KR20120132027A - plating flight bar - Google Patents

Abstract

PURPOSE: A flight bar for plating is provided to remove bubbles from a substrate with high efficiency by elastically fixing first and second bars with a damping connection part so that the second bar can shake smoothly by vibration. CONSTITUTION: A flight bar for plating comprises a first bar(2), a second bar(4), a damping connection part(6), a vibration generating part(8), a driving connection part(10), and an electric shock prevention part(12). The damping connection part includes a damping connector for connecting the first and second bars with a damping effect. The vibration generating part includes a vibrator installed on the side of the second bar to provide vibration to a plating rack. The driving connection part includes connectors which are connected to each other when the first bar hangs on a saddle to apply electricity for driving the vibration generating part. The electric shock prevention part blocks the exterior of the connectors to insulate the same when the connectors of the driving connection part are connected or disconnected.

Description

Plating flight bar

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a plating flight bar for use in plating operations of various circuit board manufacturing substrates.

In general, during the manufacturing process of a thin film circuit board, such as a printed circuit board (PCB), there is a process of plating a circuit board manufacturing substrate (hereinafter referred to as "substrate").

This plating process mainly proceeds with the electrolytic (electro) plating method which is known to be excellent in plating quality and can shorten the plating time among various plating methods, in addition to the electroless plating (chemical plating) method.

Briefly describing the electrolytic plating operation, the plating rack is held by a mounting apparatus called a flight bar, and the substrate is immersed in a plating bath to plate the substrate by an electrolytic method.

In particular, the flight bar is formed so that the plating operation can be carried out while holding the plating rack, each end of which is placed on the saddle (saddle) side installed on the opposite edge of the plating bath.

According to such an electroplating method, it is very important to proceed with plating in a state in which bubbles can be prevented from adhering to the surface of the substrate, in particular, when plating the substrate while holding the plating rack.

However, the flight bar is limited to a structure that simply holds the plating rack in a state where electroplating is possible on the plating tank side, so that bubbles stuck to the surface of the substrate can be smoothly separated and removed, especially in a state where the substrate is immersed in the plating bath. none.

Therefore, excessive defect quality may occur due to bubbles in the plating operation of the substrate.

Recently, in order to reduce the quality of defects caused by bubbles, for example, a method of separating and removing bubbles from a substrate in a manner in which a worker shakes a flight bar or a plating rack directly is used.

However, it is difficult for the operator to manually move the flight bar or the plating rack to smoothly separate and remove the bubbles from the substrate.

In particular, when the flight bar or the plating rack is moved, the connection between the saddle and the flight bar is made irregular may cause a serious problem that the electrolytic action is not performed smoothly.

The present invention has been proposed to solve the above problems,

An object of the present invention is to provide a flight bar for plating that can proceed the plating operation in a state that can be easily separated and removed bubbles stuck to the substrate side contained in the plating bath.

In order to achieve the object as described above,

A first bar extending to extend at both ends on the side of the saddle disposed with the plating bath interposed therebetween;

A second bar spaced apart from and parallel to the first bar to hold the plating rack;

A buffer connecting portion having a buffer connector formed to bufferably connect between the first bar and the second bar;

A vibration generating unit having a vibrator installed at the second bar side to transmit vibration to the plating rack side;

A driving connecting portion having connection holes formed to be connected to each other when the first bar is connected to the saddle and configured to apply electricity for driving the vibrator;

An electric shock prevention unit formed to cover the outer surfaces of the connection ports in an insulated state when the connection ports of the driving connection parts are connected to or disconnected from each other;

It provides a flight bar comprising a.

As described above, the present invention connects the first bar and the second bar with the buffer connection part, and installs a vibration generating part on the second bar side for holding the plating rack so that the vibration generated from the vibration generating part is transmitted to the plating rack side. By providing the structure, bubbles stuck to the substrate side contained in the plating bath can be easily separated and removed from the substrate using vibration.

In addition, the buffer connection part provides a structure capable of elastically connecting and fixing the buffer bar between the first bar and the second bar, so that the second bar can be smoothly shaken by vibration and further increase the separation removal force of the bubble. In addition, it is possible to prevent the vibration from being transmitted to the first bar side, thereby preventing the first bar from being abnormally shaken by the vibration on the saddle side.

In particular, the present invention, since the connection is made in a state capable of preventing electric shock when the first bar is applied to the saddle side, and is provided with a drive connecting portion and an electric shock prevention portion respectively formed so as to apply electricity to the vibration generating side. Improved work safety can be achieved.

