KR102475580B1 - Notching mold for manufacturing electrode of secondary battery - Google Patents

Abstract

The present invention relates to a notching die for machining an electrode of a secondary battery, which can easily secure a clearance between a punch and a die regardless of machining errors and assembly errors, and prevent the punch from being bent or broken due to lateral force acting on the punch. The notching die for machining an electrode of a secondary battery comprises: a die member having a die; a punch member having a punch and ascending and descending toward the die member; and a clearance adjusting member for adjusting the clearance between the die and the punch. The clearance adjusting member includes: a cam follower which is in contact with one side surface of the punch, opposing to the other side surface of the punch, to which lateral force acts, without interfering with the ascending and descending operation of the punch member; and a jig which supports the cam follower and is installed on a die plate of the die member facing the other side surface of the punch, wherein a lower portion of the other side surface of the punch can prevent collision with the cam follower during the ascending and descending operation.

Description

Notching mold for electrode processing of secondary battery {NOTCHING MOLD FOR MANUFACTURING ELECTRODE OF SECONDARY BATTERY}

The present invention relates to a notching mold for processing an electrode of a secondary battery, and more particularly, to a notching mold for processing an electrode of a secondary battery capable of securing processing precision.

In general, secondary batteries are applied to various technical fields throughout the industry due to repetitive charging and discharging.

For example, secondary batteries are not only widely used as an energy source for advanced electronic devices such as wireless mobile devices, but also electric vehicles that are being proposed as a solution to air pollution from existing gasoline and diesel internal combustion engines using fossil fuels. It is also used as an energy source.

Such a secondary battery is manufactured in a form in which a positive electrode plate, a separator, and a negative electrode plate are sequentially stacked and immersed in an electrolyte solution, and electrode tabs for electrical connection are formed on the positive electrode plate and the negative electrode plate.

The electrode tab described above is mainly formed by a notching mold prepared in a notching process. As anyone knows, the notching mold is supplied to the upper side of the die by operating a punch upward and downward. The uncoated portion of the electrode film to be formed is punched out to form an electrode tab.

However, in the conventional notching mold, since the punch and the die are individually processed and assembled, it is difficult to secure a clearance between the punch and the die due to processing and assembly errors.

In addition, in the conventional notching mold, when the electrode film is punched, a rotational moment acts on the punch, the die, and the electrode film due to the clearance, and a lateral force is applied to the side of the punch and the side of the die at right angles by the rotational moment. ) works, and in particular, there is a problem that the punch is bent or broken due to the lateral force acting on the punch.

In addition, there is another problem in that the reliability of the notching mold is lowered because the processing quality is lowered due to the above problems.

Korean Registered Patent Publication No. 10-0908573. Korean Registered Patent Publication No. 10-2189942. Korean Patent Publication No. 10-2021-0070134. Korean Registered Patent Publication No. 10-2252980.

An object of the present invention is to provide a notching mold for processing an electrode of a secondary battery that can easily secure a clearance between a punch and a die regardless of processing errors and assembly errors.

An object of the present invention is to provide a notching mold for processing an electrode of a secondary battery, which can prevent a punch from being bent or broken by a lateral force acting on the punch.

The present invention for achieving the above object is a die member having a die; a punch member having a punch and moving up and down toward the die member; And a clearance adjusting member that enables to adjust the clearance between the die and the punch; including, but, the clearance adjusting member is on the other side of the punch opposite to one side of the punch to which the lateral force acts so as not to interfere with the elevating operation of the punch member. cam follower in contact; and a jig supporting the cam follower and installed on the die plate of the die member facing the other side of the punch, wherein the lower side of the other side of the punch has a tapered inclined surface to prevent collision with the cam follower during a lifting operation. can be formed as

Specifically, the inclined surface may extend from the other side of the punch to the central side of the lower surface of the punch with an inclination angle of 0.1 to 10 degrees.

Specifically, the intersection point where the other side surface of the punch and the inclined surface connect may be in line contact with the outer ring of the Cam Follower at the time when the punch shears the electrode film.

Specifically, the outer ring of the Cam Follower rotates along the ascending and descending direction of the punch, but the outer ring is in line contact with the other side of the descending punch during clearance adjustment and shearing of the electrode film, and may be spaced apart from the other side of the punch when the punch is raised. .

