JP4470366B2 - Battery manufacturing apparatus and manufacturing method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to a battery manufacturing apparatus and manufacturing method, and more specifically, an intermediate such as a negative electrode material or a positive electrode material that is handled as a sheet-like member in the manufacturing process, an electrode base material such as a separator, aluminum foil, or copper foil, or The present invention relates to a battery manufacturing apparatus and a manufacturing method for manufacturing a battery by removing magnetic metal impurities attached to a battery component such as a current collecting lead, an intermediate, a separator, or a web made of a material.
[0002]
[Prior art]
  In the battery manufacturing process, for example, aluminum foil or copper foil constituting an electrode base material, a negative electrode material or a positive electrode material coated with an electrode active material on the electrode base material and cut to a predetermined width, a separator or a resin sheet of the material Various webs such as current collecting leads and insulating insulators are handled. Various types of webs are generally fed out from a supply unit and subjected to appropriate processing during traveling along a conveyance path having a plurality of guide rollers, and are sent to the next process.
[0003]
  By the way, a secondary battery that can be repeatedly charged is used as a power source in portable electronic devices for convenience, economy, or resource saving. Conventionally, lead batteries, nickel cadmium batteries, or nickel metal hydride batteries have been used as secondary batteries, but it is difficult to adapt to portable electronic devices that are smaller, lighter, more functional, or longer. It has become. Lithium ion secondary batteries have high energy density characteristics and can meet the required characteristics of the above-described portable electronic devices and are widely used.
[0004]
  Lithium ion secondary batteries, for example, form a battery element by superimposing a sheet-like negative electrode material and a positive electrode material on each other via a separator and winding or folding them in a spiral shape. This battery element is a non-aqueous electrolyte. At the same time, it is stored in a battery can. In the lithium ion secondary battery, a battery lid is caulked to the opening of the battery can via a sealing gasket to seal the battery element and the non-aqueous electrolyte in the battery can. In a lithium ion secondary battery, a battery can is connected to a negative electrode material via a negative electrode lead to constitute a negative electrode, and a battery lid is connected to a positive electrode material via a positive electrode lead to constitute a positive electrode.
[0005]
  A lithium ion secondary battery is formed by applying a negative electrode active material on both sides or one side of a negative electrode current collector made of a film-like copper foil or the like, and the positive electrode material is made of a film-like aluminum foil or the like. The positive electrode active material is applied to both sides or one side of the electric body.
[0006]
  In the lithium ion secondary battery, the negative electrode material 100, the positive electrode material 101, and the separators 102 and 103 are superimposed on the outer periphery of the winding roll 104 by the winding process shown in FIG. That is, in the winding process, the long negative electrode material 100 cut to a predetermined width is wound around the negative electrode material supply roll 105 and supplied, and the long positive electrode material 101 cut to a predetermined width is supplied to the positive electrode. It is wound around the material supply roll 106 and supplied. In the winding process, the long first separator 102 cut to a predetermined width is wound and supplied to the first supply roll 107, and the long second separator cut to a predetermined width is supplied. 103 is wound around the second supply roll 108 and supplied.
[0007]
  In the winding process, the negative electrode material 100 that is unwound from the negative electrode material supply roll 105 and runs on the first guide roller 109a to the fifth guide roller 109e and the first supply roll 107 is unwound. The first separator 102 that travels while being wound around the guide roller 110 is superimposed on the outer periphery of the first superposition roller 111 and guided to the take-up roll 104. In the winding process, the positive electrode material 101 that is fed from the positive electrode material supply roll 106 and is run on the first guide roller 112a to the fourth guide roller 112d and the second supply roll 108 is fed. The second separator 103 that travels while being wound around the guide roller 113 is superimposed on the outer peripheral portion of the second superposition roller 114 and guided to the take-up roll 104.
