BR102015020208B1 - Device and method of lamination for a secondary battery - Google Patents

Abstract

LAMINATION DEVICE AND METHOD FOR A SECONDARY BATTERY A lamination device and a method for a secondary battery are provided. The laminating device includes: an electrode plate roller configured to wrap an electrode plate around it and unroll the electrode plate therefrom; a separator roll configured to wrap a separator around it and unwind the separator therefrom; an affix roll configured to affix the electrode plate and separator to each other; a mandrel unit around which the electrode plate and separator supplied from the clamp roll is wound; and a cutting unit arranged between the electrode plate roll and the mandrel unit for cutting the electrode plate supplied from the electrode plate roll to the mandrel unit by a slot cutting method using linear motion.

Description

FUNDAMENTALS 1. Field

[001] One or more exemplary embodiments relate to a device and a method, and more particularly, to a laminating device and a method for a secondary battery.

2. Description of the related technique

[002] Compact and lightweight electrical/electronic devices such as cell phones, laptop computers, and video cameras have been recently developed and produced. Such portable electrical/electronic devices are equipped with a battery pack in order to be used where power supplies are not available. Such a battery pack includes at least one battery that emits a voltage of a certain level, thereby allowing an electrical/electronic device to operate for some time.

[003] Due to economic reasons, rechargeable batteries (secondary batteries) have been included in recent battery packs. Examples of secondary batteries include nickel-cadmium (Ni-Cd) batteries, nickel-metal hydride (Ni-MH) batteries, and secondary lithium batteries such as lithium (Li) and lithium-ion (Li- ion).

[004] Particularly, secondary lithium batteries have an operating voltage of 3.6V, which is three times the operating voltage of Ni-Cd batteries or Ni-MH batteries, and a high energy density per weight. Thus, the use of secondary lithium batteries increased rapidly. Generally, secondary lithium batteries use oxides containing lithium as a positive electrode active material, and carbon as a negative electrode active material. In general, according to the type of electrolyte, secondary batteries can be classified into a liquid electrolyte type and a polymer electrolyte type. Examples of lithium secondary batteries include lithium ion batteries using a liquid electrolyte and a lithium polymer secondary battery using a polymer electrolyte. Lithium secondary batteries can be formed to have various shapes such as cylindrical, prismatic, and pouch shapes.

[005] Generally, a secondary lithium battery includes: an electrode unit formed by winding the first and second electrode plates and a separator arranged between them, the separator preventing a short circuit between the first and second electrode plates and allowing only lithium ions to pass through it; a secondary lithium battery housing to accommodate the electrode unit; and an electrolyte filled into the secondary lithium battery housing to allow the flow of lithium ions.

[006] The first and second electrode plates are positive and negative electrode plates that can be formed by coating base plates with active materials, drying and laminating the base plates, and cutting the base plates to predetermined sizes. The first and second electrode plates formed as described above are laminated together with the separator to form the electrode unit. This time, the first and second electrode tabs are affixed to the first and second electrode plates to extend out of the electrode unit, so that the polarities of the first and second electrode plates are exposed on the outside. For example, the electrode unit may be formed using a laminating device by inserting ends of the first and second electrode plates and the separator supplied by the supply units into the insertion slots of a mandrel, rotating the mandrel to rotate the first and second second electrode plates and the separator around the mandrel. After that, the electrode unit can be inserted into the secondary lithium battery housing, and the secondary lithium battery housing can be closed with a cap unit provided as the end product.

SUMMARY

[007] One or more exemplary embodiments include a laminating device and a method for a secondary battery.

[008] Additional aspects will be set out in part in the following description and in part will be apparent in the description, or may be learned by practicing the present modalities.

[009] According to one or more exemplary embodiments, a laminating device for a secondary battery includes: an electrode plate roller configured to wrap an electrode plate around it and unroll the electrode plate therefrom; a separator roll configured to wrap a separator around it and unwind the separator therefrom; an affixing roller configured to affix the electrode plate and spacer to each other; a mandrel unit around which the electrode plate and separator supplied from the clamp roll is wound. ; and a cutting unit arranged between the electrode plate roll and the mandrel unit for cutting the electrode plate supplied from the electrode plate roll to the mandrel unit by a slot cutting method using linear motion.

[0010] The cutting unit may include: a linear motion unit configured to be linearly moved; and a cutter rotatably coupled to the linear motion unit so as to cut the electrode plate while being rotated when the linear motion unit can be linearly moved.

[0011] The cutting unit may additionally include a linear drive unit connected to the linear motion unit to linearly move the linear motion unit.

[0012] At least one of both sides of the cutter can be tapered.

[0013] The cutter may include: a first upper cutter rotatably coupled to the linear motion unit so as to cut a first surface of the electrode plate while being rotated when the linear motion unit can be linearly moved; and a first lower cutter rotatably coupled to the linear motion unit in a position facing the first upper cutter so as to cut a second surface of the electrode plate that is different from the first surface of the electrode plate.

[0014] A portion of the first lower cutter making contact with the second surface of the electrode plate may be flat.

[0015] The first upper cutter and the first lower cutter can be staggered.

[0016] At least portions of the first upper cutter and the first lower cutter may overlap.

