KR102515516B1 - Device for rising preventing scrap rise of notching mold for manufacturing electrode of secondary battery - Google Patents

Abstract

Disclosed is a notching mold for processing secondary battery electrodes that prevents scrap from rising. According to the present invention, the notching mold for processing secondary battery electrodes comprises: a die member having a die, a die plate and a die holder; a punch member having a punch, a punch plate, and a punch holder, and punching an electrode film into a desired shape together with the die member when the die member side is moved up and down; and a scrap lift preventing means including a pusher unit installed on the punch member and pushing the scrap in the direction of the pressing force of the punch of the punch member, and a catch pole which is installed on the die member and operates the pusher unit in conjunction with the punch member that rises after punching out the electrode film.

Description

Notching mold for secondary battery electrode processing to prevent scrap rise {DEVICE FOR RISING PREVENTING SCRAP RISE OF NOTCHING MOLD FOR MANUFACTURING ELECTRODE OF SECONDARY BATTERY}

The present invention (Disclosure) relates to a notching mold for processing a secondary battery electrode that prevents scrap from rising.

Here, background art related to the present invention is provided, and they do not necessarily mean prior art (This section provides background information related to the present disclosure which is not necessarily prior art).

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

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 aforementioned electrode tab is mainly formed by a notching mold prepared in a notching process.

In the notching mold, an electrode tab is formed by lifting and lowering a punch toward a die to punch out an uncoated portion of an electrode film supplied to an upper side of the die, and in this process, scrap is generated.

However, in the conventional notching mold, when the electrode tab is punched out, the scrap is adsorbed to the punch or pushed by compressed air in the pocket and rises to the upper side of the die.

Korean Patent Publication No. 10-2022-043716. Korean Registered Patent Publication No. 10-1622210. Korean Registered Patent Publication No. 10-1857710. Korean Registered Patent Publication No. 10-2105292.

The present invention (Disclosure) is a notching mold for processing secondary battery electrodes that prevents scrap from rising, which separates scrap from the punch when the punch rises after punching the electrode film, and at the same time allows the scrap to remain inside the pocket to prevent it from rising to the upper side of the die. The purpose of providing

In addition, the problem to be solved by the present invention is not limited to the technical problems mentioned above, and other technical problems not mentioned are clearly understood by those of ordinary skill in the art to which the present invention belongs from the description below. It could be.

This section provides a general summary of the disclosure and is not a comprehensive disclosure of its full scope or all of its features).

In order to solve the above problems, according to one of the various aspects describing the present invention, in a notching mold for processing secondary battery electrodes that prevents the rise of scrap generated during punching of secondary battery electrode films, A notching mold for electrode processing includes a die member having a die, a die plate, and a die holder; A punch member having a punch, a punch plate, and a punch holder, and punching the electrode film into a desired shape together with the die member when the die member side is moved up and down; and a pusher part installed on the punch member to push the scrap in the direction of the pressing force of the punch of the punch member, and a catch pole installed on the die member and operating the pusher part in conjunction with the punch member that rises after punching out the electrode film to prevent rising scrap. means; may include.

In the notching mold for processing secondary battery electrodes that prevents scrap from rising according to one aspect of the present invention, the catch pole is formed in the form of a vertically extending column, and the lower side of the die plate is connected to the die installation hole in which the die is installed. It is installed on the upper surface, and on both sides adjacent to the upper end of the catch pole, concave grooves for operating the pusher unit may be formed to extend along the vertical longitudinal direction of the catch pole.

In the notching mold for processing secondary battery electrodes that prevents scrap from rising according to one aspect of the present invention, the pusher unit is installed in a chamber concavely formed from the lower surface to the upper surface of the punch holder, and the pusher unit faces the chamber with a punch plate. It is exposed through an incision formed in the incision, and the upper side including the groove of the catch pole can be inserted into the incision and the chamber when the punch member is combined with the die member.

In the notching mold for processing secondary battery electrodes that prevents scrap from rising according to one aspect of the present invention, the pusher unit includes an elevating plate movably disposed inside a chamber concavely formed from a lower surface to an upper surface of a punch holder. ; a guide plate fixedly installed inside the chamber to be spaced apart from the lower side of the elevating plate; and a base plate installed on the lower surface of the punch holder so as not to interfere with the catch pole inserted into the chamber through the cut-out hole of the punch plate and confining the elevating plate and the guide plate inside the chamber, and having a punch installed on the lower surface; Including, but vertically extending pusher pins slidably fitted into the guide plate, the base plate and the punch are installed on the elevating plate, and the front side of the elevating plate elastically spans the top side of the groove of the catch pole when the punch member is raised. A pair of catch plates that temporarily stop the lifting operation of the lifting plate to allow the pusher pins to protrude outward from the lower surface of the punch to prevent scrap from rising may be integrally formed to protrude.

