KR20160138741A - Electrode Notching Processing Apparatus for Electrode of Secondary Battery - Google Patents

Abstract

The present invention relates to an apparatus for processing an electrode for a secondary battery, which enables an electrode tab to be accurately processed on a polymer electrode by sucking foreign substances and removing the same when a laser beam is irradiated and the electrode tab is sheared while continuously transferring the polymer electrode in one direction, and by securely fixing the polymer electrode to prevent shake. The provided apparatus for processing an electrode for a secondary battery comprises: a laser irradiator installed on an upper side of a movement path of a polymer electrode, and configured to irradiate the polymer electrode with a laser beam; an upper suction unit installed between the laser irradiator and the polymer electrode, having an opening unit, through which the laser beam passes, to be penetrated in a vertical direction, having a suction flow path through which air and foreign substances are sucked along an edge of the opening unit, and having an upper suction block having one end of the suction flow path connected to a suction force generation device; and a lower suction unit installed on a lower side of the movement path of the polymer electrode, and having a lower suction guide having a suction hole for sucking the foreign substances generated during a shearing process of the polymer electrode and a lower suction member installed on a lower side of the lower suction guide and having one end connected to the suction force generation unit.

Description

[0001] Electrode Notching Processing Apparatus for Electrode of Secondary Battery [0002]

The present invention relates to an apparatus for performing electrode notching processing of a secondary battery, and more particularly, to an electrode notching process for forming an electrode tab by shearing a non-coated portion of a polymer electrode of a secondary battery with a laser To an electrode processing apparatus for a secondary battery.

A notching system, which is one of the devices for producing a secondary battery, is an apparatus for forming an electrode tab by shearing a non-coated portion of a polymer electrode in the form of a film, A notch inspection unit for shearing the polymer electrode in an electrode form using a press machine or a laser notching apparatus, and a vision inspection unit for inspecting whether the processed polymer electrode is normally processed, The rewinder consists of a rewinder.

In the above notching, the untreated polymer electrode is aligned under the punch of the press machine, and then the punch is lowered to form an electrode tab at a predetermined interval by shearing the uncoated portion having no electrode active material in a predetermined shape And a method in which a laser beam is irradiated onto the non-coated portion of the electrode film on the upper side of the polymer electrode to shear the electrode tabs at regular intervals.

Among the notching methods, there is a problem that the electrode tab is not cut properly due to foreign substances accumulated on the polymer electrode or shaking of the electrode during the shearing process in the method of processing the electrode tab by irradiating the polymer electrode with the laser.

Open Patent No. 10-2014-0004011 (2014.01.10) Patent No. 10-1222615 (2013.01.09) Registration No. 10-1479724 (December 30, 2014)

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is an object of the present invention to provide a method of manufacturing a polymer electrolyte fuel cell which is capable of sucking and removing foreign substances when the electrode tab is sheared by irradiating a laser while continuously transferring the polymer electrode in one direction, And the electrode tab can be precisely machined on the polymer electrode by preventing shaking.

According to an aspect of the present invention, there is provided an electrode processing apparatus for a secondary battery, which processes a electrode tap by applying a laser to a polymer electrode continuously transferred in one direction, A laser irradiator for irradiating the electrode with a laser; And an air passage through which the laser passes is formed to penetrate up and down, and a suction flow path through which air and foreign substances are drawn is formed along the periphery of the opening portion, An upper suction unit having an upper suction block connected to the suction force generating device; A lower suction guide provided at a lower side of the movement path of the polymer electrode and having a suction hole for sucking a foreign substance generated during the shearing process of the polymer electrode, and a lower suction guide installed at a lower side of the lower suction guide, And a lower suction unit including a lower suction member that is configured to allow the user to operate the secondary suction unit.

According to one aspect of the present invention, a plurality of slots are formed in the lower suction guide at regular intervals along the width direction of the polymer electrode, and a fluid contact with an edge portion of the polymer electrode in any one of the plurality of slots And a preventive pin is detachably installed.

According to the present invention, a suction force is generated in the upper suction unit and the lower suction unit when the polymer electrode is irradiated with a laser and the cutting process is performed, so that foreign matter generated during the laser cutting process is forced through the suction holes of the upper suction block and the lower suction guide And is sucked and removed. Therefore, in the laser cutting process, foreign substances are removed from the polymer electrode without being adhered to the electrode, so that defective products can be prevented.

When the edge of the polymer electrode is held in contact with the guide pin by providing a guide pin in the slot of the lower suction guide, the polymer electrode is prevented from shaking when the electrode tab is subjected to shearing by irradiating laser to the polymer electrode, E of the electrode tab.

