KR20210152230A - System for producing electrodes of battery - Google Patents

Abstract

The present invention relates to a system for producing an electrode for a secondary battery, including: a suction plate disposed on one side of a belt and including a suction hole; a suction unit connected to the suction plate and adsorbing an electrode disposed on the other side of the belt; a magazine for loading and storing the electrode; and an electrode discharge unit for dropping the electrode into the magazine, wherein the electrode discharge unit drops the electrode only with the weight of the electrode by selectively opening the suction hole to communicate with the atmosphere.

Description

Electrode production system for secondary batteries {SYSTEM FOR PRODUCING ELECTRODES OF BATTERY}

The present invention relates to an electrode production system for secondary batteries.

In general, a chemical battery includes a positive electrode, a negative electrode, and an electrolyte, and refers to a battery that generates electrical energy by using a chemical reaction, which is a disposable primary battery and a secondary battery that can be charged and discharged repeatedly. can be divided into

Due to the advantage of being able to charge and discharge, the use of secondary batteries is gradually increasing. Among such secondary batteries, since the lithium secondary battery has a high energy density per unit weight, it is widely used as a power source for electronic communication devices or a high-output hybrid vehicle.

An electrode used in such a secondary battery is used as a positive electrode and a negative electrode of the battery, and is used to electrically connect the battery and the outside of the battery.

The electrode is produced through a process of notching and cutting the electrode material on which the electrode tab is formed at regular intervals. The cut electrode is adsorbed on the conveyor belt and transferred to the position where the magazine is arranged. A pusher is disposed above the magazine. The pusher drops the electrode into the magazine by pushing it into direct contact with the electrode.

However, there is a problem in that a significant impact is applied to the electrode while the pusher pushes the electrode. In particular, as the speed of the device for secondary battery production increases, the impact applied to the electrode by the pusher increases.

Republic of Korea Patent Publication No. 10-2015-0089803 (published on Aug. 5, 2015)

It is an object of the present invention to provide an apparatus for a secondary battery production battery that can be dropped toward a magazine without using a pusher and without damaging an electrode.

In an embodiment, a suction plate disposed on one side of the belt and including a suction hole, a suction unit connected to the suction plate for adsorbing an electrode disposed on the other side of the belt, a magazine for loading and storing the electrode, and the An apparatus for producing a secondary battery including an electrode discharge unit for dropping the electrode into a magazine, wherein the electrode discharge unit selectively opens the suction hole to communicate with the atmosphere, thereby dropping the electrode only by the weight of the electrode A battery electrode production system can be provided.

Preferably, the suction plate includes a first hole communicating with the atmosphere, and the electrode discharge unit includes a first plate disposed on the suction plate and including a third hole, and is connected to the first plate and connected to the first plate. A first driving unit for sliding the first plate is included, and when the first hole and the third hole overlap according to the movement of the first plate, the suction hole and the atmosphere communicate with each other to drop the electrode.

Preferably, the suction plate may include a first area in which the plurality of first holes are disposed, and the first area may be arranged in alignment with the magazine based on the transfer direction of the electrode material.

Preferably, the first plate may be slidably disposed along an outer surface of the suction plate in correspondence to the first region.

Preferably, the sliding direction of the first plate may be different from the transfer direction of the electrode material.

Preferably, the sliding direction of the first plate may be a direction perpendicular to the transfer direction of the electrode material.

Preferably, the first driving unit is disposed on the suction plate, and the first driving unit is disposed on the first plate and includes a guide block including a guide groove, a motor, and a connection connected to a shaft of the motor to rotate and a first roller coupled to the connecting bar and moving along the guide groove, and the first plate may slide in association with rotation of the connecting bar.

Preferably, the longitudinal direction of the guide groove may be parallel to the transport direction of the electrode.

Preferably, the first driving unit includes a second roller and a third roller, the second roller and the third roller are disposed on the stone plate to contact the first plate, respectively, the second roller and Each of the third rollers may rotate according to the sliding movement of the first plate.

Preferably, the first hole and the third hole are long holes, and a longitudinal direction of the first hole and a longitudinal direction of the third hole may be parallel to a transport direction of the electrode, respectively.

Preferably, the first plate may block the suction part and the suction hole in a state in which the first hole and the third hole overlap each other, thereby blocking the progress of the suction to the electrode.

Preferably, it further includes a suction block connected to the suction unit and disposed on one side of the first plate in the vertical direction, wherein the suction plate includes a second hole communicating with the first hole, The first plate may include a fourth hole, and in a state in which the first hole and the third hole overlap, the second hole and the fourth hole do not overlap, so that the suction unit and the suction hole may be blocked. .

Preferably, the electrode discharge unit is connected to the suction plate and includes an air supply unit for supplying air to the inside of the suction plate, and the air supply unit is connected to the first hole and the third hole according to the movement of the second plate. When overlapping, it is possible to supply air in communication with the air supply unit and the inside of the suction plate.

