KR20210000552U - System for Manufacturing Electrolytic Copper Foil - Google Patents

Abstract

The present invention is an electrolytic copper foil manufacturing apparatus for manufacturing a copper foil using an electroplating method while rotating a plurality of rollers; A plurality of peripheral devices for acquiring sensor data; And a supply unit coupled to the electrolytic copper foil manufacturing apparatus for supplying electricity to the peripheral devices, wherein the electrolytic copper foil manufacturing apparatus includes a frame member for supporting at least one of the rollers, and the supply unit It relates to an electrolytic copper foil manufacturing system including a first supply module coupled to the frame member to be electrically connected to a first power cable disposed inside of

Description

System for Manufacturing Electrolytic Copper Foil}

The present invention relates to an electrolytic copper foil manufacturing system for manufacturing copper foil used to manufacture various products such as a negative electrode for a secondary battery and a flexible printed circuit board.

Copper foil is used to manufacture various products such as negative electrodes for secondary batteries and flexible printed circuit boards (FPCB). Such copper foil is manufactured through an electroplating method in which an electrolytic solution is supplied between an anode and a cathode and then an electric current flows through it.

In manufacturing copper foil through the electroplating method as described above, an electrolytic copper foil manufacturing apparatus is used. The electrolytic copper foil manufacturing apparatus is installed inside the workshop to manufacture copper foil through the electroplating method.

In this electrolytic copper foil manufacturing apparatus, a peripheral device for acquiring sensor data capable of grasping environmental information related to the manufacture of copper foil is installed. In addition, a considerable number of power cables are placed on the floor of a workshop where an electrolytic copper foil manufacturing device is installed to supply electricity to peripheral devices. Accordingly, in the related art, there is a high risk of occurrence of a safety accident due to jamming of a power cable placed on the floor of a work place while a worker is moving.

The present invention was devised to solve the above-described problem, and is to provide a system for manufacturing an electrolytic copper foil capable of reducing the risk of a safety accident due to a power cable for supplying electricity to a peripheral device.

In order to solve the above problems, the present invention may include the following configuration.

The electrolytic copper foil manufacturing system according to the present invention includes an electrolytic copper foil manufacturing apparatus for manufacturing copper foil using an electroplating method while rotating a plurality of rollers; A plurality of peripheral devices for acquiring sensor data; And a supply unit coupled to the electrolytic copper foil manufacturing apparatus and supplying electricity to the peripheral devices. The electrolytic copper foil manufacturing apparatus may include a frame member for supporting at least one of the rollers. The supply unit may include a first supply module coupled to the frame member to be electrically connected to a first power cable disposed inside the frame member.

According to the present invention, the following effects can be achieved.

The present invention is implemented to reduce the area occupied by the power cable on the floor of the workplace. Accordingly, the present invention can reduce the risk of occurrence of a safety accident due to jamming of the power cable placed on the floor of the workplace while the worker is moving. Therefore, the present invention can improve the safety for the workplace.

1 is a schematic block diagram of an electrolytic copper foil manufacturing system according to the present invention
2 is a schematic configuration diagram of an electrolytic copper foil manufacturing apparatus in the electrolytic copper foil manufacturing system according to the present invention
3 is a schematic side view of an electrolytic copper foil manufacturing apparatus in the electrolytic copper foil manufacturing system according to the present invention
4 is a schematic block diagram of an electrolytic copper foil manufacturing apparatus in the electrolytic copper foil manufacturing system according to the present invention
5 is a schematic side view showing a part of the frame member to which the first supply module is coupled in the electrolytic copper foil manufacturing system according to the present invention
6 is a schematic cross-sectional view taken along line II of FIG. 5

Hereinafter, an embodiment of an electrolytic copper foil manufacturing system according to the present invention will be described in detail with reference to the accompanying drawings.

Referring to Figure 1, the electrolytic copper foil manufacturing system 1 according to the present invention is to manufacture a copper foil (銅箔). Copper foil is used to manufacture negative electrodes for secondary batteries and flexible printed circuit boards (FPCB). The electrolytic copper foil manufacturing system 1 according to the present invention may include an electrolytic copper foil manufacturing apparatus 2, a peripheral device 3, and a supply unit 4.

