KR102221652B1 - Electroplating coupling mechanism - Google Patents

Abstract

The present invention discloses a kind of electroplating coupling mechanism, and includes one electroplating roller. The electroplating roller here has one annular roller, one rotating shaft, one clamping part and several blade vortex, and one first port of the rotating shaft is installed on the annular roller, and the clamping part is one bottom of the annular roller. It is installed on the part and used to rotate by one actuator, and the blade vortex is installed at the bottom of the annular roller.

Description

Electroplating coupling mechanism

The present invention relates to a kind of electroplating coupling mechanism, and in particular, to an electroplating coupling mechanism used for electroplating or chemical plating a plurality of small parts.

In general, there are two methods of electroplating. One is plating plating and the other is barrel plating. Plating plating is a type of electroplating method in which parts are installed on a jig and plated and deposited, and is generally used for electroplating of large-sized parts. However, for small parts that cannot be installed on a jig or are not suitable for installation due to factors such as shape and size, barrel plating is generally used. Barrel plating is also referred to as roller electroplating, and it is to achieve the purpose of protecting, decorating or functional of the surface by placing a certain amount of small parts in a dedicated roller and depositing various metal or alloy plating layers on the surface of the parts in an indirect conduction method in a rolling state. . Compared with plating plating, there is a relatively large change in the way that barrel plating parts are plated. Among them, plating plating proceeds in a state where the parts are divided separately, but in barrel plating, the parts are assembled and then separated and then separated. In this process, the mixing cycle of parts is created. In addition, plating plating is carried out with the part fully exposed, while barrel plating is carried out in a sealed (although there are holes in the wall plate) and in a roller with a relatively low solution concentration. Changes in the plating method of the parts lead to the two most important defects in barrel plating. That is, defects due to mixing cycle and structural defects of barrel plating. The above defects have a major impact on improving the production efficiency and product quality of barrel plating, and prevent the superiority of barrel plating from being fully exhibited.

Furthermore, the current barrel plating technology connects the roller to one driving device, loads the plating waiting accessory into the roller, and then puts it in the electroplating tank and drives the above driving device to rotate the plating waiting accessory, which causes the electrolyte and Promote enough contact to allow electrochemical action to take place. Electroplating is carried out on the surface of very many needle-shaped or flake-shaped fine and small electronic parts in an electroplating roller. Among the existing technologies, there are many types of electroplating rollers, and most of the electroplating rollers are driven horizontally. It is driven by the device. These electroplating rollers generally have a complex structure, are not easy to install and replace solutions, have low electroplating efficiency, and have a relatively high maintenance cost.

In addition, a kind of electroplating roller is installed at the bottom of the drive shaft so that the electroplating tank with the anode installed can be rotated, and the electroplating roller uses the centrifugal force that acts when the electroplating roller is rotated to cause the conductive liquid inside the electroplating roller. The electroplating roller is fixed at the bottom of the drive shaft and cannot be moved or replaced, so the electroplating process of automatically moving and replacing the plating bath cannot be achieved. .

Therefore, there is a need to provide an improved kind of electroplating coupling mechanism to solve the problems existing in the existing technology.

In consideration of this point, the present invention aims to provide a kind of electroplating coupling mechanism, and by using a blade vortex, the conductive liquid in the annular roller forms a vortex to quickly change the conductive liquid and pass through the power line guide ring. This makes it possible to stabilize the flow direction of the conductive liquid and allow the conductive liquid to be immersed in small parts evenly, so that the surface of the small parts is uniformly electroplated.

In order to achieve the above object, the present invention provides a kind of electroplating coupling mechanism to be used for electroplating several small parts, and the electroplating coupling mechanism includes one electroplating roller and used to store small parts. Heavy electroplating rollers have one annular roller, one rotating shaft, one clamping part and several blade vortex. One 1st port of the rotating shaft is installed on the annular roller, the clamping part is installed at the lower part of the annular roller and used to rotate by one actuator, and the blade vortex is installed at the lower part of the annular roller.

