JP5561191B2 - Electrode laminate manufacturing apparatus and manufacturing method - Google Patents

Description

  The present invention relates to an electrode laminate manufacturing apparatus and manufacturing method.

  As an electrode laminate manufacturing apparatus and manufacturing method, for example, Patent Document 1 discloses a secondary battery manufacturing apparatus and manufacturing method. In this prior art, in order to improve the productivity of the lithium secondary battery, electrodes composed of a plurality of positive electrodes and negative electrodes are arranged on a continuous separator (separator sheet) while maintaining a predetermined interval for each electrode. The other continuous separator is superposed on the continuous separator on which the electrodes are arranged, the continuous separators around the electrodes are welded together, and the electrodes are folded so that the positive and negative electrodes are alternately overlapped via the continuous separator. A means for manufacturing a laminate is employed.

JP 2009-9919 A

  In the above-described prior art, if there is a defective state such as misalignment between the electrode and the separator sheet, all the electrode laminates for one set that is folded and folded, for example, 100 layers if the capacity is increased It becomes a defective product. For this reason, in the prior art, in order to accurately arrange the electrodes one by one on the separator sheet using the transfer device, a means for intermittently feeding the separator sheet is adopted. There is a problem that it is difficult to improve the production speed.

  This invention is made | formed in view of the said problem, and provides the manufacturing apparatus and manufacturing method of an electrode laminated body which can aim at the improvement of a production rate.

In order to solve the above-described problems, the present invention provides a conveyor device that supports one surface of an electrode and conveys the electrode at an interval in the longitudinal direction, and a first roll that is synchronized with the conveyance. A first sticking device for sticking the other surface of the electrode to the first separator sheet extended in the longitudinal direction and separating the one surface from the conveyor device, and a second roll in synchronization with the transport. And a second sticking device for sticking the second separator sheet fed out in the longitudinal direction to the first separator sheet from one surface side of the electrode spaced apart from the conveyor device. Adopt manufacturing equipment.
By adopting this configuration, in the present invention, since the first separator sheet is fed out from the first roll in synchronization with the conveyance of the electrodes, it is possible to perform continuous pasting without stopping the conveyance of the electrodes. . In addition, after the electrode is attached to the first separator sheet, the electrode is separated from the conveyor device, and the second separator sheet fed out from the second roll is also attached from the separated surface side in synchronization with the conveyance of the electrode. By attaching, continuous attachment can be performed without stopping the conveyance of the electrodes. Thereby, pinching by the separator sheet of an electrode can be made continuous.

Moreover, in this invention, before affixing on the other surface of the said electrode to the said 1st separator sheet, it has the adhesive agent supply apparatus which supplies an adhesive agent to at least one part of the other surface of the said electrode. Is adopted.
By adopting this configuration, in the present invention, by supplying an adhesive to at least a part of the other surface of the electrode, it is possible to reliably attach the electrode to the first separator sheet and from the conveyor device. It is possible to prevent positional deviation between the electrode after separation and the first separator sheet.

Further, in the present invention, after the second separator sheet is attached to the first separator sheet, the second separator sheet is cut together with the first separator sheet at the intervals for each electrode. A configuration is adopted in which a cell forming apparatus for forming a cell in which the electrode is sandwiched between separators is employed.
By adopting this configuration, in the present invention, after bonding two separator sheets, by cutting for each electrode, it is possible to remove only a part in which a defective state such as misalignment has occurred. Can be improved.

Moreover, in this invention, the structure of having the lamination apparatus which laminates | stacks alternately the said cell and the 2nd electrode from which the said electrode differs in polarity is employ | adopted.
By adopting this configuration, in the present invention, the electrode and the second electrode are stacked by alternately laminating the cell in which the electrode (for example, the positive electrode) is sandwiched between the separators and the second electrode (for example, the negative electrode) having different polarities. The electrodes can be alternately stacked via a single separator.

