KR102254554B1 - Electroplating divice for copper foil manufacturing - Google Patents

Abstract

The present invention relates to an electroplating apparatus for manufacturing copper foil and, more specifically, to an electroplating apparatus for manufacturing copper foil, capable of improving cooling efficiency by enabling a drum electroplated with copper particles to be evenly cooled, and improving plating quality by reducing electric resistance caused by an incomplete contact point between different kinds of metal on the drum while performing current conduction evenly on the entire area of the drum. To achieve the purpose, the apparatus includes: a plating member (100) storing an electrolyte therein, having an anode (120) provided on a side, where the electrolyte is stored, to carry a positive charge, and providing a space to perform electroplating; a shaft member (200) delivering a rotation force by combining a drum member (300) with the plating member (100), and receiving coolant introduced from the outside and circulating the introduced coolant; and the drum member (300) combined with the shaft member (200) while having a part soaked in the electrolyte of the plating member (100), and inducing electrolysis by being connected with a side adjacent to the anode (120) as a cathode carrying a negative charge, wherein copper foil is electroplated and formed on a surface when electroplating begins in accordance with electricity application, and the plated surface is cooled as the coolant of the shaft member (200) is introduced during the electroplating.

Description

Electroplating divice for copper foil manufacturing}

The present invention is an electroplating apparatus for manufacturing copper foil, and the drum to which copper particles are electrodeposited enables uniform cooling to improve cooling efficiency, and reduces electrical resistance due to incomplete contact between dissimilar metals in the drum, It relates to an electroplating apparatus for manufacturing copper foil to improve plating quality by performing current conduction uniformly over an area.

In general, in electroplating, in a plating solution containing ions of the metal to be plated, the target to be plated is used as the cathode, and the electrode of the underlying metal or insoluble metal is used as the anode, and ions of the metal to be plated are reduced and precipitated on the surface of the plating target. Copper foil obtained through electroplating is a plating method that is typically made of a very thin copper plate and is widely used in electrical and electronic products such as batteries and printed circuit boards, so that methods for improving the quality of copper foil and mass production have been developed. Has become.

Such copper foil uses an electroplating apparatus capable of an electrodeposition method for copper plating. In the plating apparatus for manufacturing copper foil, a drum that continuously rotates is usually coupled to a sulfuric acid plating bath, and an anode forming an anode in the sulfuric acid plating bath is The electrolyte is filled between the anode and the drum in a state in which the bottom is provided at random intervals, and the anode forms an insoluble anode, and the drum is a cathode, so that the electroplating starts according to the application of electricity, so that copper foil is electrodeposited on the surface of the drum. do.

For example, looking at the conventional Korean Patent Publication No. 10-1126969, in the method of manufacturing an electrolytic copper foil, a foil process of manufacturing an untreated copper foil by electrodepositing copper particles through electroplating; And a surface treatment process of producing a surface-treated copper foil by electrochemical or chemical treatment of the surface of the untreated copper foil, wherein the electrolytic copper foil subjected to the surface treatment process includes copper particles having a ratio of a short radius to a major radius of 0.4 to 0.9. Copper with a proportion of at least 80% of the total copper particles, and a proportion of copper particles with a major radius of 1㎛ to 5µm is more than 70% of the total copper particles, and with a major radius of at least twice the average major radius of all copper particles. A method for producing an electrolytic copper foil in which the proportion of the particles is 15% or less of the total copper particles, and the sum of the carbon content and the sulfur content is 0.5% or less is proposed.

In addition, referring to the related art Korean Patent Publication No. 10-2018-0105476, there is provided an apparatus for manufacturing a copper foil, comprising: a foil making apparatus for manufacturing copper foil by applying a current to an electrolyte containing copper sulfate; And a plating device for additionally plating the shiny surface of the copper foil, wherein the plating device includes: a plating bath for accommodating an electrolyte solution; A second anode immersed in the electrolytic solution of the plating bath to form a positively charged electrode; A first electrification roll installed outside the plating bath, receiving the copper foil of the foil-making device, injecting negative charges to the shiny surface, and seeking to flow into the electrolytic solution of the plating bath; A second conductive roll for drawing out the copper foil on which the shiny side is additionally plated from the electrolytic solution of the plating bath and injecting negative electric charges to the surface thereof; And a copper foil manufacturing apparatus including a submerged roll immersed in the electrolytic solution of the plating bath, passing through the second anode between the first conductive roll and the second conductive roll to guide the additionally plated copper foil. have.

