KR102814818B1 - A device to prevent sheet metal from jamming in a notching mold that opens and closes a die insert using a cylinder - Google Patents

Abstract

A device for preventing a sheet metal from being caught in a notching mold for opening and closing a die insert using a cylinder is disclosed. The device for preventing a sheet metal from being caught in a notching mold for opening and closing a die insert using a cylinder of the present invention includes an upper mold in which a punch is installed, a pusher pin that moves up and down along the upper mold; a lower mold in which a die for striking a sheet intersecting the punch is installed, a housing block having a pneumatic cylinder formed inside, the pneumatic cylinder having a piston and an operating bar having one end connected to the piston; a shutter plate connected to the other end of the operating bar of the pneumatic cylinder; an air-control punch holder spaced apart from the upper portion of the housing block and controlling the operation of the pneumatic cylinder by the moving up and down of the pusher pin; and an air-control punch that is fixed to the lower portion of the air-control punch holder, moves up and down together with the air-control punch holder, and has air holes that open and close air passages for controlling the forward and backward movement of the piston of the pneumatic cylinder. According to the present invention, it is possible to prevent snagging and damage caused by a thin plate hitting a die insert during transport after punching in a notching mold for punching out electrode films.

Description

{A device to prevent sheet metal from jamming in a notching mold that opens and closes a die insert using a cylinder}

The present invention relates to a device for preventing sheet metal from being caught in a notching mold that opens and closes a die insert using a cylinder, and more specifically, to a device for preventing sheet metal from being caught in a notching mold that opens and closes a die insert using a cylinder, which prevents sheet metal from being caught and damaged by hitting the die insert during transport after being punched out in a film punching notching mold.

Secondary batteries, unlike primary batteries, are batteries that repeatedly charge and discharge. These secondary batteries are widely used in portable devices such as mobile phones, laptop computers, and camcorders, as well as in transportation such as hybrid cars and electric cars, and their range of applications is gradually expanding.

Secondary batteries can be classified according to the shape of the electrode assembly of the positive electrode/separator/negative electrode structure. The stack type is a structure in which electrodes cut to a certain size are sequentially laminated with a separator interposed between them, and the winding type is a structure in which electrodes that have not been cut are simultaneously wound and laminated with a separator interposed between them. Both methods have tabs on the electrodes to enable the movement of electricity in the electrodes to meet the demands of high-capacity, high-output secondary batteries.

In the process of manufacturing the electrodes of these electrode assemblies, a notching process is performed.

In the notching process, the notching mold is mounted on a press with an upper mold and a lower mold respectively to punch out the thin plate which is the electrode film. The upper mold is equipped with a notching punch and the lower mold is equipped with a die. The thin plate which is the electrode film is continuously fed between the notching punch and the die, and when the notching punch and the die intersect, the thin plate which is the electrode film is punched out, thereby continuously forming a tab portion.

However, there is a problem that the electrode film is damaged when the tab portion sags and hits the die insert during transport. In particular, when the tab portion is large, there is a high possibility of such damage occurring.

Accordingly, a device is required to prevent the phenomenon in which the tab portion, which occurs during the notching process of the thin film, which is an electrode film, sags and hits the die insert.

To this end, a method is being developed to move the tab-jamming prevention unit device in accordance with the timing of the notching mold punching using sensors, etc., but existing sensors, etc. have the problem that malfunctions and errors occur, making it difficult to operate at the correct timing.

Republic of Korea Publication Patent No. 10-2059581

The present invention has been made in consideration of the above-described problems, and its purpose is to provide a film plate jamming prevention device for a film notching mold that opens and closes a die insert using a cylinder to prevent jamming and damage caused by a film plate hitting a die insert during transport after stamping in the film stamping notching mold.

The present invention for solving the above problem comprises a device for preventing a thin plate from getting caught in a notching mold for opening and closing a die insert using a cylinder, in an upper mold where a punch is installed, a pusher pin that moves up and down along the upper mold; a lower mold where a die for striking a thin plate intersecting the punch is installed, a housing block having a pneumatic cylinder formed inside, which has a piston and an operating bar having one end connected to the piston; a shutter plate connected to the other end of the operating bar of the pneumatic cylinder; an air-control punch holder spaced apart from the upper portion of the housing block and controlling the operation of the pneumatic cylinder by the moving up and down of the pusher pin; and an air-control punch that is fixed to the lower portion of the air-control punch holder, moves up and down together with the air-control punch holder, and has air holes that open and close air passages for controlling the forward and backward movement of the piston of the pneumatic cylinder.