[0017] The first upper cutter and the first lower cutter can be rotated towards the electrode plate when the electrode plate is directed towards the first upper cutter and the second lower cutter.

[0018] The first upper cutter and the first lower cutter include a support, and the support may include a penetration hole through which the electrode plate passes.

[0019] The cutting unit may additionally include: a guide gear arranged on the support; and a rotating gear unit attached to the cutter and connected and connected to the guide gear unit, wherein when the linear motion unit can be moved, the rotating gear unit can be moved in the guide gear unit while being rotated, so to rotate the cutter.

[0020] The cutter may include: a rotating shaft connected to the rotating gear unit and rotatably inserted into the linear motion unit; and a blade connected to the rotating shaft so as to be rotated together with the rotating gear unit.

[0021] The cutter may additionally include a cutter support securing the blade to the rotating shaft.

[0022] The cutter may additionally include a pressing part by pressing the blade towards the electrode plate.

[0023] The cutting unit may include: a linear motion unit configured to be moved linearly; a rotary cutter coupled to the linear motion unit so as to cut a first surface of the electrode plate while being rotated when the linear motion unit is linearly moved; and a linear cutter facing the cutting device so as to cut a second surface of the electrode plate that is different from the first surface of the electrode plate.

[0024] In accordance with one or more exemplary embodiments, a laminating method for a secondary battery includes: unrolling a first electrode plate from a first electrode plate roll and a first separator from a first separator roll; affixing the first separator to the first electrode plate by pressing the first electrode plate and the first separator using the first affixing rollers; winding the first electrode plate, to which the first separator is affixed, using a mandrel unit; and cutting the first electrode plate by a slot cutting method if the chuck unit stops.

[0025] The chuck unit can roll the first electrode plate and the first separator like a swiss roll.

[0026] The lamination method may further include winding a second electrode plate and a second separator around the mandrel unit by unwinding the second electrode plate from a second electrode roll plate and the second separator from there. of a second separating roller and supplying the second electrode plate and the second separator to the mandrel unit.

[0027] The first electrode plate, the first separator, the second electrode plate, and the second separator can be stacked sequentially.

[0028] The lamination method may additionally include cutting the second electrode plate via a slot cutting method when the chuck unit stops.

BRIEF DESCRIPTION OF THE DRAWINGS

[0029] These and/or other aspects will become apparent and more readily appreciated from the following description of exemplary embodiments, taken in conjunction with the accompanying drawings, in which: FIG. 1 is a schematic view illustrating a laminating device for a secondary battery, according to an exemplary embodiment; FIG. 2 is a schematic view illustrating a cutting unit shown in FIG. 1, according to an exemplary embodiment; FIG. 3 is a cross-sectional view taken along line III-III of FIG. two; FIG. 4 is a schematic view illustrating a wound electrode plate assembly with a mandrel unit shown in FIG. 1; FIG. 5 is a schematic view illustrating a cutting unit shown in FIG. 1, according to another exemplary embodiment; and FIG. 6 is a cross-sectional view taken along line VI-VI of FIG. 5.

DETAILED DESCRIPTION

[0030] Reference will be made in detail to the modalities, examples of which are illustrated in the accompanying drawings, in which reference numbers refer to elements in the whole. In this regard, the present embodiments may take different forms and should not be construed as being limited to the descriptions set forth herein. Accordingly, the embodiments are merely described below, with reference to the figures, to explain aspects of the present description. As used herein, the term "and/or" includes any and all combinations of one or more of the associated items listed. Expressions such as “at least one of,” when preceding a list of elements, modify the entire list of elements and do not modify the individual elements of the list. In the following description, technical terms are used only to explain exemplary embodiments, and not for purposes of limitation. Singular terms may include the plural form unless specifically mentioned. The meaning of “comprises” and/or “comprising” specifies an element, a step, a process, an operation, and/or devices. It should be understood that while the terms first and second are used herein to describe various elements, these elements are not to be limited by these terms. Terms are used only to distinguish an element from other elements.

[0031] FIG. 1 is a schematic view illustrating a laminating device 10 for a secondary battery, in accordance with an exemplary embodiment. FIG. 2 is a schematic view illustrating a first 100th cutting unit shown in FIG. 1. FIG. 3 is a cross-sectional view taken along line III-III of FIG. 2. FIG. 4 is a schematic view illustrating an electrode assembly 1 wound with a mandrel unit 600 shown in FIG. 1.

[0032] Referring to FIGS. 1 to 4, the laminating device 10 for a secondary battery may include: electrode plate rollers 200 and 300 for winding electrode plates 24 and around and unrolling electrode plates 2 and 4 therefrom; and separator rollers 400 and 500 for winding separators 3 around them and unrolling separators 3 therefrom.

[0033] Electrode plate rolls 200 and 300 may include: a first electrode plate roll 200 for wrapping a first electrode plate 2 around it and unwinding the first electrode plate 2 therefrom; and a second laminating electrode plate 300 for wrapping a second electrode plate 4 around it and unrolling the second electrode plate 4 therefrom.