1 is a side view of an electrode working apparatus for a secondary battery according to an embodiment of the present invention.
Fig. 2 is a plan view of the electrode working apparatus for the secondary battery shown in Fig. 1. Fig.
3 is a plan view showing a configuration of an upper suction unit of the electrode working apparatus for a secondary battery of Fig. 1;
Fig. 4 is an enlarged cross-sectional view of a principal portion of the electrode working apparatus for the secondary battery of Fig. 1; Fig.
5 is a cross-sectional view of an upper suction block constituting an upper suction unit of the electrode working apparatus for a secondary battery of Fig. 1;
Fig. 6 is a plan view of a lower suction guide constituting a lower suction unit of the electrode working device for a secondary battery of Fig. 1;
7 is a longitudinal sectional view of the lower suction guide of Fig.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of an electrode working apparatus for a secondary battery according to the present invention will be described in detail with reference to the accompanying drawings.

1 and FIG. 7 show an electrode processing apparatus for a secondary battery according to an embodiment of the present invention. Referring first to FIGS. 1 and 2, the electrode processing apparatus for a secondary battery of the present invention includes a polymer electrode E, And two laser irradiators 20 for irradiating laser beams on both side edge portions of the polymer electrode E are provided on the conveying roller 10 An upper guide frame 50 and a lower guide frame 60 for guiding the polymer electrode E when the polymer electrode E is notched by the laser irradiator 20 are provided on the conveying roller 10, And are spaced apart from each other by a predetermined distance.

Any one of the plurality of conveying rollers 10 receives the power from the driving means such as a motor and rotates to transfer the polymer electrode E continuously in one direction.

The laser irradiator 20 performs a notching process for applying a laser to the uncoated portions on both side edges of the polymer electrode E from above the polymer electrode E to shear the electrode tab.

The upper guide frame 50 and the lower guide frame 60 are formed in a plate shape so that the center of the upper guide frame 50 and the lower guide frame 60 are opened. The polymer electrode E passes through a gap between the upper guide frame 50 and the lower guide frame 60 .

An upper suction unit 30 for sucking foreign matter generated during the notching process of the polymer electrode E and a lower suction unit 30 for sucking a foreign substance generated during the notching process of the polymer electrode E are provided between the laser irradiator 20 and the polymer electrode E, Unit 40 are respectively installed. The upper suction unit 30 and the lower suction unit 40 are disposed opposite to each other with the polymer electrode E interposed therebetween.

The upper suction unit 30 includes an upper suction block 31 mounted on an edge portion of one side of the polymer electrode E and a connecting member 35 connected to one end of the upper suction block 31. [ ). The upper suction unit 30 is slidably installed along a guide member 37 provided so as to cross the upper side of the polymer electrode E so as to be adjustable in position corresponding to the width of the polymer electrode E. do. In this embodiment, two upper suction units 30 having the same configuration are provided so as to be slidable along the guide member 37 so that foreign substances can be sucked from both edge portions of the polymer electrode E.

3 and 4, the lower surface of the upper suction block 31 constituting the upper suction unit 30 is installed to be connected to the upper surface of the upper guide frame 50. As shown in FIG. The upper suction block 31 is formed so that a circular opening 31a through which the laser irradiated by the laser irradiator 20 passes is vertically passed through the upper suction block 31. Air and foreign matter And a suction passage 32 through which the suction passage 32 is formed. The upper end of the inner side surface of the opening 31a is formed to communicate with the inside of the suction path 32. When a suction force is generated through the suction path 32, And the upper surface of the upper suction block 31 through the space between the upper surface of the upper suction block 31 and the upper surface of the upper suction block 31.

In order to allow air and foreign matter to flow more smoothly into the suction passage 32 of the upper suction block 31, the suction passage 32 communicates with the suction passage 32 on the inner side surface of the opening 31a, A plurality of auxiliary suction holes (33) through which foreign substances are sucked are formed at regular intervals along the circumferential direction.

A curved flow passage guide wall 34 is formed inside the suction passage 32 of the upper suction block 31 so that the suction passage 32 immediately around the opening 31a can have a generally circular shape .

One end of the upper suction block 31 communicates with the connecting member 35, and the connecting member 35 is connected to a suction force generating device that generates a suction force from the outside.

As shown in FIGS. 3, 5 and 6, the lower suction unit 40 is disposed under the movement path of the polymer electrode E and sucks foreign substances generated during the cutting process of the polymer electrode E. A lower suction guide 41 having a suction hole 42 formed therein and a lower suction member 45 provided below the lower suction guide 41 and having one end connected to the suction force generating device.

