JP6642072B2 - Secondary battery manufacturing apparatus and secondary battery manufacturing method - Google Patents

Description

  The present invention relates to a secondary battery manufacturing apparatus and a secondary battery manufacturing method, and more specifically, is manufactured through a process of laminating an electrode plate having separators disposed on both main surfaces and electrode plates having different polarities. The present invention relates to a secondary battery manufacturing apparatus and a secondary battery manufacturing method.

  In a stacked battery, for example, a plurality of negative electrode plates and a positive electrode plate (electrode foil coated with an electrode material such as an active material) are alternately stacked via a separator, and an electrode plate group is disposed inside an exterior body together with an electrolyte. It is configured to house.

  As a method of laminating a separator between the negative electrode plate and the positive electrode plate, there is a method of alternately laminating the negative electrode plate and the positive electrode plate in a state where a bag-shaped separator is mounted on the positive electrode plate or the negative electrode plate.

Patent Literature 1 discloses a method of stacking electrodes using an electrode stacking device as described below.
That is, as shown in FIGS. 5A and 5B, the electrode plate laminating apparatus 100 of Patent Literature 1 includes a positive electrode plate P packaged with a separator and a negative electrode plate N in a bare state on a loading stage. An apparatus used for stacking (stacking) on the apparatus 420, a rotating shaft 110 as an apparatus main body vertically erected at the center of the apparatus, and a first transfer arm 120 provided on a peripheral surface of the rotating shaft 110. And a second transfer arm 130.

  Further, in the electrode plate laminating apparatus of Patent Document 1, as shown in FIGS. 5A and 5B, a positive electrode plate P and a negative electrode plate N in a bare state are held by a separator. In the case and when loading, the height positions of the first transfer arm 120 and the second transfer arm 130 are individually controlled.

  Further, in claim 12 of Patent Document 1, when a predetermined number of works are stacked, after transferring the electrode plate stacking group including the predetermined number of works to another process, the first transfer arm or the second It is described that the transfer arm starts loading on the loading stage from an electrode plate having the same polarity as the uppermost electrode plate in the electrode plate stacking group.

  By doing so, the uppermost layer and the lowermost layer can successively form the same electrode plate stacking group (battery cell), and a battery comprising each electrode plate stacking group (battery cell) is manufactured in a later step. (See paragraph 0019 of Patent Document 1).

JP 2012-174389 A

  However, in the above conventional method, there is no problem when the uppermost layer and the lowermost layer of the electrode plate stacking group are a positive electrode individually mounted with a separator, but a naked negative electrode not wrapped by a separator has an uppermost layer and a lowermost layer, That is, in the case of the outermost layer, there is a problem that dents due to contact and attachment or mixing of foreign matter (contamination) are liable to occur when the material is transported to a subsequent process and processed.

  Also, if a separator for protecting the negative electrode of the outermost layer (outermost layer separator) is to be laminated on the outermost side of the laminated body of the electrode plates, a separator supply unit for supplying the outermost layer separator is separately required. In addition to the increase in equipment cost, there is a problem that the amount of separator used also increases.

  The present invention has been made to solve the above problems, and does not cause deterioration of characteristics due to the outermost layer being an electrode plate not wrapped by a separator, and suppresses the amount of the separator used, thereby efficiently. It is an object to provide a secondary battery manufacturing apparatus and a secondary battery manufacturing method capable of manufacturing a secondary battery.

In order to solve the above problems, a secondary battery manufacturing apparatus of the present invention includes:
A first electrode plate and a second electrode plate having a different polarity from the first electrode plate are laminated via a separator, and an outermost layer separator is provided as an outermost layer in the laminating direction. Manufacturing apparatus for a secondary battery having a structure
A first strip separator supply unit that draws out and supplies the first strip separator from the roll;
A first band-shaped separator disposed downstream of the first band-shaped separator supply unit, for inspecting a predetermined region of the first band-shaped separator, and determining whether the predetermined region is good, good, acceptable, or not; An inspection unit;
A second belt-like separator supply unit that draws out and supplies the second belt-like separator from the roll,
A second strip separator that is arranged downstream of the second strip separator supply unit and inspects a predetermined area of the second strip separator to determine whether the predetermined area is good, good, or bad. An inspection unit;
A cutting unit that is disposed downstream of the first and second band-shaped separator inspection units and cuts the first and second band-shaped separators in a state of being overlapped with each other for each predetermined region;
The inspection result by the first band-like separator inspection unit is good, the predetermined region serving as the first separator of the first band-like separator, and the inspection result by the second band-like separator inspection unit are good. A first electrode plate supply unit that supplies a first electrode plate between the predetermined regions of the second band-shaped separator to be a second separator;
The first electrode is formed by joining predetermined portions of the first and second strip-shaped separators, which are disposed above and below the first electrode plate, and serve as the first and second separators, in the predetermined region. A separator joining portion, wherein a plate forms a package body packaged by the first and second separators;
In the set of the predetermined regions serving as the first and second separators, which are cut in a state of being overlapped with each other, the relationship between the inspection results in the first and second belt-like separator inspection units is good and good. , Good and good, good and good, and good and good, and the predetermined area constituting a set not including the bad, the outermost layer separator storage unit to store as the outermost layer separator,
A discard unit that discards a set including at least one of the sets of the first and second separators cut for each of the predetermined areas in a state where they are overlapped with each other and the test result of which is not possible;
A second electrode plate supply unit for supplying a second electrode plate having a different polarity from the first electrode plate;
The outermost layer separator, a package body in which the first electrode plate is wrapped by the first and second separators, and a lamination portion for laminating a second electrode plate having a different polarity from the first electrode plate. It is characterized by having.