1 to 3 are diagrams schematically showing the overall structure and internal structure of the plating flight bar according to an embodiment of the present invention.
4 and 5 are views for explaining the operation of the buffer connection portion and the vibration generating portion of the plating flight bar according to an embodiment of the present invention.
6 and 7 are views for explaining the detailed structure of the driving connection portion and the electric shock prevention portion of the plating flight bar according to an embodiment of the present invention.
8 and 9 are views for explaining the operation of the driving connection portion and the electric shock prevention portion of the plating flight bar according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

The embodiments of the present invention will be described by those skilled in the art to which the present invention is applicable.

Therefore, the embodiments of the present invention can be modified into various other forms, so that the claims of the present invention are not limited by the embodiments described below.

1 to 3, reference numeral 2 designates a first bar and reference numeral 4 designates a second bar.

The first bar 2 and the second bar 4 are formed so as to correspond to the normal saddle spacing S arranged on the opposite edge side of the plating bath T as shown in FIG. 1.

That is, the first bar 2 is formed to extend so that both ends have a length that can be over the saddle (S) side, arranged in the direction connecting between the opposite edges of the plating bath (T) during the plating operation do.

Both end portions of the first bar 2 may be provided with the engaging portions 2a as shown in FIG. 1. Then, although not shown in the drawing, one side of a conventional hoist device (eg, hook) can be easily transported on the side of the hooking portion 2a.

The second bar 4 extends to a length corresponding to the first bar 2, and a plating rack R is installed to allow the substrate G to be plated.

For example, as shown in FIG. 1, a normal cathode bar Q is installed below the second bar 4, and the upper part of the plating rack R is fixed to the cathode bar Q side. Can be.

The said 1st bar 2 and the 2nd bar 4 are provided in the state spaced apart and parallel and spaced apart.

The first bar 2 and the second bar 4 are spaced apart from each other so as to have a space capable of securing a space for installing the shock-absorbing connection part 6 and the vibration generating part 8 described later.

The first bar 2 and the second bar 4 are provided without being directly connected to each other, and the first bar 2 is supported on the saddle S side of the plating bath T. And the second bar 4 serves to hold the plating rack (R).

When the first bar 2 is disposed to correspond to the plating bath T, a current supply for electroplating may be formed on the plating rack R side.

For example, although not shown in the drawing, an external electric current is connected to one side of the saddle S so that when the end of the first bar 2 spans the saddle S side, an external current is generated from the saddle S and the first side. Through the one bar (2) and the cathode bar (Q) can be applied to the plating rack (R) side.

Then, since the current is automatically supplied to the plating rack R side when the first bar 2 is applied to the saddle S side, it is possible to secure an improved operation convenience.

Plating flight bar according to an embodiment of the present invention, including a buffer connection (6).

The buffer connection part 6 is formed to be capable of buffer connection between the first bar 2 and the second bar (4).

The shock absorbing connector 6 is provided with a shock absorbing connector (C), and the shock absorbing connector (C) is set to have a connection structure that can elastically cushion shocks or vibrations acting in the up, down, left, and right directions. do.

That is, the shock-absorbing connector (C), for example, may be used as the rubber plate bent in a substantially U "shape, as shown in Figure 2, the lower portion of the first bar (2) in the state that the two are disposed to correspond to each other The inner surface is fixed to one side, the upper portion may be installed in a fixed state on the inner side of the second bar (2).

In addition to the substantially "U" shaped rubber plate, the shock-absorbing connector (C) may use a rubber plate of various shapes capable of bufferably connecting the first bar (2) and the second bar (4).

In addition, the above-mentioned shock-absorbing connector (C) is not limited to using a rubber plate, and in addition, although not shown in the drawings, ordinary springs (for example, coil springs and leaf springs) may be used.

In addition, the buffer connector (C) may be provided with one or more spaced apart between the first bar (2) and the second bar (4) as shown in FIG.

Plating flight bar according to an embodiment of the present invention, comprises a vibration generating portion (8).

The vibration generating unit 8 is forcibly separating and removing bubbles W1 stuck to the surface of the substrate G by vibrating when the plating operation is performed while the plating rack R is immersed in the plating tank T. It is formed to be.

The vibration generator 8 includes a vibrator V, which is attached to the second bar 4 side.

That is, the vibrator V may be provided, for example, with one side attached to the second bar 4 side between the first bar 2 and the second bar 4 as shown in FIG. 3. Can be.

Although not shown in the drawing, the vibrator V may have a conventional structure that generates vibration while moving the vibrating element by a magnetic driving method or a motor driving method.

In addition, as shown in FIG. 3, the vibrator V penetrates through one side of the first bar 2 between the two bars 2 and 4 and protrudes outwardly, and the protruding portion is a separate cover V1. It is good to install so that it is covered by).

Then, when the vibrator V is installed between the first bar 2 and the second bar 4, a space can be easily secured and can be protected from external impact or contact.

One or more vibrators V may be provided on the second bar 4 side according to a required working environment.