Preferably, the air supply unit may include a valve disposed between the first air supply unit and the second air supply unit, the first air supply unit and the second air supply unit, and the suction plate.

Preferably, when the first hole and the first hole overlap, the valve may alternately communicate the first air supply unit and the second air supply unit with the suction plate.

Preferably, the suction plate includes a fifth hole communicating with the atmosphere, the electrode discharge part includes a body part and a second driving part rotating the body part, and a partial region of the body part rotates to rotate the body part. By selectively blocking a partial region from communicating with the fifth hole and the suction unit, communicating the fifth hole with the atmosphere, and communicating the suction hole with the atmosphere, the electrode may be dropped.

Preferably, the body part includes a first body and a second body rotatably disposed inside the first body, and the second driving part is connected to the second body, and the first body has a direction The first flow path, the second flow path, and the third flow path are different from each other and include a third flow path, and the second body includes a fourth flow path and a fifth flow path that are different from each other and are connected to each other, and the first flow path communicates with the fifth hole, the shopping mall second flow path communicates with the suction unit, the third flow path communicates with the atmosphere, and the first flow path and the fifth flow path are aligned according to the rotation of the second body, When the third flow path and the fifth flow path are aligned, the suction hole and the atmosphere may communicate.

Preferably, a longitudinal direction of the second flow path and a longitudinal direction of the third flow path are parallel to each other, and a longitudinal direction of the first flow path is a longitudinal direction of the second flow path and a longitudinal direction of the third flow path. It may be in a vertical direction.

Preferably, a longitudinal direction of the third flow path and a longitudinal direction of the fourth flow path may be perpendicular to each other.

Preferably, a longitudinal direction of the second flow path and a longitudinal direction of the third flow path may be parallel.

Preferably, when the first flow path, the second flow path, the third flow path, the fourth flow path, and the fifth flow path are combined with each other to induce suction or release of the suction for the electrode, when viewed as a unit, A plurality of the unit body may be disposed, and the plurality of the unit body may be disposed to be spaced apart from each other in a direction of a rotation axis of the second body.

Preferably, the electrode discharge unit includes a third driving unit connected to a part of the suction plate, and the third driving unit lifts a part of the suction plate so that the separation distance between the suction plate and the belt increases, The electrode may be dropped by communicating the suction hole with the atmosphere.

Preferably, the suction plate includes a separable second region, the second region is connected to the third driving unit to be vertically movable, and the second region is based on the transfer direction of the electrode material. may be arranged in alignment with the magazine.

Preferably, the inner space of the second area may be disposed to be partitioned from the inner space of another area of the suction plate.

Preferably, the third driving unit may include, based on the vertical direction, such that a first distance that is a separation distance between the second region and the belt is greater than a second distance that is a distance between an upper surface and a lower surface of the suction plate. 2 areas can be lifted.

Preferably, the first distance may be within 5mm to 40mm.?

According to the embodiment, there is an advantage that the electrode can be dropped toward the magazine without physically contacting the electrode.

According to an embodiment, there is an advantage that the electrode can be dropped towards the magazine without damaging the electrode.

1 is a front view showing an electrode production system for a secondary battery according to an embodiment;
2 is a view showing an electrode adsorbed by a suction unit;
3 is a view showing a suction plate;
Figure 4 is a bottom view of the suction plate shown in Figure 3,
5 is a view showing an electrode discharge unit;
6 is an exploded view of the electrode discharge unit shown in FIG. 5;
7 is a perspective view of the guide block shown in FIG. 5;
8 is a bottom view of the suction block shown in FIG. 5;
9 is a side cross-sectional view taken on the basis of AA of FIG. 5 in a suction state;
10 is a view showing a state in which the first hole of the suction plate and the third hole of the first plate overlap so that the inside of the suction plate communicates with the atmosphere as a state in which the suction is released;
11 is a view showing a state in which the first plate blocks the suction as a state in which the suction is released;
12 is a side cross-sectional view taken on the basis of CC of FIG. 5 in a suction state;
13 is a side cross-sectional view based on DD of FIG. 10 in a state in which the suction is released;
14 is a view showing an electrode discharge unit of another type;
15 is a view showing the body part of the electrode discharge part in FIG. 14;
16 is a view showing a suction plate and a body portion based on CC of FIG. 15;
17 is a view showing the electrode discharge unit and the electrode shown in FIG. 16 in a state of suction;
18 is a view showing the body portion of the electrode discharge unit disposed on the suction plate;
19 is a view showing an electrode discharge unit in a state in which the suction is released;
20 is a view showing an electrode discharge unit and a suction plate of another type;
21 is a view showing an electrode discharge unit and a suction plate in a state in which the suction is released.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The embodiments of the present invention are provided to more completely explain the present invention to those of ordinary skill in the art, and the following embodiments can be modified in various other forms, and the scope of the present invention is not limited It is not limited to the following examples. Rather, these examples are provided so that this disclosure will be more thorough and complete, and will fully convey the spirit of the invention to those skilled in the art.