Specifically, an accommodation groove for rotatably accommodating the lower side of the outer ring may be recessed in the die plate facing the lower side of the outer ring.

Specifically, the jig includes a clamp provided as a horizontal flat plate disposed on the upper surface of the die plate facing the other side surface of the punch; and a plurality of clamp fixing bolts that separate the clamps from the die plate so that the clamps are moved when the clearance is adjusted, and fix the clamps to the die plate when the clearance is adjusted. A cam follower may be installed via a stud so that the outer race rotates along the lifting direction of the punch.

Specifically, first through-holes through which clamp fixing bolts pass vertically are formed in the clamp, first fastening holes into which threads of the clamp fixing bolts are fastened are formed on the upper side of the die plate, and the first through-holes are formed on the other side of the clamp. It may be formed in the form of a long hole extending to one side from.

Specifically, the jig further includes a positioning bolt that moves the clamp and cam follower to the other side of the punch or moves the clamp and cam follower away from the other side of the punch when adjusting the clearance. The bolt is integrally formed on the other side of the clamp and passes through a second through hole formed horizontally in the skirt extending vertically toward the end side of the die plate adjacent to the other side of the punch, and formed on the end side of the die plate facing the skirt. It can be fastened to the fastening hole.

Since the notching mold for processing an electrode of a secondary battery according to the present invention includes a clearance adjusting member, it is possible to easily adjust and secure the clearance between the punch and the die regardless of processing and assembly errors, and at the same time shear There is an advantage in preventing the punch from being bent or broken due to the lateral force acting on the punch during processing.

1 is a perspective view showing a notching mold for processing an electrode of a secondary battery according to the present invention;
FIG. 2 is a view looking up at the notching mold for processing the electrode of a secondary battery according to the present invention from “A” shown in FIG. 1, schematically showing a state in which a punch member is raised,
3 is a view showing a state in which the punch member of FIG. 2 is lowered toward the die member, and is a view schematically showing the time point at which the punch shears the shear film, and
4 is a view showing a state in which the punch member of FIG. 2 is lowered toward the die member, and is a view schematically showing a state in which the punch shears the shear film and is inserted into the pocket.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Like elements in the drawings are indicated by like symbols wherever possible.

In addition, detailed descriptions of well-known functions and configurations that may unnecessarily obscure the subject matter of the present invention will be omitted.

1 to 4 are views showing a notching mold for processing an electrode of a secondary battery according to the present invention, and the notching mold for processing an electrode of a secondary battery according to the present invention moves up and down toward the die member 10 and the die member 10 It includes a punch member (30).

Here, the die member 10 and the punch member 30 have the same configuration as the conventional notching mold, and an example of the die member 10 and the punch member 30 will be described below.

First, the die member 10 includes a die 20, a die plate 16 on which the die 20 is installed, and a die holder 12 on which the die plate 16 is installed. .

As shown, the die holder 12 is provided in a flat plate shape having a predetermined thickness, and the die holder 12 has a scrap outlet 14 through which scrap S generated during shear processing of the electrode film F is discharged. It is formed to penetrate vertically.

Like the die holder 12, the die plate 16 is provided in a flat plate shape having a predetermined thickness, and is fixed to the upper surface of the die holder 12 by means of bolts or the like.

At this time, the die plate 16 facing the scrap outlet 14 is formed with a die installation hole 18 in which the die 20 is installed. In addition, between the die 20 installed in the die installation hole 18 and the die installation hole 18, a pocket 22 into which the punch 36 of the punch member 30 enters and exits during shear processing of the electrode film F is formed. .

On the other hand, the die 20 installed in the die installation hole 18 is formed with a die cutting 24 provided in a shape corresponding to the shape of the electrode film F to be sheared, such a die 20 is a bolt, etc. It may be installed in the die installation hole 18 through a medium or press-fitted into the die installation hole 18.

Here, anyone knows that the scrap outlet 14, the die installation hole 18, the die 20, and the pocket 22 may be formed and installed on one side or both sides of the die holder 12 and the die plate 16. You will be able to.