  Moreover, in this invention, while supporting the one surface of an electrode and conveying the said electrode by a conveyor apparatus at intervals in a longitudinal direction, it synchronizes with the said conveyance from a 1st roll, and it is said longitudinal direction. A first pasting step of pasting the other surface of the electrode to the first separator sheet that has been fed out and separating the one surface from the conveyor device, and the longitudinal direction in synchronism with the transport from a second roll. A second pasting step of pasting the second separator sheet fed out in the direction to the first separator sheet from one surface side of the electrode spaced apart from the conveyor device. adopt.

According to the present invention, a conveyor device that supports one surface of the electrode and conveys the electrode at a distance in the longitudinal direction, and a first roll that is fed out from the first roll in the longitudinal direction in synchronization with the conveyance. The other surface of the electrode was affixed to the separator sheet, and the first surface was separated from the conveyor device and the first surface was fed out from the second roll in the longitudinal direction in synchronization with the conveyance. By adopting an apparatus for producing an electrode laminate having a second separator sheet and a second sticking device for sticking the second separator sheet to the first separator sheet from one surface side of the electrode separated from the conveyor device The sandwiching of the electrode by the separator sheet can be continuous.
Therefore, in the present invention, the production rate of the electrode laminate can be improved.

It is a block diagram which shows the electrode lamination apparatus in embodiment of this invention. It is a top view which shows the positive electrode cut out with the cutter apparatus in embodiment of this invention. It is a block diagram which shows another line of the electrode lamination apparatus in embodiment of this invention. It is a top view which shows the negative electrode cut out with the cutter apparatus in embodiment of this invention. It is a block diagram which shows another line of the electrode lamination apparatus in another embodiment of this invention.

  Embodiments of the present invention will be described below with reference to the drawings. In addition, in the following description, the case where the manufacturing apparatus and manufacturing method of the electrode laminated body of this invention are applied to the electrode laminated apparatus which manufactures a lithium secondary battery is illustrated.

FIG. 1 is a configuration diagram illustrating an electrode stacking apparatus 1 according to an embodiment of the present invention.
The electrode stacking apparatus 1 includes a positive electrode roll 2 that feeds out the positive electrode sheet PS, and a cutter apparatus 3 that cuts out the positive electrode (electrode) P from the positive electrode sheet PS that is fed out from the positive electrode roll 2. Further, a transport roller pair 4 is provided between the positive electrode roll 2 and the cutter device 3. A guide 5 and a nip roller 6 are provided on the downstream side of the cutter device 3.

  The positive electrode roll 2 has a configuration in which a positive electrode sheet PS of, for example, a metal foil having a thickness of about 8 to 20 μm, on which lithium-containing metal oxide is printed (attached) as an active material, is provided. The positive electrode sheet PS is formed by using, for example, an aluminum foil as a base material and arranging a powdery lithium-containing metal oxide on the surface of the base material. The positive electrode sheet PS fed from the positive electrode roll 2 is cut by the cutter device 3.

FIG. 2 is a plan view showing the positive electrode P cut out by the cutter device 3 in the embodiment of the present invention. In addition, the dashed-dotted line in FIG. 2 shows a cut line.
The cutter device 3 cuts off a part of one end in the width direction of the positive electrode sheet PS along the cut line C1 to form a tab P1. The cut piece P2 falls on the tray 7 shown in FIG. The cutter device 3 cuts the positive electrode sheet PS along the cut line C2, and separates the positive electrode P in the longitudinal direction. The size of the positive electrode P is approximately A4 size.

  Returning to FIG. 1, the electrode stacking apparatus 1 sandwiches the cut out positive electrode P with the nip roller 6 at one end portion 10 a in the longitudinal direction (left and right direction in FIG. 1) and from the one end portion 10 a in the longitudinal direction to the other. It has the conveyor apparatus 10 which conveys the positive electrode P to the edge part 10b. The conveyor apparatus 10 is comprised from the belt conveyor which endlessly rolls in a longitudinal direction. The conveyor device 10 has a support surface 11 that supports the lower surface (one surface) of the positive electrode P, and conveys the positive electrode P at a predetermined speed with an interval in the longitudinal direction (conveying step).