The terminology used herein is used to describe specific embodiments, not to limit the present invention. As used herein, the singular form may include the plural form unless the context clearly dictates otherwise. Also, as used herein, “comprise” and/or “comprising” refers to the specific existence of the recited shapes, numbers, steps, actions, members, elements, and/or groups thereof. and does not exclude the presence or addition of one or more other shapes, numbers, movements, members, elements and/or groups. As used herein, the term “and/or” includes any one and all combinations of one or more of those listed items.

It is to be understood that although the terms first, second, etc. are used herein to describe various members, regions and/or regions, these members, parts, regions, layers, and/or regions should not be limited by these terms. do. These terms do not imply a specific order, upper and lower, or superiority, and are used only to distinguish one member, region or region from another member, region or region. Accordingly, a first member, region, or region described below may refer to a second member, region, or region without departing from the teachings of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described with reference to drawings schematically illustrating embodiments of the present invention. In the drawings, variations of the illustrated shape may be expected, for example depending on manufacturing technology and/or tolerances. Accordingly, embodiments of the present invention should not be construed as limited to the specific shape of the region shown herein, but should include, for example, changes in shape caused by manufacturing.

The electrode production system for secondary batteries is a device for automatically and continuously producing electrodes used in secondary batteries.

1 is a front view showing an electrode production system for a secondary battery according to an embodiment. In the drawing, the direction indicated by the y-axis is the transfer direction of the electrode, and the direction indicated by the z-axis is the vertical direction of the electrode production system for secondary batteries in a direction perpendicular to the transfer direction of the electrode.

As shown in FIG. 1 , the electrode production system for a secondary battery according to the embodiment includes an unwinding unit 100 , a notching unit 200 , a cutting unit 300 , and a stacking device 400 . An electrode material formed of a strip-shaped metal plate extending horizontally from the unwinding part 100 at the entrance is supplied. The electrode material may be formed of copper in the case of producing a negative electrode battery, and may be formed of aluminum in the case of producing a positive electrode battery.

The notched part 200 produces an electrode by forming an electrode tab on the supplied electrode material. The cutting unit 400 cuts the electrode to a required size of the product. The cut electrode is supplied to the stacking device 400 .

The unwinding unit 100 continuously supplies an electrode material formed of a band-shaped metal plate. The unwinding unit 100 continuously supplies the electrode material from the plurality of electrode material supply reels, including a plurality of electrode material supply reels and servomotors. The reel can be stored by winding each electrode material in the form of a roll. Two reels can be arranged. One reel may be for supplying the electrode material currently, and the other reel may be for provisionally supplying the electrode material. The servomotor can drive the reel so that the electrode material is supplied.

The unwinding unit 100 automatically replaces the electrode material by the unwinder auto splicing so that the electrode material can be continuously supplied immediately. However, the present invention is not limited thereto, and the electrode material may be replaced manually.

The notched part 200 forms an electrode tab on the electrode material through a mold moving up and down. The notching part 200 passes through the electrode material supplied from the unwinding part 100 between the upper mold plate and the lower mold plate, and in the process of passing, the mold upper plate moves and notches the electrode material. An electrode including an electrode tab protruding to one side is created by forming notches at regular intervals in the electrode material. Feeding devices for continuously supplying the electrodes from the rear of the notched part 200 by continuously moving the electrodes passing through the notched part 200 in a pulling method for continuously pulling them may be provided.

The cutting unit 300 is a device for sequentially and sequentially cutting the electrodes. The cutting unit 300 may include a cutting means for cutting the electrodes, and a moving means for moving the cut electrodes, such as a conveyor. A cleaning means may be separately provided in the moving means. In addition, an apparatus for inspecting the cut electrode through an image may be provided. High-quality electrodes are selected, and poor-quality electrodes can be taken out and removed.

In the drawing, the direction indicated by the x-axis is the width direction of the electrode and the width direction of the suction plate, the direction indicated by the y-axis in the width direction of the electrode is the transfer direction of the electrode, and the direction indicated by the z-axis is perpendicular to the transfer direction of the electrode. The direction is the vertical direction of the electrode production system for secondary batteries.

The stacking device 400 may include an electrode discharge unit 410 and a magazine 420 .

The electrode discharge unit 410 is a device for dropping the electrode (S) from the belt (B) toward the magazine (420). The electrode discharge unit 410 is aligned with the magazine 420 in the transport direction. The magazine 420 loads and stores the electrodes S dropped by the electrode discharge unit 410 . A plurality of magazines 420 may be disposed along the transport direction. Correspondingly, a plurality of electrode discharge units 410 may also be disposed.

2 is a view showing the electrode (S) adsorbed by the suction unit.