Referring to FIG. 1, the electrolytic copper foil manufacturing apparatus 2 manufactures copper foil using an electroplating method. The electrolytic copper foil manufacturing apparatus 2 may be located inside the workshop 100. The electrolytic copper foil manufacturing apparatus 2 may manufacture copper foil using an electro-copper method while rotating a plurality of rollers 2a. The electrolytic copper foil manufacturing apparatus 2 has an electrodeposition function of electrodepositing copper foil using the rollers 2a, a winding function for winding copper foil, a conveying function for conveying copper foil, and guiding the transport of copper foil. At least one of the guiding function and the cutting function of cutting the copper foil may be implemented. The electrolytic copper foil manufacturing apparatus 2 may include a frame member 20 for supporting at least one of the rollers 2a. At least one of the rollers 2a may be rotatably coupled to the frame member 20. At least one of the rollers 2a may be directly coupled to the frame member 20 or may be coupled through a separate frame. The frame member 20 may correspond to a main frame that entirely supports the electrolytic copper foil manufacturing apparatus 2.

1 to 4, the electrolytic copper foil manufacturing apparatus 2 may include an electrodeposition part 21, a conveying part 22, a cutting part 23, and a winding part 24.

The electrodeposition part 21 is to electrodeposit copper foil. The electrodeposited part 21 may electrodeposit copper foil using an electroplating method using an electrolyte. The electrodeposition part 21 may include a cathode roller 211 and a cathode member 212. When the cathode roller 211 and the anode member 212 are energized through an electrolyte and current flows, copper ions dissolved in the electrolyte may be reduced by the cathode roller 211. Accordingly, the cathode roller 211 may be electrodeposited with copper foil on the surface.

The cathode roller 211 may rotate about a rotation axis. The cathode roller 211 may continuously perform an electrodeposition operation of electrodepositing the copper foil to the surface while rotating about the rotation axis and an unwinding operation of detaching the electrodeposited copper foil from the surface. The cathode roller 211 may be formed in a drum shape as a whole, but is not limited thereto and may be formed in a different shape as long as the electrodeposition operation and the unwinding operation can be continuously performed while rotating around a rotation axis May be. The cathode roller 211 may correspond to the roller 2a.

The positive electrode member 212 is energized with the negative electrode roller 211 through an electrolyte. The anode member 212 may be disposed below the cathode roller 211. The anode member 212 may be disposed to be spaced apart from the surface of the cathode roller 211. The surface of the anode member 212 and the surface of the cathode roller 211 may be formed in the same shape. For example, when the cathode portion 2 is formed in a circular rectangular shape and the surface thereof is formed to have a curved surface, the cathode portion 3 may be formed in a semicircular rectangular shape so that the surface thereof is formed in a curved surface.

The electrodeposition part 21 may include an electrodeposition frame 213 (shown in FIG. 3 ).

The electrodeposition frame 213 supports the cathode roller 211. The cathode roller 211 may be rotatably coupled to the electrodeposition frame 213. The cathode roller 211 may be rotated by a rotational force generated by a driving source (not shown) such as a motor while being supported by the electrodeposition frame 213.

The electrodeposition frame 213 may be coupled to the frame member 20. Accordingly, the frame member 20 may support the anode roller 211 supported by the electrodeposition frame 213 by supporting the electrodeposition frame 213. Although not shown, the cathode roller 211 may be directly coupled to the frame member 20 without the electrodeposition frame 213.

1 to 4, the transport unit 22 is to transport the copper foil. The conveying part 22 may convey the copper foil electrodeposited on the surface of the cathode roller 211 to the cutting part 23. The transport unit 22 may dry the electrolyte, etc. remaining on the surface of the copper foil while transporting the copper foil.

The conveying part 22 may include a conveying roller 221 and a conveying frame 222.

The conveying roller 221 may rotate about a rotation axis. The conveying roller 221 may transport the copper foil from the electrodeposition part 21 to the cutting part 23 while rotating about the rotation axis. The transport roller 221 may be formed in a drum shape as a whole, but is not limited thereto, and may be formed in another shape as long as it is a shape capable of transporting copper foil while rotating around a rotation axis. The conveying roller 221 may correspond to the roller 2a.