  In the apparatus for manufacturing a secondary battery according to the aspect of the invention, it is preferable that the cutting portion is disposed downstream of the separator joining portion.

  The first electrode plate is cut at a predetermined position of each predetermined region serving as the first and second separators at the separator bonding portion, and then cut, so that the individual pieces of the package body in which the first electrode plate is wrapped by the first and second separators are cut. Can be reliably obtained.

  Further, it is preferable that the separator joining portion has a heating means for partially heating and welding the predetermined region serving as the first and second separators.

  With the above configuration, the first and second separators can be easily and reliably welded, and the present invention can be further effectively demonstrated.

  Further, the relationship between the inspection results in the first and second belt-like separator inspection sections is any of good and good, good and good, good and good, and good and good, and It is preferable that the predetermined region to be configured is configured to be directly conveyed to the laminating section as the outermost layer separator and provided for lamination.

  With the above configuration, the load on the outermost layer separator storage unit that stores the outermost layer separator can be reduced, equipment costs can be reduced, and a secondary battery can be manufactured efficiently.

Further, the method for manufacturing a secondary battery of the present invention includes:
A first electrode plate and a second electrode plate having a different polarity from the first electrode plate are laminated via a separator, and an outermost layer separator is provided as an outermost layer in the laminating direction. A method for manufacturing a secondary battery having a bent structure,
The outermost layer separator, a package in which the first electrode plate is packaged by the two separators, and a laminating step of laminating a second electrode plate having a different polarity from the first electrode plate,
The pass / fail of the predetermined area of the belt-like separator drawn from the roll is determined in three stages of pass, pass, and fail.
The two predetermined regions where the result of the determination is good are selected into two separators, and the predetermined region where the result of the determination is either good or good is selected as the outermost layer separator, The predetermined area where the result is not possible is selected as a separator to be discarded .

Further, another method of manufacturing a secondary battery according to the present invention includes:
A first electrode plate and a second electrode plate having a different polarity from the first electrode plate are laminated via a separator, and an outermost layer separator is provided as an outermost layer in the laminating direction. A method for manufacturing a secondary battery having a bent structure,
A first strip separator supply step of drawing out and supplying the first strip separator from the roll;
Inspecting a predetermined area of the first strip separator, and determining whether the pass / fail is good, acceptable, or not;
A second strip separator supplying step of drawing out and supplying the second strip separator from the roll;
Inspecting a predetermined region of the second band-shaped separator, the pass / fail of the second band-shaped separator is determined in three stages of good, good, and bad;
A cutting step of cutting the first and second band-shaped separators in a state of being overlapped with each other for each predetermined region;
A first electrode for supplying a first electrode plate between the predetermined regions of the first and second strip separators, both of which have been determined to be good in the first and second strip separator inspection processes; Plate supply process,
The first and second band-shaped separators, which are disposed above and below the first electrode plate, serve as first and second separators, and join predetermined portions of the predetermined region in the predetermined region to form the first electrode plate. Is a separator joining step of forming a package body packaged by the first and second separators,
In the set of the predetermined regions serving as the first and second separators cut in a state of being overlapped with each other, the relationship between the inspection results in the inspection process of the first and second band-shaped separators is good and good. , Good and good, good and good, and good and good, and the predetermined area constituting a set that does not include bad, a step of storing the outermost layer separator in the outermost layer separator storage unit,
A discarding step of discarding a set including at least one of the sets of the first and second separators cut for each of the predetermined areas in a state where they are overlapped with each other and having the inspection result unacceptable,
A laminating step of laminating the outermost layer separator, a package in which the first electrode plate is packaged by the first and second separators, and a second electrode plate having a polarity different from that of the first electrode plate; It is characterized by including.

  In the method for manufacturing a secondary battery according to the present invention, it is preferable that the cutting step is performed after the separator joining step.

  In the separator joining step, the first electrode plate is cut after joining predetermined portions of the respective predetermined regions serving as the first and second separators, whereby the first electrode plate is individually packaged by the first and second separators. Pieces can be obtained reliably.

  In addition, it is preferable that the separator joining step includes a heating unit that partially heats and welds the predetermined region to be the first and second separators.