Referring to Figure 2, the electrode (S) is transported by the belt (B) moving along the transport direction (y). The electrode (S) may be disposed on the lower side of the belt (B). The suction unit 500 may be disposed on the upper side of the belt (B). When the suction unit 500 operates, the electrode (S) is adsorbed with the belt (B) interposed therebetween and the electrode (S) is fixed so as not to be separated from the belt (B) during transport.

The electrode discharge unit 410 selectively opens the suction hole 610 to communicate with the atmosphere, thereby dropping the electrode S. The electrode discharge unit 410 can communicate the suction hole 610 with the atmosphere within a short time (less than 0.125 seconds).

The electrode (S) production system for a secondary battery according to the embodiment can drop the electrode (S) simply by releasing the adsorption process without a device for adding a separate force to drop the electrode (S), such as a pusher or an air blower. can Since the electrode S is dropped by its own weight, it is possible to drop the electrode S without contact with the electrode S.

3 is a view showing the suction plate 600, FIG. 4 is a bottom view of the suction plate 600 shown in FIG.

3 and 4 , the suction plate 600 may include a first area 601 in which a plurality of first holes 611 communicating with the atmosphere are disposed. The first hole 611 communicates the outside with the inner space of the suction plate 600 . The first region 601 is arranged in alignment with the magazine 420 based on the transfer direction y of the electrode S. The electrode S is dropped from the first area 601 and the dropped electrode S is loaded in the magazine 420 .

Also, the suction plate 600 is a suction hole 610 , in which a first hole 611 and a second hole 611a communicating with the first hole 611a may be disposed. A plurality of second holes 611a may be disposed, and the 1-2 holes 611a may be disposed on one side of the first hole 611 in the transport direction y. The first hole 611 and the second hole 611a may be selectively opened and closed by the first plate 411 .

5 is a view showing the electrode discharge unit 410, FIG. 6 is an exploded view of the electrode discharge unit 410 shown in FIG.

5 and 6 , the electrode discharge unit 410 may include a first plate 411 and a first driving unit 412 .

The first plate 411 is a plate-shaped member and may be disposed along the outer surface of the suction plate 600 . The first plate 411 may include a plurality of third holes 411a and fourth holes 411b. The first plate 411 is slidably disposed along the outer surface of the suction plate 600 . The sliding movement direction of the first plate 411 is a direction parallel to the width direction (x) of the electrode (S) perpendicular to the transfer direction (y) of the electrode (S).

Based on the transport direction y, the third hole 411a is aligned with the first hole 611 , and the fourth hole 411b is aligned with the second hole 611a .

A suction block SB may be further disposed on the upper side of the suction plate 600 . The first plate 411 may be disposed between the suction block SB and the suction plate 600 in the vertical direction z. The suction block SB is disposed to overlap the second hole 611a.

7 is a perspective view of the guide block 412a shown in FIG.

Referring to Figures 5 to 7 . The first driving unit 412 may include a guide block 412a, a motor 412b, a connecting bar 412c, and a first roller 412d. The guide block 412a is disposed on the upper surface of the first plate 411 . The guide block 412a may include a guide groove H.

The guide block 412a may include a base 412aa and a first sidewall 412ab and a second sidewall 412ac protruding from the base 412aa, respectively. The guide groove H corresponds to a space between the first sidewall 412ab and the second sidewall 412ac. The guide groove H is a device for converting the rotational motion of the motor 412b together with the first roller 412d into a linear motion of the first plate 411 . The longitudinal direction of the guide groove (H) may be parallel to the transport direction (y) of the electrode (S).

The connecting bar 412c may be connected to the rotation shaft of the motor 412b so that the longitudinal direction of the connecting bar 412c is parallel to the radial direction of the motor 412b. The first roller 412d is disposed at an end of the connecting bar 412c. The axial direction of the first roller 412d may be parallel to the vertical direction z. The first roller 412d comes into contact with the guide groove H and moves along the guide groove H in association with the rotation of the connecting bar 412c.

The motor 412b may be fixed to the suction plate 600 through a separate support 412ba. The axial direction of the motor 412b may be a direction parallel to the vertical direction z.

Each of the first hole 611 and the third hole 411a may be a long hole. The longitudinal direction of the first hole 611 and the longitudinal direction of the third hole 411a may be parallel to the transport direction y of the electrode S, respectively.

8 is a bottom view of the suction block SB shown in FIG.

Referring to FIG. 8 , the suction block SB may include a connection hole SB1 and a connection passage SB2 communicating with the connection hole SB1 . A plurality of connection holes SB1 may be disposed. All of the plurality of connection holes SB1 are connected to the connection passage SB2 . The suction block SB may be disposed above the first plate 411 such that the connection passage SB2 overlaps the third hole 411a. The connection hole SB1 is connected to the suction unit 500 .

9 is a side cross-sectional view taken along line A-A of FIG. 5 in a state of suction.

5 and 9 , in the suction state, the first plate 411 covers the first hole 611 of the suction plate 600 so that the inside of the suction plate 600 is not opened to the atmosphere.