[0034] The separation rollers 400 and 500 may include: a first separation roller 400 for winding a turn of the same first separator 3a and delamination of the first separator 3a thereof; and a second separating roller 500 for winding a second turn of the same separator 3b and unrolling the second separator 3b therefrom.

[0035] The laminating device 10 may include clamping rollers 700 and 800 for gathering and joining electrode plates 2 and 4 unrolled from electrode plate rolls 200 and 300 and separators 3 unrolled from separator roll 400 and 500 Clamping rollers 700 and 800 can be supplied as pairs each including two mutually facing rollers for pressing and affixing electrode plates 2 and 4 and spacers 3.

[0036] For example, the affix cylinders 700 and 800 may include: first affix rollers 700 for gathering and affixing together the first electrode plate 2 and the first spacer 3a; and second affixing rollers 800 for gathering and affixing together the second electrode plate 4 and the second spacer 3b.

[0037] In addition, the laminating device 10 may include a tension-maintaining roller 900 disposed on a path of at least one selected from the first electrode plate 2, the first separator 3a, the second electrode plate 4 and the second separator 3b to maintain the voltage of the at least one selected from the first electrode plate 2, the first separator 3a, the second electrode plate 4 and the second separator 3b. A plurality of tension-maintaining rollers 900 may be provided. That is, at least one tension-maintaining roller 900 may be disposed on a path of at least one selected from the first electrode plate 2, the first separator 3a, the second electrode plate 4 and the second separator 3b.

[0038] The laminating device 10 may include the mandrel unit 600 to form an electrode assembly by winding the first electrode plate 2, the first spacer 3a, the second electrode plate 4 and the second spacer 3b. The chuck unit 600 can form a swiss roll 1 electrode array.

[0039] In addition, the laminating device 10 may include a cutting unit 100 for cutting electrode plates 2 and 4 by a slot cutting method when electrode plates 2 and 4 are supplied from the electrode rolls. electrode plate 200 and 300 from cylinders 200 and from electrode plate 300 to mandrel unit 600. One or more cutting units 100 may be provided. In detail, the cutting units 100 may include the first cutting unit 100a arranged between the first electrode plate roll 200 and the mandrel unit 600 for cutting the first electrode plate 2 when the first electrode plate 2 is provided. from the first electrode plate roll 200 to the mandrel unit 600. In addition, the cutting units 100 may include a second cutting unit 100b disposed between the second electrode plate roll 300 and the mandrel unit 600 to cutting the second electrode plate 4 when the second electrode plate 4 is fed from the second electrode plate roll 300 to the mandrel unit 600.

[0040] The first and second cutting units 100a and 100b may have the same or similar structures. In the following description, the first cutting unit 100a will be described primarily in detail for the sake of brevity of description.

[0041] In detail, the first cutting unit 100a may include a first linear motion unit 110a. Furthermore, the first cutting unit 100a may include a first cutter 120a rotatably installed in the first linear motion unit 110a to cut the first electrode plate 2 during rotation when the first linear motion unit 110a is linearly moved. The first cutter 120a may include a first upper cutter 120a-1 disposed above a first surface 2a of the first electrode plate 2 for cutting the first surface 2a of the first electrode plate 2. Furthermore, the first cutter 120a may include a first lower cutter 120a-2 arranged beneath a second surface 2b of the first electrode plate 2 for cutting the second surface 2b of the first electrode plate 2.

[0042] A portion of at least one selected from a first upper cutter 120a-1 and first lower cutter 120a-2 making contact with the first electrode plate 2 may be tapered. For example, a portion of the first upper cutter 120a-1 making contact with the first electrode plate 2 may be tapered, and a lower portion of the first cutter 120a-2 making contact with the first electrode plate 2 may be flat. On the contrary, the portion of the first upper cutter 120a-1 making contact with the first electrode plate 2 may be flat, and the portion of the first lower cutter 120a-2 making contact with the first electrode plate 2 may be tapered. Furthermore, both parts of the first upper cutter 120a-1 and the first lower cutter 120a-2 making contact with the first electrode plate 2 may be tapered. However, for ease of illustration, the following description will be presented under the assumption that the portion of the upper first cutter 120a-1 making contact with the first electrode plate 2 is tapered and the lower portion of the first cutter 120a-2 making contact with the first electrode plate 2 is flat.

[0043] As described above, at least one of the two sides of the first upper cutter 120a-1 may be tapered. In detail, the end of the first upper cutter 120a-1 making contact with the first electrode plate 2 may be inclined.

[0044] The first upper cutter 120a-1 and the first lower cutter 120a-2 can be staggered. In detail, the first upper cutter 120a-1 and the first lower cutter 120a-2 can be arranged in different positions along the length of the first electrode plate 2. In this case, a surface of the first upper cutter 120a-1 can be separated. from a lower surface of the first cutter 120a-2 by a certain length.

[0045] At least the portions of the first upper cutter 120a-1 and the first lower cutter 120a-2 may overlap each other. For example, when the first upper cutter 120a-1 and the first lower cutter 120a-2 have a circular shape, the distance between the center of the first upper cutter 120a-1 and the center of the first lower cutter 120a-2 may be less than than the sum of the radius of the first upper cutter 120a-1 and the radius of the first lower cutter 120a-2.