However, in the conventional plating apparatus, since the roll-type drum on which copper foil is electrodeposited has no cooling structure or has a structure that performs cooling by being limited to the shaft of the drum, the cooling efficiency of the drum is significantly lowered, thereby increasing the heat load on the drum, and plating. There was also a problem in that the temperature in the bath could not be kept constant.

In addition, conventionally, the outer circumferential body and the inner circumferential body of the drum are made of dissimilar metals, but the bonding surface between the outer circumferential body and the inner circumferential body of the drum cannot achieve perfect contact due to the curvature characteristic of the roll, so the current density for the polarity of the drum is not uniform and uniform. There was a problem that the quality of the copper foil was remarkably deteriorated by the current density of the drum that was not used.

Korean Patent Publication No. 10-1126969 is presented. Korean Patent Publication No. 10-2018-0105476 is presented.

The present invention is to solve the conventional problems, while creating a flow path for introducing the cooling water into the drum of the plating apparatus, forming a space to fill the cooling water introduced into the drum, cooling while performing evenly cooling the entire part of the drum. Its purpose is to improve efficiency.

In addition, the present invention provides a number of conductors for directly performing current conduction between the outer peripheral body and the inner peripheral body coupling portion of the drum and arranges and provides a number of conductors for direct current conduction, so that electricity by incomplete contact between the dissimilar metals of the drum. Its purpose is to improve plating quality by making current conduction evenly over the entire area of the drum while reducing resistance.

In order to solve this object, the present invention;

A plating member containing an electrolyte solution, an anode provided as an anode having a positive charge on a side where the electrolyte solution is accommodated, and providing a space for electroplating;

A shaft member that couples a drum member to the plating member to transmit rotational power, and that coolant is introduced from the outside and circulates the introduced coolant;

A part of the electrolytic solution of the plating member is put into the electrolytic solution of the plating member while being axially coupled to the shaft part, and as a negatively charged negative electrode, it is linked from the side adjacent to the anode to induce electrolysis.When electroplating starts according to the application of electricity, copper foil is deposited on the surface. It provides an electroplating apparatus for manufacturing a copper foil, characterized in that it is formed by electrodeposition, and comprises a drum member configured to cool the plating surface by flowing the cooling water of the shaft member during electroplating.

According to the present invention, cooling is performed evenly on the entire drum of the plating apparatus, thereby improving the cooling efficiency of the drum and minimizing the thermal load.

In addition, by directly conducting the current conduction of the drum of the plating apparatus, electrical resistance due to incomplete contacts between the different metals of the drum is reduced, and current conduction is uniform over the entire area of the drum, thereby improving the plating quality.

1 to 2 are views showing an electroplating apparatus for manufacturing copper foil according to a first embodiment of the present invention.
3 is a view showing an electroplating apparatus for manufacturing copper foil according to a second embodiment of the present invention.

The features of the electroplating apparatus for manufacturing copper foil according to the present invention may be understood by the embodiments described in detail below with reference to the accompanying drawings.

Meanwhile, in describing the embodiments, detailed descriptions thereof will be omitted for components widely known and used in the technical field to which the present invention belongs or does not belong. This is to convey the point more clearly.

Hereinafter, as an embodiment of the basic configuration of the present invention, the configuration of each part of the electroplating apparatus for manufacturing copper foil according to the first embodiment will be described in detail with reference to FIGS. 1 to 2. 1 is a configuration diagram of an electroplating apparatus, and FIG. 2 is a view of a drum member in the electroplating apparatus.

A schematic view of the electroplating apparatus 1 for manufacturing copper foil accordingly includes a plating member 100 providing a space for electroplating; A shaft member 200 that transmits rotational power to the drum member 300 and functions to circulate coolant; A drum member 300 formed by electrodepositing copper foil and performing cooling of the plated surface during electroplating.

Looking at the detailed configuration of the copper foil manufacturing electroplating apparatus 1 having such a configuration with reference to the accompanying drawings in detail as follows.

First, the plating member 100;

The electrolyte is accommodated inside, the anode 120 is provided as an anode having a positive charge on the side where the electrolyte is accommodated, and a space for electroplating is provided.

For example, the plating member 100 further includes a plating bath 110 in which an electrolyte is accommodated.

The plating bath 110 is manufactured in the form of a tank having a space in which an electrolyte is accommodated, and the drum member 300 is installed in the opening while having an opening in the upper portion of the plating bath 110, and the plating bath The electrolytic solution is introduced into 110 and filled, and the filled electrolytic solution is discharged, and a circulation cycle for circulating the electrolytic solution accommodated in the plating bath 110 is provided.

