CN220012881U - Vibration device for circuit board electroplating - Google Patents

Abstract

The utility model discloses an oscillating device for circuit board electroplating, and relates to the technical field of electroplating equipment. The vibration device comprises a frame body, a hanging frame, a driving assembly and a vibration assembly; wherein, the frame body is provided with a guide rail; the hanger comprises a first main body and a second main body movably connected with the first main body, and a clamp assembly for clamping a circuit board is arranged on the second main body; the driving assembly is arranged on the frame body and connected with the first main body, and is used for driving the hanging frame to move along the guide rail; the vibration assembly is arranged on the second main body and used for generating vibration so as to drive the second main body to shake relative to the first main body. The technical scheme of the utility model can solve the problem of uneven electroplating caused by the adhesion of bubbles on the surface of the prior circuit board to be electroplated.

Description

Vibration device for circuit board electroplating

Technical Field

The utility model relates to the technical field of electroplating equipment, in particular to an oscillating device for electroplating a circuit board.

Background

Electroplating means that plating solution for pre-plating metal is filled in a plating tank, then the substrate metal to be plated is used as a cathode to be suspended and immersed in the plating solution through a hanger, and cations of the pre-plating metal in the plating solution are deposited on the surface of the substrate metal through the action of electrolysis, so that a surface processing method of a plating layer is formed. For example, today, most of the plating of circuit boards is performed by clamping the circuit boards together by a rack, and placing the circuit boards into a plating cylinder for plating; the bubbles and gas are easy to adhere to the surface of the circuit board and enter the electroplating cylinder, the bubbles and the gas are difficult to be discharged, and the bubbles are not conductive in the electroplating process, so that the bubbles adhering to the surface of the circuit board cannot be deposited with metal, and the electroplating on the surface of the electroplated workpiece is uneven.

Disclosure of Invention

The utility model mainly aims to provide an oscillating device for circuit board electroplating, which aims to solve the problem of uneven electroplating caused by the adhesion of bubbles on the surface of a circuit board to be electroplated.

In order to achieve the above object, the present utility model provides an oscillating device for electroplating a circuit board, comprising:

the frame body is provided with a guide rail;

the hanging rack comprises a first main body and a second main body movably connected with the first main body, and a clamp assembly for clamping a circuit board is arranged on the second main body;

the driving assembly is arranged on the frame body and connected with the first main body, and is used for driving the hanging frame to move along the guide rail;

and the vibration assembly is arranged on the second main body and is used for generating vibration so as to drive the second main body to shake relative to the first main body.

In an embodiment, the second body is slidably connected to the first body, and the oscillating device further includes a limiting component connected to the first body and the second body, where the limiting component is used to limit the amplitude of the second body oscillating relative to the first body.

In an embodiment, the limiting assembly comprises a first limiting plate arranged on the first main body, a second limiting plate arranged on the second main body, a connecting column and an elastic piece, wherein the first limiting plate and the second limiting plate are oppositely arranged, and the connecting column is fixedly connected with the first limiting plate and is in sliding connection with the second limiting plate; the elastic piece is sleeved on the periphery of the connecting column, and comprises a first limiting section and a second limiting section, wherein the first limiting section is limited between the first limiting plate and the second limiting plate, and the second limiting section is limited between one end, away from the first limiting plate, of the connecting column and the second limiting plate.

In an embodiment, one of the first body and the second body is provided with a sliding rail, and a sliding block slidingly connected to the sliding rail, and the other is connected to the sliding block.

In an embodiment, the oscillating device further includes an elastic conductive member and a conductive rail connected to an external power source, the conductive rail is connected to the first body through the elastic conductive member, and the oscillating assembly includes an oscillating motor and a grounding wire electrically connected to the oscillating motor and the elastic conductive member.

In an embodiment, the oscillating device further comprises an electric rail supporting seat, the electric rail supporting seat is connected with the conductive rail through an insulating piece and extends towards one side far away from the second main body, and the electric rail supporting seat is used for laying a power line of an external power supply.

In an embodiment, the oscillating device further comprises a guiding assembly connected with the first main body, the guiding assembly comprises fixing seats arranged on two sides of the length direction of the first main body, and first guiding wheels rotatably connected with the fixing seats, and the first guiding wheels are abutted against the top surface of the guiding rail.