  With the configuration described above, the first and second separators can be easily and reliably welded and joined, and the present invention can be made more effective.

  Further, the relationship between the inspection results in the inspection step of the first and second belt-shaped separators is any of good and good, good and good, good and good, and good and good, and does not include bad. In the case of the relationship, the predetermined region serving as the outermost layer separator may be directly supplied to the laminating step without being transported to the outermost layer separator storage unit.

  With the above configuration, the trouble of storing the outermost layer separator can be reduced, and the secondary battery can be manufactured efficiently.

  Since the secondary battery manufacturing apparatus and the secondary battery manufacturing method of the present invention are configured as described above, the electrode plate not wrapped by the separator is the outermost layer while suppressing the usage of the separator. As a result, it is possible to efficiently manufacture a secondary battery by preventing deterioration of characteristics.

  Specifically, the relationship between the inspection results of the first and second band-shaped separators is such that the packaging of the electrode plate is formed using only the separators having a good and good relationship, so that a highly reliable electrode plate can be obtained. While forming the package, not only those having a good and good test result, but also other than those, which have sufficient practicality as the outermost layer separator, the test result is good and good, good and good, and By using the separator in either of the possible and acceptable relations as the outermost layer separator, the amount of the separator used can be reduced without deteriorating the reliability, and the electrode plate that is not wrapped by the separator may be the outermost layer. Thus, the secondary battery can be manufactured efficiently without causing the deterioration of the characteristics due to the above.

  That is, according to the secondary battery manufacturing apparatus and the secondary battery manufacturing method of the present invention, for example, the first electrode plate wrapped with the first and second separators and the first electrode plate have polarities. The second electrode plate, which is not packaged with a separator, and a secondary battery manufactured through a step of laminating the outermost separator, without deteriorating the reliability, and suppressing waste of separator material. , And can be manufactured efficiently.

It is a figure showing composition of a principal part of a manufacturing device of a secondary battery concerning an embodiment of the present invention. In the secondary battery manufacturing apparatus according to the embodiment of the present invention, a position correction stage for correcting the position of the package body based on the position of the electrode plate, an outermost layer separator storage unit for storing the outermost layer separator, the inspection result is It is a figure showing a disposal part etc. which discards a separator including an impossible separator. It is a figure showing composition of a stack type secondary battery manufactured by a manufacturing device of a secondary battery concerning an embodiment of the present invention. (A)-(c) is a figure which shows the lamination method in the laminated part at the time of manufacturing a secondary battery using the manufacturing apparatus of the secondary battery concerning embodiment of this invention. (A), (b) is a figure which shows the conventional electrode loading device used for laminating the electrode plate packaged by the separator and the bare electrode plate not packaged by the separator.

  Hereinafter, embodiments of the present invention will be described, and features of the present invention will be described in more detail.

[Embodiment 1]
1 and 2 are diagrams showing a configuration of a secondary battery manufacturing apparatus according to Embodiment 1 of the present invention.
As shown in FIG. 3, the manufacturing apparatus for a secondary battery according to the first embodiment includes a first electrode plate (a positive electrode plate in this embodiment) 5 between a first separator 11 and a second separator 12. A laminated structure 6 in which a package (positive plate package) 10 formed by being sandwiched and a second electrode plate (negative plate) 15 having a polarity different from that of the first electrode plate are alternately laminated with an electrolyte. It is used for manufacturing a laminated secondary battery formed by being housed inside the exterior body 8 together with the secondary battery 7. However, in this embodiment, the laminated structure 6 includes the outermost layer separators 13 on the upper side and the lower side.

Then, the apparatus for manufacturing a secondary battery according to the first embodiment, as shown in FIG.
(A) a first band-shaped separator supply unit 50 that draws out and supplies the first band-shaped separator 11a;
(B) a second strip separator supply unit 60 that pulls out and supplies the second strip separator 12a;
(C) a first band-shaped separator inspection unit 3a that inspects a predetermined region of the first band-shaped separator 11a and determines three levels of good, good, and bad;
(D) a second band-like separator inspection unit 3b that inspects a predetermined region of the second band-like separator 12a and determines a good, good, or bad three-stage;
(E) a predetermined region of the first band-shaped separator 11a having a good inspection result, which is to be the first separator 11, and a second region 12 of the second band-shaped separator 12a having a good inspection result. A first electrode plate supply unit 55 that supplies the first electrode plate 5 between predetermined regions,
(F) The first and second strip-shaped separators 11a and 12a arranged above and below the first electrode plate 5 are joined, and the first and second separators 11 and 12 of the first electrode plate 5 are joined. A separator joining portion 65 forming the package 10;
(G) A predetermined region of the band separators 11a and 12a sandwiching the first electrode plate 5 after joining at the separator joining portion 65, or a region of the band separators 11a and 12a not sandwiching the first electrode plate 5. A cutting unit 70 for cutting a predetermined area;
(H) As shown in FIG. 2, the inspection results in the first and second belt-like separator inspection sections are acceptable or better (good and good, good and good, good and good, and good). The first separator 11 and the second separator 12, which are obtained by cutting the predetermined region constituting the set (i.e. An outermost-layer separator storage unit 75 for storing the outer-layer separator 13,
(I) A discarding unit 80 for discarding a set including at least one of the sets of the first and second separators 11 and 12 that are cut for each predetermined area in a state where they are superimposed on each other and whose inspection result is not possible. (FIG. 2),
(J) As shown in FIGS. 4 (a), (b) and (c), a package 10 in which the outermost layer separator 13 and the first electrode plate 5 are packaged by the first and second separators 11 and 12 And a laminated portion 90 (FIG. 4) for laminating the second electrode plate 15 having a different polarity from the first electrode plate 5.
The laminating unit 90 is configured so that the laminating head 92 laminates the outermost layer separator 13, the package 10, and the second electrode plate 15 on the laminating stage 91 in a predetermined order.