The punch member 30 includes a punch 36, a punch plate 34 on which the punch 36 is installed, and a punch holder 32 on which the punch plate 34 is installed.

Like the die holder 12, the punch holder 32 is provided in a flat plate shape having a predetermined thickness, and is spaced apart from the upper side of the die holder 12 so that the lower surface faces the upper surface of the die holder 12. .

The punch holder 32 installed in this way is installed in the guide post P installed in the die holder 12 and the guide bush B installed in the punch holder 32 and movably fitted into the guide post P. It is installed to be able to move up and down to the member 10 side.

Like the punch holder 32, the punch plate 34 is provided in a flat plate shape having a predetermined thickness, and is fixed to the lower surface of the punch holder 32 via bolts or the like.

At this time, a punch 36 is installed on the lower surface of the punch plate 34 facing the die 20, and the punch 36 is a cut punch provided in a shape corresponding to the shape of the electrode film F to be sheared. 37 is formed, and the upper surface of the punch 36 is fixed to the lower surface of the punch plate 34 via the punch fixing bolts 35.

And the punch 36 is formed to have a cross-sectional shape that matches the shape of the pocket 22 so that it can enter and exit the pocket 22.

That is, the punch 36 shears the electrode film F placed on the die 20 while descending during shearing of the electrode film F, and simultaneously enters the pocket 22 and then moves out of the pocket 22. At this time, the electrode film F is sheared into a desired shape by the action of the die 20 and the punch 36.

And the punch member 30 may further include a stripper 38 installed below the punch plate 34 so as not to interfere with the punch 36 .

Here, it will be appreciated that the punch 36 may be installed on one or both sides of the punch plate 34 .

Meanwhile, the notching mold for processing an electrode of a secondary battery according to the present invention further includes a clearance adjusting member 40 unlike conventional notching molds.

The clearance adjusting member 40 enables to continuously adjust the gap between the individually processed and assembled die 20 and the punch 36, that is, the clearance, and the lateral force during shear processing The bending of the punch 36 is prevented.

The clearance adjusting member 40 includes a normal cam follower 42 and a jig 50 supporting the cam follower 42 .

The cam follower 42 is disposed on the other side of the punch 36 spaced apart from the die 20 so that the outer ring 44 rotates along the lifting direction of the punch 36, and the outer ring 44 adjusts the clearance and shears. Selective line contact is made on the other side of the punch 36 during processing.

That is, the cam follower 42 is disposed on the side of the other side of the punch 36 opposite to one side of the punch 36 on which the lateral force acts during shearing, and the punch 36 descends during clearance adjustment and shearing. It is in line contact with the other side of, and is spaced apart from the other side of the punch 36 when the punch 36 rises.

The cam follower 42 disposed on the other side of the punch 36 is installed on the jig 50 via the stud 46 .

Here, since the configuration of the cam follower 42 including the outer ring 44 and the stud 46 and the connection relationship between the components are well-known techniques, a detailed description thereof will be omitted.

On the other hand, the lower side of the other side of the punch 36 in line contact with the outer ring 44 of the Cam Follower 42 is tapered to the inclined surface 48 to prevent collision with the Cam Follower 42 during shearing. is formed

As shown, the inclined surface 48 extends from the other side of the punch 36 toward the center of the lower surface of the punch 36 with an inclination angle θ of 0.1 to 10 degrees.

At this time, if the inclination angle (θ) of the inclined surface 48 is less than 0.1 degree, the lower surface of the punch 36 descending during shearing and the corner portion connecting the other side surface of the punch 36 may collide with the cam follower 42. In addition, when the inclination angle θ of the inclined surface 48 exceeds 10 degrees, the pressing force acting on the lower surface of the punch 36 during shearing is reduced.

In addition, the intersection point C where the other side surface of the punch 36 and the inclined surface 48 connect is in line contact with the outer ring 44 of the cam follower 42 at the time when the punch 36 shears the electrode film F. is set

Preferably, in the die plate 16 facing the lower side of the outer ring 44 of the cam follower 42, an accommodation groove 68 rotatably accommodating the lower side of the outer ring 44 is recessed, The receiving groove 68 enables the outer ring 44 to be prevented.