  An inspection camera 12 and an adhesive supply device 13 are provided in the middle of the conveyance path by the conveyor device 10. The inspection camera 12 is configured to take an image of the positive electrode P supported by the support surface 11 of the conveyor device 10 from above and transmit data acquired by the imaging to a control device (not shown). In a control device (not shown), the imaging data is subjected to image processing, and the posture and shape of the positive electrode P, the active material peeling, and the presence or absence of a defective state such as a hole are inspected.

  The adhesive supply device 13 is configured to supply the adhesive to at least a part of the upper surface (the other surface) of the positive electrode P before the positive electrode P reaches the other end portion 10b in the longitudinal direction of the conveyor device 10. . The adhesive supply device 13 of the present embodiment includes a dispenser 14 that drops an adhesive having a predetermined viscosity from above on the positive electrode P supported by the support surface 11 of the conveyor device 10. The dispenser 14 drops an adhesive on the four corners of the upper surface of the positive electrode P from which at least the tab P1 is removed.

  The electrode laminating apparatus 1 attaches the upper surface of the positive electrode P to the first separator sheet SS1 fed out in the longitudinal direction in synchronization with the conveyance of the conveyor device 10 and separates the lower surface of the positive electrode P from the conveyor device 10. It has the sticking apparatus 20 (1st sticking process). The first sticking device 20 includes a first separator roll 21 that feeds the first separator sheet SS1 and a pressing roller 22 that presses the fed first separator sheet SS1 against the upper surface side of the positive electrode P.

  The first separator roll 21 is configured to feed out a first separator sheet SS1 made of an insulating resin material having a thickness of about 8 to 25 μm, for example. The first separator sheet SS1 is made of, for example, porous polyethylene or polyester. The pressing roller 22 is configured to sandwich the first separator sheet SS1 and the positive electrode P between the other end portion 10b of the conveyor device 10 in the longitudinal direction.

  The first separator roll 21 and the pressing roller 22 are rotationally driven in synchronization with the conveyance of the positive electrode P in the conveyor device 10 under the control of a control device (not shown). As a result, at the other end portion 10b in the longitudinal direction of the conveyor device 10, the relative speed difference between the first separator sheet SS1 and the positive electrode P is zero or almost eliminated, and the relative positional deviation does not occur. The upper surface of the positive electrode P is continuously pressed against the separator sheet SS1 without stopping the conveyance.

  Since the adhesive is dropped on the upper surface of the positive electrode P, the positive electrode P can be attached to the first separator sheet SS1 side by the pressing. When the first separator sheet SS <b> 1 is conveyed downstream from the other end portion 10 b in the longitudinal direction of the conveyor device 10, the lower surface of the positive electrode P is separated from the support surface 11 of the conveyor device 10. The separated first separator sheet SS1 and the lower surface side of the positive electrode P are supported by the air float device 23 in a non-contact manner.

  The electrode laminating apparatus 1 attaches the second separator sheet SS2 fed out in the longitudinal direction in synchronization with the conveyance of the conveyor apparatus 10 to the first separator sheet SS1 from the lower surface side of the positive electrode P separated from the conveyor apparatus 10. Two pasting devices 30 (second pasting step). The second sticking device 30 includes a second separator roll 31 that feeds the second separator sheet SS2, and a transport roller that sandwiches the fed second separator sheet SS2 together with the first separator sheet SS1 to which the positive electrode P is stuck. And a pair 32.

  The second separator roll 31 feeds out the second separator sheet SS2 having substantially the same configuration as the first separator sheet SS1. Note that an adhesive is applied to the surface of the second separator sheet SS2, and the adhesive is melted by heating by the heating and melting fixing device 33 disposed on the downstream side, so that the first separator sheet SS1 and the first separator sheet SS2 2 separator sheet SS2 is welded.