In an embodiment, the guide assembly further comprises second guide wheels rotatably connected with the fixing base, the second guide wheels are located at two sides of the extending direction of the guide rail, and the second guide wheels are abutted to the side face of the guide rail.

In an embodiment, the first main body is further provided with a first conductive plate for connecting with an external power supply, the fixture assembly is provided with a second conductive plate, and the first conductive plate and the second conductive plate are electrically connected to guide current provided by the external power supply to the circuit board to be electroplated.

In an embodiment, the first conductive plate is connected with a conductive connection flat, the conductive connection flat extends to one end of the first main body close to the second main body, and a flexible conductive piece is connected between the conductive connection flat and the second conductive plate.

According to the technical scheme, the guide rail is arranged on the frame body, so that the hanger can move along the guide rail under the drive of the driving assembly when being placed on the frame body; vibration subassembly can produce vibrations when the operation, through will vibrate the subassembly setting in the second main part, make vibration that vibration subassembly produced can transmit to the second main part, because first main part and second main part are swing joint, the second main part is when vibrations relative first main part rocks. The clamp assembly for clamping the circuit board is arranged on the second main body, so that the clamp assembly is driven to shake together when the second main body shakes relative to the first main body; when the clamp assembly clamps the circuit board in the electroplating solution, namely the circuit board shakes in the electroplating solution, the circuit board gets rid of bubbles attached to the surface.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, and it is obvious that the drawings in the following description are only some embodiments of the present utility model, and other drawings may be obtained according to the structures shown in these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic diagram of an oscillating device for electroplating a circuit board according to an embodiment of the present utility model;

FIG. 2 is a side view of an embodiment of an oscillating device for plating a circuit board according to the present utility model;

FIG. 3 is a top view of an oscillating device for electroplating a circuit board according to an embodiment of the present utility model;

FIG. 4 is a schematic diagram illustrating an assembly of a first body and a second body of an oscillating device for electroplating a circuit board according to an embodiment of the utility model;

fig. 5 is an enlarged schematic view at a in fig. 1.

Reference numerals illustrate:

the achievement of the objects, functional features and advantages of the present utility model will be further described with reference to the accompanying drawings, in conjunction with the embodiments.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

It should be noted that all directional indicators (such as up, down, left, right, front, and rear … …) in the embodiments of the present utility model are merely used to explain the relative positional relationship, movement, etc. between the components in a particular posture (as shown in the drawings), and if the particular posture is changed, the directional indicator is changed accordingly.

Furthermore, the description of "first," "second," etc. in this disclosure is for descriptive purposes only and is not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In addition, the technical solutions of the embodiments may be combined with each other, but it is necessary to base that the technical solutions can be realized by those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should be considered to be absent and not within the scope of protection claimed in the present utility model.

The utility model provides an oscillating device for circuit board electroplating, which can drive a circuit board to linearly move through the oscillating device when the circuit board is electroplated, and can drive the circuit board to shake in electroplating solution, so that the circuit board effectively gets rid of bubbles attached to the surface through a shaking mode, and the uniform electroplating of the surface of the circuit board is realized.

Referring to fig. 1 to 5, in the present embodiment, the oscillating device 10 includes a frame 100, a hanger 200, a driving assembly 400 and an oscillating assembly 500; wherein, the frame body 100 is provided with a guide rail 110; the hanger 200 comprises a first main body 210 and a second main body 220 movably connected to the first main body 210, wherein a clamp assembly 300 for clamping a circuit board 310 is arranged on the second main body 220; the driving assembly 400 is disposed on the frame 100 and connected to the first main body 210, and the driving assembly 400 is configured to drive the hanger 200 to move along the guide rail 110; the oscillating assembly 500 is disposed on the second body 220, and the oscillating assembly 500 is configured to generate vibration to drive the second body 220 to shake relative to the first body 210.