  Further, as a transport mechanism for transporting the first and second belt-shaped separators 11a and 12b and the like, a metal transport belt 31 having suction holes (not shown) and a lower surface side of the transport belt 31 are provided. A resin plate 32 on which the conveyor belt 31 slides, a driving roller 33 a and a driven roller 33 b for driving the conveyor belt 31, and a decompression disposed on the lower surface side of the resin plate 32 supporting the conveyor belt 31. A transfer mechanism having a chamber 35 is used. The resin plate 32 also has grooves and holes (not shown) communicating with the suction holes of the conveyor belt 31 and the decompression chamber 35. Note that a resin plate having a porous structure can be used as the resin plate 32.

As shown in FIG. 1, the first band-shaped separator supply section 50 is configured to draw out and supply the first band-shaped separator 11a from the roll 4a.
Also, as shown in FIG. 1, the second belt-like separator supply section 60 is configured to draw out the second belt-like separator 12a from the roll 4b and supply it.

  In addition, the first band-shaped separator inspection unit 3a is arranged downstream of the first band-shaped separator supply unit 50, and inspects a predetermined region of the first band-shaped separator 11a, that is, a region to be the first separator 11. It has a function of judging the quality of a predetermined area in three stages: good, good, and bad, and includes an illuminating means 1a and an inspection camera 2a.

  The second belt-like separator inspection unit 3b is arranged downstream of the second belt-like separator supply unit 60, and inspects a predetermined region of the second belt-like separator 12a, that is, a region to be the second separator 12. It has a function of determining the quality of a predetermined area in three stages of good, acceptable, and unacceptable, and includes an illumination unit 1b and an inspection camera 2b.

  In the first and second strip-shaped separator inspection sections 3a and 3b, "good" in the case of "determining the quality of the predetermined area in three stages of good, acceptable, and unacceptable" means that the state of the predetermined area is good. This means that the electrode plate is in a state suitable for being used as a separator for forming a package by sandwiching the electrode plate from the upper surface side and the lower surface side of each electrode plate. It can also be used as the outermost layer separator.

  Also, "OK" means that it is not suitable for use as a separator for forming a package by sandwiching individual electrode plates, but can be used as an outermost layer separator.

  Further, “impossible” means that it cannot be used as any of the separator for sandwiching the individual electrode plates to form the package and the outermost layer separator.

  In addition, the first electrode plate supply unit 55 includes a first band-shaped separator 11 a having a good inspection result by the first band-shaped separator inspection unit 3 a, a predetermined region serving as the first separator 11, and a second region. This is an area where the first electrode plate 5 is supplied between predetermined areas of the second belt-like separator 12a, which are to be the second separators 12, in which the inspection result by the belt-like separator inspection unit 3b is good. In such a secondary battery manufacturing apparatus, a predetermined area on the conveyor belt 31 is the first electrode plate supply unit 55.

  Further, the separator joining portion 65 is provided in a predetermined region of the first and second strip-shaped separators 11a and 12a, which are disposed above and below the first electrode plate 5 and become the first and second separators 11 and 12, respectively. The parts are joined to perform the function of forming the package 10 of the first electrode plate 5 by the first and second separators 11 and 12, and have a configuration described below. Note that, as the separator joining portion 65, a so-called heat welding type joining unit having a heating unit that partially heats and fuses predetermined regions to be the first and second separators 11 and 12 is used. .

  In the apparatus for manufacturing a secondary battery according to this embodiment, the separator joining portion 65 includes a head main body 23 having a heater (not shown) and a contact pin 27 provided in a housing portion 24 formed in the head main body 23. , A pressing body 28 and an urging means 29.