  The second separator roll 31 and the conveying roller pair 32 are synchronized with the conveyance of the positive electrode P in the conveyor device 10 under the control of a control device (not shown), that is, synchronized with the feeding of the first separator sheet SS1. Rotating drive. Thereby, between the conveyance roller pair 32, the relative speed difference between the second separator sheet SS2 and the first separator sheet SS1 and the positive electrode P is zero or almost eliminated, and relative displacement is not caused. The second separator sheet SS2 is continuously pasted to the first separator sheet SS1 from the lower surface side of the positive electrode P separated from the conveyor device 10 without stopping the conveyance.

  Inspection cameras 34 and 35 and a nip roller 36 are provided between the conveying roller pair 32 and the heating and melting fixing device 33. The inspection camera 34 is configured to image the first separator sheet SS1 from above and transmit data acquired by the imaging to a control device (not shown). The inspection camera 35 is configured to image the second separator sheet SS2 from below and transmit data acquired by the imaging to a control device (not shown). In a control device (not shown), the imaged data is subjected to image processing, and the presence or absence of a defective state such as a crease, wrinkle, or defect (pinhole or tear) of the first separator sheet SS1 and the second separator sheet SS2 is inspected.

  On the downstream side of the inspection cameras 34 and 35, the first separator sheet SS1 and the second separator sheet SS2 bonded together with the positive electrode P interposed therebetween are sandwiched between the nip roller 36 at one end portion 37a in the longitudinal direction. The conveyor device 37 has an endlessly rolling belt from one end portion 37a to the other end portion 37b. A heating and melting and fixing device 33 is provided in the middle of the conveying path by the conveyor device 37. The heat-melt fixing device 33 melts the adhesive applied to the surface of the second separator sheet SS2 by heating, and welds the first separator sheet SS1 and the second separator sheet SS2.

  After the first separator sheet SS1 and the second separator sheet SS2 are attached to the downstream side of the heat-melting / fixing device 33, the second separator together with the first separator sheet SS1 is spaced at each interval between the positive electrodes P. A cutter device (cell forming device) 40 that cuts the sheet SS2 and forms a cell C in which the positive electrode P is sandwiched between the separators S is provided. The cutter device 40 includes a heat cutter that burns out the second separator sheet SS2 together with the first separator sheet SS1. The cell C formed by the cutting of the cutter device 40 is conveyed downstream by the conveyor device 37.

  A transfer device 50 is provided on the downstream side of the cutter device 40. The transfer device 50 has a suction hand capable of sucking and holding the cell C. Under the control of a control device (not shown), the transfer device 50 transfers and stocks the cells C that have cleared the inspection in the inspection cameras 12, 34, and 35 to the tray 42 through the path 41, while the inspection cameras 12, The cell C determined to be defective by the inspections 34 and 35 is discarded through the path 43. In this way, by cutting the first separator sheet SS1 and the second separator sheet SS2 after being bonded together and forming the cells C, only a part where a defective state such as misalignment has occurred can be removed. Therefore, the yield can be improved.

FIG. 3 is a configuration diagram showing another line of the electrode stacking apparatus 1 according to the embodiment of the present invention.
The electrode laminating apparatus 1 includes a negative electrode roll 52 that feeds out the negative electrode sheet NS, and a cutter device 53 that cuts out the negative electrode (electrode) N from the negative electrode sheet NS fed out of the negative electrode roll 52. Further, a conveyance roller pair 54 is provided between the negative electrode roll 52 and the cutter device 53. A guide 55 and a nip roller 56 are provided on the downstream side of the cutter device 53.

  The negative electrode roll 52 has a configuration in which a negative electrode sheet NS of, for example, a metal foil having a thickness of about 8 to 20 μm, on which carbon materials are printed (attached) as active materials, is provided. The negative electrode sheet NS is formed by, for example, using copper foil as a base material and arranging powdery carbon on the surface of the base material. The negative electrode sheet NS fed from the negative electrode roll 52 is cut by the cutter device 53.