When the vibrator V is provided on the second bar 4 side, the vibration generated by the driving of the vibrator V passes through the second bar 4 and the cathode bar Q, and the plating rack R is provided. Can be delivered to the side.

That is, if the connection between the first bar (2) and the second bar (4) by the buffer connection portion 6 as described above, and the vibration generating portion 8 is installed on the second bar (4) side, Figure 4 As described above, the vibration generated by the driving of the vibrator V may be smoothly transmitted to the plating rack R side while suppressing transmission of the vibration from the second bar 4 side to the first bar 2 side. Can be.

In addition, since the second bar 4 is elastically connected and fixed to the first bar 2 side by the buffer connection part 6, the plating rack is elastically moved by the vibration generated from the vibrator V side. The vibration can be more smoothly transmitted to the R) side.

Therefore, as shown in FIG. 5, when plating the substrate G while the plating rack R is immersed in the plating tank T side, the bubbles W1 stuck to the surface of the substrate G are vibrated from the vibrator V. FIG. It can be easily separated and forcibly removed by the drive of.

On the other hand, the plated flight bar according to an embodiment of the present invention, the vibration generating unit 8 and the drive connecting portion 10 and the electric shock prevention portion 12 is formed.

The driving connecting portion 10 is formed so as to supply electricity for driving the vibration generating part 8 from the outside while the connection is made when the first bar 2 is placed on the saddle S side.

6 and 7, the driving connector 10 includes a first connector J disposed on the saddle S side, and the first bar 2 so as to correspond to the first connector J. FIG. It may be provided with a second connector (K) disposed on the side.

The first connector J may be formed in a rod shape, and two ("+" and "-" poles) are spaced apart at one side of the saddle S with one end facing upward. Can be placed in an upright position.

The second connector K may be formed in a rod shape corresponding to the first connector J, and may be disposed in a state of being erected at one end of the first bar 2 with one end facing downward. have.

The first and second connectors J and K may be installed at the saddle S or the first bar 2 in a state of being fixed to a separate bracket B side as shown in FIG. 6. .

Although the first connector J and the second connector K are not shown in the drawings, the first connector J and the second connector K, for example, are connected in a state in which some of the ends are fitted to each other, or in addition, some surfaces thereof are in simple contact (face contact). It can be formed so that the connection is made.

Although the first connector J and the second connector K are not shown in the drawing, when the connection is made with each other, the first connector J is supplied with electricity from the outside, and the second connector K is the vibration. It is connected in a conventional manner so that electricity can be applied to the generator 8 side.

According to the structure of the first connector (J) and the second connector (K), when the first bar 2 is placed on the saddle (S) side, the connection is made in contact with each other, the vibration is generated Electricity for driving the vibrator V can be supplied to the unit 8 side.

Therefore, the drive connecting portion 10 can not only supply electricity for driving the vibration generating portion with a simple connection structure, but also in particular, during the operation of striking the first bar 2 to the saddle S side. It is formed to be made can provide further improved operation convenience.

The electric shock prevention unit 12 is to prevent an electric shock accident that may occur due to the contact with the drive connecting unit 10.

In particular, the electric shock prevention unit 12 is not only in a state in which the first connector J and the second connector K of the driving connector 10 are connected to each other, but also in a non-connected state. It is formed to prevent electric shock by contact.

6 and 7, the electric shock prevention unit 12 may include a first contact preventing device L corresponding to the first connector J and a second connector corresponding to the second connector K. FIG. 2 may be formed to include a contact preventer (M).

The first contact preventing device (L) has a slide groove (L1) of which one side is open, it is set in a state in which the first connector (J) is fitted in the slide groove (L).

That is, the first contact preventing device (L) may be installed on the saddle (S) side with the first connector (J) is inserted into the slide groove (L1) side and the opening of the groove is upward. .

The lower portion of the first contact preventing device (L) is installed in a state that is elastically supported by the elastic force of the elastic member (L2) as shown in FIG.

Then, the first contact preventing device (L) can maintain a state in which the elastic member of the elastic member (L2) is always moved upwardly by the elastic force when the external force is not applied.

The elastic member (L2) can be used in the spring, for example, a compression coil spring or a leaf spring can be used.

In addition, the length of the slide groove (L1) of the first contact preventer (L) is formed longer than the length of the first connector (J).

Then, when the first contact preventing device (L) is moved upward, the first connector (J) may be in a state that does not protrude from the inside of the slide groove (L1).

The first contact preventing device (L) is, for example, while moving elastically along the longitudinal direction of the slide groove (L1) the upper portion of the first connection port (J) is exposed to the outside, or inside You can enter to make the outer surface obscured.

The second contact preventing device (M) has a fixing groove (M1) is open at one side, the second connector (K) is fitted in the fixing groove (M1).