[0008]
  In the winding process, the negative electrode material 100 and the first separator 102 guided via the first superposition roller 111 and the positive electrode material 101 and the second separator led via the second superposition roller 114 103 is wound on the outer peripheral portion of the winding roll 104 while being stacked in a laminated state with the positive electrode material 101 on the inner layer side to form a battery element. In the next step, the battery element is wound, for example, in a spiral shape and stored in the battery can.
[Problems to be solved by the invention]
[0009]
  By the way, in a battery, there exists a problem that a battery characteristic deteriorates by magnetic metal impurities, such as iron and nickel mixed in the inside of a battery element. For this reason, in the battery manufacturing process, a process for removing magnetic metal impurities using a magnetic separator is generally performed during the processing of material powders such as carbon and polymer materials used as an electrode active material. ing.
[0010]
  However, in the battery manufacturing process, various processes are performed after the powder processing process, and materials and parts that are not subjected to magnetic selection are supplied to manufacture the battery. Therefore, in the conventional battery manufacturing process, the fundamental problem of removing the contamination of the magnetic metal impurities that causes the characteristic deterioration in the entire process has not been achieved.
[0011]
  In the manufacturing process of the lithium ion secondary battery, it is also considered to adopt a process of removing foreign matter adhering to the surface with, for example, a rotating brush used in a general sheet material conveying process. However, such a brush structure may greatly affect the characteristics of the negative electrode material 100 and the positive electrode material 101, and the size of the equipment is increased, and sufficient removal accuracy cannot be obtained.
[0012]
  Therefore, the present invention improves the characteristics by removing magnetic metal impurities with a simple apparatus and process for the sheet-shaped battery parts and intermediates, separators or webs made of materials in the whole manufacturing process. Manufacturing batteriesofThe present invention has been proposed for the purpose of providing a manufacturing apparatus and a manufacturing method.
[0013]
[Means for Solving the Problems]
  A battery manufacturing apparatus according to the present invention that achieves the above-described object includes a guide roller that forms a conveyance path by running a sheet-shaped battery component, an intermediate body, a separator, or a web made of a material on the outer periphery.Ru. The battery manufacturing apparatus includes a cylindrical roller body in which at least one guide roller has a longer axis than the width of the web, and a magnet provided inside the roller body in a non-contact state with the web. It is comprised by the magnetic roller which consists of means.In the battery manufacturing apparatus, a magnetic roller is formed of a non-magnetic material, and a cylindrical roller main body on which a web slides on an outer peripheral portion, and a cross section provided inside the roller main body and having a radius of curvature substantially equal to the radius of curvature thereof. Is composed of magnetic means having a substantially semicircular arc shape, and adsorbs the adhering magnetic metal impurities by sliding the web to a region magnetized by opposing the magnetic means on the outer periphery of the roller body. Remove.
[0014]
  According to the battery manufacturing apparatus according to the present invention configured as described above, an appropriate process is performed while the web fed from the supply unit is traveling in the conveyance path, and is supplied to the next process. . According to the battery manufacturing apparatus, the web of the magnetic rollerRubbing travels in the magnetized area by opposing magnetic meansAs a result, the magnetic metal impurities adhering to the web are adsorbed and removed in the traveling path. Therefore, according to the battery manufacturing apparatus, it is possible to manufacture a battery with improved yield by reducing the mixing of magnetic metal impurities without the need for a new process or large-scale capital investment.
[0015]
  In addition, the battery manufacturing method according to the present invention that achieves the above-described object includes a sheet-like battery part or an intermediate body, a separator, or a material formed from a supply unit.TheOn the outer periphery of the guide rollerMultiplyDrive to the next processYouThe Battery manufacturing methodIsA magnet comprising at least one guide roller having a cylindrical roller body having a longer axis than the width of the web and magnetic means provided in the roller body in a non-contact state with the web. A roller is used. Battery manufacturing methodIs, Run the web around the magnetic rollerThe magnetic metal impurities adhering in the magnetized region opposite to the magnetic region where the magnetic means is disposed are removed by adsorption, and the magnetic metal impurities adsorbed and removed by the cleaning means disposed in the non-magnetized region facing the non-arranged region of the magnetic means are removed and recovered..