[0046] In addition, the first cutting unit 100a may include a first linear drive unit 130a connected to the first linear motion unit 110a for linearly displacing the first linear motion unit 110a. The first linear drive unit 130a may include a motor and gear assembly connected to the first linear motion unit 110a. In another exemplary embodiment, the first linear drive unit 130a may include a cylinder connected to the first linear motion unit 110a. For clarity of illustration, the following description will be withheld on the assumption that the first linear drive unit 130a includes a cylinder.

[0047] The first cutting unit 100a may include a first support 140a through which a first penetration hole 141a is formed so that the first electrode plate 2 can pass through the first penetration hole 141a. The first support 140a can be attached to an external frame.

[0048] The first cutting unit 100a may include: a first guide gear 150a disposed on the first support 140a; and a first rotating gear unit 160a fixed to the first upper cutter 120a-1 or the first lower cutter 120a-2 and connected to the first guide gear unit 150a so as to rotate the first upper cutter 120a-1 or the first lower cutter 120a -2 while rotating along the first guide gear unit 150a when the first linear motion unit 110a is moved.

[0049] The first guide gear unit 150a may include racks, and the first rotating gear unit 160a may include pinion gears. However, the first guide gear unit 150a and the first rotating gear unit 160a are not limited thereto. That is, the first guide gear unit 150a and the first rotating gear unit 160a can be constituted by any combination of gears, as long as the first guide gear unit 150a and the first rotating gear unit 160a are capable of converting the movement linear motion of the first linear motion unit 110a in rotary motion.

[0050] The first guide gear unit 150a may include: a first upper guide gear unit 150a-1 disposed on the first support 140a along a path of movement of the first upper cutter 120a-1; and a first lower guide gear unit 150a-2 disposed on the first support 140a along a path of movement of the first lower cutter 120a-2.

[0051] In addition, the first rotary gear unit 160a may include: a first upper rotary gear unit 160a-1 configured to move on the first upper guide gear unit 150a-1; and a first lower rotating gear unit 160a-2 configured to move over the first lower guide gear unit 150a-2. In this case, the first cutter 120a may include the first rotary axes 121a-1 and 121a-2 connected to the first unit and rotary gear 160a and rotatably inserted into the first linear motion unit 110a. Furthermore, the first cutter 120a may include first blades 122a-1 and 122a-2 connected to the first rotating shafts 121a and 121a-1-2 and rotating together with the first rotating gear unit 160a.

[0052] First cutter 120a may include first cutter holders 123a-1 and 123a-2, which secure first blades 122a-1 and 122a-2 to first rotary axes 121a-1 and 121a-2. Furthermore, the first cutter 120a may include first pressure parts 124a-1 and 124a-2 which push the first blades 122a-1 and 122a-2 against the first electrode plate 2. The first pressure parts 124a-1 and 124a -2 may include elastic parts such as compression, rubber or silicone springs.

[0053] In detail, the first upper cutter 120a-1 may include: the first rotary axis (first upper rotary axis) 121a-1 connected to the first upper rotary reducer 160a-1; and the first blade (first upper blade) 122a-1 connected to the first upper rotary shaft 121a-1 and configured to rotate in conjunction with the first upper rotary gear unit 160a-1. The first upper rotary axis 121a-1 may be rotatably coupled to the first support 140a with an in-between lamination disposed therebetween.

[0054] Furthermore, the first upper cutter 120a-1 may comprise the first cutter support (first upper cutter support) 123a-1 disposed on at least one side of the first upper blade 122a-1 and receiving the first upper rotating shaft 121a-1. The first upper cutter 120a-1 may include the first pressing part (first pressing upper part) 124a-1 arranged between the first upper rotary axis 121a-1 and the first upper blade 122a-1 for pushing the first upper blade 122a-1 against 2a the first surface of the first electrode plate 2.

[0055] The first lower cutter 120a-2 may include: the first rotary shaft (first lower rotary axis) 121a-2 connected to the first lower rotary reducer 160a-2; and the first blade (first lower blade) 122a-2 connected to the first lower rotating shaft 121a-2 and configured to rotate in conjunction with the first lower rotating gear unit 160a-2. The thickness of the first lower blade 122a-2 may be different from the thickness of the first upper blade 122a-1. In detail, the thickness of the first lower blade 122a-2 may be greater than the thickness of the first upper blade 122a-1.

[0056] In addition, the first lower cutter 120a-2 may include the first cutter holder (first lower cutter holder) 123a-2 disposed on at least one side of the first lower blade 122a-2 and receiving the first lower rotating shaft 121a-2. The first upper cutter 120a-2 may include the first pressing part (first pressing lower part) 124a-2 disposed between the first rotating lower shaft 121a-2 and the first lower blade 122a-2 for pushing the first lower blade 122a-2 against 2b the second surface of the first electrode plate 2.

[0057] Like the first cutting unit 100a, 100b of the second cutting unit may include a second linear motion unit (not shown), a second cutter (not shown), a second linear drive unit (not shown), a second bracket (not shown), a second gear guide unit (not shown), and a second rotating gear unit (not shown). Since the second linear motion unit, the second cutter, the second linear drive unit, the second support, the second guide gear unit, and the second rotary gear unit are similar or identical to the first 110th drive unit, linear motion, the first cutter 120a, the first linear drive unit 130a, 140a of the first support, the first gear guide unit 150a, and the first rotary gear unit 160a, the detailed description thereof will not be repeated.