By arranging the guide rail 110 on the frame body 100, the hanger 200 can move along the guide rail 110 under the drive of the driving assembly 400 when being placed on the frame body 100; the vibration assembly 500 may generate vibration during operation, and the vibration assembly 500 is disposed on the second body 220, so that the vibration generated by the vibration assembly 500 may be transferred to the second body 220, and the second body 220 is rocked relative to the first body 210 during vibration due to the movable connection between the first body 210 and the second body 220. The clamp assembly 300 for clamping the circuit board 310 is disposed on the second body 220, so that when the second body 220 shakes relative to the first body 210, the clamp assembly 300 is driven to shake together; when the fixture assembly 300 clamps the circuit board 310 in the plating solution, that is, the circuit board 310 is shaken in the plating solution, the circuit board 310 gets rid of bubbles attached to the surface.

Specifically, in an embodiment, the second body 220 is slidably connected to the first body 210, and the oscillating device 10 further includes a limiting assembly 600 connected to the first body 210 and the second body 220, where the limiting assembly 600 is used to limit the amplitude of the oscillation of the second body 220 relative to the first body 210.

It can be appreciated that the second body 220 is slidably connected to the first body 210, and the swinging motion of the second body 220 relative to the first body 210 is the sliding motion of the second body 220 relative to the first body 210, that is, the second body 220 slides relative to the first body 210 under the driving of the oscillating assembly 500. Further, considering that when the shaking amplitude of the second body 220 is too large, the circuit board 310 cannot be helped to get rid of bubbles, and bubbles attached to the surface of the circuit board 310 may be increased, the oscillating device 10 is further provided with a limiting component 600 connected to the first body 210 and the second body 220, so as to limit the shaking amplitude of the second body 220 relative to the first body 210, that is, limit the sliding distance of the second body 220 relative to the first body 210, and avoid the excessive shaking amplitude of the second body 220.

Referring to fig. 1 and 5, in an embodiment, the limiting assembly 600 includes a first limiting plate 610 disposed on the first main body 210, a second limiting plate 620 disposed on the second main body 220, a connecting post 630, and an elastic member 640, where the first limiting plate 610 and the second limiting plate 620 are disposed opposite to each other, and the connecting post 630 is fixedly connected to the first limiting plate 610 and slidably connected to the second limiting plate 620; the elastic member 640 is sleeved on the outer periphery of the connecting post 630, and the elastic member 640 includes a first limiting section 641 limited between the first limiting plate 610 and the second limiting plate 620, and a second limiting section 642 limited between one end of the connecting post 630 away from the first limiting plate 610 and the second limiting plate 620.

The connecting post 630 is fixedly connected to the first limiting plate 610, and simultaneously is slidably connected to the second limiting plate 620, so that when the second main body 220 slides relative to the first main body 210, the second limiting plate 620 is driven to slide along the connecting post 630; the elastic member 640 is sleeved on the outer periphery of the connecting post 630, the elastic member 640 includes a first limiting section 641 and a second limiting section 642, the first limiting section 641 is limited between the first limiting plate 610 and the second limiting plate 620, the second limiting section 642 is limited between one end of the connecting post 630 away from the first limiting plate 610 and the second limiting plate 620, i.e. the first limiting section 641 and the second limiting section 642 are respectively located at two sides of the second limiting plate 620. When the second limiting plate 620 moves towards the first limiting plate 610, the first limiting section 641 is pressed against, and the first limiting section 641 is elastically compressed; when the second limiting plate 620 moves away from the first limiting plate 610, the first limiting section 641 pushes against the second limiting plate 620, the second limiting plate 620 pushes against the second limiting section 642, and the second limiting section 642 is elastically compressed. The second limiting plate 620 is always located between the first limiting section 641 and the second limiting section 642, and the distance that the second limiting plate 620 can slide toward or away from the first limiting plate 610 is related to the degree of compression deformation of the first limiting section 641 and the second limiting section 642, i.e. the amplitude of the shake of the second main body 220 is limited. Meanwhile, by converting the shaking of the second body 220 into the sliding of the second limiting plate 620 on the connection post 630, the reciprocal sliding of the second limiting plate 620 on the connection post 630, that is, the reciprocal sliding of the second body 220 relative to the first body 210 is realized by utilizing the interaction among the first limiting section 641, the second limiting section 642 and the second limiting plate 620.