[0016]
  According to the battery manufacturing method of the present invention configured as described above, an appropriate process is performed while the web fed from the supply unit is traveling in the conveyance path, and is supplied to the next process. . According to the battery manufacturing method, magnetic metal impurities adhering to the web are removed.The magnetic metal impurities removed by suction and removed by the cleaning means arranged in the non-magnetized region of the magnetic roller are removed and collected in the magnetized region of the magnetic roller, so that reattachment to the web is reliably prevented. . Therefore, according to the battery manufacturing method,It is possible to manufacture a battery with improved yield by reducing the mixing of magnetic metal impurities and eliminating the need for new process organization and large-scale capital investment.
[0017]
DETAILED DESCRIPTION OF THE INVENTION
  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. The manufacturing apparatus and manufacturing method of the lithium ion secondary battery shown as the embodiment manufactures the lithium ion secondary battery 50 shown in FIG. 4, for example, through the electrode forming process and the battery forming process in substantially the same manner as before. To do. The lithium ion secondary battery 50 is a battery element in which a sheet-like negative electrode material 51 and a positive electrode material 52 are superposed on a take-up roll 1, which will be described in detail later, via separators 53 and 54 and wound in a spiral shape. The battery element 55 is accommodated in a bottomed cylindrical battery can 57 together with a non-aqueous electrolyte via an insulating material 56. In the lithium ion secondary battery 50, a battery lid 58 is caulked to the upper end opening of the battery can 56 via a sealing gasket 59 to seal the battery element 55 and the non-aqueous electrolyte in the battery can 57.
[0018]
  In the lithium ion secondary battery 50, the battery can 57 is connected to the negative electrode material 51 via the negative electrode lead 60 to form a negative electrode, and the battery lid 58 is connected to the positive electrode material 52 via the positive electrode lead 61. Constitute. The lithium ion secondary battery 50 has a positive electrode lead 61 fixed by welding to a safety valve mechanism 62 having a current interruption function, and is connected to a battery lid 58 via the safety valve mechanism 62. In the lithium ion secondary battery 50, if the internal pressure of the battery increases abnormally, the safety valve mechanism 62 is pushed up and deformed, so that the positive electrode lead 61 is cut leaving the welded part. To cut off the current.
[0019]
  The lithium ion secondary battery 50 is formed by applying a negative electrode active material on both sides or one side of a negative electrode current collector in which a negative electrode material 51 is made of a film-like copper foil or the like, and a positive electrode material 52 is made of a film-like aluminum foil or the like. A positive electrode active material is applied to both sides or one side of the positive electrode current collector. For the negative electrode material 51, as a negative electrode active material, for example, a carbon material that can be doped / undoped with lithium ions, a polymer material such as polyacetylene and polypyrrole, or SnO₂An oxide such as polyvinylidene fluoride is mixed with this, and a negative electrode paint that is dispersed in an organic solvent such as n-methylpyrodoline and made into a slurry is used.
[0020]
  The negative electrode material 51 is formed by uniformly applying a negative electrode paint on the negative electrode current collector by, for example, a doctor blade method, etc., and performing a high temperature drying process to evaporate the residual organic solvent of the dispersion medium, and further performing a pressure treatment by a roll press. The negative electrode active material is formed on the negative electrode current collector to form a high density. The negative electrode material 51 is cut into a predetermined width by a slitter and wound around a negative electrode material supply reel 2 which will be described in detail later. The negative electrode material 51 is formed to have a width dimension of 57.5 mm and a length of 575 mm, although the cutting width and length differ depending on the type of battery.