In the notching mold for processing secondary battery electrodes that prevents scrap from rising according to one aspect of the present invention, the catch plates provided as a pair are spaced apart from each other in the horizontal longitudinal direction of the elevating plates, and a punch member is provided between the catch plates. During the lifting operation, a guide groove through which the catch pole is guided is formed, and the catch pin is elastically supported via the catch spring built into the catch plate so that each catch plate protrudes toward the guide groove. It can be stretched elastically on the upper side.

In the notching mold for processing secondary battery electrodes that prevents scrap from rising according to one aspect of the present invention, the extended end of the catch pin extending toward the guide groove is formed to have a semicircular curvature, and the upper end of the groove has a catch pin It can be formed into a smooth streamlined curve so that it can escape after being overlaid.

In the notching mold for processing secondary battery electrodes that prevents scrap from rising according to one aspect of the present invention, a guide plate is installed on guide bars into which an elevating plate is movably fitted, and a lower end of the elevating plate is elevated to the guide plate. Possibly fitting pressure bars are installed, and pressure springs may be fitted to the pressure bars to elastically support the lifting plate to the guide plate so as to be able to move up and down.

In the notching mold for processing a secondary battery electrode that prevents scrap from rising according to one aspect of the present invention, a punch fixing plate for supporting a stud portion of the punch is inserted into the punch, and the punch fixing plate may be fixed to the lower surface of the base plate. there is.

According to the present invention, since the pusher pins protrude from the punch when the punch rises after punching the electrode film, it is possible to easily separate the scrap from the punch and at the same time provide the effect of allowing the scrap to remain inside the pocket.

Therefore, the present invention can further provide an effect of prolonging the life of the punch and die and improving productivity by preventing defects caused by interference of scrap rising to the upper side of the conventional die.

1 is a view schematically showing a notching mold for processing a secondary battery electrode that prevents scrap from rising according to the present invention.
Figure 2 is an exploded view showing the scrap rise prevention means shown in Figure 1;
3 to 5 are diagrams schematically showing an operating state of a notching mold for processing a secondary battery electrode that prevents scrap from rising according to the present invention.

Hereinafter, an embodiment in which a notching mold for processing a secondary battery electrode that prevents scrap from rising according to the present invention is implemented will be described in detail with reference to the drawings.

However, the essential (intrinsic) technical idea of the present invention cannot be said to be limited by the embodiments described below, and based on the essential (intrinsic) technical idea of the present invention, a person skilled in the art below It is revealed that the embodiments described in include the range that can be easily proposed as a method of substitution or change.

In addition, since the terms used below are selected for convenience of description, in grasping the essential (intrinsic) technical idea of the present invention, they are not limited to the dictionary meaning and are appropriately interpreted in a meaning consistent with the technical idea of the present invention. It should be.

1 to 5 of the accompanying drawings are views schematically showing a notching mold for processing a secondary battery electrode that prevents scrap from rising according to the present invention.

Referring to FIGS. 1 to 5 , the notching mold for processing a secondary battery electrode for preventing scrap from rising according to the present invention includes a die member 10, a punch member 30, and a means for preventing scrap from rising 100.

First, the die member 10 includes a die 20 , a die plate 16 and a die holder 12 .

The die holder 12 is provided in a flat plate shape having a predetermined thickness, and the die holder 12 includes an electrode film (F; see FIGS. 3 to 5) and scrap generated when punching (S; see FIGS. 4 and 5) A scrap outlet 14 through which the scrap is discharged is formed.

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.

In addition, a die installation hole 18 in which the die 20 is installed faces the scrap outlet 14 in the die plate 16 .

The die 20 is formed with a die cutting 22 provided in a shape corresponding to the shape of the electrode film F to be punched out, and such a die 20 is installed in the die installation hole 18 through a bolt or the like. It is press-fitted into the die mounting hole 18.

At this time, between the die cut 22 of the die 20 installed in the die installation hole 18 and the die installation hole 18 facing the die cut 22, the punch member 30 when punching the electrode film (F) A pocket 24 into which the punch 36 enters and exits is formed.