  Further, the contact pin 27 constituting the separator joining portion 65 is accommodated in the accommodating portion 24 provided in the head main body 23, and is located below the flange portion 25 as an engaging portion and the flange portion 25, A first separator, an electrode foil, and a contact portion that comes into contact with a welded body, which is a laminate including the second separator; When the lower surface of the flange portion 25 comes into surface contact with the head main body 23 to receive heat from the head main body 23 and the contact pin 27 comes into contact with the body 20 to be welded, Between the outer peripheral surface of the flange portion 25 serving as the engaging portion and the outer peripheral surface of the lower shaft portion and the inner peripheral surface of the housing portion 24 so that the axis can be inclined with respect to the axial direction. Is configured so that a gap exists.

  When the reaction force from the welded body 20 becomes larger than the urging force of the urging means 29, the contact pin 27 rises in a relative positional relationship with the head main body 23 and retreats into the accommodating portion 24. The contact pin 27 is configured to be pressed against the welded body 20 with a stable urging force.

  A part of the contact pin 27 has a tapered shape that gradually increases upward. This is because the contact pin 27 has a flat surface area of the lower end part from the lower end part to the upper end part. This is because the heat capacity is increased as compared with the case where they are formed to be the same.

  Further, the cutting section 70 includes a cutting blade 71 and a cutting stage 72, and the first and second band-shaped separators 11a and 12a, which are overlapped with each other so as to sandwich the first electrode plate 5, are connected to each other by the above-described method. After joining at the separator joining portion 65, the belt-shaped separators 11a and 12a can be cut at predetermined positions in predetermined regions to be the first and second separators 11 and 12.

  Furthermore, the apparatus for manufacturing a secondary battery according to this embodiment transports and transfers the package 10 in which the first electrode plate 5 is packaged by the first and second separators 11 and 12 to the next step. Is provided. As shown in FIG. 2, the package 10 is transported to the position correction stage 74 by the transfer head 73. In the package 10, the position of the first electrode plate 5 in the package 10 is recognized in the position correction stage 74, and the position of the package 10 is corrected based on the recognized position of the first electrode plate 5. Is done.

  Further, the outermost layer separator storage unit 75 shown in FIG. 2 indicates that the relationship of the combination of the inspection results in the first and second belt-like separator inspection units is any one of good and acceptable, acceptable and good, and acceptable and acceptable. Provided for storing the separator in which the first separator 11 and the second separator 12 overlap each other, obtained as a result of cutting the predetermined area constituting the set by the cutting unit 70, as the outermost layer separator 13. It is. When the number of the outermost layer separators 13 stored in the outermost layer separator storage unit 75 is small, the combination of the inspection results in the first and second band-like separator inspection units is a group having a good and good relation. Can be stored as the outermost layer separator 13 in a state where the first separator 11 and the second separator 12 overlap each other, which are obtained by cutting the predetermined region constituting the above by the cutting unit 70.

  In addition, a separator for sandwiching the first electrode plate 5, that is, a separator that cannot be used as a separator for packaging the first electrode plate but can be used as an outermost layer separator is effectively used. It is arranged so that it can be done.

  However, in the secondary battery manufacturing apparatus of the present invention, the relationship between the inspection results in the first and second band-shaped separator inspection sections 3a and 3b is more than acceptable (good and good, good and good, good and good, respectively). And a predetermined area having a relation of (OK) or (OK) is transported directly to the laminating section 90 without being stored in the outermost layer separator storage section 75 as the outermost layer separator 13 and is provided for lamination. It is also possible. By doing so, it is possible to reduce the load on the outermost layer separator storage unit 75 for storing the outermost layer separator 13, reduce the equipment cost, and efficiently manufacture the secondary battery.

  In addition, the discarding unit 80 discards a set including at least one of the sets of the first and second separators 11 and 12 cut for each predetermined region in a state where the inspection result is not possible. And a container 81 for accommodating the discarded separator. In addition, when the outermost layer separator 13 stored in the outermost layer separator storage unit 75 exceeds a predetermined amount, no further storage is necessary, so that the first and second band-like separator inspection units are not required. The first separator 11 and the first separator 11 are obtained by cutting a predetermined region forming a set having a relation of any of the good and the good, the good and the good, and the good and the good results. It is also possible to discard the separator in which the second separator 12 overlaps.

  Next, a method of manufacturing a stacked secondary battery using the manufacturing apparatus for a secondary battery according to this embodiment will be described.

  (1) First, the first band-shaped separator 11a is pulled out from the roll 4a of the first band-shaped separator supply unit 50 and supplied, and the first band-shaped separator inspection unit 3a determines a predetermined region of the first band-shaped separator 11a. The inspection is performed, and the quality is determined in three stages: good, acceptable, and unacceptable.

  (2) In addition, the second belt-like separator 12a is pulled out from the roll 4b of the second belt-like separator supply unit 60 and supplied, and the second belt-like separator inspection unit 3b uses the second belt-like separator inspection unit 3b to remove a predetermined area of the second belt-like separator 11b. The inspection is performed, and the quality is determined in three stages: good, acceptable, and unacceptable.