FIG. 4 is a plan view showing the negative electrode N cut out by the cutter device 53 according to the embodiment of the present invention. In addition, the dashed-dotted line in FIG. 4 shows a cut line.
The cutter device 53 cuts off part of one end in the width direction of the negative electrode sheet NS along the cut line C3 to form a tab N1. The cut piece N2 falls on the tray 57 shown in FIG. The cutter device 53 cuts the negative electrode sheet NS along the cut line C4, and separates the negative electrode N in the longitudinal direction. The size of the negative electrode N is approximately A4 size like the positive electrode P.

  Returning to FIG. 3, the electrode stacking apparatus 1 sandwiches the cut negative electrode N with the nip roller 56 at one end 60 a in the longitudinal direction, and the belt rotates endlessly from the one end 60 a to the other end 60 b in the longitudinal direction. It has a moving conveyor device 60. The conveyor device 10 has a support surface 61 that supports the lower surface (one surface) of the negative electrode N, and conveys the negative electrode N at a predetermined speed with an interval in the longitudinal direction.

  An inspection camera 62, an adhesive supply device 63, and a transfer device 65 are provided in the middle of the conveyance path by the conveyor device 60. The inspection camera 62 is configured to take an image of the negative electrode N supported on the support surface 61 of the conveyor device 60 from above and transmit data acquired by the imaging to a control device (not shown). In a control device (not shown), the imaging data is subjected to image processing, and the posture and shape of the negative electrode N, the active material peeling, and the presence or absence of a defective state such as a hole are inspected.

  The adhesive supply device 63 is configured to supply the adhesive to at least a part of the upper surface of the negative electrode N. The adhesive supply device 63 of this embodiment has a dispenser 64 that drops an adhesive having a predetermined viscosity from above on the negative electrode N supported on the support surface 61 of the conveyor device 60. The dispenser 64 drops an adhesive on the four corners of the upper surface of the negative electrode N from which at least the tab N1 is removed.

  Under the control of a control device (not shown), the transfer device 65 presses the cell C stocked on the tray 42 onto the negative electrode N that has been inspected by the inspection camera 62, adheres them together, and passes the tray 67 through the path 66. The cell C and the negative electrode N are alternately stacked. Thereby, the positive electrode P and the negative electrode N can be alternately overlapped with one separator S interposed therebetween. In addition, the negative electrode N determined to be in a defective state by the inspection by the inspection camera 62 falls from the other end portion 60b in the length direction of the conveyor device 60 and is discarded.

Then, this superposition is repeated, and the separator S, the positive electrode P, the separator S, and the negative electrode N are set as one set, and a plurality of the sets (for example, about 100 sets) are stacked, so that the positive electrode P and the negative electrode N It is possible to form an electrode laminate in which the separator S is laminated with the separator S interposed therebetween.
Thereafter, the tray 67 on which the electrode stack is placed is moved to another place, and a predetermined process is performed. Specifically, tabs (not shown) of the positive electrode P and the negative electrode N are welded, the electrode laminate is put into a laminate film made of, for example, aluminum, an electrolytic solution is injected, and the electrode laminate is impregnated. Thereafter, the laminate type battery cell is obtained by sealing and sealing.

Therefore, according to the above-described embodiment, the conveyor device 10 that supports the lower surface of the positive electrode P and conveys the positive electrode P at an interval in the longitudinal direction, and the first separator roll 21 synchronizes with the conveyance. The upper surface of the positive electrode P is attached to the first separator sheet SS1 fed out in the longitudinal direction, and the lower surface is separated from the conveyor device 10, and the second separator roll 31 is synchronized with the conveyance. The second separator sheet SS2 fed out in the longitudinal direction is attached to the first separator sheet from the lower surface side of the positive electrode P separated from the conveyor device 10, and the electrode laminating apparatus 1 is provided. By adopting, the sandwiching of the positive electrode P by the separator sheet can be made continuous.
Therefore, in this embodiment, the production rate of the electrode laminate can be improved.