Specifically, the connection post 630 may be a bolt, the first limiting plate 610 and the second limiting plate 620 are provided with corresponding connection holes, one end of the bolt, which is opposite to the bolt head, sequentially passes through the connection holes on the second limiting plate 620 and the connection holes on the first limiting plate 610, and is fixedly connected with the first limiting plate 610 through a nut, a gasket reinforcing connection can be arranged between the nut and the first limiting plate 610, two ends of the second limiting section 642 are respectively abutted to the second limiting plate 620 and the bolt head of the bolt, and the first limiting section 641 and the second limiting section 642 can be provided with two independent springs.

Referring to fig. 4, there are many ways of sliding connection between the first body 210 and the second body 220, in one embodiment, a sliding rail 211 is disposed on the first body 210, and a sliding block 212 is slidably connected to the sliding rail 211, and the sliding block 212 is connected to the second body 220; when the slider 212 slides on the sliding rail 211, the second body 220 slides relative to the first body 210. Similarly, the sliding rail 211 may be disposed on the second body 220, the sliding block 212 is connected to the first body 210, and is slidably connected to the sliding rail 211, and when the sliding rail 211 slides relative to the sliding block 212, the second body 220 slides relative to the first body 210.

Further, the first body 210 and the second body 220 are hollow, the sliding rail 211 and the sliding block 212 are disposed in the hollow cavity of the first body 210, the second body 220 is sleeved on the outer periphery of the first body 210 and is connected with the sliding block 212, or the second body 220 is inserted into the hollow cavity of the first body 210 and is connected with the sliding block 212. Specifically, the sliding rail 211 is disposed at one end of the first body 210 near the second body 220, and only portions of adjacent ends of the first body 210 and the second body 220 are slidably connected.

It is understood that the arrangement direction of the sliding rail 211 affects the sliding direction of the sliding block 212 on the sliding rail 211, that is, affects the swinging direction of the second body 220 relative to the first body 210. Taking the hanger 200 as an example, if the sliding rail 211 is also disposed along the horizontal direction and the sliding block 212 can move along the sliding rail 211 in the lateral direction or the longitudinal direction, the second body 220 can shake in the lateral direction or the longitudinal direction. If the sliding rail 211 is vertically disposed, the sliding block 212 may move vertically along the sliding rail 211, so as to shake the second body 220 vertically. Accordingly, the setting direction of the limiting assembly 600 is the same as the setting direction of the sliding rail 211, so as to ensure that the limiting assembly 600 limits the amplitude of the second body 220 swinging in the corresponding direction.

Correspondingly, when the hanger 200 is horizontally disposed, one end of the second main body 220 away from the first main body 210 is bent downward, and the fixture assembly 300 is vertically connected to the portion of the second main body 220 bent downward, so that the circuit board 310 can extend into the electroplating solution from top to bottom after the fixture assembly 300 clamps the circuit board 310.

Referring to fig. 1, in an embodiment, the oscillating device 10 further includes an elastic conductive member 710 and a conductive rail 700 for connecting to an external power source, the conductive rail 700 is connected to the first body 210 through the elastic conductive member 710, and the oscillating assembly 500 includes an oscillating motor 510 and a grounding wire 520 electrically connecting the oscillating motor 510 and the elastic conductive member 710.

Vibration can be generated after the vibration motor 510 is electrified and operated, the vibration motor 510 and the elastic conductive piece 710 are connected through the electric connection wire 520, and the elastic conductive piece 710 is connected with the conductive rail 700 used for being connected with an external power supply, so that after the external power supply conducts current to the conductive rail 700, the current can be conducted to the vibration motor 510 through the elastic conductive piece 710 and the electric connection wire 520, and the starting operation of the vibration motor 510 is realized. The elastic conductive member 710 is connected to the conductive rail 700 and the first main body 210, so that when the conductive rail 700 or the first main body 210 is affected by vibration, the elastic conductive member 710 can be deformed elastically under the influence of vibration, so as to maintain stable current transmission between the conductive rail 700 and the elastic conductive member 710, i.e. ensure continuous and stable operation of the oscillating motor 510.