The electrode film F to be punched is guided to the top of the die 20 and the die plate 16 thus formed.

Here, the scrap discharge port 14, the die installation hole 18, the die 20, and the pocket 24 are a die holder ( 12) and one side of the die plate 16, or the other side of the die holder 12 and the die plate 16, or the electrode film (F) so that the bottom line side opposite to the top line of the electrode film (F) can be punched It will be appreciated that it can be formed and installed on both sides of the die holder 12 and the die plate 16 so that the top line and bottom line sides of ) can be punched simultaneously.

The punch member 30 includes a punch 36, a punch plate 34 and a punch holder 32.

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. .

And the punch holder 32 moves up and down toward the die holder 12. To this end, a guide bush (not shown) is installed in the punch holder 32, and the guide bush is fitted to the die holder 12 so as to be able to move up and down. A guide post (not shown) is installed.

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.

The punch plate 34 installed in the punch holder 32 supports the punch 36 so that the punch 36 maintains its vertical operation when the electrode film F is punched.

The punch 36 is formed to have a cross-sectional shape conforming to the shape of the pocket 22 so as to be able to enter and exit the pocket 24, and the punch 26 corresponds to the shape of the electrode film F to be punched out. Punch cutting 38 provided in the shape of is formed.

This punch 36 is installed to face the die 20 via the scrap rising prevention means 100.

That is, the punch 36 descends along the punch holder 32 and the punch plate 34 to punch the electrode film F placed on the die 20, and at the same time enters the pocket 24 and enters the punch holder ( 32) and the punch plate 34 rise to the outside of the pocket 24. At this time, the electrode film F is punched into a desired shape by the die cutting 22 and the punch cutting 38, and the electrode film F ) Scrap S generated during punching is discharged to the outside through the scrap outlet 14.

And the punch member 30 further includes a stripper 40 installed below the punch plate 34 so as not to interfere with the punch 36, the function of the stripper 40 and the connection relationship of the stripper 38 are known Since it is a technique of , a detailed description thereof will be omitted.

Here, the punch 36 is a punch to punch one side of the punch holder 32 and the punch plate 34 or the bottom line side of the electrode film F to punch the top line side of the electrode film F It can be installed on both sides of the punch holder 32 and the punch plate 34 so that the other side of the holder 32 and the punch plate 34 or the top line and bottom line side of the electrode film F can be punched simultaneously. Everyone will know.

On the other hand, the scrap lifting prevention means 100 interlocks with the pusher unit 120 that pushes the scrap S in the direction of the pressing force of the punch 36 and the punch member 30 that rises after punching the electrode film F, thereby pushing the pusher unit 120 includes a catch pole 110 to actuate.

As shown, the catch pole 110 is formed in the form of a column extending vertically, and the lower side thereof is installed on the upper surface of the die plate 16 through a bolt or the like.

Preferably, the catch pole 110 has a die plate connected to the die installation hole 18 to prevent the punch 36 from being pushed when the electrode film F is punched without interfering with the punching of the electrode film F ( 16) is installed on the upper surface.

In addition, concave grooves 112 extending along the vertical longitudinal direction of the catch pole 110 are formed on both sides adjacent to the upper end of the catch pole 110 .

At the top side of the groove 112 formed in this way, the pusher part 120 that rises along the punch member 30 is stretched elastically, and the pusher part 120 that spans the groove 112 is the punch member 30 that continues to rise. As a result, it exits the top side of the groove 112 and rises.

At this time, when the pusher part 120 is stretched over the top side of the groove 112, the pusher part 120 protrudes the pusher pin 124 to be described below outward from the lower surface of the punch 36. As a result, the scrap S remains inside the pocket 24 while being pressed in the direction of the pressing force of the punch 36, and the scrap S remaining inside the pocket 24 is a suction device connected to the scrap outlet 14 ( (not shown) is withdrawn to the outside of the scrap outlet 14.

Preferably, the top side of the groove 112 may be formed in a smooth streamlined curve so that the pusher unit 120 can easily escape after being crossed.

The pusher unit 120 is installed on the punch holder 32 so as to be exposed through the punch plate 34 .

To this end, a cutout 42 is formed in the punch plate 34, and the cutout 42 and the subsequent chamber 44 are concave from the lower surface to the upper surface of the punch holder 32. is formed

Of course, the top side of the catch pole 110 including the groove 112 is inserted into the incision 42 and the chamber 44 when the punch member 30 is combined with the die member 10 (see FIG. 3 ).

