KR20130073300A - Electrode notching apparatus for secondary battery - Google Patents

Abstract

PURPOSE: An electrode notching apparatus for a secondary battery is provided to improve work rate and accuracy by quickly locating an electrode film to an accurate pitch. CONSTITUTION: An electrode notching apparatus for a secondary battery includes an unwinder part (10) with an unprocessed electrode film (F) is winded in a roll shape; a film feeder part (30) continuously repeating a horizontal transfer function by grinding an electrode film from the unwinder part; a notching processing part (20) shear-processing an electrode film being transferred by the film feeder part into a designated electrode pattern; and a vision examination part (40) inspecting an electrode part of the shear-processed electrode film; and a rewinder part (50) which re-winds the electrode film into a roll shape.

Description

Electrode Notching Apparatus for Secondary Battery {Electrode Notching Apparatus for Secondary Battery}

The present invention relates to an apparatus for performing electrode notching of a secondary battery, and more particularly, to perform electrode notching processing for forming electrode tabs by shearing a plain portion of a polymer electrode film of a secondary battery. It relates to a device to.

In general, a notching system for shearing a polymer electrode film of a secondary battery in the form of an electrode includes an unwinder for releasing a film for a polymer electrode wound in a roll form, and a polymer using a press machine. It consists of a notching processing part for shearing the electrode film in the form of an electrode, a vision inspection part for checking whether the processed electrode is normally processed, and a rewinder part for rewinding the processed electrode in a roll shape.

In the conventional electrode notching system, the unwinder, the notching processing part, the vision inspection part, and the rewinder part are arranged in-line, and the electrode film is transferred to a predetermined pitch by winding the electrode film in the rewinder part. An electrode notching process is performed.

However, the conventional electrode notching system as described above transfers the electrode film depending only on the driving force of the rewinder, so that the feeding speed of the electrode film is slow and the electrode film may not be transferred to the correct process position, thereby reducing the precision. There is a problem.

The present invention is to solve the conventional problems as described above, an object of the present invention is to provide an electrode notching device of a secondary battery that can improve the working speed and precision by transferring the electrode film to a quick and accurate pitch.

The present invention for achieving the above object is an unwinder unit, the electrode film of the raw state is wound in a roll form; A film feeder unit which continuously and repeatedly performs the action of horizontally conveying the electrode film released from the unwinder unit by a predetermined distance; A notching processing portion disposed between the unwinder portion and the film feeder portion to shear the electrode film conveyed by the film feeder portion to a predetermined electrode pattern; A vision inspection unit disposed at the other side of the film feeder unit and inspecting the electrode unit of the sheared electrode film by photographing the electrode unit; It is disposed on one side of the vision inspection unit provides a secondary battery electrode notching device comprising a rewinder unit for winding the electrode film inspected through the vision inspection unit in the form of a roll.

According to the present invention, since the film feeder unit for carrying out the operation of transferring the electrode film by a predetermined pitch is composed of two film feeding unit to perform the film transfer operation alternately with each other, the transfer operation of the electrode film is made continuously without interruption As a result, the work speed can be improved.

In addition, since the film feeder unit transfers the electrode film by a predetermined pitch, the electrode film can be transferred to the correct processing position of the notching processing unit. Therefore, there also exists an advantage that the precision of a notching process can be improved.

1 is a perspective view schematically showing the overall configuration of the electrode notching apparatus of a secondary battery according to an embodiment of the present invention.
FIG. 2 is a front view of the electrode notching apparatus of the secondary battery of FIG. 1.
3 is a cross-sectional view of the main portion of the notching processing unit of the electrode notching apparatus of the secondary battery of FIG. 1.
4 is a cross-sectional view of the main parts of the notching processing unit of the electrode notching apparatus of the secondary battery of FIG. 1.
FIG. 5 is a plan view schematically illustrating a structure of a film feeder of the electrode notching apparatus of the secondary battery of FIG. 1.
6A to 6B are front views illustrating the operation of the film feeder unit of FIG. 5 in sequence.

