KR20140103216A - METHOD OF SURFACE TREATMENT FOR Mg ALLOYS FRAME OF GLASSES - Google Patents

Abstract

A method for a surface treatment of an eyeglasses frame made of magnesium alloy according to the present invention is capable of removing oil on the surface of the eyeglasses frame made of magnesium alloy, removing and neutralizing the agent for removing oil on the surface of the eyeglasses frame made of magnesium alloy at the same time washing and drying the same, and performing a surface treatment of the eyeglasses frame made of magnesium alloy dried thereafter. The present invention includes a laser surficial treatment step, wherein a laser processor is used to emit laser to treat the surface of the eyeglasses frame. More specifically, the laser surficial treatment step includes: a first laser surficial treatment step for primarily forming an oxide coating on the surface of the eyeglasses frame by treating the surface of the eyeglasses frame for 5-10 seconds with 1-100mW of laser power, using the laser processor; and a second laser surficial treatment step for secondarily forming an oxide film by treating the oxide film primarily formed on the eyeglasses frame, by treating the oxide film for 1-15 seconds with 1-50W of laser power using the laser processor.

Description

[0001] METHOD OF SURFACE TREATMENT FOR MAGNETIC ALLOYS FRAME OF GLASSES [0002]

The present invention relates to a method for surface treatment of an eyeglass frame made of a magnesium alloy material, and more particularly, to a method for surface-treating a surface of an eyeglass frame made of a magnesium alloy material and a magnesium alloy The present invention relates to a surface treatment method of an eyeglass frame made of a material.

In general, magnesium alloy has excellent dimensional stability and is superior to aluminum alloy and steel in terms of low strength, electromagnetic wave shielding, and vibration damping, and is widely used in automobile and aircraft parts, mobile phone cases, notebook computer cases, And the surface is treated to prevent corrosion due to its weak corrosion resistance.

Since the magnesium alloy is a well-oxidized metal, a surface treatment process is indispensably required. Anodizing, plasma electrolytic oxidation and the like are often used for surface treatment of products made of such magnesium alloy .

That is, the surface of the magnesium alloy product is surface-treated to form a thin film layer of MgO or the like. Normally, sodium hydroxide (NaOH) is used as the electrolytic solution used in the wet surface treatment method. OH-) binds to the surface layer of the magnesium alloy product. When the surface is treated by the wet surface treatment method, oxides are formed by a strong current field formed inside the oxide film, and MgO and Mg (OH) ₂ Thereby forming a thin film layer.

However, since the wet surface treatment method requires a long time to form an oxide thin film layer on the surface layer of the magnesium alloy product, the surface of the product can not be treated more quickly, and the surface of the product may be surface- It is not possible to form an oxide film on the substrate.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the problems of the prior art as described above, and it is an object of the present invention to provide a method of forming an oxide film on a surface of an eyeglass frame made of a magnesium alloy material, The present invention also provides a method of treating a surface of a spectacle frame made of a magnesium alloy, which can easily perform surface treatment on a fine portion of the spectacle frame, and can selectively treat only a specific portion of the spectacle frame.

In order to accomplish the above object, the present invention provides a method of removing the surface of a frame made of a magnesium alloy material, removing and neutralizing the material for removing the surface of the frame made of a magnesium alloy material, A method for surface treatment of an eyeglass frame made of a magnesium alloy material, the surface of which is treated with a dried magnesium alloy material, characterized by comprising a laser surface treatment step of treating the surface of the eyeglass frame with a laser using a laser processing machine, A method of surface treatment of a spectacle frame of a material is provided.

In addition, the laser surface treatment step may include a first laser surface treatment for treating the surface of the spectacle frame for 5 to 10 seconds at a laser power of 1 to 100 mW using a laser processor to form an oxide film on the surface of the spectacle frame first step; And a second laser surface treatment step in which an oxide film formed on the spectacle frame is first treated with a laser power of 1 to 50 W for 1 to 15 seconds to form an oxide film secondarily .

According to the method of the present invention for processing a surface of a spectacle frame made of a magnesium alloy material, since the surface of the spectacle frame is treated with a laser using a laser processing machine for a short time, an oxide film is rapidly formed on the surface of the spectacle frame made of a magnesium alloy material It is possible to easily carry out the surface treatment to the fine portion of the spectacle frame and to selectively treat only the specific portion of the spectacle frame.

Further, in the first laser surface treatment step, the fine foreign matters adhering to the surface of the spectacle frame are cleared, so that not only an oxide film layer formed on the surface of the spectacle frame is firmly formed, but also a second laser surface treatment step There is an advantage that the oxide film layer can be formed uniformly in the secondary.

Fig. 1 is an enlarged photograph of the surface of an aluminum frame made of an aluminum material, which is surface-treated by the method of surface treatment of an aluminum frame according to the present invention.

Hereinafter, a preferred embodiment of a surface treatment method of an eyeglass frame made of a magnesium alloy material according to the present invention will be described in detail.

The present invention processes the surface of a magnesium-based spectacle frame, and removes oil, a release agent, and the like on the surface of the spectacle frame formed by a mold or the like before the formation of the oxide film on the surface with the laser beam.

That is, as in the prior art, after removing the oil adhering to the surface of the spectacle frame, washing and drying the same, the surface treatment is performed using a laser processor (not shown).

For example, in the present embodiment, the surface of the frame of the magnesium alloy material is removed, the material for removing the surface of the frame is removed and neutralized, and the frame is cleaned and dried. In order to remove the oil and herd on the surface of the spectacle frame, the spectacle frame made of magnesium alloy material is pretreated with the degreasing step, the trichlorethylene removing step, the acetone neutralizing step, the washing and drying step.

In the degreasing step, which removes the surface of the product, the product is treated with a solution of trichlorethylene (C ₂ HCl ₃ , trichlorethylene (TCE)).

