length. In the ambit of the invention, it is thus equally possible to perform anodizing treatment over a fraction only of a surface of a part or over an entire surface of a part.
In addition, the treatment chamber 10 comprises two sealing gaskets 13a and 13b situated facing each other and forming two distinct walls of the treatment chamber. As shown, the sealing gaskets 13a and 13b are present at the top and bottom ends of the treatment chamber 10. The gaskets 13a and 13b may be made of flexible material.
Thus, in the embodiment shown of the device 1 the electrolyte 11 used for anodizing is contained between the part 3 and the counter-electrode 7 by static sealing making use of the flexible gaskets 13a and 13b. The treatment chamber 10 thus constitutes a tank of electrolyte 11 for coating the surface S of the part 3. As mentioned above, the treatment chamber 10 has a volume and dimensions that are adapted to the dimensions and to the shape of the surface S to be treated of the part 3. In the example shown, the treatment chamber 10 defines a single compartment.
In addition, the device 1 includes a system 20 for storing and circulating the electrolyte 11. The system 20 comprises a storage vessel 21 in which the electrolyte 11 is stored, with the temperature of the electrolyte 11 stored in the storage vessel being maintained at a value that is determined by a cooling system (not shown). The pH of the electrolyte 11 present in the storage vessel 10 is also maintained at a fixed value. During anodizing treatment, the electrolyte 11 coming from the storage vessel 21 flows along a first channel 23 to the treatment chamber 10. The system 20 also has a second channel 25 enabling the electrolyte 11 to flow from the treatment chamber 10 to the storage vessel 21. The second channel 25 enables the electrolyte 11 present in the treatment chamber 10 to be discharged and returned to the storage vessel 21 where it can be cooled. The electrolyte 11 is caused to circulate through the system 20 by a pump 27. By way of example, the pump 27 may be a pump that is sold under the name YB1-25 by the supplier TKEN.
Advantageously, the flow of electrolyte 11 from the storage vessel 21 to the treatment chamber 10 and from the treatment chamber 10 to the storage vessel 21 is not interrupted throughout the duration of the anodizing treatment. In other words, it is preferred to renew the electrolyte 11 present in the treatment chamber 10 continuously throughout the anodizing treatment.
The first channel 23 may have a diameter d1 over all or part of its length that is less than or equal to 10 centimeters (cm), e.g. lying in the range 1 cm to 3 cm. The second channel 25 may present a diameter d2 over all or part of its length that is less than 10 cm, e.g. lying in the range 1 cm to 3 cm. The treatment chamber 10 may have a volume that is less than or equal to 0.5 m3, e.g. lying in the range 10 cubic decimeters (dm3) to 40 dm3. The storage vessel 21 may have a volume greater than or equal to 0.5 m3, e.g. lying in the range 0.5 m3 to 2 m3.
The materials forming the gaskets 13a and 13b, the first channel 23, and the second channel 25 are selected so as to ensure that electricity does not pass between the counter-electrode 7 and the part 3.
The device 1 shown in
The final thickness of the coating formed after anodizing treatment measured perpendicularly to the surface of the underlying part may lie in the range 2 micrometers (μm) to 200 μm.
There follows an example of operating conditions that may be implemented in order to perform micro arc oxidation treatment with a device 1 as described above:
In particular, for performing micro arc oxidation treatment, it is possible to use an electrolyte 11 having the following composition:
Nevertheless, the invention is not limited to performing a micro arc oxidation method. A device of the invention may be used for performing any type of anodizing, such as for example sulfuric anodic oxidation (SAO), chromic anodic oxidation (CAO), sulfotartric anodic oxidation (STAO), or sulfo-phosphoric anodic oxidation (SPAO).
By way of example, the treated part may be a blade, e.g. made of titanium, or a pump body. It is also possible to use a device of the invention to repair a layer of anodizing that has been damaged, the device making it possible to perform localized repair with a coating being formed by anodizing solely in the damaged zone.
In a variant that is not shown, it is possible to treat a plurality of distinct parts using a plurality of devices of the invention optionally connected to the same generator. The parts may optionally be treated simultaneously.
The storage vessel 21 is dedicated to storing and renewing the electrolyte and no anodizing treatment is performed therein. By separating the storage vessel 21 from the treatment chamber 10, it is possible to configure devices of the invention so as to perform treatments additional to anodizing, as described in detail below. So far as the inventors are aware, these treatments additional to anodizing are not performed or are not performed in satisfactory manner in methods known in the state of the art.
The term “including/containing/comprising a” should be understood as “including/containing/comprising at least one”.
The term “in the range . . . to . . . ” should be understood as including the limits.
Number | Date | Country | Kind |
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14 53990 | Apr 2014 | FR | national |
Filing Document | Filing Date | Country | Kind |
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PCT/FR2015/051062 | 4/20/2015 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2015/166165 | 11/5/2015 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
5338416 | Mlcak | Aug 1994 | A |
9790611 | Yoshida | Oct 2017 | B2 |
20030094377 | Krishna et al. | May 2003 | A1 |
20040217012 | Gramm | Nov 2004 | A1 |
20050077183 | Yagi et al. | Apr 2005 | A1 |
20140151239 | Kobayashi | Jun 2014 | A1 |
Number | Date | Country |
---|---|---|
1900381 | Jan 2007 | CN |
0 410 919 | Jan 1991 | EP |
59-166696 | Sep 1984 | JP |
2009-185331 | Aug 2009 | JP |
2005052221 | Jun 2005 | WO |
WO-2014002520 | Jan 2014 | WO |
Entry |
---|
International Search Report dated Jul. 24, 2015 in PCT/FR2015/051062 filed Apr. 20, 2015. |
Number | Date | Country | |
---|---|---|---|
20170051427 A1 | Feb 2017 | US |