Further, the oscillating device 10 further includes an electrical rail support 800, the electrical rail support 800 is connected to the electrical rail 700 through an insulating member 810, and extends toward a side far away from the second main body 220, and the electrical rail support 800 is used for laying a power cord of an external power source. Accordingly, the number of the conductive rails 700 and the electrical rail supporting seats 800 may be multiple, the conductive rails 700 may be isolated by the insulating member 810, so as to avoid the current communication conducted on the conductive rails 700 to form a loop, and the power lines on different electrical rail supporting seats 800 may be respectively connected to different conductive rails 700. In order to facilitate the introduction of the power cord of the external power source, the power rail support base 800 may be extended toward the direction facing away from the second body 220, so as to avoid the interference between the introduced power cord and the movable second body 220.

Specifically, in one embodiment, the driving assembly 400 includes a sprocket 420 and a chain 410, the sprocket 420 is connected to the first body 210, and when the sprocket 420 is engaged with the chain 410, the chain 410 drives the sprocket 420 to move unidirectionally, so that the first body 210 moves along the guide rail 110. The conveying direction of the chain 410 is the same as the extending direction of the guide rail 110, and when the sprocket 420 is engaged with the chain 410, the sprocket 420 is stationary with respect to the chain 410, and the sprocket 420 moves along with the chain 410 in the extending direction of the guide rail 110. And the sprocket 420 is connected to the first body 210 such that the first body 210 moves together in the extending direction of the guide rail 110 under the driving of the sprocket 420.

Referring to fig. 1 to 3, in an embodiment, the oscillating device 10 further includes a guiding assembly 900 connected to the first main body 210, the guiding assembly 900 includes a fixing base 910 disposed on two sides of the first main body 210 in the length direction, and a first guiding wheel 920 rotatably connected to the fixing base 910, and the first guiding wheel 920 abuts against the top surface of the guiding rail 110.

Further, in order to avoid that the rolling path of the first guide wheel 920 deviates from the extending direction of the guide rail 110, a guide chute extending in the same direction as the guide rail 110 may be provided on the top surface of the guide rail 110, the first guide wheel 920 rolls along the guide chute, and the inner walls on two sides of the guide chute may limit the first guide wheel 920 to avoid separating from the guide rail 110.

In another embodiment, the guide assembly 900 further includes a second guide wheel 930 rotatably connected to the fixing base 910, the second guide wheel 930 is located at two sides of the extending direction of the guide rail 110, and the second guide wheel 930 abuts against the side surface of the guide rail 110. That is, in the process that the first body 210 moves along the guide rail 110, the first guide wheel 920 rolls along the top surface of the guide rail 110, the second guide wheels 930 on both sides of the guide rail 110 roll along the side surfaces of the guide rail 110, and the limit of the first guide wheel 920 on the top surface of the guide rail 110 is realized by the second guide wheels 930 arranged on both sides of the guide rail 110, so that the first guide wheel 920 is prevented from being separated from the guide rail 110.

It will be appreciated that during the electroplating process, the circuit board 310 to be electroplated needs to be conducted with an on-current, so in one embodiment, the first main body 210 is provided with a first conductive plate 213 for connecting with an external power source, and the fixture assembly 300 is provided with a second conductive plate 221, and the first conductive plate 213 and the second conductive plate 221 are electrically connected to guide the current provided by the external power source to the circuit board 310 to be electroplated.

Considering that the position of the connection portion between the second body 220 and the first body 210 may be changed during the shaking process of the second body 220 with respect to the first body 210, for example, when the second body 220 moves longitudinally with respect to the first body 210, the distance between the first body 210 and the second body 220 is changed, which in turn results in the change of the distance between the clamp assembly 300 and the first body 210, and if the first conductive plate 213 and the second conductive plate 221 are directly connected by a fixing guide such as a flat iron, the shaking motion of the second body 220 is limited.

Referring to fig. 2, in order to solve the above-mentioned problem, in an embodiment, the first conductive plate 213 is connected to a conductive connection flat 230, the conductive connection flat 230 extends to an end of the first body 210 near the second body 220, and a flexible conductive member 240 is connected between the conductive connection flat 230 and the second conductive plate 221. The conductive connection flat 230 may be a fixed conductive member such as a flat iron, so as to extend the conductive distance of the first conductive plate 213, and then connect the conductive connection flat 230 with the second conductive plate 221 through the flexible conductive member 240, so as to realize conduction between the first conductive plate 213 and the second conductive plate 221. Since the flexible conductive member 240 has flexibility, during the swinging of the second body 220, the flexible conductive member 240 can perform corresponding flexible deformation according to the movement of the second body 220, and the swinging movement of the second body 220 is not limited while the stable conduction of the first conductive plate 213 and the second conductive plate 221 is not affected. Specifically, the flexible conductive element 240 includes, but is not limited to, a flexible wire or the like. Preferably, the first conductive plate 213, the second conductive plate 221, the conductive connection flat 230, and the flexible conductive member 240 are disposed near the bottom surface of the hanger 200, so as to improve the safety during conduction.