The jig 50 includes a clamp 52, a plurality of clamp fixing bolts 54 and a positioning bolt 60.

The clamp 52 supports the cam follower 42, and the clamp 52 is provided as a horizontal flat plate having a predetermined thickness, and the upper surface of the die plate 16 facing the other side surface of the punch 36. placed on top

At this time, the cam follower 42 is installed via the stud 46 on one side of the clamp 52 adjacent to the other side of the punch 36 .

Here, since the connection relationship between one side of the clamp 52 and the stud 46 of the cam follower 42 is a well-known technique, a detailed description thereof will be omitted.

However, if the outer ring 44 of the cam follower 42 can be in line contact with the other side of the punch 36 during clearance adjustment and shearing, one side of the clamp 52 and the stud 46 of the cam follower 42 It doesn't matter what kind of connection you have.

The clamp fixing bolts 54 separate the clamp 52 from the die plate 16 so that the clamp 52 on which the cam follower 42 is installed moves when the clearance is adjusted, and when the clearance adjustment is completed, the clamp 52 is removed from the die plate ( 16) is fixed.

The clamp fixing bolts 54 pass through the clamp 54 vertically and are fastened to the upper side of the die plate 16 .

To this end, first through-holes 56 through which the clamp fixing bolts 54 vertically penetrate are formed in the clamp 54, and the screw portions of the clamp fixing bolts 54 are fastened to the upper side of the die plate 16. 1 fastening holes 58 are formed.

At this time, the first through holes 56 are formed in the form of long holes extending from the other side of the clamp 54 to one side, whereby the clamp 52 and the cam for adjusting the clearance even without removing the clamp fixing bolts 54 The floor 42 can be moved.

That is, since the first through-holes 56 are provided in the form of long holes, the clamp 54 and the cam follower 42 are moved while the clamp fixing bolt 54 is slightly loosened so that the clamp 52 moves when adjusting the clearance. When the clearance is adjusted, the clamp 54 is fixed to the die plate 16 by completely tightening the threads of the clamp fixing bolts 54 into the first fastening holes 58.

Here, on the inner circumferential surface of the first fastening hole 58, a female screw engaged with a male screw formed in the screw portion of the clamp fixing bolt 54 is formed.

On the other hand, the positioning bolt 60 enables the clamp 52 and the cam follower 42 to be moved finely toward the other side of the punch 36 or away from the other side of the punch 36 when adjusting the clearance. .

The positioning bolt 60 is integrally formed on the other side of the clamp 52 and horizontally penetrates the skirt 62 extending vertically to the end side of the die plate 16 adjacent to the other side of the punch 36, the clamp It is fastened to the end side of the die plate 16 facing the skirt 62 so as not to interfere with the fixing bolts 54 .

To this end, a second through hole 64 through which the positioning bolt 60 passes horizontally is formed in the skirt 62, and a threaded portion of the positioning bolt 60 is fastened to the end side of the die plate 16. 2 fastening holes 66 are formed.

That is, when adjusting the clearance, when the position adjusting bolt 60 is tightened while the clamp fixing bolt 54 is slightly loosened, the clamp 54 and the cam follower 42 move to the other side of the punch 36 while the punch 36 Press the other side of the to adjust the clearance.

Conversely, when adjusting the clearance, if the positioning bolt 60 is loosened while the clamp fixing bolt 54 is slightly loosened, the clamp 54 and the cam follower 42 can be moved away from the other side of the punch 36, , Under this condition, the clearance is adjusted while tightening the positioning bolt 60 again.

Here, on the inner circumferential surface of the second fastening hole 66, a female screw engaged with a male screw formed in the threaded portion of the position adjusting bolt 60 is formed.

In addition, the clamp fixing bolts 54 and the positioning bolt 60 prevent the cam follower 42 and the clamp 54 from being pushed by a lateral force acting on one side of the punch 36 during shearing, thereby It is possible to prevent bending of the punch 36 due to lateral force.

Hereinafter, an example in which the clearance is adjusted using the clearance adjusting member 40 will be briefly described.