In addition, the plating member 100, while being immersed in the electrolytic solution of the plating bath 110, is provided to surround the bottom of the drum member 300 at arbitrary intervals, the anode 120 provided as an anode having a positive charge; further includes do.

The anode 120 is an anode that is coupled to the inside of the plating bath 110 and has a positive charge when electricity is applied, and is an electrode that conducts electroplating while passing electricity to the electrolyte solution of the plating bath 110, and the anode 120 ) Is manufactured as a frame that surrounds the outer circumferential surface of the outer circumferential body 320 in a state spaced apart at random intervals under the outer circumferential body 320 of the drum member 300 to conduct electricity in response to the negative electrode of the drum member 300 Let it be.

In this case, the anode 120 may spray platinum or iridium liquid toward the outer peripheral body 320 of the drum member 300 as an insoluble anode.

And, the shaft member 200;

The drum member 300 is coupled to the plating member 100 to transmit rotational power, and cooling water is introduced from the outside to circulate the introduced cooling water.

For example, the shaft member 200 is manufactured in a multi-stage shaft shape in which both ends are axially coupled to rotate in place in the upper center of the plating bath 110, and both ends of the shaft member 200 are bearing housings for shaft coupling. A structure such as the back is provided so that the shaft member 200 is supported by the plating bath 110, and the drum member 300 is axially coupled outside the central portion of the shaft member 200.

At this time, the shaft member 200 has a power means such as an electric motor for transmitting rotational power to one end, and the electric motor can operate according to a control signal from a control panel separately provided in the plating apparatus 1 , The shaft member 200 rotates through the power of the electric motor, and the rotational power of the shaft member 200 is transmitted to the drum member 300.

In addition, the shaft member 200 supplies the cooling water introduced from the outside to the inside of the drum member 300 through the inlet 211, and the cooling water supplied to the drum member 300 through the outlet 212 It further includes a flow path 210 for discharging to the outside to circulate the cooling water.

The flow path 210 is formed as a path through which coolant can move inside the shaft member 200, and the flow path 210 has an inlet 211 formed to allow cooling water to flow from the outside to one side of the shaft member 200 And, an outlet 212 for discharging the cooling water introduced to the other side of the inlet 211 is formed.

At this time, the inlet 211 and the outlet 212 are respectively connected to the cooling unit 330 of the drum member 300 to supply cooling water to the cooling unit 330 and to supply the cooling water supplied to the cooling unit 330. It provides a cycle to discharge and circulate.

And, the drum member 300;

While being axially coupled to the shaft member 200, a part of the electrolytic solution of the plating member 100 is put into the electrolyte solution, and as a negative electrode exhibiting a negative charge, it is linked from the side adjacent to the anode 120 to induce electrolysis. When electroplating is started, copper foil is electrodeposited on the surface to be formed, and cooling water of the shaft member 200 is introduced during electroplating to cool the plating surface.

For example, the drum member 300 further includes an inner circumferential body 310 coupled to the shaft member 200 to apply a current to the outer circumferential body 320.

The inner circumferential body 310 is fixedly coupled to the outer central portion of the shaft member 200 to transmit rotational power, and the inner circumferential body 310 is fitted in the shaft member 200 by being opposed to each other at random intervals in the form of a disk. A pair of first side plates 311 to be coupled are provided, and the first cylinder 312 is coupled to the outer circumferential surface of the pair of first side plates 311, which is an empty space inside the inner circumferential body 310. The cooling unit 330 is formed.

At this time, the first side plate 311 has a hole fitted to the shaft member 200 in the center, and the first cylinder 312 is fitted and fixed inward to the pair of first side plates 311 A stepped protrusion may be formed on the inner circumference so as to be able to be formed, and the pair of first side plates 311 and the first cylinder 312 may be integrated with each other through welding.

On the other hand, the inner circumferential body 310 may be made of a copper (Cu) material, and the electrical conductivity is very excellent due to the characteristics of the copper material so that the current applied through the shaft member 200 can be efficiently passed through the outer circumferential body 320. do.

In addition, the drum member 300 is coupled by surrounding the outer side of the inner circumferential body 310, and when electric plating starts while current is applied through the inner circumferential body 310, the outer circumference formed by electrodepositing copper foil on the outer surface Body 320; further includes.