When the first plate 411 moves in a direction away from the motor 412b based on the width direction x of the suction plate 600 and is positioned, the first plate 411 covers the first hole 611 . are placed The sliding movement direction of the first plate 411 may be the width direction (x) of the electrode (s).

When the first plate 411 covers the first hole 611 , the inside of the suction plate 600 is blocked from the atmosphere. At this time, the fourth hole 411b of the first plate 411 and the second hole 611a of the suction plate 600 are aligned so that the connection passage SB2 and the second hole 611a communicate with each other. As such, the 1-1 hole 611 and the second hole 611a are blocked from the atmosphere, and the suction process proceeds while communicating with the suction unit 500 . The belt (B) is disposed below the suction plate cover (603). The electrode (S) is adsorbed with the belt (B) and is in a fixed state.

At this time, the first roller 412d is in contact with the first sidewall 412ab of the guide block. In this case, the longitudinal direction of the connecting bar 412c may be the width direction (x) of the suction plate 600 .

10 is a state in which the suction is released, and the first hole 611 of the suction plate 600 and the third hole 411a of the first plate 411 overlap so that the inside of the suction plate 600 communicates with the atmosphere. It is a diagram showing the state of being

10 is a state in which the suction is released, the first hole 611 of the suction plate 600 and the third hole 411a of the first plate 411 overlap so that the inside of the suction plate 600 communicates with the atmosphere. It is a diagram showing the state.

Referring to FIG. 10 , when the motor 412b operates and the connecting bar 412c rotates, for example, when the connecting bar 412c rotates clockwise, the first roller 412d moves the guide groove H ) while moving along the width direction of the suction plate 600, the first plate 411 moves toward the motor 412b. At this time, the first roller 412d may be in contact with the second sidewall 412ac.

In this way, when the first plate 411 slides until the first hole 611 and the third hole 411a are aligned, the first hole 611 and the third hole 411a are aligned, and the suction plate The interior of 600 may be in communication with the atmosphere. The inside of the suction plate 600 is at atmospheric pressure, and since the adsorption to the electrode S is released, the electrode S is separated from the belt B and falls toward the magazine 420 .

Accordingly, there is an advantage that the electrode S can be dropped toward the magazine 420 without direct physical contact with the electrode S.

The first driver 410 maintains a suction state by covering the first hole 611 with the first plate 411 while the electrode S is moving, and when the electrode S arrives at the first region 601 , , to release the suction by moving the first plate 411 so that the first hole 611 and the third hole 411a are aligned, and induce the electrode S to fall toward the magazine 420 .

The electrode discharge unit 410 may further include a second roller 412e and a third roller 412f. The second roller 412e may be disposed on one side based on the width direction of the suction plate 600 , and the third roller 412f may be disposed on the other side based on the width direction of the suction plate 600 . The second roller 412e may be fixed to the suction plate 600 through a separate support 412ea. The third roller 412f may also be fixed to the suction plate 600 through a separate support part 412fa. The second roller 412ea and the third roller 412f may be disposed to contact the upper surface of the suction plate 600 , respectively. The second roller 412e and the third roller 412f each support the sliding movement of the suction plate 600 .

When the suction plate 600 slides, the second roller 412e and the third roller 412f rotate in association with the sliding movement of the suction plate 600 .

11 is a diagram illustrating a state in which the first plate 411 blocks the suction as a state in which the suction is released.

10 and 11 , the first plate 411 aligns the first hole 611 and the third hole 411a, and the same suction hole as the first hole 611 and the second hole 611a. At the same time as communicating the 610 with the atmosphere, the second hole 611a is covered to block the inside of the suction plate 600 and the inside of the suction block SB, so that it is possible to block the progress of the suction,

12 is a view showing a suction state as an electrode discharge unit 410 including an air supply unit 414, and FIG. 13 is an electrode discharge unit 410 including an air supply unit 414 in a state in which the suction is released. It is the drawing shown.

Referring to FIG. 12 , the electrode discharge unit 410 may include an air supply unit 414 .

The air supply unit 414 is connected to the suction plate 600 and communicates with the inner space of the suction plate 600 . The air supply unit 414 may include a first air supply unit 414A, a second air supply unit 414B, and a valve 414C. The first air supply unit 414A and the second air supply unit 414B receive air of low pressure, respectively. The first air supply unit 414A and the second air supply unit 414B are respectively connected to the valve 414C. The valve 414C is connected to the suction plate 600 .

The amount of air stored in each of the first air supply unit 414A and the second air supply unit 414B may be the same as the amount of air stored in the inner space of the suction plate 600 .

As shown in FIG. 12 , when the first plate 411 moves so that the first hole 611 and the third hole 411a are aligned, the suction unit 500 and the inner space of the suction plate 600 communicate with each other. while adsorbing the electrode (S). At this time, the valve 414C is closed, and air supplied from the first air supply unit 414A and the second air supply unit 414B to the suction plate 600 is blocked. When the electrode (S) is adsorbed, the electrode (S) is fixed to the belt (B).