The transport frame 222 is to support the transport roller 221. The conveying roller 221 may be rotatably coupled to the conveying frame 222. The conveying roller 221 may be rotated by a rotational force generated by a driving source (not shown) such as a motor while being supported by the conveying frame 222.

The transport frame 222 may be coupled to the frame member 20. Accordingly, the frame member 20 may support the transport roller 221 supported on the transport frame 222 by supporting the transport frame 222. Although not shown, the transport roller 221 may be directly coupled to the frame member 20 without the transport frame 222.

1 to 4, the cutting part 23 is to cut both sides of the copper foil carried from the conveying part 22. Both sides of the copper foil are based on the width direction perpendicular to the direction in which the copper foil is conveyed from the conveying part 22. The copper foil passing through the cutting portion 23 may be transported to the winding portion 24.

The cutting part 23 may include a cutting roller 231 and a cutting frame 232.

The cutting roller 231 may rotate about a rotation axis. The cutting roller 231 may cut both sides of the copper foil while rotating about the rotation axis. The cutting roller 231 may be formed in a disk shape as a whole, but is not limited thereto, and may be formed in another shape as long as it is a shape capable of cutting both sides of the copper foil while rotating about a rotation axis. The cutting roller 231 may correspond to the roller 2a.

The cutting frame 232 supports the cutting roller 231. The cutting roller 231 may be rotatably coupled to the cutting frame 232. The cutting roller 231 may be rotated by a rotational force generated by a driving source (not shown) such as a motor while being supported by the cutting frame 232.

The cutting frame 232 may be coupled to the frame member 20. Accordingly, the frame member 20 may support the cutting roller 231 supported by the cutting frame 232 by supporting the cutting frame 232. Although not shown, the cutting roller 231 may be directly coupled to the frame member 20 without the cutting frame 232.

Referring to FIGS. 1 to 4, the winding part 24 winds the copper foil cut by the cutting part 23. The winding unit 24 may continuously wind up the copper foil while rotating. The copper foil wound on the winding part 24 may be cut to a predetermined width in a subsequent process.

The winding part 24 may include a winding roller 241 and a winding frame 242.

The take-up roller 241 may rotate around a rotation axis. The winding roller 241 may wind up the copper foil while rotating about the rotation shaft. The winding roller 241 may be formed in a drum shape as a whole, but is not limited thereto, and may be formed in another shape as long as it is a shape capable of winding copper foil while rotating about a rotation axis. The winding roller 241 may correspond to the roller 2a.

The take-up frame 242 is to support the take-up roller 241. The winding roller 241 may be rotatably coupled to the winding frame 242. The winding roller 241 may be rotated by a rotational force generated by a driving source (not shown) such as a motor while being supported by the winding frame 242.

The winding frame 242 may be coupled to the frame member 20. Accordingly, the frame member 20 may support the take-up roller 241 supported by the take-up frame 242 by supporting the take-up frame 242. Although not shown, the winding roller 241 may be directly coupled to the frame member 20 without the winding frame 242.

1 to 4, the peripheral device 3 acquires sensor data. The sensor data may be related to the internal environment. For example, the sensor data may be a temperature inside the workplace 100, a humidity inside the workplace 100, or the like. The sensor data may be related to vibration generated during the operation of the electrolytic copper foil manufacturing apparatus 2. The peripheral device 3 may operate to obtain the sensor data using electricity supplied from the supply unit 4. The peripheral device 3 may be coupled to the electrolytic copper foil manufacturing apparatus 2.

The electrolytic copper foil manufacturing system 1 according to the present invention may include a plurality of the peripheral devices 3. Each of the peripheral devices 3 may be implemented as a sensor that obtains sensor data by measuring temperature, humidity, vibration, and the like. The peripheral devices 3 include sensors that acquire sensor data by measuring temperature, humidity, vibration, etc., and a transmitter that transmits the sensor data acquired by the sensors to a server or terminal. ) It can also be implemented as a module.

