KR101116782B1 - Apparatus and method for selective plating using a catalyst - Google Patents

Abstract

The present invention relates to a partial plating apparatus and a partial plating method using a catalyst, wherein the partial plating apparatus using a catalyst according to the present invention includes a catalyst for immersing a plated body, and is set in advance on the plated surface of the plated body. A laser beam irradiation unit capable of forming a micro crack by irradiating a laser beam with a pattern; A plating part including a plating solution for dipping the plated body; And a transfer member capable of transferring the to-be-plated body along the laser beam irradiation unit and the plating unit.

Plating, partial plating, laser, catalyst

Description

Partial Plating Apparatus and Partial Plating Method Using Catalysts {APPARATUS AND METHOD FOR SELECTIVE PLATING USING A CATALYST}

The present invention relates to a partial plating apparatus and a partial plating method using a catalyst, and more particularly, to a partial plating apparatus and a partial plating method using a catalyst capable of forming a plating pattern with a laser.

Plating refers to the coating of a thin layer of another material for the purpose of improving the surface condition of an article, generally to the coating of a thin layer of another metal or alloy on a metal surface.

Types of plating include electroplating, anodizing, phosphate coating, electroless plating, and the like, generally referring to electroplating.

Electroplating is an electrochemical decomposition method in which a metal material to be plated is connected to an anode and a product to be plated is electrically connected to a cathode, thereby dissolving at the anode and depositing metal ions at the cathode.

Unlike electroplating, anodization is a method of artificially forming an oxide film by generator oxygen by placing a product on the anode. Phosphate coating is a process that does not use electricity. It is a method of forming a film by chemical action, and electroless plating is a method of forming a plating layer on the surface of a product by using an appropriate reducing material for the metal component contained in the plating liquid without using electricity.

The plating process on only a part of the surface of the object is called selective plating or selective plating. In the plating method, the plating solution is partially immersed in the plating solution, and the plating solution is partially used by using a nozzle. There existed a method of spraying a plating solution to a desired site using an absorber such as a spraying method or a nonwoven fabric, or a method of forming a plating pattern with a mask in advance and performing exposure and etching processes.

However, according to the conventional partial plating method as described above, it is impossible to immerse a minute portion of the plated body in the plating solution, it is impossible to spray to form a fine line using a nozzle, and to be buried in the minute portion using an absorber. Since this is impossible, there was a problem that a complicated pattern and a fine pattern of several μm cannot be formed.

In addition, there is a problem in that a mask is manufactured to perform plating treatment only on a part of the region, and a complicated process such as exposing, developing, and etching the plated body is required.

In addition, when the mask is manufactured and subjected to the exposure and etching process, in order to form various plating patterns, a plurality of masks must be manufactured separately for each plating pattern, which causes costly problems and problems of polluting the environment by using etching solutions. .

The present invention has been made to solve the above problems, and an object thereof is to provide a partial plating apparatus and a partial plating method capable of forming a complex pattern, a fine pattern of several μm.

Another object of the present invention is to provide a partial plating apparatus and a partial plating method capable of simplifying a conventional complicated partial plating process and easily implementing various plating patterns.

Another object is to provide a partial plating apparatus and a partial plating method which can prevent environmental pollution by not using an etching solution used in a conventional partial plating process.

Partial plating apparatus using a catalyst according to the present invention according to the above object comprises a catalyst for immersing the body to be plated, to form a micro crack by irradiating a laser beam in a predetermined pattern on the plated surface of the body to be plated A laser beam irradiator; A plating part including a plating solution for dipping the plated body; And a transfer member capable of transferring the to-be-plated body along the laser beam irradiation unit and the plating unit.

The laser beam irradiator further includes a cleaning unit capable of cleaning the plated body irradiated with the laser beam.

The laser beam irradiation unit includes a laser device for irradiating the laser beam, the laser device is characterized in that the two-dimensional plane or three-dimensional three-dimensional processing device.

The moving speed of the laser device is characterized in that the same as the moving speed of the transfer member.

The laser beam irradiation unit further includes a control unit for controlling the operation of the laser device according to a set pattern.