The pusher unit 120 installed in the punch holder 32 so as to be exposed through the punch plate 34 includes a lifting plate 122 , a guide plate 134 and a base plate 146 .

As shown, the elevating plate 122 is disposed to be elevating inside the chamber 46, and the guide plate 134 is spaced apart from the lower side of the elevating plate 122 to the inside of the chamber 46 via bolts or the like. fixedly installed

Vertically extending pusher pins 124 are installed on the elevating plate 122, and the pusher pins 124 are slidably fitted into the guide plate 134, the base plate 146, and the punch 36.

To this end, first, second, and third through holes 144, 148, and 46 into which the pusher pins 124 are inserted are formed in the guide plate 134, the base plate 146, and the punch 36, respectively.

Preferably, the pusher pins 124 are formed to have a length extending to a position adjacent to the lower surface of the punch 36 .

In addition, in the guide plate 134, the elevating plate 122 is installed on the guide bars 138 fitted to be elevating so as not to interfere with the pusher pins 124, and the pusher pins 124 are installed on the elevating plate 122. And pressure bars 140 are installed so as not to interfere with the guide bar 138, the lower side of which is movably fitted into the guide plate 134.

At this time, a pressure spring 142 is inserted into the pressure bars 140 to support the elevating plate 122 to the guide plate 134 so as to be able to move up and down elastically. The pressure spring 142 may be a conventional compression coil spring. there is.

Meanwhile, on the front side of the lifting plate 122, when the punch member 30 is raised, a pair of catch plates 126 elastically spanned over the upper end of the groove 112 formed in the catch pole 110 are integrally formed to protrude. do.

As shown, the catch plates 126 provided as a pair are spaced apart in the horizontal longitudinal direction of the elevating plate 122, and between the catch plates 126, when the punch member 30 is elevating, the catch pole 110 ) Guide groove 128 is formed.

In addition, the catch pins 130 are elastically supported on the pair of catch plates 126 so as to protrude toward the guide grooves 128 through catch springs 132 embedded in the catch plates 126 .

Preferably, the catch spring 132 may be a conventional compression coil spring.

Preferably, the extension end of the catch pin 130 extending toward the guide groove 128 is formed to have a semicircular curvature.

The base plate 146 confines the elevating plate 122 and the guide plate 134 inside the chamber 44 so as not to interfere with the catch pole 110 inserted into the chamber 44 through the incision 42. It is installed on the lower surface of the punch holder 32 via a bolt or the like as possible.

At this time, the upper surface of the punch 36 is installed in close contact with the lower surface of the base plate 146 via a bolt or the like as shown.

In addition, a punch fixing plate 150 for supporting the stud portion of the punch 36 is fitted to the punch 36, and the punch fixing plate 150 is fixed to the lower surface of the base plate 146 via bolts or the like.

Hereinafter, the operating state of the above-described scrap rising prevention means 100 will be briefly described.

The pusher unit 120 of the scrap rising prevention means 100 descends along the punch member 30 when the electrode film F is punched.

At this time, the catch pole 110 is inserted and guided into the guide groove 128, and the catch pin 130 compresses the catch spring 132 by the catch pole 110 guided along the guide groove 128. After being inserted into the catch plate 126, it protrudes toward the groove 112 formed in the catch pole 110 by the restoring force of the catch spring 132 and descends along the groove 112 (see FIG. 4).

Conversely, the pusher unit 120 rises along the punch member 30 after punching the electrode film F, and the catch pin 130 rises along the groove 112 and spans the upper end of the groove 112 ( see Figure 5).

When the catch pin 130 spans the upper side of the groove 112 in this way, the lifting plate 122 and the catch plate 126 are separated from the punch member 30, the guide plate 134 and the base plate 146 that operate upward. Otherwise, the lifting operation is temporarily stopped. At this time, the pressure spring 142 is compressed by the lifting plate 122, the lifting operation of which is temporarily stopped, and the lower ends of the pusher pins 124 protrude outward from the lower surface of the punch 36. As the scrap (S) is pressed in the direction of the pressing force of the punch 36 to prevent the rise of the scrap (S).

And, when the catch pin 130 exits the top side of the groove 112 by the continuously rising punch member 30, the guide plate 134, and the base plate 146, the restoring force of the pressure spring 142 that has been compressed As a result, the elevating plate 122 and the catch plate 126 are returned, whereby the lower end of the pusher pin 124 protruding outward from the lower surface of the punch 36 is inserted into the punch 36 again.