[0058] An electrode assembly 1 can be manufactured with the laminating device 10 as follows. First, a first electrode plate 2, a first separator 3a, a second electrode plate 4, and a second separator 3b can be respectively wound around the first electrode plate roller 200, the first separation roller 400 , the second electrode plate roll 300, and the second separation roll 500.

[0059] After the first electrode plate roll 200 to the second separation roll 500 are prepared as described above, the first electrode plate 2 and the first separator 3a can be unrolled and attached to the mandrel unit 600 through the first fixing rollers 700. Furthermore, the second electrode plate 4 and the second separator 3b can be unrolled and fixed to the mandrel unit 600 via the second fixation rollers 800. At this time, the first electrode plate and the first separator 3a can be connected to each other during the passage between the first affixing rollers 700. Furthermore, the second electrode plate 4 and the second spacer 3b can be connected to each other during the passage between the second fixation rollers 800.

[0060] After the first electrode plate 2, the first spacer 3a, the second electrode plate 4, and the second spacer 3b are attached to the chuck unit 600 as described above, the chuck unit 600 is rotated to form a set of gel-like electrodes a roll. At this time, as described above, the first affix rollers 700 can clamp the first electrode plate 2 and the first spacer 3a together, and the second fixation rollers 800 can fix the second electrode plate 4 and the first spacer 3a together. .

[0061] During the processes described above, the tension holding rollers 900 can uniformly maintain the tension of one or more of the first electrode plate 2, the first separator 3a, the second electrode plate 4 and the second separator 3b.

[0062] If the electrode assembly 1 is formed to be a certain size, as the chuck unit 600 is rotated, the rotation of the chuck unit 600 may be temporarily stopped. At this time, the first cutting unit 100a and the second cutting unit 100b can cut the first electrode plate 2 and the second electrode plate 4, respectively.

[0063] In detail, if the first electrode plate 2 passing through the first penetration hole 141a of the first support 140a is stopped, the first linear driving unit 130a can be operated to linearly move the first 110a linear motion unit.

[0064] At this time, the first upper cutter 120a-1 and the first lower cutter 120a-2 installed in the first linear motion unit 110a can be moved linearly together with the first 110th linear motion unit. At this time, the first linear motion unit 110a can be moved linearly in the width direction of the first electrode plate 2. In this state, the first upper rotary gear unit 160a-1 connected to the first upper rotary axis 121a-1 can be linearly moved. transferred over the first upper guide reducer 150a-1, and the first lower rotary gear unit 160a-2 connected to the first lower rotary shaft 121a-2 can be linearly moved over the first lower guide gear unit 150a-2.

[0065] While the first upper rotary reducer 160a-1 and the first lower rotary reducer 160a-2 are moved in the first upper guide reducer 150a-1 and the first lower guide reducer 150a-2, the first upper rotary gear drive 160a-1 and the first lower rotating gear unit 160a-2 is rotatable. Then, the first upper part of the rotary shaft 121a-1 connected to the first upper rotary reducer 160a-1 may be rotated, and the first lower rotary shaft 121a-2 connected to the first lower rotary reducer 160a-2 may be rotated. Furthermore, the first upper rotating shaft 121a-1 can rotate the first upper blade 122a-1, and the first lower rotating shaft 121a-2 may rotate the first lower blade 122a-2. Particularly, since the first upper rotary reducer, synchronizing speed can be possible 160a-1 and the first lower rotary gear unit 160a-2 are linearly moved together with the first linear motion unit 110a by a frame of block. Therefore, the first upper blade 122a-1 and the first lower blade 122a-2 can be moved with the same angular speed and the linear speed.

[0066] The first upper blade 122a-1 and the first lower blade 122a-2 can be rotated in opposite directions. For example, if the first upper blade 122a-1 is rotated clockwise, the first lower blade 122a-2 may be rotated counterclockwise. Alternatively, if the first upper blade 122a-1 is rotated counterclockwise, the first lower blade 122a-2 may be rotated clockwise. Particularly, when the first linear motion unit 110a is moved, the first upper blade 122a-1 and the first lower blade 122a-2 can be rotated towards the first electrode plate 2, when the first electrode plate 2 approaches to the first upper blade 122a-1 and the first lower blade 122a-2. The first upper blade 122a-1 and the first lower blade 122a-2 can cut the first surface 2a and the second surface 2b of the first electrode plate 2, respectively.

[0067] In this case, the first upper pressing part 124a-1 and the first lower pressing part 124a-2 can respectively press the first upper blade 122a-1 and the first lower blade 122a-2 towards the first electrode plate 2 with a constant force. At this time, the first upper pressing part 124a-1 can press the first upper blade 122a-1 to the first lower blade 122a-2, and from the first pressing the lower part 124a-2 can press the first lower blade 122a-2 in towards the first upper blade 122a-1. Therefore, while the first lower paddle 122a-1 and the first lower paddle 122a-2 cut the first electrode plate 2, the first upper paddle 122a-1 and the first lower paddle 122a-2 can press the first electrode plate 2 with a constant vigor.