1 to 6, the supply unit 4 supplies electricity to the peripheral devices 3. The supply unit 4 may receive electricity from a power supply unit 200 (shown in FIG. 1) installed in the workplace 100. The power supply unit 200 supplies electricity supplied from the outside of the workplace 100 to facilities located inside the workplace 100. The supply unit 4 may be electrically connected to the power supply unit 200 through a power cable 300 (shown in FIG. 1 ). The supply unit 4 may be electrically connected to the peripheral devices 3 through a connection cable 400 (shown in FIG. 1 ).

The supply unit 4 may include a first supply module 41.

The first supply module 41 may be electrically connected to the first power cable 310. The first power cable 310 means electrically connected to the first supply module 41 among the power cables 300. One side of the first supply module 41 may be electrically connected to the power supply unit 200, and the other side may be electrically connected to at least one of the peripheral devices 3 through the connection cable 400. Accordingly, the first supply module 41 may supply electricity to at least one of the peripheral devices 3.

The first supply module 41 may be coupled to the frame member 20 so as to be electrically connected to the first power cable 310 disposed inside the frame member 20. The first supply module 41 may be coupled to the first portion of the frame member 20. The first portion of the frame member 20 may be a portion of the rollers 2a that supports the first roller 21a (shown in FIG. 1 ). The first roller 21a may be any one of the cathode roller 211, the conveying roller 221, the cutting roller 231, and the winding roller 241. In this case, any one of the electrodeposition frame 213, the transport frame 222, the cutting frame 232, and the winding frame 242 may be coupled to the first portion of the frame member 20. .

5 shows that the first portion of the frame member 20 to which the first supply module 41 is coupled extends in the vertical direction, but is not limited thereto, and the first portion of the frame member 20 is It may be a portion extending in the left-right direction or a portion extending in a direction inclined to each of the vertical and horizontal directions.

Since the first supply module 41 is electrically connected to the first power cable 310 disposed inside the frame member 20, the inside of the frame member 20 from the first power cable 310 The portion disposed in is not disposed on the floor of the workshop 100. Accordingly, the electrolytic copper foil manufacturing system 1 according to the present invention can reduce the area occupied by the power cable 300 on the floor of the workshop 100. Therefore, the electrolytic copper foil manufacturing system 1 according to the present invention can reduce the risk of occurrence of a safety accident due to being caught by the power cable 300 placed on the floor of the workplace 100 in the process of moving the worker, the workplace ( 100) can improve the safety.

The first supply module 41 may be electrically connected to a first peripheral device 31 (shown in FIG. 1) among the peripheral devices 3 through the connection cable 400. Accordingly, the first peripheral device 31 may operate using electricity supplied from the first supply module 41. Since the first supply module 41 is coupled to the frame member 20 and the first peripheral device 31 is coupled to the electrolytic copper foil manufacturing apparatus 2, the connection cable 400 is Can be placed so that it does not lie on the floor Therefore, the electrolytic copper foil manufacturing system 1 according to the present invention can further improve the safety of the workplace 100.

The first supply module 41 may include an inverter 411 and a first connection port 412.

The inverter 411 controls the voltage of electricity supplied from the first power cable 310. The inverter 411 may adjust a voltage of electricity supplied from the first power cable 310 so as to have a voltage of a suitable size for the first peripheral device 31. The inverter 411 may be electrically connected to each of the first power cable 310 and the first connection port 412. Electricity supplied from the first power cable 310 may be supplied to the first connection port 412 after voltage is adjusted while passing through the inverter 411. The inverter 411 may be coupled to the frame member 20. The inverter 411 may be electrically connected to the first power cable 310 inside the frame member 20. The inverter 411 may be coupled to the frame member 20 so that the first connection port 412 is disposed outside the frame member 20. In this case, the inverter 411 may be coupled to the frame member 20 so that the whole of the inverter 411 is disposed outside the frame member 20. The inverter 411 may be coupled to the frame member 20 so that a part of the inverter 411 is disposed inside the frame member 20 and the rest of the inverter 411 is disposed outside the frame member 20.