[0021]
  As the positive electrode active material, for example, Li_xMO₂(M: one or more transition metals, x: different depending on the discharge state of the battery, usually 0.05 or more and 1.10 or less) And other metal oxides and metal sulfides are used. As the positive electrode material 52, a positive electrode coating material is used in which a binder such as polyvinylidene fluoride is mixed with the positive electrode active material and dispersed in an organic solvent such as n-methylpyrodrin to form a slurry.
[0022]
  The positive electrode material 52 is formed by uniformly applying a positive electrode paint on the positive electrode current collector by, for example, a doctor blade method, etc., and then subjecting the organic solvent to a high temperature drying treatment, followed by a pressure treatment by a roll press to produce a positive electrode active material Is formed on the positive electrode current collector with a high density. The positive electrode material 52 is cut into a predetermined width by a slitter and wound around the positive electrode material supply reel 3 described later in detail. The positive electrode material 52 has different cutting widths and lengths depending on the type of battery. For example, the width dimension is 55.5 mm and the length is 524 mm, which is slightly smaller than the negative electrode material 51.
[0023]
  As the non-aqueous electrolyte, a solution in which an electrolyte is dissolved in an organic solvent is used. Examples of the organic solvent include propylene carbonate, ethylene carbonate, butylene carbonate, vinylene carbonate, γ-butyrolactone, sulfolane, 1,2-dimethoxyethane, 1,2-diethoxyethane, 2-methyltetrahydrofuran, 3-methyl-1, 3-Dioxolane, methyl propionate, methyl butyrate, dimethyl carbonate, diethyl carbonate, dipropyl carbonate and the like are used. One of these organic solvents may be used alone, or two or more of them may be used in combination. The electrolyte is a lithium ion salt that can be dissolved in the above-described organic solvent and has ionic conductivity, such as LiPF.₆LiClO₄, LiBF₄, LiCF₃SO₃Or LiN (CF₃SO₂)₂Etc. are used.
[0024]
  Each of the separators 53 and 54 is made of, for example, PE (polyethylene) as a raw material, and a large number of fine holes having an inner diameter of about 1 μm or less are formed during film formation. The separators 53 and 54 are formed by cutting a sheet material having a thickness of 20 μm to 25 μm into slits with a width of 59.3 mm and a length of 753 mm, which are larger than the negative electrode material 51 and the positive electrode material 52, and will be described in detail later. Each is wound around one supply reel 4 and a second supply reel 5.
[0025]
  In the lithium ion secondary battery 50 described above, the lithium ions in the positive electrode are occluded in the negative electrode through the electrolytic solution during charging, and the lithium ions in the negative electrode are occluded in the positive electrode through the electrolytic solution in discharging. A chemical reversible reaction occurs. The lithium ion secondary battery 50 is charged and discharged by such traffic of lithium ions between the negative electrode material 51 and the positive electrode material 52.
[0026]
  In the lithium ion secondary battery 50, the negative electrode material 51, the positive electrode material 52, and the separators 53 and 54 described above are overlapped on the outer peripheral portion of the winding roll 1 by the winding process shown in FIG. It is formed. That is, in the winding process, the negative electrode material 51 is wound and supplied to the negative electrode material supply roll 2 through the cutting process, and the positive electrode material 52 is wound and supplied to the positive electrode material supply roll 3 through the cutting process. Is done. In the winding process, as will be described later, the first separator 53 superimposed on the negative electrode material 51 is wound around the first supply roll 4 and supplied, and the second separator is superimposed on the negative electrode material 52. 54 is wound around the second supply roll 5 and supplied.