The notching mold for processing secondary battery electrodes according to the present invention formed as described above, since the pusher pin 124 protrudes from the punch 36 when the punch 36 rises after punching the electrode film F, the punch 36 The scrap (S) can be easily separated from the scrap (S) at the same time it is possible to remain in the pocket (24).

Therefore, the notching mold for processing secondary battery electrodes that prevents scrap from rising according to the present invention can prevent defects caused by the interference of the scrap (S) rising to the upper side of the die (20) in advance, thereby preventing the punch (36) and the die (20). (20) to achieve longevity and productivity improvement.

Claims (8)

In the notching mold for processing secondary battery electrodes that prevents the rise of scrap generated during punching of secondary battery electrode films,
The notching mold for processing the secondary battery electrode,
a die member having a die, a die plate and a die holder;
a punch member having a punch, a punch plate, and a punch holder, and punching the electrode film into a desired shape together with the die member when the side of the die member is moved up and down; and
A pusher part installed on the punch member and pushing the scrap in the direction of the pressing force of the punch of the punch member, and a catch installed on the die member and operating the pusher part in conjunction with the punch member that rises after punching the electrode film Including; scrap rising prevention means having a pole,
The pusher part,
an elevating plate movably disposed inside the chamber concavely formed from the lower surface of the punch holder to the upper surface;
a guide plate fixedly installed inside the chamber so as to be spaced apart from the lower side of the elevating plate; and
The elevating plate and the guide plate are installed on a lower surface of the punch holder to be confined to the inside of the chamber so as not to interfere with the catch pole inserted into the chamber through the cut-out hole of the punch plate, and the lower surface has the Including; base plate on which the punch is installed,
Vertically extending pusher pins slidably fitted into the guide plate, the base plate, and the punch are installed on the elevating plate,
When the punch member is raised, the front side of the lifting plate elastically spans the upper end of the groove of the catch pole to temporarily stop the lifting operation of the lifting plate so that the pusher pins protrude outward from the lower surface of the punch, thereby scraping the scrap. A notching mold for processing secondary battery electrodes that prevents the rise of scrap in which a pair of catch plates that prevent the rise of the scrap are integrally formed to protrude.
The method of claim 1,
The catch pole is formed in the form of a column extending vertically, and the lower side is installed on the upper surface of the die plate connected to the die installation hole in which the die is installed,
On both sides adjacent to the upper end of the catch pole, the groove for operating the pusher part is formed to extend along the vertical longitudinal direction of the catch pole.
The method of claim 1,
The pusher unit is installed in the chamber concavely formed from the lower surface to the upper surface of the punch holder,
The pusher portion is exposed through the cutout formed in the punch plate to face the chamber,
A notching mold for processing a secondary battery electrode that prevents the upper end side including the groove of the catch pole from being inserted into the cut hole and the chamber when the punch member is combined with the die member.
delete The method of claim 1,
The catch plates provided as a pair are spaced apart from each other in the horizontal longitudinal direction of the elevating plate,
A guide groove through which the catch pole is guided is formed between the catch plates during the elevating operation of the punch member,
In the catch plate, catch pins are elastically supported via a catch spring embedded in the catch plate so as to protrude toward the guide groove, respectively.
The catch pin is a notching mold for processing secondary battery electrodes that prevents scrap from being raised elastically across the upper end of the groove when the punch member is raised.
The method of claim 5,
The extension end of the catch pin extending toward the guide groove is formed to have a semicircular curvature,
The upper side of the groove is formed in a smooth streamlined curve so that the catch pin can escape after being crossed. A notching mold for processing secondary battery electrodes that prevents scrap from rising.
The method of claim 5,
In the guide plate, the elevating plate is installed on guide bars into which the elevating plate is fitted,
The elevating plate is provided with pressurizing bars whose lower end side is inserted into the guide plate so as to be able to move up and down, and a pressurizing spring for elastically supporting the elevating plate to the guide plate so as to be able to move up and down is inserted in the pressurizing bars to prevent rising scrap. Notching mold for processing secondary battery electrodes.
The method of claim 1,
A punch fixing plate for supporting the stud portion of the punch is fitted to the punch,
The punch fixing plate is a notching mold for processing secondary battery electrodes to prevent scrap rising fixedly installed on the lower surface of the base plate.

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