In one embodiment of the present invention, the electroplating coupling mechanism includes one moving frame, and the electroplating roller is coupled to the moving frame, and the moving frame is one fixing plate, two side plates, two auxiliary bars, and one rotary joint. The side plate is connected to the two sides of the fixed plate, and the auxiliary bar is installed between the side plates so that the annular roller is positioned above the auxiliary bar, and the rotary joint is pivoted to the fixed plate so that it is connected with the second port of one of the rotating shafts. It is used to

In one embodiment of the present invention, the movable frame has two cathode rings, is installed on two sides of a lower part of a fixed plate, and is used for electrical connection with one cathode ring.

In one embodiment of the present invention, the moving frame has one cathode conductor and is used to electrically connect the cathode ring by connecting two cathode rings.

In one embodiment of the present invention, the annular roller is composed of one plate, one round wall, one cover, and one cathode ring, and the plate and the round wall are combined with each other, and the cover covers the round wall and The inner space is formed, and the rotating shaft is connected to the cover from the plate and extends to the outside, and the cathode ring is installed in the round wall.

In one embodiment of the present invention, the electroplating roller has one power line guide ring, is installed in the annular roller, and is separated from the round wall.

In one embodiment of the present invention, the electroplating roller has one current transfer layer, and the current transfer layer is installed on the plate of the annular roller.

In one embodiment of the present invention, the annular roller has several cathode wafers and several flow blocking guides, and the cathode wafer and flow blocking guide are installed on the current transfer layer in an Alternate Interval type, and the cathode wafers are adjacent to each other. It is located between the two flow blocking guides.

As described above, the cathode ring of the round wall of the annular roller passes through the axis of rotation and passes through the cathode wire to make electrical connection with the cathode ring. When the electroplating roller starts to rotate and generates centrifugal force, a small part in the annular roller Is moved to the cathode ring, and at the same time, the blade vortex forms a vortex with respect to the conductive liquid in the annular roller, allowing the conductive liquid to be rapidly exchanged. The conductive liquid passes through the design of the power line guide ring to stabilize the flow direction of the conductive liquid. By allowing the small parts to be immersed evenly, the effect of uniformly electroplating the surface of the small parts is obtained.

1 is a cross-sectional view of a relatively preferred embodiment of the electroplating coupling mechanism of the present invention.
2 is an exploded view of a relatively preferred embodiment of the electroplating coupling mechanism of the present invention.
3 is an exploded view of another relatively preferred embodiment of the electroplating coupling mechanism of the present invention.

Hereinafter, the description of each embodiment is illustrated as a specific embodiment for carrying out the present invention with reference to the accompanying drawings. In addition, direction terms mentioned in the present invention, for example, up, down, up, down, before, after, left, right, inside, outside, side, circumference, center, horizontal, transverse s direction, vertical, vertical direction, The axial direction, the radial direction, the uppermost layer or the lowermost layer, etc. are only directions referring to the accompanying drawings. Therefore, the directional terms used are used to describe and understand the present invention and are not used to limit the present invention.

Referring to FIGS. 1 and 2, as a relatively good embodiment of the electroplating coupling device of the present invention, several small parts (for example: resistance, inductance, capacitance, connectors, precision parts, etc. in the form of chips) are electroplated. Or it is used for chemical plating. Among them, the electroplating coupling mechanism includes one moving frame 2 and one electroplating roller 3. The present invention describes in detail the detailed structure, coupling relationship, and operation principle of each component in the following sentences.

1 and 2, the moving frame 2 includes one fixing plate 21, two side plates 22, two auxiliary bars 24, two handles 26, one rotary joint 27, two cathode rings 28 and one. There are cathode conductors 29 of the above, of which the side plate 22 is connected to the two sides of the fixing plate 21, the auxiliary bar 24 is installed between the side plate 22, and the handle part 26 is installed separately on the two sides of the upper surface of the fixing plate 21 and lifted to proceed. The rotary joint 27 is pivoted to the fixed plate 21 so that it is connected to the second port 322 with the rotary shaft 32. The cathode ring 28 is installed on the two sides of the lower part of the fixed plate 21, and the cathode wire 29 Connects the two cathode rings 28.