  (3) Next, in the first electrode plate supply unit 55, the first and second band-shaped separator inspection units 3a and 3b determine whether the first and second band-shaped separators 11a and 12a, both of which are determined to be good, are used. The first electrode plate 5 is supplied between a predetermined region, that is, a predetermined region to be the first separator 11 and a predetermined region to be the second separator 12.

  In addition, unless the inspection results of the fixed areas in the first and second strip-shaped separator inspection sections 3a and 3b are all good, the first electrode plate 5 should not be sandwiched between the predetermined areas. I do.

  (4) Then, in the separator joining portion 65, predetermined portions in predetermined regions of the first and second strip-shaped separators 11a and 12a located above and below the first electrode plate 5 are joined to form the first electrode plate. 5, the package 10 is formed by the first and second separators 11 and 12.

(5) Then, the strip-shaped separators 11a and 12a joined as described above are cut by the cutting section 70.
In the cutting section 70, among the set of predetermined areas to be the first and second separators 11 and 12, the inspection results in the first and second band-like separator inspection sections 3a and 3b are good and good, and good and good. , And a pair having a relation of “OK” or “OK” (including a pair having a good-good relation when the number of the outermost-layer separators 13 stored in the outermost-layer separator storage unit 75 is small). Is cut so that the first electrode plate is not sandwiched between the first and second separators 11 and 12.

  As described above, as described above, the separators that constitute a set that is equal to or greater than the acceptable (any of the relations of good and good, good and good, good and good, and good and good), that is, the separators whose test results are not impossible, It can be used as the outermost layer separator.

  Also, among the sets of the predetermined areas to be the first and second separators 11 and 12, at least one of the sets including a test result of which the inspection result is not possible is not sandwiched by the first electrode plate. The first and second separators 11 and 12 are cut so as to overlap each other.

  (6) Then, a set in which the inspection result obtained by cutting at the above-described cutting section 70 is equal to or more than acceptable (any one of good and good, good and good, good and good, and good and good) The first and second separators 11 and 12 that can be used as the outermost layer separator are stored in the outermost layer separator storage unit 75 as the outermost layer separator 13.

  The first and second separators 11 and 12, which can be used as the outermost layer separator, that is, the outermost layer separator 13 are transported directly to the later-described laminating unit 90 without being stored in the outermost layer separator storage unit 75. Then, it is also possible to configure so as to be provided for lamination.

  When supplying the outermost layer separator 13 from the outermost layer separator storage section 75 to the following laminating section 90, the outermost layer separator storage section 75 includes an adsorption stage 76, and the adsorption stage 76 adsorbs the two outermost layer separators 13. When the uppermost outer layer separator 13 is picked up from the suction stage 76 while being held and is supplied to the stacking unit 75, for example, a transfer head configured to hold the outermost layer separator by vacuum suction ( (Not shown) to pick up the uppermost outermost separator 13.

  In this case, the lower outermost layer separator 13 of the two outermost layer separators 13 sucked and held by the suction stage 76 is also affected by the suction of the transfer head, and the lower outermost layer separator 13 is loosened. And deformation may occur.

  Then, in this state, if the transport head is pressed to pick up the lowermost outermost layer separator 13, wrinkles are generated in the lowermost outermost layer separator 13.

  In such a case, once the suction of the suction stage 76 is turned off and then turned on again, the lowermost outermost layer separator 13 can be held on the suction stage 76 without loosening or wrinkling. It becomes possible to supply the outermost layer separator 13 without wrinkles, when it is sucked by the transport head and then supplied to the laminating section 90.

  The first and second separators, which are the outermost layer separators cut by the cutting unit, are not stored in the outermost layer separator storage unit, but are temporarily placed on a pre-supply mounting unit (not shown) and then transported to the stacking unit. In this case, wrinkles may be similarly formed on the lower separator of the pair of first and second separators. However, by adopting the same configuration as the above-described configuration, the wrinkles can be reduced. Not the outermost layer separator can be supplied to the laminate.

  (7) Also, among the sets of predetermined areas to be the first and second separators 11 and 12, at least one of which includes a set whose inspection result is unacceptable is configured as a set. Both the first and second separators are discarded in the discard unit 80. However, depending on the case, the first and second separators of this set may be stored in the outermost layer separator storage unit 75, and only the separator determined to be unacceptable may be discarded. In addition, when the outermost layer separator 13 stored in the outermost layer separator storage unit 75 exceeds a predetermined amount, no further storage is necessary, so that the first and second band-like separator inspection units are not required. The first separator 11 and the first separator 11 are obtained by cutting a predetermined region forming a set having a relation of any of the good and the good, the good and the good, and the good and the good results. The separator in which the second separator 12 overlaps may be configured to be discarded.

  (8) Then, the package 10 including the first and second separators 11 and 12 of the first electrode plate 5 is transported to the stacking unit 90, and the outermost layer separator 13 and the first electrode plate 5 are The laminated structure 6 is manufactured by laminating the second electrode plates 15 having different polarities in a predetermined order as described below.