[0068] While the first electrode plate 2 is cut by the first cutting unit 100a as described above, the second cutting unit 100b can cut the second electrode plate 4 in a similar manner. At this time, the operation of the second cutting unit 100b is similar or identical to the operation of the first cutting unit 100a, and thus a detailed description thereof will be omitted.

[0069] While the first electrode plate 2 and the second electrode plate 4 are cut as described above, the first spacer 3a and the second spacer 3b can be cut with additional cutting units. In this case, the first spacer 3a and the second spacer 3b can be cut by a general cutting method.

[0070] Thereafter, the chuck unit 600 can be rotated again to completely fabricate the electrode assembly 1.

[0071] In the set of electrodes 1, the first electrode plate 2, the first separator 3a, the second electrode plate 4 and the second separator 3b can be sequentially stacked. In this case, the first electrode plate 2 can still be arranged on the other surface of the second spacer 3b. That is, the first electrode plate 2, the first separator 3a, the second electrode plate 4 and the second separator 3b can be alternately stacked, and thus the stability of the electrode assembly 1 can be guaranteed.

[0072] According to the laminating device 10 and the laminating method for a secondary battery, since the first electrode plate 2 and the second electrode plate 4 are respectively cut by the first cutter 120a and the second cutter , the first electrode plate 2 and the second electrode plate 4 cannot be damaged.

[0073] In addition, according to the laminating device 10 and the laminating method, once the first electrode plate 2 and the second electrode plate 4 are smoothly cut, the first electrode plate 2 and the second plate electrode 4 cannot be separated, or burrs cannot be formed on the first electrode plate 2 and the second electrode plate 4.

[0074] Furthermore, according to the laminating device 10 and the laminating method, given that the generation of contaminants is avoided when the first electrode plate 2 and the second electrode plate 4 are cut, the stability of the assembly of the electrode 1 can be guaranteed.

[0075] FIG. 5 is a schematic view illustrating a first cutting unit 100c according to another exemplary embodiment. FIG. 6 is a cross-sectional view taken along line VI-VI of FIG. 5. In the following description, the same reference numbers as used in the example above refer to the same elements.

[0076] Referring to Figs. 5 and 6 , a cutting unit (not shown) may include a first 100c cutting unit and a second cutting unit (not shown). The first cutting unit 100c can cut a first electrode plate 2, and the second cutting unit can cut a second electrode plate 4.

[0077] The first 100c cutting unit and the second cutting unit may have the same or similar structures. Alternatively, the first cutting unit 100c may be configured as described below, and the second cutting unit may be similar or identical to the first cutting unit 100a described with reference to Figs. 1 to 4. However, for the sake of brevity of description, the case where the first cutting unit 100c and the second cutting unit have the same structure or similar structures will be mainly described. Furthermore, the first cutting unit 100a will be described primarily in detail for the sake of brevity of description.

[0078] The first cutting unit 100c may include a first linear motion unit 110c, 120c of a first cutter, a first linear driving unit 130c, a first support 140c, a first gear unit guide 150c, and a first rotary gear unit 160c.The first linear motion drive 110c, the first cutter 120c, the first linear drive unit 130c, the first support 140c, the first guide reducer 150c, and the first rotary gear unit 160c are similar or identical to of the first linear motion unit 110a, the first upper cutter the detailed descriptions, thus 120a-1, the first linear drive unit 130a, the first support 140a, the first upper guide reducer 150a-1, and the first upper rotating gear 160a-1, and the same will not be repeated.

[0079] The first cutter 120c may include: a first rotating shaft 121c rotatably coupled to the first support 140c; and a first blade 122c connected to the first axis of rotation 121c. In addition, the first cutter 120c may include: a first cutter support 123c into which the first rotating shaft 121c is inserted to secure the first blade 122c to the first rotating axis 121c; and a first pressing part 124c disposed between the first blades 122c and 121c of the first rotary axis to press the first blades 122c.

[0080] The first rotating shaft 121c, the first blade 122c, 123c of the first cutter holder, and the first pressing part 124c are similar or identical to the first 121a-1, 122a-1, the first cutter holder the upper part of the rotating axis of the first upper blade the detailed descriptions, thus, 123a-1, and the first upper pressing part 124a-1, and the same will not be repeated.

[0081] The first cutting unit 100c may include a first linear cutter 170c facing the first cutter 120c. The first linear cutter 170c may be attached to the first support 140c. The first 170c linear cutter can cut a second surface 2a of the first electrode plate 2 opposite a first 2a surface of the first electrode plate 2. When the first cutter 120c is rotated, the first 170c linear cutter can cut the second surface 2b of the first electrode plate 2.

[0082] A portion of the first linear cutter 170c making contact with the second surface 2b of the first electrode plate 2, may be flat. The first linear cutter 170c may extend in the direction of the width of the first electrode plate 2, and the length of the first linear cutter 170c may be greater than the width of the first electrode plate 2.