The outer circumferential body 320 is coupled while surrounding the entire outer portion of the inner circumferential body 310, and the outer circumferential body 320 is opposed to each other at random intervals in the form of a disk and is fitted to the shaft member 200 while being coupled to the A pair of second side plates 321 in close contact with the first side plate 311 of the inner circumferential body 310 are provided, and a second cylindrical body 322 which is a cylinder as an outer circumferential surface of the pair of second side plates 321 is It is coupled to be in close contact with the first cylinder 312 of the inner circumferential body 310.

At this time, the second cylinder 322 has a fitting structure so that the outer circumferential surface (first cylinder) of the inner circumferential body 310 is in close contact with the inner circumference, and the second side plate 321 is fitted with the inner circumferential body 310. The second cylinder 322 has a fitting structure in both directions, and the outer peripheral body 320 is in close contact with the inner peripheral body 310 by the fitting structure of the second cylinder 322 and the second side plate 321. Can be authorized.

The second side plate 321 may also have a hole fitted to the shaft member 200 at a center thereof.

On the other hand, the outer circumferential body 320 may be made of a titanium (Ti) material, is suitable for electroplating due to its strong reactivity due to the characteristics of the titanium material, and has good corrosion resistance and strength, so that high quality copper foil can be obtained.

Characteristically, the drum member 300 made of the outer circumferential body 320 and the inner circumferential body 310 is axially coupled to the upper opening side of the plating bath 110 through the shaft member 200, and a lower part of the plating member 100 Is accommodated in a plating bath 110 filled with an electrolyte, and the drum member 300 may perform a rotation operation during plating through the shaft member 200.

In this state, when electricity is applied to the plating member 100, electrolysis is induced while being energized in the electrolyte, so that the metal ions of the anode 120 move from the anode of the anode 120 to the cathode of the drum member 300, and electroplating is performed. Beginning, the metal ions can be obtained by electrodepositing copper foil on the outer circumferential surface of the outer circumferential body 320 as copper (Cu) ions, and peeling off the electrodeposited copper foil.

In addition, the drum member 300 is formed as a space filled with coolant inside the inner circumferential body 310, and is connected to the flow path 210 of the shaft member 200 so that the coolant is introduced and discharged to circulate while the drum member It further includes a; cooling unit 330 for performing the cooling of (300).

The cooling unit 330 is a space for cooling to fill the space formed in the inner circumferential body 310 with coolant, and the cooling unit 330 is an inlet 211 and an outlet 212 of the flow path 210 When the cooling water is connected to each of the flow paths 210 and fills the inner space of the cooling unit 330, the cooling water flows in through the inlet 211 as much as the amount discharged to the discharge port 212 and enters the cooling unit 330. The coolant to be filled is continuously circulated.

At this time, when the cooling water is filled in the cooling unit 330, the drum member 300 including the inner circumferential body 310 and the outer circumferential body 320 is cooled by the cooling water.

Characteristically, the cooling unit 330 cools the drum member 300 using circulating cooling water to reduce the thermal load during electroplating, while improving the plating quality, and the cooling water in the entire interior of the drum member 300 Cooling efficiency is good by being filled evenly, and the temperature of the drum member 300 can be kept constant as the cooling water is continuously circulated through the drum member 300.

In addition, the drum member 300 further includes a partition plate 331 that divides the space of the cooling unit 330 into the interior of the inner circumferential body 310 and allows current to be applied to the outer circumferential body 320. .

The partition plate 331 is axially coupled to the shaft member 200 in a state inserted into the space of the cooling unit 330 into the inner circumferential body 310, and the partition plate 331 is It is manufactured in the form of a disk corresponding to the cross-sectional shape in the internal cooling unit 330, and the partition plate 331 is inserted into the cooling unit 330 in one or more rows at equal intervals to fill the space of the cooling unit 330. It can be divided into many.

Meanwhile, a passage 331a for moving the cooling water is formed as a hole inside the partition plate 331 so that the cooling water can be uniformly filled in each partition space of the cooling unit 330.

Characteristically, one or more internal spaces of the cooling unit 330 can be partitioned through the partition plate 331, so that convection of the cooling water due to the rotation of the drum member 300 can be reduced, and the cooling water through the partition plate 331 To be circulated while being uniformly filled in the cooling unit 330 as a whole.

Hereinafter, as another embodiment of the present invention, an electroplating apparatus for manufacturing copper foil according to the second embodiment will be described in detail with reference to FIG. 3. 3 is a side cross-sectional view of the electroplating apparatus.