Hereinafter, an electrode notching apparatus of a secondary battery according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 to 6D illustrate an electrode notching apparatus of a secondary battery according to a preferred embodiment of the present invention. First, referring to FIGS. 1 and 2, an electrode notching apparatus of a secondary battery according to an exemplary embodiment of the present invention includes an unwinder unit 10 in which an electrode film F of a raw state is wound in a roll shape, and the unwinder unit. The film feeder 30 and the unwinder 10, which repeatedly carry out the action of horizontally conveying the electrode film F released from the unwinder continuously by a predetermined distance. ) And a notching processing portion 20 disposed between the film feeder portion 30 and shearing the electrode film F transferred by the film feeder portion 30 to a specified electrode pattern, and the film feeder portion 30. Vision inspection unit 40 and the electrode disposed on the other side of the electrode film (F) of the shearing process and the inspection, the electrode disposed on one side of the vision inspection unit 40 and inspected through the vision inspection unit 40 It comprises the rewinder part 50 (rewinder) which winds up the film F in roll form. Here, the unwinder unit 10, the notching processing unit 20, the film feeder unit 30, the vision inspection unit 40, and the rewinder unit 50 are arranged in-line.

The unwinder part 10 is provided with an air shaft 11 to which the roll 12 wound around the electrode film F in a raw state (meaning a state before notching processing) is installed, and the air shaft 11 is installed. Is rotated by a servo motor not shown in the figure to function to release the electrode film (F) wound on the roll (12).

The unwinder unit 10 includes a plurality of rollers 13 for applying a predetermined tension to the electrode film F released from the unwinder unit 10, and an electrode film F transferred along the rollers 13. Sensor 14 for line inspection to detect inconsistency of coating lines formed on both sides of the < RTI ID = 0.0 >), < / RTI > And an EPC adjusting device 16. The plurality of rollers 13, the line inspection sensor 14, the EPC sensor 15, and the EPC adjusting device 16 may be configured by using known ones configured in the existing electrode notching apparatus.

In addition, on one side of the notching processing part 20, an oil coating roller 18 for applying processing oil to the electrode film F supplied to the notching processing part 20, and the film feeder part 30. As a result, immediately after the electrode film F is transferred to a predetermined pitch, the tension holding roller 17 is horizontally moved in the direction opposite to the conveying direction of the electrode film F to apply tension to the electrode film F.

The oil coating roller 18 is made of a flexible porous foam material impregnated with oil supplied from the outside, and is sheared in contact with the uncoated portion of the electrode film F supplied to the notching processing portion 20. Supply oil for processing.

The tension holding roller 17 is connected to a pneumatic cylinder (not shown), and the electrode film (F) to be supplied to the notching processing part 20 while reciprocatingly rotating at a predetermined distance in a substantially horizontal direction about the rotating shaft 171. It keeps the tension of) constant.

The notching processing portion 20 is a press machine for shearing the uncoated portion of the electrode film F to form electrode tabs Ft at regular intervals, as shown in FIGS. 3 and 4. ) And a top and bottom of the main body 21 having a base 211 is disposed under a path through which the die passes and provided with a die 22 for supporting the lower surface of the electrode film F during shearing. A punch holder 23 configured to be movable to a hole and a punch 24 fixed to the punch holder 23 for shearing the electrode film F, and a lower portion of the main body 21, the punch holder 23 being provided. ) Is configured to include a drive device for lifting and lowering by a predetermined distance up and down.

The driving device may be coupled to a plurality of lifting shafts 251 (four in this embodiment) that vertically penetrate each corner portion of the base 211 and the lower ends of the four lifting shafts 251. Drive force transmission block 252, the elevator block 253 coupled to the drive force transmission block 252 via the drive shaft 254 at the lower side of the drive force transmission block 252, and the upper end of the elevator block ( A connecting block 255 rotatably connected to the horizontal axis 253a and a circular hole 255a formed at the bottom thereof, and coupled to the inside of the hole 255a of the connecting block 255. And an eccentric shaft 256 that is coupled to the bearing 255b to generate an eccentric rotation of the connecting block 255, and a driving motor 257 that rotates the eccentric shaft 256. Can be.