In the present invention, the air-control punch holder is connected to the housing block by a stripper bolt, and in a normal state, the air-control punch holder can be maintained in a spaced state from the housing block by an elastic spring on the outer surface of the stripper bolt.

In the present invention, when the upper mold is lowered to press the pusher pin to punch out the thin plate, the pusher pin presses the air-control punch holder while opposing the elastic spring on the outer surface of the stripper bolt, and the air-control punch connected to the lower part of the air-control punch holder in the form of a rod operates to pull the piston of the pneumatic cylinder inside the housing block sideways so that the air holes are opened and closed so that the shutter plate connected to the operating bar is pulled to open the die insert.

In the present invention, after the thin plate is punched to form a tab portion, when the upper mold is raised and the pressure applied to the pusher pin is released, the air-control punch holder pressed by the pusher pin is raised by the elastic spring on the outer surface of the stripper bolt, and the air-control punch connected to the lower part of the air-control punch holder in the form of a rod opens and closes air holes to cause the piston of the pneumatic cylinder inside the housing block to operate in a direction extending laterally, so that the shutter plate connected to the operating bar is extended to block the die insert.

In the present invention, the pneumatic cylinder formed in the housing block may be a rodless cylinder including a tube that penetrates the housing block horizontally and has front and rear ends; and a piston that is connected to an operating bar at one end and moves horizontally back and forth along the tube by pneumatic pressure inside the tube.

In the present invention, a front step portion is formed at the connection portion between the piston and the operating bar, and a front air injection space is formed between the front step portion and the tube, and the front air injection space is connected to the exterior of the housing block so that a front inlet air passage and a front exhaust air passage through which air can enter and exit are formed, respectively, and the front inlet air passage and the front exhaust air passage selectively allow air to enter or exit by the front inlet air hole and the front exhaust air hole formed in the air control punch, respectively, so that the piston can move horizontally forward or backward within the tube.

In the present invention, a rear step portion is arranged at the rear end of the tube, so that a rear air injection space is formed between the rear step portion and the tube, and the rear air injection space is connected to the exterior of the housing block to form a rear inlet air passage and a rear exhaust air passage through which air can enter and exhaust, respectively, and the rear inlet air passage and the rear exhaust air passage can selectively introduce or exhaust air by a rear inlet air hole and a rear exhaust air hole formed in the air control punch, respectively, so that the piston can move horizontally forward or backward within the tube.

In the present invention, the timing of forward and backward movement of the shutter plate can be controlled by adjusting the air pressure of the air passage that controls the forward and backward movement of the piston of the pneumatic cylinder.

According to the present invention having the configuration described above, it is possible to prevent snagging and damage caused by the thin plate hitting the die insert during transport after punching in a notching mold for punching out electrode films.

In addition, the operating speed of the shutter plate that opens and closes the die insert can be adjusted by adjusting the air pressure of the air passage that controls the forward and backward movement of the piston of the pneumatic cylinder.

FIG. 1 is a perspective view showing a plate jam prevention device of a notching mold with a die insert opened according to one embodiment of the present invention.
FIG. 2 is a perspective view showing a plate jam prevention device of a notching mold in a state where a die insert is blocked according to one embodiment of the present invention.
FIG. 3 is a front view showing a plate jam prevention device of a notching mold with a die insert opened according to one embodiment of the present invention.
FIG. 4 is a front view showing a plate jam prevention device of a notching mold in a state where a die insert is blocked according to one embodiment of the present invention.
FIG. 5 is a plan perspective view showing a plate jam prevention device of a notching mold in a state where a die insert is blocked according to one embodiment of the present invention.
FIG. 6 is a rear perspective view showing a plate jam prevention device of a notching mold in a state where a die insert is blocked according to one embodiment of the present invention.
FIG. 7 is a front perspective view showing a plate jam prevention device of a notching mold in a state where a die insert is blocked according to one embodiment of the present invention.
FIG. 8 is a front cross-sectional view showing a plate jamming prevention device of a notching mold in a state where a die insert is blocked according to one embodiment of the present invention.
FIG. 9 is a plan perspective view showing a plate jam prevention device of a notching mold with a die insert opened according to one embodiment of the present invention.
FIG. 10 is a rear perspective view showing a sheet metal snagging prevention device of a notching mold with a die insert opened according to one embodiment of the present invention.
FIG. 11 is a front perspective view showing a plate jam prevention device of a notching mold with a die insert opened according to one embodiment of the present invention.
FIG. 12 is a front cross-sectional view showing a plate jamming prevention device of a notching mold with a die insert opened according to one embodiment of the present invention.