  As mentioned above, although preferred embodiment of this invention was described referring drawings, this invention is not limited to the said embodiment. Various shapes, combinations, and the like of the constituent members shown in the above-described embodiments are examples, and various modifications can be made based on design requirements and the like without departing from the gist of the present invention.

  For example, in the above-described embodiment, the configuration in which the positive electrode P is sandwiched between the first separator sheet SS1 and the second separator sheet SS2 has been described, but the configuration in which the negative electrode N is sandwiched may be employed.

  Further, for example, the cells C may not be stacked on the tray 42, but may be transported one by one by a conveyor device (not shown) and moved to the access range of the transfer device 65, or the transfer device 50 and the transfer device 65 may be May be arranged as the same device.

  Further, for example, as in another embodiment shown in FIG. 5, the cell is dropped by placing the tray 42 above the support surface 61 of the conveyor device 60 and dropping the cells C stocked in the tray 42 one by one from the bottom. A device 70 may be provided. The cell dropping device 70 has a claw that supports the lower surface of the cell C, and the claw is opened to the left and right at the bottom, so that the cell C is dropped onto the negative electrode N supported by the support surface 61. According to this configuration, the line in which the positive electrode P is sandwiched between the separator sheets and the line in which the cell C formed by the line and the negative electrode N are overlapped can be operated in series instead of in parallel as in the above embodiment. it can.

  DESCRIPTION OF SYMBOLS 1 ... Electrode laminated apparatus (electrode laminated body manufacturing apparatus), C ... Cell, N ... Negative electrode (second electrode), P ... Positive electrode (electrode), S ... Separator, 10 ... Conveyor device, 13 ... Adhesive supply device , 20 ... first sticking device, 21 ... first separator roll (first roll), 30 ... second sticking device, 31 ... second separator roll (second roll), 40 ... cutter device ( Cell forming apparatus), SS1 ... first separator sheet, SS2 ... second separator sheet

Claims (5)

A conveyor device that supports one surface of the electrode and conveys the electrode at an interval in the longitudinal direction;
The 1st sticking apparatus which sticks the other surface of the said electrode to the 1st separator sheet extended | stretched to the said longitudinal direction synchronizing with the said conveyance from a 1st roll, and separates said one surface from the said conveyor apparatus. When,
A second separator sheet that is fed out from the second roll in the longitudinal direction in synchronization with the conveyance is attached to the first separator sheet from one surface side of the electrode that is separated from the conveyor device. An electrode laminate manufacturing apparatus, comprising: a sticking device.   2. The adhesive supply device for supplying an adhesive to at least a part of the other surface of the electrode before being attached to the other surface of the electrode on the first separator sheet. The manufacturing apparatus of the electrode laminated body of description.   After affixing the second separator sheet to the first separator sheet, the second separator sheet is cut together with the first separator sheet at the interval for each electrode, and the electrode is sandwiched between the separators The apparatus for producing an electrode laminate according to claim 1, further comprising a cell forming apparatus that forms a formed cell.   The apparatus for manufacturing an electrode laminate according to claim 3, further comprising: a laminate device that alternately laminates the cells and second electrodes having different polarities from the electrodes. A conveying step of supporting one surface of the electrode and conveying the electrode by a conveyor device at intervals in the longitudinal direction;
The 1st sticking process of sticking the other side of the electrode on the 1st separator sheet drawn out in the longitudinal direction synchronizing with the conveyance from the 1st roll, and separating the one side from the conveyor device When,
A second separator sheet that is fed out from the second roll in the longitudinal direction in synchronization with the conveyance is attached to the first separator sheet from one surface side of the electrode that is separated from the conveyor device. A method for producing an electrode laminate, comprising: an attaching step.

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