KR20190036594A - Anodizing plating apparatus - Google Patents

Abstract

The present invention relates to an anodizing partial plating apparatus, and more specifically, to an anodizing partial plating apparatus which can form an oxide film only on an inner wall of a flow path of a fluid distributor having a plurality of flow paths so as to distribute fluid. The anodizing partial plating apparatus according to the present invention is provided to form the oxide film only on the inner wall of a flow path of an object to be plated having a plurality of flow paths so as to distribute fluid, and comprises: a cap member to close the flow path; a supply hose supplying a plating solution to the flow path; a discharge hose through which the plating solution in the flow path is discharged; and an electrode rod piercing through the cap member so as to generate an electric current in the plating solution in the flow path.

Description

[0001] Anodizing plating apparatus [

The present invention relates to an anodizing partial plating apparatus, and more particularly, to an anodizing partial plating apparatus capable of forming an oxide coating only on an inner wall of a flow path of a fluid distributor in which a plurality of flow paths are formed for distributing a fluid.

In general, anodizing is an oxide film (aluminum oxide; Al ₂ O (Al ₂ O _3)), which has a strong adhesion to a base metal by oxygen generated from an anode when a metal or a component is placed on an anode and is electrolyzed in a dilute- ₃ are formed. Anodic oxidation is a compound of the anode and oxidation. In addition, there is a difference from electroplating in which metal parts are plated on a negative electrode. The most representative material of anodic oxidation is aluminum (Al), and anodizing is also performed in metallic materials such as magnesium (Mg), zinc (Zn), titanium (Ti), tantalum (Ta), hafnium (Hf), and niobium Processing. In recent years, the anodizing treatment of magnesium and titanium materials is also increasingly used.

Anodizing, which treats the surface of an aluminum material with an oxide film, when aluminum is electrolyzed from the anode, the aluminum surface is half eroded and half of the aluminum oxide film is formed. Aluminum anodizing can form unshaped membranes with different properties depending on the composition and concentration of various electrolytes, additives, electrolyte temperature, voltage, current, and so on.

As the characteristics of the anodic oxidation coating, the coating is a dense oxide, which is excellent in corrosion resistance, improves the decorative appearance, and the anode coating is considerably hard so that it has excellent abrasion resistance, improves coating adhesion, improves bonding performance, , It can exhibit distinctive colors for decoration purposes, can be pretreated by plating, and can detect surface damage.

In order to treat the hard anodizing of the aluminum metal, the aluminum oxide is immersed in the electrolytic bath containing the electrolytic solution of the acidic solution, and the oxide film is formed on the surface of the metal by flowing a constant voltage and current. The thickness of the film varies.

However, since the oxide film formed by the conventional anodizing surface treatment is formed by dipping in the electrolytic solution, a film is formed on the entire surface of the object to be plated.

However, it is necessary to partially form an oxide film on the surface depending on the object to be plated. Particularly, in the case of a brake fluid distributor, it is necessary to separately form an oxide film on the inner wall of the oil passage through which the brake fluid passes. It is necessary to form an oxide film on the inner wall of the flow path because a piston is inserted into the flow path of the brake fluid distributor and reciprocates to thereby demand high wear resistance. However, since the outer body of the brake fluid dispenser besides the oil line needs to be energized for welding work or electrical control, the formation of an oxide film having an insulating characteristic should be blocked.

Korean Registered Patent No. 10-1169960 (Aug. 06, 2012)

An object of the present invention is to provide an anodizing part plating apparatus capable of effectively forming an oxide film only on the inner wall of a flow path by circulating a plating liquid through a flow path of a plating object in which a plurality of flow paths are formed for distributing a fluid The purpose is to provide.

In order to accomplish the above object, the anodizing part plating apparatus of the present invention is for forming an oxide film only on the inner wall of the flow path of a plating object in which a plurality of flow paths are formed for distributing fluid, ; A supply hose for supplying the plating liquid through the flow path; A discharge hose through which the plating liquid in the flow path is discharged; And an electrode rod penetrating the cap member to generate a current in the plating liquid in the flow path.