The second contact preventing device M is disposed at the end side of the first bar 2 with the opening of the fixing groove M1 facing downward.

The length of the fixing groove M1 of the second contact preventing device M is longer than the length of the second connecting device K.

As a result, the outer surface of the second connection port K disposed in the fixing groove M1 may be smoothly covered.

The first contact preventing device (L) and the second contact preventing device (M) are used in a synthetic resin having excellent insulation.

According to the structure of the electric shock prevention unit 12, the first and second contact ports L and M may be connected to and disconnected from the first and second connection ports J and K. It can prevent electric shock by external contact while wrapping.

For example, when the first bar 2 is placed on the saddle S side of the plating bath T for plating the substrate G, as shown in FIG. 8, the lower portion of the second contact preventing device M is shown. By pressing the upper portion of the first contact guard (L) to the first contact guard (L) is moved downward.

Then, an upper portion of the first connection port J inserted into the slide groove L1 side of the first contact protection device L protrudes upward, so that the second connection port K is located inside the second contact protection device M. The contact can be made while contacting the bottom of the).

In this connection state, the first connector J and the second connector K are surrounded by an outer surface by the first contact preventing device L and the second contact preventing device M as shown in FIG. 8. Since the body part is in contact with the first connector J or the second connector K, electric shock can be prevented.

Then, when the first bar 2 is lifted up from the saddle S side to separate the connection state between the first connector J and the second connector K as shown in FIG. The earth L is moved upward by the elastic member L2 so that the upper portion of the first connector J enters the slide groove L1 and does not protrude outward.

In this case, the second connector K is disposed inside the second contact preventing device M, and the outer surface is always covered.

Therefore, even when the first connector J and the second connector K are separated from each other, a part of the body of the worker may be prevented from being touched while being in contact with the first connector J or the second connector K. Can be.

In the above description, the first contact preventing device L is operated to elastically cover the outer surface of the first connector J while being elastically moved by the elastic member L2. However, the present invention is not limited to this structure.

For example, although not shown in the drawing, the second contact preventing device M is elastically moved by a separate elastic member, and is operated so as to be able to elastically cover the outer surface of the second connector K in a resilient manner. The two contact protectors (L, M) may be set to move elastically as described above by separate elastic members.

Therefore, the plated flight bar according to an embodiment of the present invention, the vibration generating unit when the substrate (G) is plated in a dipping method by immersing in the plating tank (T) side while holding the plating rack (R) The vibration generated by (8) can be easily separated and removed by using the vibration of the bubbles (W1) stuck to the substrate (G) side.

Particularly, the present invention further includes a driving connecting part 10 and an electric shock prevention part 12 each configured to safely supply the electric shock prevention when the external electricity for driving the vibration generating part 8 is supplied. Improved working safety can be improved.

2: first bar 4: second bar 6: buffer connection
8: vibration generating unit 10: driving connecting portion 12: electric shock prevention unit

Claims (7)

A first bar extending to extend at both ends on the side of the saddle disposed with the plating bath interposed therebetween;
A second bar spaced apart from and parallel to the first bar to hold the plating rack;
A buffer connecting portion having a buffer connector formed to bufferably connect between the first bar and the second bar;
A vibration generating unit having a vibrator installed at the second bar side to transmit vibration to the plating rack side;
A driving connecting portion having connection holes formed to be connected to each other when the first bar is connected to the saddle and configured to apply electricity for driving the vibrator;
An electric shock prevention unit formed to cover the outer surfaces of the connection ports in an insulated state when the connection ports of the driving connection parts are connected to or disconnected from each other;
Flight bar comprising a. The method according to claim 1,
The first bar is,
And a grounding is made at the point of contact with the saddle when it is spread over the saddle side and is set such that an external current for electrolytic plating can be applied to the plating rack side. The method according to claim 1,
The buffer connector,
Rubber plate or, using a spring, between the first bar and the second bar, one side is connected to the first bar side, the other side is the flight bar for plating characterized in that the connection with the second bar side. The method according to claim 1,
The buffer connector,
Plating flight bar is installed at one or more points between the first bar and the second bar. The method according to claim 1,
The vibrator,
Plating flight bar is installed at one or more points of the second bar. The method according to claim 1,
The drive connecting portion,
A first connector disposed on the saddle side, and a second connector disposed to correspond to the first connector on the first bar side;
The first connector and the second connector,
The flight bar for plating is set to be connected to each other when the end of the first bar on the saddle side is set so that electricity for driving the vibration generating unit can be supplied from the outside. The method according to claim 1,
The electric shock prevention unit,
A contact preventing device formed to cover the connection openings of the driving connection part to cover the outer surface in an insulated state,
The contact guards,
The flight bar for plating, characterized in that the elastic member is set so as to elastically cover the outer surface to expose the connection port elastically.

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