KR20190038696A - Al-Mg-Zn . - Google Patents

Abstract

The present invention relates to an Al-Mg-Zn alloy high-luster anodizing method, and more specifically, to an Al-Mg-Zn alloy high-luster anodizing method, which can form a stable anodizing layer by minimizing inhomogeneity on the surface due to acid corrosion during an anodizing process. To this end, in the present invention, a higher voltage is applied step by step such that the desired thickness of a film may be uniform in an aluminum oxide coating. Then, in order to prevent an excessive increase in voltage, a previous step is performed in which an alternating current voltage is gradually increased step by step as in 1V, 3V, 7V, 9V, 12V for each minute to a secondary-side of an auto transformer. Next, a growing step is performed in order to increase the alternating current voltage step by step as in 14V, 15.5V for each minute.

Description

Al-Mg-Zn alloy high gloss anodizing method {

The present invention relates to an Al-Mg-Zn alloy high gloss anodizing method, and more particularly to an Al-Mg-Zn alloy high gloss anodizing method capable of forming a stable anodizing layer by minimizing surface irregularity due to acid corrosion during anodizing processing .

7000 series aluminum alloy exhibits high strength because Al-Mg-Zn type precipitates precipitate at an effective temperature.

Of the 7000 series aluminum alloys, the addition of Cu in addition to Zn and Mg exhibits the highest strength among the aluminum alloys.

7000 series aluminum alloys are manufactured by, for example, hot extrusion processing, and are used for transportation equipment, sports equipment, machine parts, and the like for aircraft and vehicles requiring high strength.

In addition to strength, the properties required when used in these applications include stress corrosion cracking resistance, impact absorbability, and system elongation. As an example of an aluminum alloy satisfying the above characteristics, there is proposed an aluminum alloy extruded material described in Patent Document 1, for example.

However, in the aluminum alloy showing a high resistance of 7000 manufactured by the component range of the above-mentioned Patent Document 1 and the conventional manufacturing method, if anodic oxidation treatment or the like is performed for the purpose of preventing surface scratches, There was an apparent problem that the shape of the muscle appeared.

Further, the aluminum alloy is required to become silver in order to give a feeling of luxury after surface treatment such as anodizing treatment, for example.

However, when the above-mentioned conventional 7000-series aluminum alloy is subjected to anodizing treatment or the like, there is an apparent problem that the surface of the 7000-series aluminum alloy is strongly yellowish in color tone.

As described above, since the conventional 7000-series aluminum alloy has a problem in the surface quality after the surface treatment and the variation in the color tone, it is difficult to adopt it.

Japanese Patent Application Laid-Open No. 2007-119904

Accordingly, in the case of the Al-Zn-Mg alloy, the corrosion of the Al-Mg-Si alloy by the alkali and the acid is weaker than the Al-Mg-Si alloy in the case of the Al-Zn-Mg alloy, and the surface roughness after the anodizing process is different due to the corrosion, In case of anodizing or dark color, the difference is not visible to the naked eye after the anodizing, but the high gloss anodizing specification solves the problem that the surface difference is prominent.

In order to achieve the above-mentioned objects, in the aluminum oxide film, a higher voltage is supplied step by step so that the thickness of the target film is uniform, and a voltage of 1V per minute is applied to the secondary side of the AUTO transformer , 3V, 7V, 9V, 12V, and the like, and then the AC voltage is stepwise increased by 14V, 15.5V or the like every minute unit.

The pre-stage is characterized in that the voltage is set to a low value in order to minimize the corrosion of the aluminum surface when the initial barrier film is formed, and the voltage is increased to perform the growth step so that the anodizing pore portion can be smoothly generated .

The growth process of the aluminum oxide film forms a uniform and thin barrier layer on the initial aluminum surface, and then the volume expansion of the barrier layer causes irregularities on the surface thereof, resulting in nonuniform current density. Subsequently, due to the nonuniformity of the current density, fine pores are formed in the portion having a large current density due to the action of the electric field and the dissolving action of the electrolyte. As the coating continues to grow, the micropores also become deeper and deeper.

In the process of forming fine pores, differences in the uniformity, gloss and abrasion resistance of the final anodized film occur depending on the thickness variation of the initially formed barrier layer.

If a stable voltage is not applied or an overvoltage occurs when the barrier layer is formed on the initial aluminum surface, local dissolution or barrier layer of the aluminum surface can not be formed, and even if the initial barrier layer is formed, it is not uniform and becomes very rough . When a low current is applied for a long time, the barrier layer on the aluminum surface can be uniformly formed, but if the processing time is prolonged, side effects such as whitening may occur.