In the driving device of the notching processing unit 20 configured as described above, when the eccentric shaft 256 is rotated inside the hole 255a of the connecting block 255 by the driving motor 257, the connecting block 255 Rotating with respect to the elevator block 253 about the horizontal axis (253a) and at the same time reciprocating up and down, accordingly, the elevator block 253 connected to the top of the connecting block 255 is vertical The drive shaft 254, the driving force transmission block 252, the lifting shaft 251, and the punch holder 23 to reciprocate in the direction to reciprocate up and down.

2, 5, and 6A to 6D, the film feeder unit 30 is disposed inline between the notching processing unit 20 and the vision inspection unit 40 to hold the electrode film F. Continuously carry out the action of horizontally feeding a certain distance. In this embodiment, the film feeder unit 30 is arranged inline on one side of the notching processing unit 20 and is configured to horizontally move independently of each other along the transport path of the electrode film F. 31 and the second film feeding unit 32. The first film feeding unit 31 and the second film feeding unit 32 are operated to grip and transfer the electrode film F while simultaneously horizontally reciprocating in the opposite direction to each other and to be in contact with the electrode film F. The operation of moving in the opposite direction to the conveying direction of the electrode film F is alternately performed. That is, when any one of the film feeding unit of the first film feeding unit 31 and the second film feeding unit 32 grips the electrode film F and transfers it toward the vision inspection unit 40, the other One film feeding unit is prepared to start the next film transfer operation by horizontally moving in a direction opposite to the transfer direction of the electrode film F (notching processing direction) in a non-contact state with the electrode film (F).

The first film feeding unit 31 is disposed directly on one side of the notching processing part 20 to move horizontally along the transfer path of the electrode film F, and a first movable block 311, and the first A first clamping block 312 installed on the upper side of the movable block 311 so as to be movable upward and downward to press and hold the electrode film F against the upper surface of the first movable block 311; A first elevating unit (not shown) installed in the first movable block 311 to reciprocally move the first clamping block 312 in a vertical direction and horizontally reciprocating the first movable block 311. It comprises a first linear motion unit (not shown).

In addition, the second film feeding unit 32 is disposed inline on one side of the first film feeding unit 31, and the second movable block 321 horizontally reciprocates along the transfer path of the electrode film F. And a second clamping block installed on the upper side of the second movable block 321 to move upward and downward to press and hold the electrode film F against the upper surface of the second movable block 321. 322, a second elevating unit (not shown) installed in the second movable block 321 to reciprocate the second clamping block 322 by a predetermined distance in the vertical direction, and the second movable block 321. It comprises a second linear motion unit (not shown) to reciprocate horizontally to move in the opposite direction to the first movable block (311).

The first and second lifting units (not shown) may be configured using a well-known lifting device such as a pneumatic cylinder, a motor and a cam mechanism, a motor and a crank mechanism.

In addition, the first and second linear motion units (not shown) may also use various known linear motion systems such as a known linear motor system, a linear motion system using a ball screw and a motor, and a linear motion system using a pulley-belt-motor. It can be configured.

The vision inspection unit 40 photographs the sheared portion of the electrode film F to inspect the gap between the electrode tabs Ft, the shape of the electrode tabs Ft, and the like. The vision inspection unit 40 is composed of a vision camera 41 for photographing the electrode film (F), and an illumination unit 42 for providing illumination for photographing.

Before the electrode film F is supplied to the vision inspection unit 40 between the front end of the vision inspection unit 40, that is, the film feeder 30 and the vision inspection unit 40, foreign substances of the electrode film F are removed. Air blower and foreign matter suction unit (not shown) may be configured to.

Immediately on one side of the vision inspection unit 40, the foreign matter suction unit 61 and 62 that sucks foreign matter from the upper and lower surfaces of the electrode film F before the sheared electrode film F is wound on the rewinder unit 50. Is composed.