[0027]
  In the winding process, as in the conventional winding process described above, the negative electrode material 51 that is fed from the negative electrode material supply roll 2 and is run on the first guide roller 6a to the fifth guide roller 6e The first separator 53 that is fed out from the first supply roll 4 and is run on the guide roller 7 is superposed on the outer periphery of the first superposition roller 8 and led to the take-up roll 1. It is burned. In the winding process, the positive electrode material 52 that is fed from the positive electrode material supply roll 3 and travels on the first guide roller 9 a to the fourth guide roller 9 d and the second supply roll 5 is fed. The second separator 54 that travels while being wound around the guide roller 10 is superimposed on the outer peripheral portion of the second superposition roller 11 and guided to the winding roll 1.
[0028]
  In the winding process, the negative electrode material 51 guided through the first superposition roller 8, the positive electrode material 52 and the second separator 54 guided through the first separator 53 and the second superposition roller 11. Are wound while being stacked on the outer peripheral portion of the winding roll 1 with the positive electrode material 52 as the inner layer side to form the battery element 55. In the next step, the battery element 55 is wound, for example, in a spiral shape and stored in the battery can 57.
[0029]
  In the winding process, magnetic roller mechanisms 12a to 12d (hereinafter, representative) that adsorb and remove magnetic metal impurities adhering to the respective surfaces in the traveling paths of the negative electrode material 51, the positive electrode material 52, and the separators 53 and 54 described above. In this case, the magnetic roller mechanism 12 is provided. The negative electrode material magnetic roller mechanism 12a is a pair of magnetic rollers 12a1 disposed between the fifth guide roller 6e and the first superposition roller 8 so as to be spaced apart in the travel direction with the travel path of the negative electrode material 51 interposed therebetween. , 12a2. The negative electrode material magnetic roller mechanism 12a adsorbs and removes the magnetic metal impurities adhering to the front and back surfaces when the negative material 51 slides on the front and back surfaces of the magnetic rollers 12a1 and 12a2.
[0030]
  The positive electrode material magnetic roller mechanism 12b is a fourth guide roller.9It is composed of a pair of magnetic rollers 12b1 and 12b2 that are disposed in the running direction between d and the second superposition roller 11 with the running path of the positive electrode material 52 therebetween. The positive electrode magnetic roller mechanism 12b adsorbs and removes magnetic metal impurities adhering to the front and back main surfaces by causing the positive electrode material 52 to slide on the front and back surfaces of the magnetic rollers 12b1 and 12b2, respectively.
[0031]
  The first separator magnetic roller mechanism 12c includes a pair of magnetic rollers disposed between the guide roller 7 and the first superposition roller 8 so as to be separated from each other in the traveling direction with the traveling path of the first separator 53 interposed therebetween. 12c1 and 12c2. The first separator magnetic roller mechanism 12c adsorbs magnetic metal impurities adhering to the front and back main surfaces as the first separator 53 slides on the front and back surfaces of the magnetic rollers 12c1 and 12c2. Remove.
[0032]
  The second separator magnetic roller mechanism 12d is a pair of magnetic rollers disposed between the guide roller 10 and the second overlapping roller 11 so as to be spaced apart in the traveling direction with the traveling path of the second separator 54 interposed therebetween. 12d1 and 12d2. The second separator magnetic roller mechanism 12d adsorbs magnetic metal impurities adhering to the front and back main surfaces as the second separator 54 slides on the front and back surfaces of the magnetic rollers 12d1 and 12d2. Remove.
[0033]
  In the winding process, as described above, immediately before the winding roller 1, each magnetic roller mechanism 12 arranged in each traveling path adheres to the front and back main surfaces of the negative electrode material 51, the positive electrode material 52, and the separators 53 and 54. Adsorb and remove the magnetic metal impurities. Therefore, in the lithium ion secondary battery 50, not only the magnetic metal impurities mixed in the material of the positive electrode material 52 in the electrode forming process are removed, but also the negative electrode material 51, the positive electrode material 52, or the separators 53, 54 in the middle of the process. Magnetic metal impurities adhering to the surface are also removed in the winding process to form the battery element 55, thereby reducing the occurrence of internal discharge and improving the characteristics.