In order to minimize the corrosion of the aluminum surface when the initial barrier coating is formed, the voltage is set to a low level so as to increase the voltage so that the anodizing pore portion can be smoothly generated after the applied shear stress, Is formed.

Hereinafter, one preferred embodiment according to the present invention will be described in detail.

First, a 7000-based material is applied to an aluminum alloy applied according to an embodiment of the present invention.

First, the terms used in the present invention are interpreted as generally applicable in metal engineering, chemical engineering, and chemical engineering.

The present invention relates to a method of forming a barrier layer on a surface layer of an Al-Zn-Mg alloy by varying an applied voltage among various parameters during an anodizing process in general, and the irregular surface Thereby stabilizing the roughness.

Generally, in order to treat anodizing with aluminum metal, aluminum metal is immersed in an electrolytic bath containing an electrolytic solution of an acidic solution, and then an oxide film is formed on the surface of the metal by flowing a constant voltage and current. In accordance with the voltage and current applied to the electrolytic bath, Of the corrosion state.

To control such corrosion conditions, the present invention includes a DC transformer, an AUTO transformer, and an AC transformer to provide a suitable applied voltage.

The DC transformer outputs a DC voltage that has been stepped down and rectified to the secondary side, and AC power that is changed step by step to the secondary side of the AUTO transformer is input through the + output terminal of the DC transformer through the AC transformer, Is output to the + terminal.

This may vary depending on the magnitude of the voltage and current output to the output terminal, and may be varied by voltage control of the voltage controlling element.

In particular, in accordance with the control of the control unit, the voltage control elements SCR are driven on the primary side R of the AUTO transformer to control the waveform change of the AC power source so that the AC output voltage of the AUTO transformer automatically increases or decreases.

At this time, in the case of the aluminum oxide film, a higher voltage should be supplied step by step so that the thickness of the target film is uniform. In order to prevent excessive current rise, the secondary side of the AUTO transformer is set to 1V, 3V, 7V, 9V , 12V, and the like, and then a step of increasing the AC voltage stepwise by 14V, 15.5V, etc. in minutes is performed.

That is, in order to minimize the corrosion of the aluminum surface when the initial barrier film is formed, the voltage is set to be low and the voltage is increased so that the generation of the anodizing pore portion can be smoothly performed after applying the shear stress applied. An anodizing layer can be formed.

During the coating process as in the above example, the thickness of the coating film in the previous stage is less than several micrometers and the thickness of the target film (several tens to several hundreds of micrometers) can be grown through the growth step.

On the other hand, the present invention provides a frequency at which the maximum film growth rate per unit electric power, that is, the maximum electric current, can be obtained.

 Aluminum alloy As the anodization progresses, the surface of the aluminum alloy changes in the concentration of Al3 + and O2- ions in the electrolyte layer, or the concentration of the electrolyte changes on the surface of the electrolyte and aluminum alloy, The pulse relaxes these concentration changes and reduces the electrical resistance so that the current flows well.

For Aluminum Alloy 7000 series, frequency 7.5 and 10.0 KHz are suitable for current density 12A / dm2 for frequencies 5.0 and 10.0 KHz and current density 18A / dm2, respectively.

In order to minimize the corrosion of the aluminum surface when the initial barrier film is formed, the voltage is set to a high voltage and then the voltage is decreased so that the generation of the anodizing pore portion can be smoothly performed after the application of the shear stress applied. An anodizing layer can be formed.

The present invention may be embodied in many other forms without departing from the spirit or essential characteristics thereof. Therefore, the above-described embodiments are merely examples in all respects, and should not be construed restrictively. The scope of the present invention is indicated by the appended claims, and the present invention is not restricted by the specification. Modifications and variations falling within the scope of the appended claims all fall within the scope of the present invention.

Claims (2)

For the aluminum oxide film, a higher voltage is supplied step by step so that the thickness of the target film is uniform. In order to prevent the excessive current rise, the AUTO transformer is gradually supplied to the secondary side at 1V, 3V, 7V, 9V, Wherein the step of growing the alternating voltage stepwise by 14V, 15.5V or the like is performed stepwise before the step of raising the alternating voltage stepwise.
The method according to claim 1,
Wherein the preliminary step is carried out by increasing the voltage so that the generation of the anodizing pore portion is smoothly performed by applying a voltage with a low voltage in order to minimize the corrosion of the aluminum surface when the initial barrier film is formed, Mg-Zn alloy high gloss anodizing method.