1 and 2, the electroplating roller 3 is used to store small parts (not shown), and the electroplating roller 3 can be coupled to the moving frame 2, of which the electroplating roller 3 is one There is an annular roller 31, one rotary shaft 32, one clamping part 33, one current transmission layer 34, one power line guide ring 36 and several blade vortex 37, and one first port 321 of the rotary shaft 32 is annular. It is installed on the roller 31, and the clamping part 33 is located below the first port 321, and the blade vortex 37 is installed on one chuck body 38 in an interval arrangement around the rotation axis 32. In addition, the clamping part 33 is installed at the bottom of the annular roller 31, of which one end of the second port 322 has a gripper shape, and the auxiliary bar 24 is installed between the side plates 22 so that the annular roller 31 It should be placed above the auxiliary bar 24. The point to be described is that the clamping unit 33 is used to install one actuator (not shown), and the clamping unit is driven by one driving wheel of the actuator.

The point to be explained is that the current-carrying layer 34 is made of titanium metal or titanium plating, spraying of titanium material, the annular roller 31 is made of plastics, and an intermediate layer between the current-carrying layer 34 and the annular roller 31 Presentation) is installed, and the intermediate layer referred to here is made of plastic materials.

1 and 2, the annular roller 31 has one plate 311, one round wall 312, one cover 313, and one cathode ring 314, and the plate 311 is Combined and Cover 313 covers the Round Wall 312 to form one inner space (not shown), and the inner space is used to store small parts, and the rotary shaft 32 connects from the plate 311 to the Cover 313 and extends to the top, and the cathode ring 314 is It is installed on one inner surface of the Round Wall 312, and the cathode conductor 29 is electrically connected to the cathode ring 314 through the rotating shaft 22. In addition, the chuck body 38 is coupled to the plate 311 so that the blade vortex 37 is positioned above the plate 311.

Based on the above structure, when the rotary joint 27 is released, the annular roller 31 and the rotating shaft 32 can be separated from the moving frame 2 together, and the cathode ring 28 on both sides of the lower part of the fixing plate 21 is in electrical contact with the cathode ring 314. Electrical connection can be made, and when the fixing plate 21 is disconnected from transmission, it is disconnected. In addition, when the cathode ring 314 rotates accelerating and reaches a constant rotation speed, the small parts (plated object) in the annular roller 31 stick to the cathode ring 314 due to centrifugal force. After a period of time, disconnection and if the cathode ring 314 is decelerated to one low rotational speed, the small part (plated object) in the annular roller 31 falls to the bottom of the annular roller 31 due to gravity, and mixing proceeds. After mixing (plated material), the cathode ring 314 is rotated and accelerated again to rotate at a constant rotational speed, intermittently, low-speed mixing and accelerated electroplating of small parts (plated material), and then low-speed mixing and accelerated electroplating. Makes the surface of (to be plated) a more uniform electroplating effect.

Through the above design, the cathode ring 314 of the round wall 312 of the annular roller 31 passes through the cathode conductor 29 through the rotation axis 22 to make an electrical connection with the cathode ring 28, and the electroplating roller 3 starts to rotate, creating a centrifugal force. At the same time, the small parts in the annular roller 31 move to the cathode ring 314, and at the same time, the blade vortex 37 forms a vortex for the conduction fluid in the annular roller 21 so that the conductive fluid is rapidly replaced. Through the design of the power line guide ring 36 Since the flowing direction of the conductive liquid can be stabilized, the conductive liquid can evenly immerse small parts, thereby achieving the effect of uniformly electroplating the surface of the small parts.