[0034]
  In the winding process, the magnetic roller mechanism 12 is disposed in each travel path of the negative electrode material 51, the positive electrode material 52, or the separators 53 and 54 in addition to the guide rollers. In the winding process, it is a matter of course that each magnetic roller mechanism 12 may be arranged so as to be replaced with a part of the guide roller in each traveling path.
[0035]
  For example, the magnetic roller 20 shown in FIG. 2 is used for each magnetic roller mechanism 12. The magnetic roller 20 includes a rod-shaped or cylindrical magnet 21, a tube 22 made of a nonmagnetic material covering the outer periphery of the magnet 21, and a pair of sleeves 23 a made of a nonmagnetic material and supporting both end portions of the magnet 21. , 23b. The magnetic roller 20 is integrally formed with support shafts 24a and 24b on the outer surfaces of the sleeves 23a and 23b, and the bearings 2 on the support shafts 24a and 24b.5a, 25b is assembled. The magnetic roller 20 is a bearing bearing 2 assembled to the support shaft portions 24a and 24b.5a, 25b is rotatably mounted between the opposing side plates by being assembled in a shaft hole provided in the opposing side plate of a device (not shown) constituting the traveling path.
[0036]
  In the magnetic roller 20, a permanent magnet or an electromagnet is used for the magnet 21, and the length thereof is longer than at least the width of the negative electrode material 51, the positive electrode material 52, or the separators 53 and 54. The magnetic roller 20 is formed with an outer shape according to the specifications of the lithium ion secondary battery 50, and the total length is, for example, 75 mm according to the shape of the negative electrode material 51, the positive electrode material 52 or the separators 53 and 54 described above. It is formed to the extent. Further, the magnetic roller 20 is formed to have an outer diameter of about 12 mm, for example, depending on a position where the outer diameter is arranged in the winding process.
[0037]
  When the magnet 21 is a permanent magnet, for example, a Ne—Fe—B magnet, a Sm—Co magnet, a neodymium magnet, a Fe—Al—Ni—Co magnet, or an oxide magnet is used. The magnet 21 is not limited to a single rod-shaped or cylindrical shape, but may be a magnet tape in which a magnetic powder is attached to the surface of a support tape, for example, wound in a cylindrical shape with a predetermined outer diameter. .
[0038]
  The tube 22 has a slightly longer axis than the magnet 21 and is formed of, for example, Teflon (registered trademark) or vinyl resin. The tube 22 covers the magnet 21, but has a thickness sufficient to sufficiently apply the magnetic force of the magnet 21 to the negative electrode material 51, the positive electrode material 52, or the separators 53, 54 that rub the outer periphery of the magnetic roller 20. The mechanical rigidity against friction is maintained.
[0039]
  In the magnetic roller 20, a tube 22 is detachably combined with a magnet 21. Although the magnetic roller 20 is not described in detail, fitting convex portions are integrally formed on the inner surfaces of the sleeves 23a and 23b, and the magnet 21 is supported by fitting a shaft hole to the fitting convex portions. . Of course, the magnetic roller 20 is not limited to the support structure of the magnet 21, and the shaft 21 is formed on one sleeve 23 a to mount the magnet 21. The other end may be supported by the sleeve 23b.
[0040]
  In the magnetic roller 20 configured as described above, the negative electrode material 51, the positive electrode material 52, or the separators 53 and 54 run on the outer peripheral portion of the tube 22, but smoothly rotate following these travels. The magnetic roller 20 applies the magnetic force of the magnet 21 to the negative electrode material 51, the positive electrode material 52, or the separators 53 and 54 that slidably run on the outer peripheral portion via the tube 22, thereby removing magnetic metal impurities attached to these surfaces. The tube 22 is adsorbed and removed from the outer periphery.