The laser device includes a spot size variable module, a focus variable module, and a laser energy homogenizer.

The partial plating apparatus according to the present invention includes a supply buffer capable of adjusting the supply of the plated body; A pre-processing unit capable of washing the plated body before the laser beam irradiation unit; And a recovery buffer for controlling the recovery of the plated body.

The partial plating method using the catalyst according to the present invention comprises the steps of: (A) dipping the plated body in the catalyst; (B) irradiating a laser beam with a predetermined pattern on the plated body to form micro cracks; (C) dipping the plated body in a plating solution; (D) cleaning the plated body.

The step (B) is characterized in that it further comprises the step of washing the plated surface of the plated body.

The partial plating apparatus and the partial plating method using the catalyst according to the present invention as described above have the following effects.

The partial plating apparatus and the partial plating method using the catalyst according to the present invention form a plating pattern by irradiating a laser beam through a laser device including a spot size variable module, a variable focus module, and a laser energy homogenizer, thereby forming a complex pattern. There is an effect of forming a fine pattern of several μm.

In addition, the partial plating apparatus and the partial plating method using the catalyst according to the present invention can simplify the conventional complicated partial plating process by partial plating using a laser beam, it is possible to easily implement a variety of plating patterns, masks There is no effect to reduce the cost because it is not manufactured separately.

In addition, the partial plating apparatus and the partial plating method using the catalyst according to the present invention do not use the etching liquid used in the conventional partial plating process, thereby having an effect of preventing environmental pollution.

In addition, there is an effect that the production speed and efficiency can be increased by performing each step of the partial plating continuously by the transfer member.

Hereinafter, the partial plating apparatus using the catalyst according to the present invention with reference to the accompanying drawings in detail as follows.

1 is a view showing an embodiment of a partial plating apparatus using a catalyst according to the present invention.

As shown in FIG. 1, the partial plating apparatus using the catalyst according to the present invention includes a catalyst for immersing a plated body, and irradiates a microcracks by irradiating a laser beam with a predetermined pattern on the surface to be plated of the plated body. The laser beam irradiation part 106 and the plating part 108 containing the plating liquid which immerses the said to-be-plated body are comprised.

In the laser beam irradiation section 106, the plated body is immersed in the catalyst, and the laser beam is irradiated to the plated surface of the plated body to form micro cracks. In this case, the laser beam irradiation unit 106 preferably includes a container for dipping the plated body into the catalyst. Microcracks are microcracks that occur on the plated body. Forming methods vary, but in the embodiment of the present invention, microcracks are formed by irradiating a laser beam, and microcracks are formed only in a portion where the laser beam is irradiated. Enters, and only the corresponding portion of the plated body is subjected to catalytic treatment.

The laser beam irradiation unit 106 further includes a laser device for irradiating the laser beam and a control unit for controlling the movement of the laser device. In this case, the laser device is preferably a two-dimensional plane or three-dimensional three-dimensional processing device, and when a predetermined pattern is input through the control unit, the laser device irradiates a laser beam on the two-dimensional plane or three-dimensional stereoscopic according to the input pattern do. Therefore, when the changed pattern is inserted into the control unit of the laser beam irradiation unit 106 to change the plating pattern, the control unit controls the movement of the laser device according to the changed pattern, so that the plating pattern can be easily changed. In this way, only the portion of the laser beam irradiator 106 that is desired to be plated to form a microcracks is subjected to catalytic treatment, thereby partially plating the desired pattern.

The laser device includes a spot size variable module, a focus variable module, and a laser energy homogenizer. The spot size variable module reduces the focus spot through the process of increasing the size of the laser beam irradiated by the focusing lens of the laser device. Through this, the line width to which the laser beam is irradiated can be adjusted. The variable focus module corrects an error in the optical path through the correction optical system to correct the light reflected from the reflector of the laser device and adjusts the light emitted from the correction optical system to focus on a desired portion through the focusing lens. This allows you to accurately focus the protrusion or depression. The laser energy homogenizer makes the energy distribution of the cross section of the laser beam uniform. Through this, the thickness of the center and the outer portion of the portion irradiated with the laser beam may be constant.