The rewinder unit 50 has a configuration similar to that of the unwinder unit 10. That is, the rewinder unit 50 rotates the roll 52 on which the processed electrode film F is wound, the air shaft 51 to which the roll 52 is fitted, and the air shaft 51 to rotate the electrode. It is comprised including the servomotor (not shown) which winds the film F in the roll 52. As shown in FIG.

The electrode notching apparatus of the secondary battery of the present invention configured as described above operates as follows.

The roll 12 is wound around the air shaft 11 of the unwinder unit 10, and the one end of the electrode film F passes through a predetermined transfer path. When the air shaft 11 of the unwinder unit 10 and the air shaft 51 of the rewinder unit 50 are rotated in a state of being fixed to the roll 52 of the 50, the electrode film F of the unwinder unit 10 is rotated. ) Is released.

The electrode film F released from the roll 12 of the unwinder unit 10 passes through the plurality of rollers 13. At this time, the inconsistency of the coating line of the holding part of the electrode film F is inspected by the sensor 14 for line inspection, and then the meandering of the electrode film F is performed by the EPC sensor 15. When detected, the EPC adjusting device 16 adjusts the advancing direction of the electrode film F so that the electrode film F can be supplied to the correct position of the notching processing part 20.

The electrode film F, which has passed through the EPC adjusting device 16, is passed through the oil coating roller 18, and the processing oil is applied to the uncoated portion of the electrode film F.

Subsequently, the electrode film F passes through the notching processing part 20. At this time, the punch 24 of the notching processing portion 20 shears the uncoated portion of the electrode film F while repeatedly reciprocating up and down by a driving device configured under the base 211 of the main body 21. The electrode tab Ft is formed.

 The electrode film F processed by the notching processing part 20 is transferred toward the vision inspection part 40 while being pulled at a predetermined pitch by the film feeder part 30. At this time, the film feeder unit 30 is the first film feeding unit 31 and the second film feeding unit 32 is an operation for holding and transporting the electrode film (F) while simultaneously horizontally reciprocating in the opposite direction and The operation of moving in the direction opposite to the conveying direction of the electrode film (F) in a non-contact state with the electrode film (F) is alternately performed. That is, as shown in FIGS. 6A and 6B, the first clamping block 312 of the first film feeding unit 31 is lowered, so that the electrode film F is disposed on the upper surface of the first movable block 311. The first movable block 311 moves toward the vision inspection unit 40 at the rear side (arrow direction) in a state of being pressed and gripped. At the same time, in the second film feeding unit 32, the second movable block 321 moves forward (arrow direction) while the second clamping block 322 is moved upward and spaced apart from the electrode film F.

Subsequently, as shown in FIG. 6C, the first clamping block 312 of the first film feeding unit 31 moves upward to release the grip of the electrode film F, and the second film feeding unit 32 is released. The second clamping block 322 is lowered to press the electrode film (F) against the upper surface of the second movable block 321 to hold the electrode film (F). In this state, as shown in FIG. 6D, the first movable block 311 of the first film feeding unit 31 moves forward to prepare for the next transfer operation, and at the same time, a second of the second film feeding unit 32. The movable block 321 moves backward to transfer the electrode film F to a predetermined pitch.

As described above, the first film feeding unit 31 and the second film feeding unit 32 move the electrode film F to the rear at a constant pitch while simultaneously moving in opposite directions, and the transfer standby position for subsequent transfer. The electrode film (F) is continuously transferred to a constant pitch while performing alternately moving to.

In the process of carrying out the film transfer operation by the first film feeding unit 31 and the second film feeding unit 32 as described above, by the first film feeding unit 31 or the second film feeding unit 32 Immediately after the film conveying operation, the tension holding roller 17 is horizontally moved a predetermined distance horizontally forward to maintain the tension of the electrode film F to keep the electrode film F flat in the notching processing portion 20. Allow shearing to take place in the unfolded state.

On the other hand, the electrode film (F) passing through the film feeder unit 30 is inspected by the vision camera 41 while passing through the vision inspection unit 40 is inspected for abnormality of the processed electrode tab (Ft), It is wound up by the roll 52 of the rewinder part 50.