  (8-1) In manufacturing the laminated structure 6, for example, as shown in FIG. 4A, first, the lower outermost layer separator 13 is placed on the lamination stage 91 of the lamination section 90. .

  (8-2) Then, on the outermost layer separator 13, using the lamination head 92, the second electrode which is different in polarity from the first electrode plate (the positive electrode plate in this embodiment) 5 and is not packaged with the separator. (In this embodiment, a negative electrode plate) 15 is laminated (see FIG. 4A).

  (8-3) Then, the package 10 in which the first electrode plate 5 is packaged with the first and second separators 11 and 12 is laminated on the second electrode plate 15 as described above. (See FIG. 4B).

  (8-4) Then, after further laminating the second electrode plate 15 on the package 10, the next package 10 is laminated on the second electrode plate 15.

(8-5) Then, the second electrode plate 15 is stacked on the packaging body 10 that is finally stacked, and the uppermost outermost separator 13 is further stacked thereon (see FIG. 4C). .
Thereby, the laminated structure 6 is formed.

  (8-6) Then, after the laminated structure 6 is housed inside the exterior body 8 together with the electrolyte 7, the exterior body 8 is sealed, so that the laminated type body having a structure as shown in FIG. The following battery is obtained.

  According to the secondary battery manufacturing apparatus and the secondary battery manufacturing method according to this embodiment, the electrodes of the first and second belt-shaped separators are inspected using only the separators having good and good relations. Since the plate package is formed, a highly reliable electrode plate package can be formed. On the other hand, by focusing on the fact that the inspection results have practicality as the outermost layer separator other than those having a good-good relationship, the relationship between the inspection results of the first and second strip-shaped separators is more than ( Good-to-good, good-to-good, good-to-good, and good-to-good), the separator that constitutes the pair is used as the outermost layer separator to ensure reliability while maintaining the reliability of the separator. It is possible to reduce the amount of use.

  Further, the secondary battery manufactured by the device and the method of the present invention, since the separator is disposed in the outermost layer of the laminated structure, by the outermost electrode plate not wrapped by the separator, It is possible to provide a highly reliable secondary battery by preventing the characteristics from deteriorating.

  The present invention is not limited to the above embodiments, and various applications and modifications can be made within the scope of the invention.

1a Illumination means constituting a first belt-like separator inspection unit 1b Illumination means constituting a second belt-like separator inspection unit 2a Inspection camera constituting a first belt-like separator inspection unit 2b Construction of a second belt-like separator inspection unit Inspection camera 3a First strip separator inspection section 3b Second strip separator inspection section 4a Roll from which first strip separator is drawn out 4b Roll from which second strip separator is drawn out 5 First electrode foil (positive electrode plate)
Reference Signs List 6 laminated structure 7 electrolyte 8 package 10 package of first electrode with first and second separators 11 first separator 11a first strip separator 12 second separator 12a second strip separator 13 outermost layer Separator 15 Second electrode plate 20 Body to be welded 23 Head body 24 Housing part 25 Flange part 26 Contact part 27 Contact pin 28 Pressing body 29 Biasing means 31 Metal transport belt 32 Resin plate 33a Drive roller 33b Followed roller 35 Decompression chamber 50 First band-shaped separator supply part 55 First electrode plate supply part 60 Second band-shaped separator supply part 65 Separator joint part 70 Cutting part 71 Cutting blade 72 Cutting stage 73 Transfer head 74 Position correction stage 75 Most Outer separator storage unit 76 Suction stage 80 Disposal unit 81 Disposal Container 90 stacked portion 91 stacking stage 92 laminated head for accommodating a separator

Claims (9)