13, when the first plate 411 moves so that the first hole 611 and the third hole 411a are aligned, the atmosphere and the inside of the suction plate 600 communicate with each other, and the electrode S ) is released. When the adsorption to the electrode (S) is released, the electrode (S) is separated from the belt (B) and falls toward the magazine (420). Accordingly, there is an advantage that the electrode S can be dropped toward the magazine 420 without direct physical contact with the electrode S.

At this time, at the moment when the first hole 611 and the third hole 411a are aligned, the valve 414C is opened for a short time and the inside of the first air supply unit 414A or the inside of the second air supply unit 414B is suctioned. It communicates with the inner space of the plate 600 . Since low-pressure air is stored inside the first air supply unit 414A or the inside of the second air supply unit 414B, respectively, there is an advantage in that the air opening to the suction hole 610 is quickly induced. If the air opening for the suction hole 610 is quick, the electrode S is dropped toward the magazine 420 more quickly, and there is an advantage in that the electrode S production process can be performed quickly.

Meanwhile, when the suction process and the suction release process are switched at high speed, there may be insufficient time to fill the first air supply unit 414A or the second air supply unit 414B with air. Accordingly, the valve 414C alternately communicates the first air supply unit 414A and the second air supply unit 414B with the suction plate 600 to form a first air supply unit 414A or a second air supply unit ( 414B), it is possible to secure time to fill the air.

14 is a view showing another type of electrode discharge unit 410, FIG. 15 is a view showing the body part 416 of the electrode discharge unit 410 in FIG. 10, and FIG. It is a view showing the suction plate 600 and the body portion 416 as a reference.

14 to 16 , the suction plate 600 may include a fifth hole 630 communicating with the atmosphere. The fifth hole 630 communicates with the suction hole 610 of the suction plate 600 . Another type of electrode discharging part 410 may include a body part 416 and a second driving part 417 for rotating a part of the body part 416 . The electrode discharge unit 410 blocks a partial region of the body portion 416 from selectively communicating with the fifth hole 630 and the suction unit 500 as a partial region of the body portion 416 is rotated, and a fifth By communicating the hole 630 with the atmosphere, the suction hole 610 and the atmosphere are communicated, so that the electrode S is dropped.

The body portion 416 may include a first body 416a and a second body 416b. The second body 416b is rotatably disposed inside the first body 416a. The second driving unit 417 is connected to the second body 416b. The second driving unit 417 may be a motor. When the second driving unit 417 operates, the second body 416b may rotate with respect to the axial center C. The second body 416b may be a member having an overall cylindrical shape. The first body 416a may be disposed to surround the second body 416b. The first body 416a is fixed to the suction plate 600 .

The first body 416a may include a first flow path U1 , a second flow path U2 , and a third flow path U3 . The first flow path U1 , the second flow path U2 , and the third flow path U3 may have different directions and may be spaced apart from each other. The first flow path U1 is aligned with and communicates with the fifth hole 630 . The second flow path U2 communicates with the suction unit 500 . The third flow path U3 communicates with the atmosphere. The longitudinal direction of the second flow path U2 and the longitudinal direction of the third flow path U3 are parallel, and the longitudinal direction of the first flow path U1 is the longitudinal direction of the second flow path U2 and the third flow path U3. It may be perpendicular to the longitudinal direction. The longitudinal direction of the second flow path U2 and the longitudinal direction of the third flow path U3 may be parallel to the transport direction y of the electrode S. The longitudinal direction of the first flow path U1 may be parallel to the vertical direction z.

The second body 416b may include a fourth flow path U4 and a fifth flow path U5 . The fourth flow path U4 and the fifth flow path U5 are connected to each other, but directions may be different. For example, the direction may be perpendicular to the longitudinal direction of the fourth flow path U4 and the longitudinal direction of the fifth flow path U5 .

The first flow path U1 , the second flow path U2 , the third flow path U3 , the fourth flow path U4 , and the fifth flow path U5 are combined with each other to induce the suction or the release of the suction into one unit. When viewed, a plurality of unit bodies may be disposed on the body portion 416 . These unit bodies may be disposed spaced apart from each other in the axial direction of the second body 416b.

FIG. 17 is a view showing the electrode discharge part 410 and the electrode S shown in FIG. 16 in a suction state.

16 and 17 , the first flow path U1 and the fourth flow path U4 are aligned, and the second flow path U2 and the fifth flow path U5 are aligned with the second body 416b. When the position is determined, the suction hole 610 communicates with the suction unit 500 to maintain a state of suction with respect to the electrode S.

18 is a view showing the body portion 416 of the electrode discharge unit 410 disposed on the suction plate 600, FIG. 19 is a view showing the electrode discharge unit 410 in a state in which the suction is released .