Hereinafter, a device for preventing sheet metal from jamming of a notching mold for opening and closing a die insert using a cylinder according to a preferred embodiment of the present invention will be described in detail with reference to the attached drawings.

The notching mold for secondary batteries punches out a thin plate, which is a continuously supplied electrode film, and processes tabs into the electrode film at regular intervals.

The device for preventing a thin plate from getting caught in the notching mold of the present invention is arranged in a path through which an electrode film passes between an upper mold to which a punch is coupled and a lower mold to which a die is coupled, and opens and closes a die insert using a cylinder. As a result, it is possible to prevent the thin plate from getting caught or damaged by hitting the die insert during transport after punching in the notching mold for punching out electrode films.

That is, at the moment when the tab portion is struck, the plate catch prevention device of the notching mold of the present invention opens the die insert to strike, and when the plate on which the tab portion is formed is transported after striking, the die insert is blocked to prevent the tab portion from being caught on the die insert.

FIG. 1 is a perspective view showing a plate jam prevention device of a notching mold with a die insert open according to an embodiment of the present invention, and FIG. 2 is a perspective view showing a plate jam prevention device of a notching mold with a die insert closed according to an embodiment of the present invention. FIG. 3 is a front view showing a plate jam prevention device of a notching mold with a die insert open according to an embodiment of the present invention, and FIG. 4 is a front view showing a plate jam prevention device of a notching mold with a die insert closed according to an embodiment of the present invention.

Referring to FIGS. 1 to 4, the plate catch prevention device (10) of the notching mold is provided with a pusher pin (220) that is connected to an upper mold in which a punch (210, see FIGS. 8 and 12) is installed and moves up and down along the upper mold.

The lower mold in which the die (110, see Fig. 8 and Fig. 12) is installed includes a housing block (120) having a pneumatic cylinder formed therein, which has a piston (320) and an operating bar (330) connected to one end of the piston (320), a shutter plate (130) connected to the other end of the operating bar (330) of the pneumatic cylinder, an air-controlled punch holder (140) spaced apart from the upper portion of the housing block (120) and controlling the operation of the pneumatic cylinder by the lowering of the pusher pin (220), and air holes (151, 312, 313, 314, see Fig. 5 and Fig. 9) that are fixed in the form of a rod to the lower portion of the air-controlled punch holder (140) and move up and down together with the air-controlled punch holder (140) and control the forward and backward movement of the piston (320) of the pneumatic cylinder. It includes an air conditioner control punch (150) equipped with (see Figs. 152, 153, 154, Figs. 6, 7, 10, and 11).

Referring to FIGS. 3 and 4, when the upper mold is lowered to press the pusher pin (220) to stamp out the thin plate, which is the electrode film, the pusher pin (220) presses the air-control punch holder (140) while opposing the elastic spring (175) on the outer surface of the stripper bolt (170), and the air-control punch (150) coupled to the lower part of the air-control punch holder (140) in the form of a rod operates in a direction that pulls the piston (320) of the pneumatic cylinder inside the housing block (120) sideways by opening and closing the air holes (151, 152, 153, 154, see FIGS. 6, 7, 10, and 11) so that the shutter plate (130) connected to the operating bar (330) is pulled to open the die insert.

On the other hand, when the upper mold is raised after the thin plate, which is an electrode film, is punched out to form a tab portion and the pressure applied to the pusher pin (220) is released, the air-control punch holder (140) pressed by the pusher pin (220) is raised by the elastic spring (175) on the outer surface of the stripper bolt (170), and the air-control punch (150) coupled in the form of a rod to the lower part of the air-control punch holder (140) opens and closes the air holes (151, 152, 153, 154) so that the piston (320) of the pneumatic cylinder inside the housing block (120) operates in a direction extending laterally, thereby extending the shutter plate (130) connected to the operating bar (330) to block the die insert.