In the electrode notching apparatus of the secondary battery according to the present invention as described above, the film feeder unit 30, which performs the operation of transferring the electrode film F by a predetermined pitch, performs two film feedings alternately with each other. Since the unit 31 and 32 are configured, the transfer operation of the electrode film F may be continuously performed without interruption, and thus an operation speed may be improved.

In addition, since the film feeder 30 transfers the electrode film F by a predetermined pitch, the electrode film F may be transferred to the correct processing position of the notching processing part 20. Therefore, there also exists an advantage that the precision of a notching process can be improved.

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the scope of the present invention.

10: unwinder unit 11: air shaft
12 roll 17 tension roller
18: oil coating roller 20: notching processing part
21: body 22: die
23: punch holder 24: punch
30: film feeder unit 31, 32: first and second film feeding unit
40: vision inspection unit 41: vision camera
42: lighting unit 50: rewinder unit
51: air shaft 52: roll
F: Electrode Film Ft: Electrode Tab

Claims (5)

An unwinder part 10 in which the raw electrode film F is wound in a roll shape;
A film feeder unit (30) which continuously and repeatedly performs an operation of holding the electrode film (F) released from the unwinder unit (10) and horizontally transferring the predetermined distance by a predetermined distance;
A notching processing unit 20 disposed between the unwinder unit 10 and the film feeder unit 30 to shear the electrode film F transferred by the film feeder unit 30 to a predetermined electrode pattern; ;
A vision inspection unit 40 disposed on the other side of the film feeder unit 30 and photographing and inspecting an electrode unit of the electrode film F sheared;
Electrode notching device of the secondary battery, characterized in that it comprises a rewinder unit 50 is disposed on one side of the vision inspection unit 40 wound around the electrode film (F) inspected through the vision inspection unit 40 in the form of a roll . According to claim 1, The film feeder unit 30 is arranged inline on one side of the notching processing unit 20 is configured to horizontally reciprocate independently of each other along the transport path of the electrode film (F), The first film feeding unit 31 alternately simultaneously performs the operation of gripping and transferring the electrode film F and the operation of moving in the opposite direction to the conveying direction of the electrode film F while being in contact with the electrode film F. ) And a second film feeding unit 32, the electrode notching device of a secondary battery, characterized in that configured. The method of claim 2, wherein the first film feeding unit 31 is disposed on one side of the notching processing portion 20, the first movable block horizontally reciprocating along the transport path of the electrode film (F) 311 and a first clamping block installed on the upper side of the first movable block 311 to move upward and downward to press and hold the electrode film F against the upper surface of the first movable block 311. 312 and the first elevating unit installed in the first movable block 311 to reciprocate the first clamping block 312 by a predetermined distance in the vertical direction, and the first movable block 311 horizontally. A first linear motion unit for reciprocating movement;
The second film feeding unit 32 may include a second movable block 321 disposed inline on one side of the first film feeding unit 31 and horizontally reciprocating along the transfer path of the electrode film F. The second clamping block 322 is installed on the upper side of the second movable block 321 so as to be movable upward and downward to press and hold the electrode film F against the upper surface of the second movable block 321. And a second elevating unit installed in the second movable block 321 to reciprocally move the second clamping block 322 in a vertical direction, and horizontally reciprocating the second movable block 321. Electrode notching device of a secondary battery, characterized in that it comprises a second linear motion unit to move in the opposite direction to the first movable block (311). According to any one of claims 1 to 3, Between the unwinder 10 and the notching processing portion 20 is provided so as to be able to reciprocate in the horizontal direction, the electrode by the film feeder 30 It is characterized in that it further comprises a tension holding roller 17 for horizontally moving in the direction opposite to the conveying direction of the electrode film F immediately after the film F is transferred to a predetermined pitch to apply tension to the electrode film F. Electrode notching device of secondary battery. According to any one of claims 1 to 3, Between the unwinder portion 10 and the notching processing portion 20 is connected to the notching processing portion of the electrode film (F) notching processing portion 20 Electrode notching device for a secondary battery, characterized in that it further comprises an oil coating roller 18 for applying the processing oil to the electrode film (F) supplied to the.

Images