The first connection port 412 is for supplying electricity to the first peripheral device 31. Since the first connection port 412 is electrically connected to the inverter 411, electricity may be supplied from the first power cable 310 through the inverter 411. The first connection port 412 may be electrically connected to the first peripheral device 31 through the connection cable 400. Accordingly, the first connection port 412 may supply electricity whose voltage supplied from the inverter 411 is adjusted to the first peripheral device 31. The first connection port 412 may be disposed outside the frame member 20. Accordingly, the electrolytic copper foil manufacturing system 1 according to the present invention, even if the first power cable 310 is disposed inside the frame member 20, the first peripheral device ( Ease of connecting 31) to the first power cable 310 may be improved. The first connection port 412 may be coupled to the inverter 411. The first connection port 412 may be implemented as a USB port (Universal Serial Bus Port).

The first supply module 41 may include a second connection port 413.

The second connection port 413 is for supplying electricity to the second peripheral device 32 among the peripheral devices 3. The second peripheral device 32 and the first peripheral device 31 may be for acquiring different sensor data. The second peripheral device 32 and the first peripheral device 31 may be for acquiring the same sensor data. In this case, since the second peripheral device 32 and the first peripheral device 31 are disposed at different positions, different measurement positions for acquiring sensor data may be implemented.

Since the second connection port 413 is electrically connected to the inverter 411, electricity may be supplied from the first power cable 310 through the inverter 411. The second connection port 413 may be electrically connected to the second peripheral device 32 through the connection cable 400. Accordingly, the second connection port 413 may supply electricity whose voltage supplied from the inverter 411 is adjusted to the second peripheral device 32. The second connection port 413 may be disposed outside the frame member 20. Accordingly, the electrolytic copper foil manufacturing system 1 according to the present invention, even if the first power cable 310 is disposed inside the frame member 20, the second peripheral device ( Ease of electrically connecting 32) to the first power cable 310 may be improved. The second connection port 413 may be coupled to the inverter 411. The second connection port 413 and the first connection port 412 may be coupled to the inverter 411 so as to be disposed at positions spaced apart from each other. The second connection port 413 may be implemented as a USB port.

Although not shown, the first supply module 41 may be implemented to include three or more connection ports. The connection ports may be coupled to the inverter 411 so as to be disposed at positions spaced apart from each other. The connection ports are electrically connected to different peripheral devices 3 through different connection cables 400, so that electricity can be supplied to different peripheral devices 3.

Here, the frame member 20 may include a first receiving groove 201 (shown in FIG. 6 ).

The first receiving groove 201 accommodates the first power cable 310. The first power cable 310 may be disposed in the frame member 20 by being accommodated in the first receiving groove 201. The first supply module 41 may be electrically connected to a first power cable 310 disposed inside the frame member 20 through the first receiving groove 201. 6 shows that one first power cable 310 is accommodated in the first receiving groove 201, but is not limited thereto, and two or more first power cables 310 are provided in the first receiving groove 201. ) May be accepted.

The first receiving groove 201 may be formed through one side of the frame member 20. Accordingly, the first power cable 310 is drawn out to the outside of the frame member 20 through one side of the frame member 20, so that the power supply unit 200 disposed to be spaced apart from the electrolytic copper foil manufacturing apparatus 2 Can be electrically connected to. The first receiving groove 201 may be formed to be connected from one side of the frame member 20 to a portion of the frame member 20 to which the inverter 411 is coupled.

The supply unit 4 may include a second supply module 42 (shown in FIG. 1 ).

The second supply module 42 may be electrically connected to a second power cable (not shown). The second power cable means electrically connected to the second supply module 42 among the power cables 300. One side of the second supply module 42 may be electrically connected to the power supply unit 200, and the other side may be electrically connected to at least one of the peripheral devices 3 through the connection cable 400. Therefore, the electrolytic copper foil manufacturing system 1 according to the present invention uses the second supply module 42 and the first supply module 41 to improve the safety of the workplace 100 while supplying electricity to a peripheral device ( The number of 3) can be increased.