The pneumatic cylinder inside the housing block (120) is a rodless cylinder in which a piston (320) and an operating bar (330) connected to the piston (320) perform linear movement in both directions by compressed air supplied from both sides of a tube (310).

The above shutter plate (130) has a number of holes punched in the upper and lower directions. These holes are punched to ensure smooth air flow when the scrap is sucked in by the press suction after the notching.

The above air conditioner control punch holder (140) moves up and down along the guide pin (160) and is connected to the housing block (120) by the stripper bolt (170). In the normal state, the air conditioner control punch holder (140) is kept apart from the housing block (120) by the elastic spring (175) on the outer surface of the stripper bolt (170).

On the other hand, when the upper mold is lowered to press the pusher pin (220) to punch out the thin plate, which is the electrode film, the pusher pin (220) presses the air conditioner punch holder (140) while opposing the elastic spring (175) on the outer surface of the stripper bolt (170).

The stripper bolt (170) includes a head, a body extending vertically from one side of the head, and a screw part integrally formed at an extended end of the body. A female screw part is provided inside the housing block (120) so that the stripper bolt (170) can be coupled.

FIG. 5 is a plan perspective view showing a plate jamming prevention device of a notching mold in a state where a die insert is blocked according to one embodiment of the present invention, FIG. 6 is a rear perspective view, and FIG. 7 is a front perspective view. FIG. 8 is a front sectional view showing a plate jamming prevention device of a notching mold in a state where a die insert is blocked according to one embodiment of the present invention.

FIG. 9 is a plan perspective view showing a plate jamming prevention device of a notching mold with a die insert opened according to one embodiment of the present invention, FIG. 10 is a rear perspective view, and FIG. 11 is a front perspective view. FIG. 12 is a front sectional view showing a plate jamming prevention device of a notching mold with a die insert opened according to one embodiment of the present invention.

Referring to FIGS. 5 to 12, the pneumatic cylinder formed in the housing block (120) has a tube (310) formed that penetrates horizontally through the housing block (120), and the front and rear sides of the tube (310) are finished by a front housing backing block (121) and a rear housing backing block (122), respectively.

Inside the above tube (310), a piston (320) is positioned that moves horizontally back and forth along the tube (310) by air pressure, and an operating bar (330) that has a smaller diameter than the piston (320) is connected at one end to the center of the piston (320) and is coupled to the front. A shutter plate (130) is coupled to the other end of the operating bar (330).

Referring to FIGS. 5 to 8, a front step portion (340) having a diameter smaller than that of the piston (320) and larger than that of the operating bar (330) is formed at the connection portion between the front piston (320) and the operating bar (220), so that when the front step portion (340) connected to the piston (320) comes into contact with the front housing backing block (121), the operating bar (330) is extended the longest. At this time, a front air injection space (350) is formed between the front step portion (340) and the tube (310).

The front air injection space (350) has a sealed space by the front housing backing block (121) at the front, the piston (320) at the rear, and the tube (310) at the side. The front air injection space (350) is connected to the outside, and a front inlet air passage (311) and a front exhaust air passage (312) through which air can enter and exit, respectively, are formed in the housing block (120). The front inlet air passage (311) and the front exhaust air passage (312) allow the piston (320) to move horizontally forward or backward within the tube (310) while selectively introducing or exhausting air by the front inlet air hole (151) and the front exhaust air hole (152) formed in the air control punch (150), respectively.

Referring to FIGS. 9 to 12, a rear step portion (360) smaller in diameter than the piston (320) is arranged on the rear housing backing block (122), which is the rear end of the tube (310). When the piston (320) comes into contact with the rear step portion (360), the operating bar (330) enters the tube (310) the most and is exposed to the outside the shortest, and the shutter plate (130) at the other end of the operating bar (330) is in a state where the die insert is completely opened. (See FIG. 9) At this time, a rear air injection space (370) is formed between the rear step portion (360) and the tube (310).