Figure 2a is a view showing the energy distribution of the laser beam cross section by the laser device according to the prior art, Figure 2b is a diagram showing the energy distribution of the laser beam cross section by the laser device according to the present invention. Referring to Figures 2a and 2b, the energy distribution of the cross section of the laser beam by the laser device according to the prior art has a high Gaussian distribution in the center portion and low peripheral portion, while the laser beam in the laser device according to the present invention The energy distribution of the cross section is represented uniformly throughout by the laser energy homogenizer.

In the plating unit 108, the plated body is immersed in the plating solution, and the plating layer is formed by various known methods such as electroplating, anodizing, phosphate coating, and electroless plating. At this time, the plating layer is formed only on the selected portion where the microcracks are formed and catalyzed by the laser device of the laser beam irradiator 106, and partial plating of a desired pattern is performed.

The partial plating apparatus using the catalyst according to the present invention may include a laser beam irradiator 106 and a transfer member (not shown) capable of transferring the plated body along the plating unit 108. Therefore, plating is performed while the plated body is moved by the transfer member.

The partial plating apparatus using the catalyst according to the present invention may further include a first washing unit 120 before the laser beam irradiation unit 106, and further includes a third washing unit 124 after the plating unit 108. The laser beam irradiator 106 may further include a second cleaning unit 122. The first washing unit 120, the second washing unit 122, and the third washing unit 124 serve to wash the plated body. The first cleaning unit 120 may remove impurities on the outer surface of the plated body by washing the plated body before immersing the plated body in the catalyst. The second cleaning unit 122 can easily remove the catalyst remaining on the outer surface of the to-be-plated body by irradiating a laser beam to the to-be-plated body and then removing the to-be-plated body from the catalyst. At this time, the catalyst inside the microcracks remains on the plated body, and the catalyst remaining on the outside of the microcracks is removed. The third cleaning unit 124 may easily remove the plating solution remaining on the plated body by removing the plated body from the plating solution and then washing the plated body.

It is preferable that the start stage of the partial plating apparatus using the catalyst according to the present invention further includes a supply buffer, and the end stage further includes a recovery buffer. The supply buffer can control the supply of the plated body, and the recovery buffer can control the number of the plated body, so that the plating process can be continuously performed while the plated body moves smoothly by the transfer member.

The laser beam irradiator 106 of the partial plating apparatus using the catalyst according to the present invention may further include a pretreatment unit, and the pretreatment unit may prepare the plated body in a constant state before immersion in the catalyst such as washing the plated body. Can be. In this case, the first cleaning unit 120 may be included in the pretreatment unit.

Partial plating apparatus using a catalyst according to an embodiment of the present invention is configured as a device that can be performed once partial plating, but the present invention is not limited to this, partial plating so that a plurality of partial plating can be formed of a plurality of layers A plurality of devices can be connected and formed. In addition, the entire plating apparatus and the partial plating apparatus capable of plating the entire surface of the plated body may be combined to be formed.

Hereinafter, the partial plating method using the catalyst according to the present invention with reference to the accompanying drawings in detail as follows.

3A to 3F are cross-sectional views showing an embodiment of a partial plating method using a catalyst according to the present invention.

According to the partial plating method using the catalyst according to the present invention, as shown in FIG. 3A, the plated body 210 is washed as a pretreatment step to remove impurities on the outer surface of the plated body 210.

As shown in FIG. 3B, the plated body 210 is immersed in the catalyst 260, and the laser beam 220 is irradiated onto the plated surface of the plated body 210 to form micro cracks. The micro cracks are formed only in the portion to which the laser beam 220 is irradiated, so that the micro cracks are catalytically treated only in the corresponding portion of the plated body 210. The laser beam 220 is irradiated from a laser device (not shown), and the laser device is controlled to perform two-dimensional or three-dimensional solid processing by a controller (not shown). Accordingly, only a portion of the desired plating may be selectively formed into microcracks, and the catalyst may be treated.

As shown in FIG. 3C, the catalyst body 260 remaining on the outer surface of the plated body is removed by removing the plated body 210 from the catalyst 260 and washing the same. At this time, the catalyst 260 inside the microcracks remains on the plated body 210, and only the catalyst 260 remaining outside the microcracks is removed.