A first electrode plate and a second electrode plate having a different polarity from the first electrode plate are laminated via a separator, and an outermost layer separator is provided as an outermost layer in the laminating direction. Manufacturing apparatus for a secondary battery having a structure
A first strip separator supply unit that draws out and supplies the first strip separator from the roll;
A first band-shaped separator disposed downstream of the first band-shaped separator supply unit, for inspecting a predetermined region of the first band-shaped separator, and determining whether the predetermined region is good, good, acceptable, or not; An inspection unit;
A second belt-like separator supply unit that draws out and supplies the second belt-like separator from the roll,
A second strip separator that is arranged downstream of the second strip separator supply unit and inspects a predetermined area of the second strip separator to determine whether the predetermined area is good, good, or bad. An inspection unit;
A cutting unit that is disposed downstream of the first and second band-shaped separator inspection units and cuts the first and second band-shaped separators in a state of being overlapped with each other for each predetermined region;
The inspection result by the first band-like separator inspection unit is good, the predetermined region serving as the first separator of the first band-like separator, and the inspection result by the second band-like separator inspection unit are good. A first electrode plate supply unit that supplies a first electrode plate between the predetermined regions of the second band-shaped separator to be a second separator;
The first electrode is formed by joining predetermined portions of the first and second strip-shaped separators, which are disposed above and below the first electrode plate, and serve as the first and second separators, in the predetermined region. A separator joining portion, wherein a plate forms a package body packaged by the first and second separators;
In the set of the predetermined regions serving as the first and second separators, which are cut in a state of being overlapped with each other, the relationship between the inspection results in the first and second belt-like separator inspection units is good and good. , Good and good, good and good, and good and good, and the predetermined area constituting a set not including the bad, the outermost layer separator storage unit to store as the outermost layer separator,
A discarding unit that discards a set including at least one of the sets of the first and second separators cut for each of the predetermined regions in a state of being superimposed on each other and including the test result that is not possible;
A second electrode plate supply unit for supplying a second electrode plate having a different polarity from the first electrode plate;
The outermost layer separator, a package body in which the first electrode plate is wrapped by the first and second separators, and a lamination portion for laminating a second electrode plate having a different polarity from the first electrode plate. An apparatus for manufacturing a secondary battery, comprising:   The secondary battery manufacturing apparatus according to claim 1, wherein the cutting section is disposed downstream of the separator joining section.   3. The secondary battery according to claim 1, wherein the separator joint has heating means for partially heating and welding the predetermined region serving as the first and second separators. 4. Manufacturing equipment.   The relationship between the inspection results in the first and second belt-like separator inspection sections is any of good and good, good and good, good and good, and good and good, and constitutes a set that does not include bad. The secondary battery according to any one of claims 1 to 3, wherein the predetermined region is configured to be directly conveyed to the laminating section as the outermost layer separator and provided for lamination. manufacturing device. A first electrode plate and a second electrode plate having a different polarity from the first electrode plate are laminated via a separator, and an outermost layer separator is provided as an outermost layer in the laminating direction. A method for manufacturing a secondary battery having a bent structure,
The outermost layer separator, a package in which the first electrode plate is packaged by the two separators, and a laminating step of laminating a second electrode plate having a different polarity from the first electrode plate,
The pass / fail of the predetermined area of the belt-like separator drawn from the roll is determined in three stages of pass, pass, and fail.
The two predetermined regions where the result of the determination is good are selected into two separators, and the predetermined region where the result of the determination is either good or good is selected as the outermost layer separator, A method for manufacturing a secondary battery, comprising: sorting the predetermined region where the result is not possible into separators to be discarded . A first electrode plate and a second electrode plate having a different polarity from the first electrode plate are laminated via a separator, and an outermost layer separator is provided as an outermost layer in the laminating direction. structure a method of manufacturing a secondary battery that have a,
A first strip separator supply step of drawing out and supplying the first strip separator from the roll;
Inspecting a predetermined area of the first strip separator, and determining whether the pass / fail is good, acceptable, or not;
A second strip separator supplying step of drawing out and supplying the second strip separator from the roll;
Inspecting a predetermined region of the second band-shaped separator, the pass / fail of the second band-shaped separator is determined in three stages of good, good, and bad;
A cutting step of cutting the first and second band-shaped separators in a state of being overlapped with each other for each predetermined region;
A first electrode for supplying a first electrode plate between the predetermined regions of the first and second strip separators, both of which have been determined to be good in the first and second strip separator inspection processes; Plate supply process,
The first and second band-shaped separators, which are disposed above and below the first electrode plate, serve as first and second separators, and join predetermined portions of the predetermined region in the predetermined region to form the first electrode plate. Is a separator joining step of forming a package body packaged by the first and second separators,
In the set of the predetermined regions serving as the first and second separators cut in a state of being overlapped with each other, the relationship between the inspection results in the inspection process of the first and second band-shaped separators is good and good. , Good and OK, OK and OK, and OK and OK, and the predetermined area constituting a set that does not include Impossible, a step of storing the outermost layer separator in the outermost layer separator storage unit,
A discarding step of discarding a set including at least one of the sets of the first and second separators cut for each of the predetermined areas in a state where they are overlapped with each other and having the inspection result unacceptable,
A laminating step of laminating the outermost layer separator, a package in which the first electrode plate is packaged by the first and second separators, and a second electrode plate having a different polarity from the first electrode plate; A method for manufacturing a secondary battery, comprising:   The method according to claim 6, wherein the cutting step is performed after the separator bonding step.   8. The secondary battery according to claim 6, wherein the separator joining step includes a heating unit that partially heats and welds the predetermined region serving as the first and second separators. 9. Manufacturing method.   The relationship between the inspection results of the first and second band-shaped separators in the inspection step is any of good and good, good and OK, OK and OK, and OK and OK. The secondary according to any one of claims 6 to 8, wherein, in some cases, the predetermined region serving as the outermost layer separator is directly supplied to the laminating step without being transported to the outermost layer separator storage unit. Battery manufacturing method.

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