The rear air injection space (370) has a sealed space by the rear housing backing block (122) at the rear, the piston (120) at the front, and the tube (310) at the side. The rear air injection space (370) is connected to the outside, and a rear inlet air passage (313) and a rear exhaust air passage (314) through which air can enter and exit, respectively, are formed in the housing block (120). The rear inlet air passage (313) and the rear exhaust air passage (314) allow the piston (320) to move horizontally forward or backward within the tube (310) while selectively introducing or exhausting air by the rear inlet air hole (153) and the rear exhaust air hole (154) formed in the air control punch (150), respectively.

Below, the operating mechanism of the pneumatic cylinder formed inside the housing block (120) is described.

Referring to FIGS. 5 to 8, as the punch (210) and the pusher pin (220) connected to the upper mold are raised and lowered, the shutter plate (130) blocks the die insert of the die (110), and the thin plate, which is the electrode film, is transported without being damaged by being caught on the die insert.

When the pusher pin (220) rises, the air conditioner control punch holder (140) pressed by the pusher pin (220) rises by the elastic spring (175) on the outer surface of the stripper bolt (170), and the air conditioner control punch (150) that is extended and fixed to the lower part of the air conditioner control punch holder (140) also rises.

When the air control punch (150) rises, the rear inlet air hole (153) opens in alignment with the rear inlet air passage (313), and the rear exhaust air hole (154) closes while being misaligned with the rear exhaust air passage (314), so that air is injected into the rear air injection space (370) at the rear of the piston (320). In addition, the front exhaust air hole (152) opens in alignment with the front exhaust air passage (312), and the front inlet air hole (151) closes while being misaligned with the front inlet air passage (311), so that residual air in the tube (310) in front of the piston (320) is discharged into the front exhaust air passage (312) connected to the front air injection space (350). As a result, the piston (320) of the pneumatic cylinder moves forward by the pneumatic pressure acting forward, and the operating bar (330) and shutter plate (130) connected to the piston (320) move forward to block the die insert.

Referring to FIGS. 9 to 12, the punch (210) and the pusher pin (220) connected to the upper mold are lowered, and the shutter plate (120) opens the die insert of the die (110), so that the thin plate, which is the electrode film, is punched out as the punch (210) and the die (110) intersect.

When the pusher pin (220) is lowered, the air conditioner punch holder (140) is lowered against the elastic spring (175) on the outer surface of the stripper (170) by the pusher pin (220), and the air conditioner punch (150) that is extended and fixed to the lower part of the air conditioner punch holder (140) is also lowered.

When the air control punch (150) descends, the front inlet air hole (151) opens in alignment with the front inlet air passage (311), and the front exhaust air hole (152) closes while being misaligned with the front exhaust air passage (312), so that air is injected into the front air injection space (350) at the front of the piston (320). In addition, the rear exhaust air hole (154) opens in alignment with the rear exhaust air passage (314), and the rear inlet air hole (153) closes while being misaligned with the rear inlet air passage (313), so that residual air in the tube (310) at the rear of the piston (320) is discharged into the rear exhaust air passage (314) connected to the rear air injection space (370). As a result, the piston (320) of the pneumatic cylinder moves backwards due to the pneumatic pressure acting backwards, and the operating bar (330) and shutter plate (130) connected to the piston (320) move backwards to open the die insert.

In the present invention, the forward and backward timing of the operating bar (330) connected to the piston (320) and the shutter plate (130) can be controlled by controlling the forward and backward speed of the piston (320) of the cylinder. This is done by controlling the air pressure that supplies air to the front inlet air passage (311) and the rear inlet air passage (313). That is, if the air pressure of the front inlet air passage (311) and the rear inlet air passage (313) is increased, the shutter plate (130) can be operated quickly.

The present invention described above is not limited to the above-described drawings and detailed description, and it goes without saying that various modifications and changes made by those skilled in the art within the scope and spirit of the present invention as described in the claims below are also included within the scope of the present invention.