As shown in FIG. 3D, the plated body 210 is immersed in the plating solution 230, and the plating layer 240 is formed by various known methods such as electroplating, anodizing, phosphate coating, and electroless plating. do. At this time, the plating layer 240 is formed only in the selected portion where the microcracks are formed and catalyzed by the laser device, partial plating of the desired pattern is performed.

As shown in FIG. 3E, the plated body 210 on which the plating layer 240 is formed is washed to remove the plating solution still remaining on the plated body 210.

As shown in FIG. 3F, the plating layer 240 is formed on the surface to be plated of the plated body 210 to complete partial plating of a desired pattern.

In the partial plating method using the catalyst according to the present invention, before immersing the to-be-plated body 210 in the catalyst 260, the catalyst is removed from the catalyst 260, and after the plating layer 240 is formed, the washing process is performed, respectively. In some cases, it may be omitted and proceeded.

In the partial plating method using the catalyst according to the embodiment of the present invention, the partial plating method is configured to be performed once, but the present invention is not limited thereto, and the partial plating method may be performed so that a plurality of partial platings may be formed of a plurality of layers. It can be done multiple times in succession. In addition, the entire plating method and the partial plating method that can be plated on the entire surface of the plated body may be combined.

The plated body and the plating liquid used in the partial plating apparatus and the partial plating method using the catalyst according to the present invention may use various metals, nonmetals and the like according to the needs of the user.

Although the embodiments of the present invention have been described above, the present invention is not limited to the above embodiments, and those skilled in the art to which the present invention pertains can be changed and modified within the scope of the present invention. .

1 is a view showing an embodiment of a partial plating apparatus according to the present invention

Figure 2a is a view showing the energy distribution of the laser beam cross section by the laser device according to the prior art

Figure 2b is a view showing the energy distribution of the laser beam cross section by the laser device according to the present invention

3A to 3F are cross-sectional views showing an embodiment of the partial plating method according to the present invention.

Claims (9)

A laser beam irradiator including a catalyst for immersing a to-be-plated body and irradiating a laser beam in a predetermined pattern on a surface to be plated of the to-be-plated body soaked in the catalyst; A plating part including a plating solution for dipping the plated body on which the microcracks are formed; And And a transfer member capable of transferring the plated body along the laser beam irradiation unit and the plating unit. Partial plating apparatus using a catalyst. The method of claim 1, The laser beam irradiation unit further comprises a cleaning unit for irradiating the laser beam irradiated with the laser beam to wash the plated body is formed, Partial plating apparatus using a catalyst. The method of claim 1, The laser beam irradiation unit It includes a laser device for irradiating the laser beam, The laser device is characterized in that the two-dimensional plane or three-dimensional solid-state processing device, Partial plating apparatus using a catalyst. The method of claim 3, wherein The moving speed of the laser device is characterized in that the same as the moving speed of the conveying member, Partial plating apparatus using a catalyst. The method of claim 3, wherein The laser beam irradiation unit Further comprising a control unit for controlling the operation of the laser device according to a set pattern, Partial plating apparatus using a catalyst. The method of claim 3, wherein The laser device includes a spot size variable module, a focus variable module, and a laser energy homogenizer, Partial plating device. The method of claim 1, A supply buffer for controlling supply of the plated body; A pre-processing unit capable of washing the plated body before the laser beam irradiation unit; And Further comprising a recovery buffer for controlling the recovery of the plated body, Partial plating apparatus using a catalyst. (A) dipping the plated body in the catalyst; (B) irradiating a laser beam in a predetermined pattern to the plated body contained in the catalyst to form microcracks, and then removing the plated body on which the microcracks are formed from the catalyst; (C) dipping the plated body taken out from the catalyst in a plating solution and then taken out; (D) cleaning the plated body taken out of the plating liquid, Partial plating method using a catalyst. The method of claim 8, Step (B) is, Characterized in that it further comprises the step of washing the plated surface of the plated body taken out from the catalyst, Partial plating method using a catalyst.

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