The foregoing description is only of the preferred embodiments of the present utility model and is not intended to limit the scope of the utility model, and all equivalent structural changes made by the description of the present utility model and the accompanying drawings or direct/indirect application in other related technical fields are included in the scope of the utility model.

Claims (10)

1. An oscillating device for electroplating a circuit board, comprising:

the frame body is provided with a guide rail;

the hanging rack comprises a first main body and a second main body movably connected with the first main body, and a clamp assembly for clamping a circuit board is arranged on the second main body;

the driving assembly is arranged on the frame body and connected with the first main body, and is used for driving the hanging frame to move along the guide rail;

and the vibration assembly is arranged on the second main body and is used for generating vibration so as to drive the second main body to shake relative to the first main body.

2. The vibration apparatus for electroplating of a circuit board according to claim 1, wherein the second main body is slidably connected to the first main body, the vibration apparatus further comprises a limiting component connected to the first main body and the second main body, and the limiting component is used for limiting the amplitude of the second main body swinging relative to the first main body.

3. The vibration device for electroplating of a circuit board according to claim 2, wherein the limiting assembly comprises a first limiting plate arranged on the first main body, a second limiting plate arranged on the second main body, a connecting column and an elastic piece, the first limiting plate and the second limiting plate are oppositely arranged, and the connecting column is fixedly connected with the first limiting plate and is slidably connected with the second limiting plate; the elastic piece is sleeved on the periphery of the connecting column, and comprises a first limiting section and a second limiting section, wherein the first limiting section is limited between the first limiting plate and the second limiting plate, and the second limiting section is limited between one end, away from the first limiting plate, of the connecting column and the second limiting plate.

4. The vibration apparatus for plating a circuit board according to claim 2, wherein one of the first body and the second body is provided with a slide rail, and a slider slidably connected to the slide rail, and the other is connected to the slider.

5. The oscillating device for plating a circuit board according to claim 2, wherein the oscillating device further comprises an elastic conductive member and a conductive rail for connecting an external power source, the conductive rail is connected to the first body through the elastic conductive member, and the oscillating assembly comprises an oscillating motor and a grounding wire electrically connecting the oscillating motor and the elastic conductive member.

6. The vibration apparatus for electroplating of a circuit board according to claim 5, further comprising an electric rail supporting seat, wherein the electric rail supporting seat is connected to the conductive rail through an insulating member and extends toward a side far away from the second main body, and the electric rail supporting seat is used for laying a power line of an external power supply.

7. The vibration apparatus for electroplating of a circuit board according to claim 1, further comprising a guide assembly connected to the first main body, wherein the guide assembly comprises a fixing seat arranged at two sides of the length direction of the first main body, and a first guide wheel rotatably connected to the fixing seat, and the first guide wheel abuts against the top surface of the guide rail.

8. The vibration apparatus for electroplating of a circuit board according to claim 7, wherein the guiding assembly further comprises second guiding wheels rotatably connected to the fixing base, the second guiding wheels are located at two sides of the extending direction of the guiding rail, and the second guiding wheels are abutted against the side surface of the guiding rail.

9. The vibration apparatus for plating a circuit board according to claim 1, wherein the first main body is further provided with a first conductive plate for connection with an external power source, the jig assembly is provided with a second conductive plate, and the first conductive plate and the second conductive plate are electrically connected to guide a current supplied from the external power source to the circuit board to be plated.

10. The vibration apparatus for plating a circuit board according to claim 9, wherein the first conductive plate is connected with a conductive connection pad, the conductive connection pad extends to an end of the first body near the second body, and a flexible conductive member is connected between the conductive connection pad and the second conductive plate.