[0083] Also, the thickness of the first linear cutter 170c may be different from the thickness of the first blade 122c. In detail, the thickness of the first linear cutter 170c may be greater than the thickness of the first blade 122c. Therefore, the first 170c linear cutter can support the first electrode plate 2, while the first 122c paddle cuts the first electrode plate 2.

[0084] The first cutting unit 100c can be operated as follows. If the laminating device 10 starts operating, as described above, a first electrode plate 2, a first spacer 3a, a second electrode plate 4, and a second spacer 3b can be wound around the mandrel unit 600.

[0085] At this point, after an electrode assembly 1 is formed around the chuck unit 600 to have a certain size, the operation of the chuck unit 600 can be suspended, and the first cutting unit 100c and the second unit cutter can be operated to cut the first electrode plate 2 and the second electrode plate 4. Since the operation of the second cutting unit is similar or identical to the operation of the first cutting unit 100c, a detailed description of the second cutting unit cut will be omitted.

[0086] If the first linear drive unit 130c is operated, the first linear motion unit 110c can be moved linearly. Then, the first rotary axis 121c, the first unit 160c rotary gear, and the first blade 122c can be moved linearly according to the movement of the first unit 110c in linear motion. Particularly, the first rotary reducer 160c can be rotated while being linearly moved in the first drive gear drive 150c.

[0087] If the first rotary reducer 160c is rotated, as described above, the first rotation axis 121c and the first blade 122c may also be rotated. At this time, the first blade 122c can cut a first surface 2a of the first electrode plate 2 while being rotated, as described above. Furthermore, since the first surface of the first electrode plate 2 is pressed as the first blade is moved 122c, a second surface 2b of the first electrode plate 2 can be cut by the first linear cutter 170c. Particularly, since the first blades 122c and 170c of the first linear cutter are staggered, the first and second surfaces 2a and 2b of the first electrode plate 2 can be cut by the first blades 122c and 170c of the first cutter, respectively.

[0088] When the first blade 122c is moved linearly by being rotated as described above, pressing the first part 124c can press the first blade 122c so that a uniform force can be applied from the first blade 122c to the first surface 2a of the first electrode plate 2. Therefore, the first blade 122c can cut the first surface 2a of the first electrode plate 2 with a constant force.

[0089] During the processes described above, the second cutting unit can cut the second electrode plate 4. Since the operation of the second cutting unit is similar or identical to the operation of the first cutting unit 100a, a description in detail of the same will be omitted.

[0090] When or after the first electrode plate 2 and the second electrode plate 4 are/will be cut, the chuck unit 600 can be rotated again to completely fabricate the electrode assembly 1.

[0091] According to the laminating device 10 and the laminating method for a secondary battery, since a first electrode plate 2 and a second electrode plate 4 are respectively cut by the first cutter 120a and the second cutter, the first plate electrode plate 2 and the second electrode plate 4 cannot be damaged.

[0092] Furthermore, according to the laminating device 10 and the laminating method, once the first electrode plate 2 and the second electrode plate 4 are smoothly cut, the first electrode plate 2 and the second plate electrode 4 cannot be separated, or burrs cannot be formed on the first electrode plate 2 and the second electrode plate 4.

[0093] In addition, according to the laminating device 10 and the laminating method, as long as the generation of contaminants is avoided when the first electrode plate 2 and the second electrode plate 4 are cut, the stability of the assembly of the electrode 1 can be guaranteed.

[0094] As described above, according to one or more of the above exemplary embodiments, an electrode plate or a separator can be precisely cut.

[0095] It should be understood that exemplary embodiments described herein are to be considered in a descriptive sense and not for purposes of limitation. Descriptions of features or aspects within each exemplary embodiment should typically be considered as available for other similar features or features in other exemplary embodiments.

[0096] While one or more exemplary embodiments have been described with reference to the figures, it should be understood by those skilled in the art that various changes in form and detail may be made without departing from the spirit and scope as defined by the following claims.

Claims (19)