The lower suction guide 41 is formed in the shape of a rectangular plate having a substantially triangular suction hole 42 formed to penetrate vertically and is fixed to the lower guide frame 60. A plurality of slots 43 are formed at predetermined intervals along the width direction of the polymer electrode on one side of the suction hole 42 of the lower suction guide 41, E to prevent shaking of the polymer electrode E when laser cutting is performed. The slot 43 is formed to communicate with the rim of the suction hole 42 of the lower suction guide 41.

The electrode working apparatus for a secondary battery of the present invention having the above-described configuration operates as follows.

The rotation of the conveying roller 10 causes the polymer electrode E to be conveyed continuously or at a constant pitch in one direction. The polymer electrode E is guided while passing between the upper guide frame 50 and the lower guide frame 60 and irradiated with a laser from the upper side of the polymer electrode E to the lower side of the polymer electrode E).

At this time, the laser passes through the open portion 31a of the upper suction block 31 to cut the polymer electrode E. The portion where the cutting operation is performed is performed by the open portion 31a of the upper suction block 31 It becomes an enclosed form. The inner surface of the open portion 31a of the upper suction block 31 acts on the wall surface so that the foreign substance generated in the laser cutting process of the polymer electrode E contacts the open portion 31a of the upper suction block 31, The phenomenon of scattering to the outside is prevented.

When a laser beam is irradiated to the edge portion of the polymer electrode E as described above, a suction force is generated through the upper suction block 31 when the electrode tab is subjected to shearing, so that the air and the foreign substance are sucked through the suction path 32 of the upper suction block 31 ). Therefore, the foreign substance generated during the laser cutting is not accumulated on the polymer electrode E.

At the same time, a suction force is also generated in the lower suction unit 40 so that air and foreign matter flow into the lower suction member 45 through the suction holes 42 of the lower suction guide 41 and are removed. Therefore, in the laser cutting process, the foreign matter can be removed without being adhered to the polymer electrode E, thereby preventing defective products.

When the electrode tabs are subjected to shearing by irradiating the polymer electrode E with a laser and the foreign matter is sucked and removed from the upper suction unit 30 and the lower suction unit 40, It is possible to prevent the polymer electrode E from shaking at the time of laser cutting by providing the flow preventive pin 44 in the slot 43 of the polymer electrode E so that the edge of the polymer electrode E is held in contact with the flow preventive pin 44 .

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: Feed roller 20: Laser irradiator
30: Upper suction unit 31: Upper suction block
31a: opening portion 32:
33: auxiliary suction hole 34: flow guide wall
35: connecting member 37: guide member
40: Lower suction unit 41: Lower suction guide
42: Suction hole 43: Slot
44: anti-flow pin 45: lower suction member
50: upper guide frame 60: lower guide frame
E: polymer electrode

Claims (6)

An electrode machining apparatus for a secondary battery in which electrode tabs are subjected to shearing by irradiating a laser beam onto polymer electrodes continuously transferred in one direction,
A laser irradiator 20 disposed above the movement path of the polymer electrode to irradiate the polymer electrode with a laser;
And an opening 31a through which the laser passes is formed so as to penetrate up and down between the laser irradiator 20 and the polymer electrode E. Air and foreign matter along the circumference of the opening 31a An upper suction unit (30) having an upper suction block (31) in which one end of the suction passage (32) is connected to a suction force generating device;
A lower suction guide 41 provided below the movement path of the polymer electrode and having a suction hole 42 for sucking foreign substances generated during the shearing process of the polymer electrode, And a lower suction unit (40) including a lower suction member (45) whose one end is connected to the suction force generating device. The method according to claim 1, wherein a plurality of slots (43) are formed in the lower suction guide (41) at regular intervals along the width direction of the polymer electrode, and the edge of the polymer electrode and a flow preventive pin (44) that is in contact with an edge portion of the electrode is detachably installed. 3. The secondary battery according to claim 2, wherein the suction hole (42) of the lower suction guide (41) has a triangular shape, and the slot (43) is formed to communicate with a rim portion of the suction hole Electrode working device. The apparatus according to claim 1, wherein the upper suction unit (30) is provided slidably along a guide member (37) provided so as to cross the upper side of the polymer electrode (E) And the position of the electrode is adjusted. The air conditioner according to claim 1, wherein a plurality of auxiliary suction holes (33) communicating with the suction passage (32) and sucking air and foreign matter are formed in the inner surface of the opening (31a) of the upper suction block (31) Wherein the electrode is formed at regular intervals. The polymer electrode (E) according to claim 1, further comprising an upper guide frame (50) and a lower guide frame (60) which are vertically spaced apart from the movement path of the polymer electrode (E) Is guided while passing through a clearance between the upper guide frame (50) and the lower guide frame (60), the lower surface of the upper suction block (31) is connected to the upper surface of the upper guide frame (50) And the lower suction guide (41) is coupled to the lower guide frame (60).

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