The supply hose and the discharge hose are both connected to one cap member, and the plating liquid flowing into the flow path through the supply hose is circulated while being discharged to the discharge hose.

The cap member may include a first cap member for simultaneously blocking one end of the first flow path and one end of the second flow path and a second cap member for blocking the other end of the first flow path, Wherein the first cap member is connected to the first cap member to supply the plating liquid to the first flow path, the first discharge hose is connected to the second cap member to discharge the plating liquid in the first flow path, And the second supply hose is connected to the first cap member to supply the plating liquid to the second flow path while the second discharge hose communicates with the second flow path And the second electrode rod penetrates through the first cap member to generate a current in the plating liquid in the second flow path.

The discharge hose is formed with an oxidation reaction discharge confirmation window for confirming bubbles generated by anodizing plating.

The supply hose is provided with a flow rate control valve.

The anodizing part plating apparatus of the present invention can partially improve the wear resistance by circulating the plating liquid through the flow path of the plating object in which a plurality of flow paths are formed for distributing the fluid, effectively forming an oxide film only on the inner wall of the flow path.

1 is a perspective view of an anodizing partial plating apparatus coupled to a plating object according to an embodiment of the present invention;
FIG. 2 is a perspective view of a plating object and an anodizing partial plating apparatus according to an embodiment of the present invention, viewed from one direction. FIG.
FIG. 3 is a perspective view of an object to be plated and an anodizing partial plating apparatus according to an embodiment of the present invention viewed from one direction. FIG.
FIG. 4 is a view showing a separate anodizing part plating apparatus including a first cap member and a second cap member according to an embodiment of the present invention; FIG.
FIG. 5 is a view of another embodiment of an anodizing partial plating apparatus including a third cap member according to an embodiment of the present invention. FIG.
6 is a view showing a flow of a plating liquid according to an embodiment of the present invention.
Figure 7 illustrates an anodizing partial plating system in accordance with an embodiment of the present invention.
8 shows a cleaning system of an anodizing partial plating apparatus according to an embodiment of the present invention.

In the present invention, a plating object is provided with a plurality of flow paths for distributing fluid, and the anodizing part plating apparatus of the present invention is for forming an oxide coating only on the inner wall of the flow path.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

An anodizing partial plating apparatus according to an embodiment of the present invention basically comprises a cap member, a supply hose, a discharge hose and an electrode.

1 to 3, a first flow path L1, a second flow path L2 and a third flow path L3 are formed on the object A to be plated according to the embodiment of the present invention. An outlet 60 communicating with the second flow path L2 is formed in the object A to be plated.

Specifically, the object A to be plated in this embodiment can be a brake fluid distributor for distributing the brake fluid. The first flow path L1 is opened to both sides of the object A to be plated and penetrates the object A to be plated and the second flow path L2 is opened in one direction and communicated with the discharge port 60. [ The third flow path L3 is opened only in one direction.

The cap member is composed of a first cap member 10, a second cap member 20, and a third cap member 30 depending on the position to which the cap member is coupled.

As shown in FIG. 2, the first cap member 10 simultaneously blocks one end of the first flow path L1 and one end of the second flow path L2. The first cap member 10 is connected to a first supply hose 11 for supplying the plating liquid to the first flow path L1. The first cap member 10 is coupled to the first electrode rod 12 through the first cap member 10 to generate a current in the plating liquid in the first flow path L1.

The first cap member 10 is connected to a second supply hose 13 for supplying the plating liquid to the second flow path L2. A second electrode rod 14 is coupled to the first cap member 10 through the first cap member 10 to generate a current in the plating liquid in the second flow path L2.