1. Lamination device (10) for a secondary battery, the laminating device (10) comprising: a roll of electrode plate (200, 300) configured to wrap an electrode plate (2, 4) around it and unrolling the electrode plate (2, 4) therefrom; a separator roll (400, 500) configured to wrap a separator (3) around it and unwind the separator (3) therefrom; an affixing roller (700, 800) configured to affix the electrode plate (2, 4) and spacer (3) to each other; a mandrel unit (600) around which the electrode plate (2, 4) and spacer (3) supplied from the affix roll (700, 800) are wound; and a cutting unit (100a, 100c) arranged between the electrode plate roll (200, 300) and the mandrel unit (600) for cutting the electrode plate (2, 4) supplied from the electrode plate roll. electrode (200, 300) to the mandrel unit (600) by a slot cutting method using linear motion, characterized in that the cutting unit (100a, 100c) comprises: a linear motion unit (110a, 110c ) configured to be moved linearly; and a cutter (120a, 120c) rotatably coupled to the linear motion unit (110a, 110c) so as to cut the electrode plate (2, 4) while being rotated when the linear motion unit (110a, 110c) is moved linearly. 2. Lamination device (10) according to claim 1, characterized in that the cutting unit (100a, 100c) additionally comprises a linear drive unit (130a, 130c) connected to the linear motion unit (110a, 110a, 110c) to linearly move the linear motion unit (110a, 110c). 3. Lamination device (10) according to claim 1, characterized in that at least one of both sides of the cutter (120a, 120c) can be tapered. 4. Lamination device (10) according to claim 1, characterized in that the cutter (120a) additionally comprises: a first upper cutter (120a-1) rotatably coupled to the linear motion unit (110a) of so as to cut a first surface (2a) of the electrode plate (2) while being rotated when the linear motion unit (110a) is moved linearly; and a first lower cutter (120a-2) rotatably coupled to the linear motion unit (110a) in a position facing the first upper cutter (120a-1) so as to cut a second surface (2b) of the electrode plate ( 2) which is different from the first surface (2a) of the electrode plate (2). 5. Lamination device (10) according to claim 4, characterized in that a portion of the first lower cutter (120a-2) that makes contact with the second surface (2b) of the electrode plate (2) is flat . 6. Lamination device (10) according to claim 4, characterized in that the first upper cutter (120a-1) and the first lower cutter (120a-2) are staggered. 7. Lamination device (10) according to claim 4, characterized in that at least portions of the first upper cutter (120a-1) and the first lower cutter (120a-2) overlap. 8. Lamination device (10) according to claim 4, characterized in that the first upper cutter (120a-1) and the first lower cutter (120a-2) are rotated towards the electrode plate (2) when the electrode plate (2) approaches the first upper cutter (120a-1) and the first lower cutter (120a-2). 9. Laminating device (10) according to claim 1, characterized in that the cutting unit (100a, 100c) additionally comprises a support (140a, 140c), and the support (140a, 140c) comprises a hole penetration (141a, 141c) through which the electrode plate (2) passes. 10. Laminating device (10) according to claim 9, characterized in that the cutting unit (100a, 100c) additionally comprises: a guide gear unit (150a, 150c) arranged on the support (140a, 140c) ; and a rotating gear unit (160a, 160c) attached to the cutter (120a, 120c) and connected to the guide gear unit (150a, 150c), wherein when the linear motion unit (110a, 110c) is moved, the unit The rotating gear unit (160a, 160c) is moved in the guide gear unit (150a, 150c) while rotated so as to rotate the cutter (120a, 120c). 11. Laminating device (10) according to claim 10, characterized in that the cutter (120a, 120c) comprises: a rotating shaft (121a-1, 121a-2, 121c) connected to the rotating gear unit ( 160a, 160c) and rotatably inserted into the linear motion unit (110a, 110c); and a blade (122a-1, 122a-2, 122c) connected to the rotating shaft (121a-1, 121a-2, 121c) so as to be rotated together with the rotating gear unit (160a, 160c). 12. Lamination device (10) according to claim 11, characterized in that the cutter (120a, 120c) additionally comprises a cutter support (123a-1, 123a-2, 123c) fixing the blade (122a- 1, 122a-2, 122c) to the rotary axis (121a-1, 121a-2, 121c). 13. Laminating device (10) according to claim 11, characterized in that the cutter (120a, 120c) additionally comprises a pressing part (124a-1, 124a-2, 124c) pressing the blade (122a- 1, 122a-2, 122c) towards the electrode plate (2). 14. Lamination device (10) according to claim 1, characterized in that the cutting unit (100c) comprises: a linear motion unit (110c) configured to be linearly moved; a cutter (120c) rotatably coupled to the linear motion unit (110c) so as to cut a first surface (2a) of the electrode plate (2) while being rotated when the linear motion unit (110c) is linearly moved; and a linear cutter (170c) facing the cutter (120c) so as to cut a second surface (2b) of the electrode plate (2) which is different from the first surface (2a) of the electrode plate (2). 15. Lamination method for a secondary battery, the laminating method characterized in that it comprises: unrolling a first electrode plate (2) from a first electrode plate roll (200) and a first separator (3a) from a first separator roll (400); affixing the first separator (3a) to the first electrode plate (2) by pressing the first electrode plate (2) and the first separator (3a) using first affixing rollers (700); winding the first electrode plate (2, 4), to which the first separator (3a) is affixed, through the use of a mandrel unit (600); and if the chuck unit (600) stops, cutting the first electrode plate (2, 4) by a slot cutting method using a laminating device (10) as defined in any one of claims 1 to 14. 16. Lamination method as claimed in claim 15, characterized in that the mandrel unit (600) winds the first electrode plate (2, 4) and the first separator (3a) in a roll type. Lamination method according to claim 15, characterized in that it additionally comprises winding a second electrode plate (4) and a second separator (3b) around the mandrel unit (600) by unwinding the second electrode plate (600). electrode (4) from a second electrode plate roll (300) and the second separator (3b) from a second separator roll (300) and supply the second electrode plate (4) and the second separator (3b) to the chuck unit (600). 18. Lamination method according to claim 17, characterized in that the first electrode plate (2), the first separator (3a), the second electrode plate (4), and the second separator (3b) are stacked. Lamination method according to claim 17, characterized in that it additionally comprises cutting the second electrode plate (4) through a slot cutting method when the mandrel unit (600) stops.

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