Furthermore, by using the design of the clamping unit 33, it is easy to clamp the actuator and rotates by the actuator. In addition, the design of the rotary joint 27 allows the electroplating roller 3 to be installed on the moving frame 2 or disassembled from the moving frame 2, thereby shortening the disassembly and replacement speed of the electroplating roller 3 and enhancing the efficiency of the electroplating work. do. In addition, through the movement of the clamping part 33, the annular roller 31 rotates, and the small parts in the annular roller 31 are moved to the cathode ring 314 by the centrifugal force at the time of rotation, so that the small parts move efficiently in the conductive liquid. Make it rollable.

Referring to FIG. 3, as another relatively good embodiment of the electroplating coupling mechanism of the present invention, the same component names and reference numbers of the above relatively good embodiments are generally used, but the difference between the two is: the annular roller 31 There are several cathode wafers 317 and several flow blocking guides 318, and the cathode wafer 317 and flow blocking guide 318 are installed on the current transfer layer 34 in an alternate interval method, and the cathode wafer 317 is between two adjacent flow blocking guides 318. It is located in Therefore, this comparatively good embodiment makes it easy to move and replace the electroplating roller 3 in the same way, and to achieve the effect of uniformly electroplating the surface of small parts according to the demand for electroplating of other types of small parts. do.

As described above, the cathode ring 314 of the round wall 312 of the annular roller 31 passes through the cathode conductor 29 through the rotation axis 22 to make electrical connection with the cathode ring 28, and the electroplating roller 3 starts to rotate and the centrifugal force is generated. When generated, the small part in the annular roller 21 is moved to the cathode ring 314. At the same time, the blade vortex 37 forms a vortex for the conductive liquid in the annular roller 21, allowing the conductive liquid to be quickly replaced. Through the design of the power line guide ring 36, the flow direction of the conductive liquid can be stabilized. By allowing the parts to be immersed evenly, it achieves the effect of evenly electroplating the surface of small parts.

The present invention has been previously described with the above related embodiments, but the above embodiments are merely a legend for carrying out the present invention. It should be noted that the disclosed embodiments do not limit the scope of the present invention. On the contrary, the modification and equal installation of the spirit and scope of the claim are all included within the scope of the present invention.

Claims (8)

In the electroplating coupling mechanism used for electroplating a plurality of small parts,
The electroplating coupling mechanism,
It includes an electroplating roller for storing small parts,
The electroplating roller,
Annular rollers;
Rotating shaft-one first port of the rotating shaft is installed on the annular roller -;
A clamping unit installed at a lower portion of the annular roller and rotated by a driver; And
Including; a plurality of blade vortex installed at the bottom of the annular roller,
The roller consists of a plate, a round wall, a cover, and a cathode ring. The plate and the round wall are combined with each other, and the cover covers the top of the round wall to form an inner space, and the rotating shaft connects the plate and the cover to the outside. Expand and install the cathode ring in the round wall,
The electroplating roller further comprises a power line guide ring, installed in the annular roller, and separated from the round wall.
The method of claim 1,
The electroplating coupling mechanism further comprises a moving frame, the electroplating roller is coupled to the moving frame,
The moving frame,
Fixed plate;
Two side plates coupled to two sides of the fixing plate;
Two auxiliary bars-installed between the two side plates so that the annular roller is located above the auxiliary bars -; And
Rotary joint-An electroplating coupling mechanism comprising: a rotary joint connected to a fixed plate so as to be rotated and used for coupling with one second port of the rotary shaft.
The method of claim 2,
The moving frame,
The electroplating coupling mechanism further comprising two cathode rings and used to make electrical connection with one cathode ring by being installed on two sides of one lower portion of the fixing plate.
The method of claim 3,
The moving frame,
An electroplating coupling mechanism comprising a cathode conductor and used to electrically connect the cathode rings by connecting the two cathode rings.
The method of claim 1,
The electroplating roller further includes a current transfer layer, and the current transfer layer is installed on the plate of the annular roller.
The method of claim 5,
The annular roller includes a plurality of cathode wafers and a plurality of flow blocking guides, the cathode wafer and the flow blocking guide are installed on the current transfer layer in an Alternate Interval format, and the cathode wafer is two adjacent flow blocking guides. Electroplating coupling mechanism, characterized in that located between the dragon guide. delete delete

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