As shown in FIG. 3, the second cap member 20 blocks the other end of the first flow path L1. The first flow path L1 is closed by the first cap member 10 and the second cap member 20. The first discharge hose 21 is connected to the second cap member 20 to discharge the plating liquid in the first flow path L1.

The discharge port 60 communicating with the second flow path L2 is connected to the second discharge hose 22 to discharge the plating solution in the second flow path L2.

As shown in FIG. 2 or 3, the third cap member 30 blocks the third flow path L3. The third flow path L3 is opened only in one direction and closed by the third cap member 30. [ The third cap member 30 is connected to the third supply hose 31 for supplying the plating liquid to the third flow path L3 and the third discharge hose 32 for discharging the plating liquid in the third flow path L3. Respectively. A third electrode rod 33 penetrating the third cap member 30 and generating a current in the plating liquid in the third flow path L 3 is coupled to the third cap member 30.

As shown in FIGS. 4 and 5, the liquid injection confirmation transmission window 41 is formed in the first to third supply hoses 11, 13 and 31 described above. Confirmation of liquid injection The transparent window 41 is made of a transparent material and is formed in a cylindrical shape larger than the thickness of the hose, so that the plating liquid passing through the hose can be easily confirmed.

An oxidation reaction discharge confirmation window 42 is formed in the first to third discharge hoses 21, 22 and 32. The oxidation reaction discharge confirmation window 42 is made of a transparent material similar to the liquid injection confirmation window 41 and has a cylindrical shape larger than the thickness of the hose. Bubbles are generated when an anodic coating is formed on the inner walls of the first to third flow paths L1, L2 and L3 by the anodizing, and these bubbles are discharged through the first to third discharge hoses 21, 22, And is discharged to the outside. At this time, the bubble discharged together with the plating solution can be confirmed through the oxidation reaction discharge confirmation window 42. Accordingly, the operator can easily confirm that the anodizing plating operation is normally performed in the first to third flow paths L1, L2, and L3.

The first to third supply hoses 11, 13 and 31 are provided with a flow rate control valve 50 so that the first to third flow passages L1 to L3 are connected via the first to third supply hoses 11, L2, and L3 of the plating liquid.

Next, the inner wall plating work of the plating object (A) (brake fluid distributor) using the anodizing partial plating apparatus according to the embodiment of the present invention will be described in order.

First, as shown in FIG. 1, the first cap member 10 is coupled to the object A so that the first flow path L1 and the second flow path L2 are blocked. At this time, the first electrode rod 12 is inserted into the first flow path L1, and the second electrode rod 14 is inserted into the second flow path L2.

Then, the second cap member 20 is bonded to the object A so that the first flow path L1 is closed. That is, the first cap member 10 and the second cap member 20 are bonded to the opposite surfaces of the object A to be plated.

Further, the second discharge hose 22 is connected to the discharge port 60.

The third cap member 30 is coupled to the upper portion of the object A to be closed so that the third flow path L3 is closed. At this time, the third electrode rod 33 is inserted into the third flow path L3.

In the present embodiment, as shown in FIG. 7, a system for plating the inner wall of the flow path of the object A with an anodizing part includes a plating liquid reservoir 70 in which a plating liquid is stored and a cleaning water tank 80 in which wash water is stored do. The plating liquid storage tank 70 and the cleaning water tank 80 each have a pump (not shown). The plating liquid storage tank 70 and the washing water tank 80 may be selectively connected to the first to third supply hoses 11, 13 and 31 by the control of a valve.

The present system is provided with a recovery line 71 connected to the plating liquid reservoir 70 for circulating the plating liquid. Further, as shown in Fig. 8, the present system is provided with a drainage tank 82 and a drainage line 81 for discharging wash water. The first to third discharge hoses 21, 22 and 32 are connected to the collecting line 71 by the operator to send the plating liquid to the plating liquid reservoir 70 or to the drain line 81 to discharge the washing water to the drain tank 82 ). ≪ / RTI >

The valve of the cleaning water tank 80 is closed and the valve of the plating liquid storage tank 70 is opened in order to anodize the inner wall of the flow path of the object A to be anodized. And the first to third discharge hoses (21, 22, 32) are connected to the recovery line (71). 6, when the pump connected to the plating liquid reservoir 70 is operated, the plating liquid is supplied to the first through third flow paths L1, L2 through the first through third supply hoses 11, L2, and L3.