18 and 19 , the second body 416b rotates, for example, the second body 416b rotates clockwise to align the first flow path U1 and the fifth flow path U5. When the third flow path U3 and the fourth flow path U4 are aligned and communicated with each other, the suction hole 610 is opened to the atmosphere to release the suction for the electrode S. When the suction for the electrode (S) is released, the electrode (S) is separated from the belt (B) and falls toward the magazine (420).

Accordingly, there is an advantage that the electrode S can be dropped toward the magazine 420 without direct physical contact with the electrode S.

20 is a view showing the electrode discharge unit 410 and the suction plate 600 in another form, and FIG. 21 is a view showing the electrode discharge unit 410 and the suction plate 600 in a state in which the suction is released. .

20 and 21 , the electrode discharge unit 410 may include a third driving unit 418 connected to a portion of the suction plate 600 . The third driving unit 418 is connected to a portion of the suction plate 600 . The third driving unit 418 lifts a part of the suction plate 600 in the vertical direction to communicate the suction hole 610 with the atmosphere to drop the electrode S. The third driving unit 418 may include a motor and various power conversion devices that convert the rotational motion of the motor into linear motion.

The suction plate 600 may include a separable second region 602 . The second region 602 may be aligned with the magazine 420 based on the transfer direction y of the electrode S. The inner space K1 of the second area 602 is partitioned from the inner space K2 of another area of the suction plate 600 . The second region 602 is connected to the third driving unit 418 and is disposed to be movable in the vertical direction (z).

In a state in which the second region 602 is not separated, the suction state is maintained. In the suction state, the electrode (S) is fixed to the belt (B).

When the third driving unit 418 operates to lift the second region 602 of the suction plate 600 , the second region 602 of the suction plate 600 moves away from the belt B. As the suction hole 610 of the second region 602 moves away from the belt B, the belt B communicates with the atmosphere through the separation space M between the second region 602 and the belt B, and the electrode ( Suction for S) is released and the electrode S falls toward the magazine 420 .

At this time, in the third driving unit 418 , based on the vertical direction z, the first distance L1 that is the separation distance between the second region 602 and the belt B is the upper surface and the lower surface of the suction plate 600 . The second region 602 may be lifted to be greater than the second distance L2, which is the distance therebetween. Meanwhile, the first distance may be within 5 mm to 40 mm.

As described above, specific embodiments of the secondary battery electrode (S) production system of the present invention have been described, but it is apparent that various implementation modifications are possible within the limits that do not depart from the scope of the present invention.

Therefore, the scope of the present invention should not be limited to the described embodiments, and should be defined by the following claims as well as the claims and equivalents.

That is, it should be understood that the above-described embodiment is illustrative in all respects and not restrictive, and the scope of the present invention is indicated by the claims to be described later rather than the detailed description, and the meaning and scope of the claims; All changes or modifications derived from the concept of equivalents thereof should be construed as being included in the scope of the present invention.

100: unwinding unit
200: notching part
300: cutting unit
400: stacking device
410: electrode discharge unit
411a: 3rd hole
411b: 4th hole
411: first plate
412: first driving unit
414: air supply unit
416: body part
417: second driving unit
418: third driving unit
420: magazine
500: suction unit
600: suction plate
610: suction hole
611: Hall 1
611a: 2nd hole
630: 5th hole
SB: suction block

Claims (26)