The second supply module 42 may be coupled to the frame member 20 to be electrically connected to a second power cable disposed inside the frame member 20. In this case, the second supply module 42 and the first supply module 41 may be coupled to the frame member 20 so as to be disposed at positions spaced apart from each other. The second supply module 42 may be coupled to the second portion of the frame member 20. The second portion of the frame member 20 may be a portion of the rollers 2a that supports the second roller 22a. The second roller 22a may be any one of the cathode roller 211, the conveying roller 221, the cutting roller 231, and the winding roller 241. The second roller 22a and the first roller 21a may be different from each other. In this case, any one of the electrodeposition frame 213, the transport frame 222, the cutting frame 232, and the winding frame 242 may be coupled to the second portion of the frame member 20. .

Since the second supply module 42 is electrically connected to a second power cable disposed inside the frame member 20, a portion of the second power cable disposed inside the frame member 20 is It is not placed on the floor of the workplace 100. Accordingly, the electrolytic copper foil manufacturing system 1 according to the present invention can further reduce the area occupied by the power cable 300 on the floor of the workshop 100. Therefore, the electrolytic copper foil manufacturing system 1 according to the present invention can further improve the safety of the workplace 100.

Although not shown, the second supply module 42 may include an inverter, a first connection port, and a second connection port. The inverter, the first connection port, and the second connection port of the second supply module 42 are the inverter 411, the first connection port 412, and the second connection of the first supply module 41 Since each port 413 is implemented to substantially coincide with each other, a detailed description thereof will be omitted. In addition, the frame member 20 may include a second receiving groove. Since the second receiving groove is implemented to substantially coincide with the first receiving groove 201, a detailed description thereof will be omitted.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and various substitutions, modifications and changes are possible within the scope of the technical spirit of the present invention. It will be obvious to those who have the knowledge of.

1: electrolytic copper foil manufacturing system 2: electrolytic copper foil manufacturing apparatus
3: peripheral device 4: supply unit
2a: roller 21a: first roller
22a: second roller 20: frame member
31: first peripheral device 32: second peripheral device
41: first supply module 42: second supply module
21: electrodeposition unit 22: transport unit
23: cut part 24: winding part
211: negative roller 221: conveying roller
231: cutting roller 241: take-up roller
213: cathode frame 222: transport frame
232: cutting frame 242: winding frame

Claims (5)

Electrolytic copper foil manufacturing apparatus 2 for manufacturing copper foil using an electroplating method while rotating a plurality of rollers 2a;
A plurality of peripheral devices 3 for acquiring sensor data; And
It is coupled to the electrolytic copper foil manufacturing apparatus 2, and includes a supply unit 4 for supplying electricity to the peripheral devices 3,
The electrolytic copper foil manufacturing apparatus 2 includes a frame member 20 for supporting at least one of the rollers 2a,
The supply unit 4 includes a first supply module 41 coupled to the frame member 20 so as to be electrically connected to a first power cable 310 disposed inside the frame member 20 Electrolytic copper foil manufacturing system. The method of claim 1, wherein the first supply module (41) is
An inverter 411 electrically connected to the first power cable 310 disposed inside the frame member 20 and controlling a voltage of electricity supplied from the first power cable 310;
A first connection port 412 electrically connected to the inverter 411 and configured to supply electricity with a regulated voltage supplied from the inverter 411 to a first peripheral device 31 from among the peripheral devices 3; And
A second connection port 413 electrically connected to the inverter 411 and for supplying electricity with a regulated voltage supplied from the inverter 411 to a second peripheral device 32 among the peripheral devices 3. Electrolytic copper foil manufacturing system comprising a. The method of claim 1,
The frame member 20 includes a first receiving groove 201 for accommodating the first power cable 310,
The first supply module (41) is electrically connected to the first power cable (310) disposed inside the frame member (20) through the first receiving groove (201). The method of claim 3,
The first supply module 41 includes a first connection port 412 for supplying electricity to a first peripheral device 31 among the peripheral devices 3, and the first connection port 412 is the frame Electrolytic copper foil manufacturing system, characterized in that coupled to the frame member (20) so as to be disposed outside the member (20). The method of claim 3,
The first receiving groove 201 passes through one side of the frame member 20 so that the first power cable 310 is electrically connected to the power supply unit 200 disposed spaced apart from the electrolytic copper foil manufacturing apparatus 2. Electrolytic copper foil manufacturing system, characterized in that formed.

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