In order to adjust the clearance using the clearance adjusting member 40, first, in a state in which the punch 36 is lowered to the bottom dead center, the punch fixing bolt 35 is slightly loosened so that the punch 36 swings, and then the cam follower 42 ) and loosen the clamp fixing bolt 54 a little so that the clamp 52 is moved.

As described above, when the punch 36 is rocked and the cam follower 42 and the clamp 52 are movable, when the positioning bolt 60 is tightened, the clamp 54 and the cam follower 42 move the punch 36 At this time, the outer ring 44 of the cam follower 42 moved by the positioning bolt 60 presses the punch 36 while making line contact with the other side surface of the punch 36, so that the clearance is to be adjusted

When the clearance adjustment is completed, the punch fixing bolt 35 and the clamp fixing bolt 54 are completely tightened to secure the punch 36 and the clamp 54 to the punch plate 34 and the die plate 16, respectively. complete the adjustment.

Since the notching mold for processing an electrode of a secondary battery according to the present invention formed as described above includes the clearance adjusting member 40, it is easy to maintain a clearance between the punch 36 and the die 20 regardless of processing and assembly errors. At the same time, it is possible to prevent the punch 36 from being bent or broken due to the lateral force acting on the punch 36 during shearing.

In the foregoing, although specific embodiments of the present invention have been described and shown, the present invention is not limited to the described embodiments, and it is common knowledge in the art that various modifications and variations can be made without departing from the spirit and scope of the present invention. It is self-evident to those who have

Therefore, such modifications or variations should not be individually understood from the technical spirit or viewpoint of the present invention, and modified embodiments should fall within the scope of the claims of the present invention.

Claims (8)

a die member having a die;
a punch member having a punch and moving up and down toward the die member; and
A clearance adjusting member for adjusting the clearance between the die and the punch; including,
The clearance adjusting member,
a cam follower contacting the other side of the punch opposite to the one side of the punch on which the lateral force acts so as not to interfere with the lifting operation of the punch member; and
A jig supporting the cam follower and installed on the die plate of the die member facing the other side of the punch;
The lower side of the other side of the punch is formed as a tapered inclined surface to prevent a collision with the cam follower during a lifting operation,
The jig,
a clamp provided as a horizontal flat plate disposed on an upper surface of the die plate facing the other side surface of the punch;
a plurality of clamp fixing bolts separating the clamps from the die plate so that the clamps are moved when the clearance is adjusted, and fixing the clamps to the die plate when the clearance adjustment is completed; and
A positioning bolt for moving the clamp and the cam follower to the other side of the punch or moving the clamp and the cam follower away from the other side of the punch when adjusting the clearance; including,
The cam follower is installed on one side of the clamp adjacent to the other side of the punch via a stud so that the outer ring of the cam follower rotates along the lifting direction of the punch,
The positioning bolt,
It is integrally formed on the other side of the clamp and is formed on the end side of the die plate facing the skirt through a second through hole formed horizontally in the skirt extending vertically toward the end side of the die plate adjacent to the other side surface of the punch. A notching mold for processing an electrode of a secondary battery fastened to a second fastening hole.
The method of claim 1,
The inclined surface is a notching mold for processing electrodes of a secondary battery extending from the other side of the punch to the central side of the lower surface of the punch with an inclination angle of 0.1 to 10 degrees.
The method of claim 2,
The intersection point where the other side surface of the punch and the inclined surface are connected is in line contact with the outer ring of the cam follower at the time when the punch shears the electrode film.
The method of claim 1,
The outer ring of the cam follower rotates along the lifting direction of the punch,
The outer ring is in line contact with the other side of the punch that descends during clearance adjustment and electrode film shearing, and is spaced apart from the other side of the punch when the punch rises.
The method of claim 4,
A notching mold for processing an electrode of a secondary battery in which an accommodation groove rotatably accommodating the lower side of the outer ring is recessed in the die plate facing the lower side of the outer ring.
delete The method of claim 1,
First through-holes through which the clamp fixing bolts pass vertically are formed in the clamp,
First fastening holes into which the screw parts of the clamp fixing bolts are fastened are formed on the upper side of the die plate,
The first through holes are formed in the form of long holes extending from the other side of the clamp to one side, the notching mold for processing the electrode of a secondary battery.

delete

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