7, the plating liquid in the first to third flow paths L1, L2, L3 is discharged through the first to third discharge hoses 21, 22, 32, and the plating liquid in the recovery line 71 And is recovered into the plating solution reservoir 70.

At this time, the object A to be plated is electrically connected to the (-) terminal, the first to third electrode rods 33 are electrically connected to the (+) terminal, and the first to third flow paths L1, Thereby generating a current in the plating liquid in the plating liquid. Accordingly, an oxide film is formed only on the inner walls of the first to third flow paths L1, L2, and L3, and the remaining portion of the object A is not formed with an oxide film.

On the other hand, after completing the anodizing partial plating operation, the first to third flow paths L1, L2 and L3 can be cleaned. First, the first to third discharge hoses (21, 22, 32) are connected to a drain line (81). Then, the valve of the plating solution reservoir 70 is closed and the valve of the cleaning water tank 80 is opened. 8, when the pump connected to the washing water tank 80 is actuated, the washing water flows through the first to third supply hoses 11, 13 and 31 through the first to third flow paths L1, L2, and L3, and is discharged through the first to third discharge hoses 21, 22, and 32. [ The first to third discharge hoses 21, 22, and 32 are connected to the drain line 81, and the wash water is discharged to the drain tank 82.

The anodizing partial plating apparatus according to the present invention is not limited to the above-described embodiments but can be variously modified and embodied within the scope of the technical idea of the present invention.

10: first cap member, 11: first supply hose,
12: first electrode rod, 13: second supply hose,
14: second electrode rod, 20: second cap member,
21: first discharge hose, 22: second discharge hose,
30: third cap member, 31: third supply hose,
32: third discharge hose, 33: third electrode,
41: Confirmation of liquid injection transmission window, 42: Confirmation of oxidation reaction discharge transmission window,
50: Flow control valve, 60: Exhaust port,
70: plating solution reservoir, 71: recovery line,
80: washing water tank, 81: drainage line,
82: drainage tank,

Claims (5)

An anodizing part plating apparatus for forming an oxide film only on an inner wall of a flow path of a plating object in which a plurality of flow paths are formed for distributing a fluid,
A cap member for closing the flow path;
A supply hose for supplying the plating liquid through the flow path;
A discharge hose through which the plating liquid in the flow path is discharged; And
And an electrode rod penetrating the cap member to generate a current in the plating liquid in the flow path. The method according to claim 1,
Wherein the cap member is connected to both the supply hose and the discharge hose, and the plating liquid circulating through the supply hose is circulated while being discharged to the discharge hose. The method according to claim 1,
Wherein the cap member includes a first cap member that simultaneously blocks one end of the first flow path and one end of the second flow path and a second cap member that blocks the other end of the first flow path,
The first supply hose is connected to the first cap member to supply the plating liquid to the first flow path,
The first discharge hose is connected to the second cap member to discharge the plating liquid in the first flow path,
The first electrode rod penetrates the first cap member to generate a current in the plating liquid in the first flow path,
The second supply hose is connected to the first cap member to supply the plating liquid to the second flow path,
The second discharge hose is connected to an outlet communicating with the second flow path to discharge the plating liquid in the second flow path,
And the second electrode rod penetrates the first cap member to generate a current in the plating liquid in the second flow path. The method according to claim 1,
Wherein the discharge hose is formed with an oxidation reaction discharge confirmation window for confirming bubbles generated by anodizing plating. The method according to claim 1,
Wherein the supply hose is provided with a flow control valve.

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