According to this, the drum member 300 of the electroplating apparatus 1 having the above-described structure; A plurality of conductors 340 are coupled to be arranged at regular intervals around the inner circumferential body 310, and the combined outer ends are in contact with the outer circumferential body 320 to conduct current directly to the outer circumferential body 320. It further includes;

The plurality of conductors 340 are coupled to be arranged at regular intervals along the circumference of the first cylinder 312 of the inner circumferential body 310, and the conductor 340 is manufactured in the form of a headless bolt to the inner circumferential body 310 The inner circumferential body 310 to which the conductor 340 is coupled is formed with a helical hole corresponding thereto, and a conductor on the inner circumferential surface of the outer circumferential body 320 through the helical coupling of the conductor 340 By advancing the outer end of the coupling part of the 340, it is possible to make perfect contact.

At this time, while the plurality of conductors 340 are in close contact with the inner circumference of the outer circumferential body 320, the current applied through the inner circumferential body 310 is directly transmitted to each contact point where the plurality of conductors 340 are in contact, and the cylindrical chain Because the outer circumferential body 320 and the inner circumferential body 310 have curvature, it is not easy to completely contact the outer circumferential body 320 and the inner circumferential body 310 and require ultra-precision processing. Let's do it.

Characteristically, as the plurality of conductors 340 are arranged and arranged at regular intervals to directly conduct current between the outer peripheral body 320 and the inner peripheral body 310 coupling portion of the drum member 300, it is possible to directly conduct current conduction. As a result, electric resistance due to incomplete contact between the outer circumferential body 320 and the inner circumferential body 310 is reduced, and current conduction is uniformly performed on the entire area of the drum member 300, thereby greatly improving the plating quality.

As described above. Although the present invention has been expressed in the description and drawings illustrating specific preferred embodiments, the terms used herein are for the purpose of easily describing the present invention, and the meaning of these terms and the scope described in the claims are limited. Not to do,

The present invention is capable of various changes, modifications, and modifications by those of ordinary skill in the technical field to which the present invention pertains within the scope not departing from the spirit and scope of the invention indicated by the claims according to the above-described embodiments. Anyone can easily see that it can.

One; Plating device 100; Plated member
110; Plating bath 200; Shaft member
210; Euro 300; Drum absent
310; Inner circumferential body 320; Outer circumferential body
330; Cooling unit 340; conductor

Claims (5)

A plating member 100 for receiving an electrolyte and providing an anode 120 as an anode having a positive charge on a side where the electrolyte is accommodated, and providing a space for electroplating;
A shaft member 200 that couples the drum member 300 to the plating member 100 to transmit rotational power, and circulates the cooling water while cooling water is introduced from the outside;
While being axially coupled to the shaft member 200, a part of the electrolytic solution of the plating member 100 is put into the electrolytic solution, and as a negative electrode exhibiting a negative charge, it is linked from the side adjacent to the anode 120 to induce electrolysis. When electroplating is started, copper foil is electrodeposited on the surface to be formed, and the cooling water of the shaft member 200 is introduced during electroplating to include a drum member 300 for cooling the plating surface,
The drum member 300 is axially coupled to the shaft member 200, the inner circumferential body 310 for applying a current to the outer circumferential body 320; And
The outer circumferential body 320 is formed by enclosing the outer side of the inner circumferential body 310, and when electroplating is started while current is applied through the inner circumferential body 310, the outer circumferential body 320 is formed by electrodepositing copper foil on the outer surface.
The inner circumferential body 310 and the outer circumferential body 320 are made of different metal materials,
The inner circumferential body 310 is provided with a pair of first side plates 311 facing each other and fitted to the shaft member 200 in the form of a disk, and the pair of first side plates 311 is cylindrical in the outer circumferential surface. The first cylinder 312 is combined and made,
The outer circumferential body 320 is provided with a pair of second side plates 321 in close contact with the pair of first side plates 311 while being fitted to the shaft member 200, and the pair of second side plates (321) further comprising a second cylinder 322, which is a cylinder as an outer circumferential surface, is formed by being in close contact with the first cylinder 312,
The drum member 300 is coupled to the first cylinder 312 of the inner circumferential body 310 to be disposed at regular intervals, and the outer end of the coupled side is attached to the second cylinder 322 of the outer circumferential body 320 Electroplating apparatus for manufacturing copper foil, including a plurality of conductors 340 that allow current conduction to be performed directly on the outer circumferential body 320 while being in contact. delete delete delete delete

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