10: Anti-slip plate 110: Die
120: Housing block 121: Front housing backing block
122: Rear housing backing block 130: Shutter plate
140: Air conditioner control punch holder 150: Air conditioner control punch
151: Front inlet air hole 152: Front exhaust air hole
153: Rear inlet air hole 154: Rear exhaust air hole
160: Guide pin 170: Stripper bolt
175: Elastic spring 210: Punch
220: Pusher pin 310: Tube
311: Forward inlet air passage 312: Forward exhaust air passage
313: Rear inlet air passage 314: Rear exhaust air passage
320: Piston 330: Actuator
340: Front chin 350: Front air injection space
360: Rear chin 370: Rear air injection space

Claims (8)

In the upper mold where the punch is installed,
Includes a pusher pin that moves up and down along the upper mold.
In the lower mold, a die for striking a thin plate by crossing the above punch is installed,
A housing block having a pneumatic cylinder formed inside, which has a piston and an operating bar connected at one end to the piston;
A shutter plate connected to the other end of the operating bar of the above pneumatic cylinder;
An air-controlled punch holder that is spaced apart from the upper portion of the housing block and controls the operation of the pneumatic cylinder by the raising and lowering of the pusher pin; and
A thin plate jam prevention device for a notching mold that opens and closes a die insert using a cylinder including an air-controlled punch, which is fixed to the lower part of the air-controlled punch holder and moves up and down together with the air-controlled punch holder, and which has air holes for opening and closing air passages that control the forward and backward movement of a piston of a pneumatic cylinder. In the first paragraph,
The above air conditioner control punch holder is connected to the housing block by a stripper bolt,
A device for preventing sheet metal jamming of a notching mold for opening and closing a die insert, characterized in that in a normal state, the air-control punch holder is kept apart from the housing block by an elastic spring on the outer surface of the stripper bolt. In the second paragraph,
A plate jam prevention device for a notching mold that opens and closes a die insert using a cylinder, characterized in that when the upper mold is lowered to press the pusher pin to punch out the above-mentioned thin plate, the pusher pin presses the air-control punch holder while opposing the elastic spring on the outer surface of the stripper bolt, and the air-control punch connected to the lower part of the air-control punch holder in the form of a rod opens and closes air holes so that the piston of the pneumatic cylinder inside the housing block is pulled laterally, thereby pulling the shutter plate connected to the operating bar to open the die insert. In the second paragraph,
A plate catch prevention device for a notching mold that opens and closes a die insert using a cylinder, characterized in that when the upper mold rises after the above-mentioned thin plate is punched to form a tab portion and the pressure applied to the pusher pin is released, the air-control punch holder pressed by the pusher pin rises by the elastic spring on the outer surface of the stripper bolt, and the air-control punch connected to the lower part of the air-control punch holder in the form of a rod opens and closes air holes to cause the piston of the pneumatic cylinder inside the housing block to operate in a direction extending laterally, thereby causing the shutter plate connected to the operating bar to extend and block the die insert. In the first paragraph,
The pneumatic cylinder formed in the above housing block is
A tube that penetrates horizontally through the housing block and is finished at the front and rear; and
A device for preventing sheet metal jamming of a notching mold for opening and closing a die insert using a cylinder, characterized in that the cylinder is a rodless cylinder including a piston connected to an operating bar at one end and horizontally moved back and forth along the tube by pneumatic pressure inside the tube. In paragraph 5,
A front step portion is formed at the connection portion between the piston and the operating bar, and a front air injection space is formed between the front step portion and the tube.
The above front air injection space is connected to the outside of the housing block, and a front inlet air passage and a front discharge air passage are formed, respectively, through which air can enter and exit.
A device for preventing plate jamming of a notching mold for opening and closing a die insert using a cylinder, characterized in that the front inlet air passage and the front exhaust air passage are configured such that air can be selectively introduced or discharged by the front inlet air hole and the front exhaust air hole formed in the air control punch, respectively, while the piston can move forward or backward horizontally within the tube. In paragraph 5,
A rear step portion is arranged at the rear end of the above tube, so that a rear air injection space is formed between the rear step portion and the tube.
The above rear air injection space is connected to the outside of the housing block to form a rear inlet air passage and a rear exhaust air passage through which air can enter and exhaust, respectively.
A device for preventing plate jamming of a notching mold for opening and closing a die insert using a cylinder, characterized in that the rear inlet air passage and the rear exhaust air passage are configured such that air can be selectively introduced or discharged by the rear inlet air hole and the rear exhaust air hole formed in the air control punch, respectively, while the piston can move forward or backward horizontally within the tube. In the first paragraph,
A device for preventing plate jamming of a notching mold for opening and closing a die insert using a cylinder, characterized in that the timing of the forward and backward movement of a shutter plate is controlled by adjusting the air pressure of an air passage that controls the forward and backward movement of a piston of the above-mentioned pneumatic cylinder.