A suction plate disposed on one side of the belt and including a suction hole, a suction unit connected to the suction plate for adsorbing an electrode disposed on the other side of the belt, a magazine for loading and storing the electrode, and the electrode as the magazine As an apparatus for producing a secondary battery comprising an electrode discharge unit for dropping the
The electrode discharge unit selectively opens the suction hole to communicate with the atmosphere, and the electrode production system for a secondary battery drops the electrode only by its own weight. According to claim 1,
The suction plate includes a first hole communicating with the atmosphere,
The electrode discharge unit,
a first plate disposed on the suction plate and including a third hole;
and a first driving unit connected to the first plate to slide the first plate,
When the first hole and the third hole overlap according to the movement of the first plate, the suction hole and the atmosphere communicate with each other to drop the electrode. 3. The method of claim 2,
The suction plate includes a first area in which the plurality of first holes are disposed,
Based on the transfer direction of the electrode material, the first area is arranged in alignment with the magazine electrode production system for a secondary battery. 4. The method of claim 3,
The first plate is slidably disposed along the outer surface of the suction plate to correspond to the first region. 3. The method of claim 2,
The slide direction of the first plate is different from the transfer direction of the electrode material for a secondary battery electrode production system. 6. The method of claim 5,
The sliding direction of the first plate is a secondary battery electrode production system in a direction perpendicular to the transfer direction of the electrode material. 3. The method of claim 2,
The first driving unit is disposed on the suction plate,
The first driving unit is disposed on the first plate and includes a guide block including a guide groove, a motor, a connecting bar connected to the shaft of the motor to rotate, and a first moving along the guide groove by being coupled to the connecting bar. including a roller;
The first plate is an electrode production system for a secondary battery that slides in association with the rotation of the connection bar. 8. The method of claim 7,
The longitudinal direction of the guide groove is parallel to the transport direction of the electrode for a secondary battery electrode production system. 9. The method of claim 8,
The first driving unit includes a second roller and a third roller,
The second roller and the third roller are disposed on the stone plate so as to be in contact with the first plate, respectively,
The second roller and the third roller are each rotated according to the sliding movement of the first plate electrode production system for a secondary battery. 3. The method of claim 2,
The first hole and the third hole are long holes,
The longitudinal direction of the first hole and the longitudinal direction of the third hole are respectively parallel to the transport direction of the electrode for a secondary battery electrode production system. 3. The method of claim 2,
The first plate blocks the suction unit and the suction hole in a state in which the first hole and the third hole overlap each other, thereby preventing the suction of the electrode from proceeding. 12. The method of claim 11,
Further comprising a suction block connected to the suction unit and disposed on one side of the first plate in the vertical direction,
The suction plate includes a second hole communicating with the first hole,
The first plate includes a fourth hole,
In a state in which the first hole and the third hole overlap, the second hole and the fourth hole do not overlap, so that the suction unit and the suction hole are blocked. 3. The method of claim 2,
The electrode discharge unit is connected to the suction plate and includes an air supply unit for supplying air to the inside of the suction plate,
When the air supply unit overlaps the first hole and the third hole according to the movement of the second plate, the air supply unit supplies air communicating with the inside of the suction plate. 14. The method of claim 13,
The air supply unit includes a first air supply unit and a second air supply unit, and a valve disposed between the first air supply unit and the second air supply unit and the suction plate. 15. The method of claim 14,
When the first hole and the first hole overlap,
The valve is an electrode production system for a secondary battery that alternately communicates the first air supply unit and the second air supply unit with the suction plate. According to claim 1,
The suction plate includes a fifth hole communicating with the atmosphere,
The electrode discharge unit,
It includes a body part and a second driving part for rotating the body part,
The partial region of the body part rotates to selectively block the partial region of the body part from communicating with the fifth hole and the suction part, and communicates the fifth hole with the atmosphere, thereby communicating the suction hole with the atmosphere, Electrode production system for secondary batteries that drop electrodes. 17. The method of claim 16,
The body portion includes a first body and a second body rotatably disposed inside the first body,
The second driving unit is connected to the second body,
The first body includes a first flow path, a second flow path, and a third flow path that have different directions and are spaced apart from each other,
The second body includes a fourth flow path and a fifth flow path that are different from each other and are connected to each other,
The first flow path communicates with the fifth hole, the shopping mall second flow path communicates with the suction unit, and the third flow path communicates with the atmosphere,
When the first flow path and the fifth flow path are aligned according to the rotation of the second body, and the third flow path and the fifth flow path are aligned, the suction hole and the atmosphere communicate with each other. 18. The method of claim 17,
The longitudinal direction of the second flow path and the longitudinal direction of the third flow path are parallel to each other,
A longitudinal direction of the first flow path is a direction perpendicular to a longitudinal direction of the second flow path and a longitudinal direction of the third flow path. 19. The method of claim 18,
A secondary battery electrode production system in which the longitudinal direction of the third flow path and the longitudinal direction of the fourth flow path are perpendicular to each other. 20. The method of claim 19,
A secondary battery electrode production system in which the longitudinal direction of the second flow path and the longitudinal direction of the third flow path are parallel. 21. The method of claim 20,
When the first flow path, the second flow path, the third flow path, the fourth flow path, and the fifth flow path are combined with each other to induce suction or release of the electrode, when viewed as a unit,
A plurality of the units are arranged,
The plurality of units are spaced apart from each other in the direction of the axis of rotation of the second body, and are disposed to be spaced apart from each other. According to claim 1,
The electrode discharge unit,
and a third driving unit connected to a part of the suction plate,
The third driving unit lifts a portion of the suction plate to increase the separation distance between the suction plate and the belt, and communicates the suction hole with the atmosphere to drop the electrode. 23. The method of claim 22,
The suction plate includes a second separable region,
The second region is connected to the third driving unit and is arranged to be movable up and down,
Based on the transfer direction of the electrode material, the second region is arranged in alignment with the magazine electrode production system for a secondary battery. 24. The method of claim 23,
The inner space of the second area is divided from the inner space of the other area of the suction plate, and the secondary battery electrode production system is disposed. 23. The method of claim 22,
The third driving unit lifts the second area so that a first distance that is a separation distance between the second region and the belt is greater than a second distance that is a distance between the upper and lower surfaces of the suction plate based on the vertical direction. electrode production system for secondary batteries. 23. The method of claim 22,
The first distance is within 5mm to 40mm of the secondary battery electrode production system.

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