As a reference, trichlorethylene (C ₂ HCl ₃ , trichlorethylene (TCE)) is a colorless transparent liquid that gives off a sweet smell. It is used for cleaning and dyeing in the textile industry, drying An organic solvent used as a solvent, a diluent for a lacquer, a cleansing agent for glass or an optical instrument, and a fat removing agent for leather.

Such trichlorethylene is used to remove glasses on the surface of magnesium alloys such as eyeglass frames, parts for automobiles and aircraft, mobile phone cases, and notebook computer cases.

In the degreasing step, the trichlorethylene removed on the surface of the degreased product such as oil is removed. In the trichlorethylene removal step, the degreased product is treated with an acetone solution to remove the trichlorethylene solution on the surface. To remove it.

In order to clean the acetone-treated product with water, it is necessary to neutralize acetone adhered to the product. In the acetone neutralization step, the acetone treated in the step of removing the chlorochloroethylene is treated with a methanol solution to neutralize the acetone on the product surface .

Methanol (CH ₃ OH) is the simplest alcohol, also known as methyl alcohol, and is also called wood spirit because it is obtained from wood vinegar obtained by the dry distillation of wood. It is a methyl ester type of various carboxylic acids such as salicylic acid, Various types of methyl ether are contained in various natural products.

Methanol is a colorless, transparent, volatile liquid with a unique orientation and is well mixed with solvents such as water, ethanol, benzene, ether and the like. It is mixed with gasoline and used as cold fuel for automobiles. It is mixed with ethanol, .

Anyway, it is necessary to neutralize the acetone adhered to the surface of the product with methanol, and in the washing step, the product treated in the acetone neutralization step is washed with water, and the water is removed and dried.

The dried spectacle frame is surface-treated in the laser surface treatment step to form an oxide film on the surface of the spectacle frame. In the laser surface treatment step, the surface of the spectacle frame is treated with a laser using a laser processing machine, .

In the laser surface treatment step, the surface of the spectacle frame can be treated with a laser using a laser processor for a short time, so that not only an oxide film can be formed on the surface of the spectacle frame made of magnesium alloy, It is possible to selectively treat only a specific part of the spectacle frame.

It is a matter of course that it is necessary to create an inert gas atmosphere of nitrogen and argon gas around the laser in the above laser surface treatment step.

On the other hand, since it is impossible to remove fine oil and foreign matters from the surface of the spectacle frame even though the surface of the spectacle frame is washed and dried after the surface of the spectacle frame is removed, In the laser surface treatment step, the spectacle frame is preferably subjected to surface treatment twice with a laser processing machine.

Therefore, in the laser surface treatment step, the surface of the spectacle frame is treated for 5 to 10 seconds at a laser power of 1 to 100 mW using a laser processor to form a first oxide film on the surface of the spectacle frame, step; And a second laser surface treatment step in which an oxide film formed first in the spectacle frame is treated with a laser power of 1 to 50 W for 1 to 15 seconds to form an oxide film secondarily, The surface of the spectacle frame is processed to form an oxide film on the surface of the spectacle frame as shown in Fig.

Here, in the first laser surface treatment step, an oxide film is primarily formed on the surface of the spectacle frame, while foreign substances finely remaining on the surface of the spectacle frame are cleared. In the second laser surface treatment step, And to thicken the oxide film by expanding the thickness.

Of course, if the laser power is lower than 1 mW at the first laser surface treatment step, the surface treatment time is longer than necessary, and when the laser power is higher than 100 mW, the primary oxide film is generated at a higher rate The rigidity of the oxide film may be deteriorated due to the failure to burn minute particles remaining on the surface of the spectacle frame, and the time of the first laser surface treatment step smoothly generates a secondary oxide film in the second laser surface treatment step It is an optimum time considering the optimum thickness of the oxide film and unnecessary waste of time.

When the laser power is lower than 1 W in the second laser surface treatment step, the thickness of the oxide film primarily generated is insufficient. When the laser power is higher than 50 W, the oxide film formation time becomes too short, The activity of the work may be deteriorated. If the surface treatment is performed with a laser for less than 1 second, the thickness of the oxide film may be too thin and corrosion resistance and durability may be deteriorated. If the surface treatment is performed for 15 seconds or more with a laser, the surface of the magnesium alloy- The formed oxide film has a high hardening speed and is hardened easily, and the irregular oxide film can reduce the sophisticated color feeling and wearing feeling that are used for the spectacle frame.

Thus, in the first laser surface treatment step, an oxide film is primarily formed on the surface of the spectacle frame while cleansing microscopic foreign substances adhering to the surface of the spectacle frame, and an oxide film layer formed primarily on the surface of the spectacle frame is firmly formed And an oxide film layer can be formed thicker and more uniformly in the oxide film layer formed first, secondarily in the second laser surface treatment step.

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Claims (2)

Removing and neutralizing the material for removing the surface of the magnesium alloy frame, removing the surface of the frame of the magnesium alloy material frame, cleaning and drying the material, and drying the dried frame of the magnesium alloy material And a surface treatment method of an eyeglass frame made of a magnesium alloy material,
And a laser surface treatment step of treating the surface of the spectacle frame with a laser using a laser processing machine. The method according to claim 1,
The laser surface treatment step may include a first laser surface treatment step of treating the surface of the spectacle frame for 5 to 10 seconds at a laser power of 1 to 100 mW using a laser processor to form an oxide film on the surface of the spectacle frame first ;
And a second laser surface treatment step of forming an oxide film on the surface of the spectacle frame by first treating an oxide film formed on the spectacle frame for 1 to 15 seconds at a laser power of 1 to 50 W using a laser processing machine Wherein the surface of the frame is made of a magnesium alloy material.

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