[0041]
  In the magnetic roller 20, the tube 22 is removed from the magnet 21 when the winding operation of the negative electrode material 51, the positive electrode material 52 and the separators 53 and 54 to the winding roll 1 is completed. The magnetic roller 20 recovers the magnetic metal impurities from the outer peripheral portion of the tube 22 by causing the magnetic metal impurities to lose the action of the magnetic force from the magnet 21. As described above, the magnetic roller 20 holds the magnet 21 and the negative electrode material 51, the positive electrode material 52, or the separators 53 and 54 in a non-contact state via the tube 22, so that abrasion powder or the like generated from the magnet 21 is negative. Adhering to the material 51, the positive electrode material 52 or the separators 53 and 54 is prevented.
[0042]
  In the magnetic roller 20, the tube 22 is detachably combined with the magnet 21, so that the magnetic metal impurities can be easily collected and cleaned, and the magnetic metal impurities can be adsorbed and removed with higher accuracy. Is done.
[0043]
  A magnetic roller 30 shown as a second embodiment in FIG. 3 includes a roller body 31 formed in a cylindrical shape by a non-magnetic material, a magnet 32 housed in the roller body 31, and a roller body 31. It comprises a bearing mechanism (not shown) that is rotatably supported. As will be described in detail later, the magnetic roller 30 is provided with a magnetic metal impurity collecting mechanism including a cleaning member 33 and a dust cover 34 located on the outer peripheral portion of the roller body 31.
[0044]
  The roller body 31 is made of a lightweight metal material such as aluminum, and has a mechanical rigidity that does not cause deformation or distortion even when the negative electrode material 51, the positive electrode material 52, or the separators 53 and 54 run on the outer periphery. It is formed with a thickness sufficient to exert a magnetic force of 32 on the outer peripheral surface. The roller body 31 also has a total length of about 75 mm according to the shape specifications of the negative electrode material 51, the positive electrode material 52 or the separators 53 and 54 described above, and varies depending on the arrangement position in the winding process. Is formed to be approximately 12 mm. The roller body 31 is formed by a smooth outer peripheral surface, and slidably travels without scratching the negative electrode material 51, the positive electrode material 52, or the separators 53 and 54.
[0045]
  The magnet 32 is also made of a permanent material having a shape in which a cross section having a radius of curvature substantially equal to the radius of curvature of the roller body 31 has a semicircular arc shape rather than the width of the negative electrode material 51, the positive electrode material 52 or the separators 53 and 54. A magnet or an electromagnet is used. The magnet 32 has a width (arc length) facing a region slightly larger than the winding angle of the negative electrode material 51, the positive electrode material 52, or the separators 53 and 54 that slidably run on the outer peripheral portion of the roller body 31. Is formed. When the magnet 32 is also a permanent magnet, for example, a Ne—Fe—B magnet, a Sm—Co magnet, a neodymium magnet, a Fe—Al—Ni—Co magnet, an oxide magnet, or the like is used. The magnetic force is preferably about 10,000 Gauss.
[0046]
  The magnet 32 is attached to a support member (not shown) and disposed in the inner space of the roller body 31 so as to face the traveling area of the negative electrode material 51, the positive electrode material 52 or the separators 53 and 54. The magnet 32 applies a magnetic force to the facing portion of the outer peripheral portion of the roller body 31 that rotates in opposition to the outer peripheral surface, so that the traveling region of the negative electrode material 51, the positive electrode material 52, or the separators 53 and 54 is magnetized. 31a. Therefore, the magnetic roller 30 adsorbs and removes magnetic metal impurities adhering to the surfaces of the negative electrode material 51, the positive electrode material 52, or the separators 53, 54 that slidably run on the magnetized region 31 a of the roller body 31.
[0047]
  The magnetic roller 30 becomes a non-magnetized region 31b when the outer periphery of the roller body 31 becomes a magnetized region 31a in a region facing the magnet 32 and rotates to the opposite side of the magnet 32 arrangement position. In the magnetic roller 30, a cleaning member 33 is disposed on the outer peripheral portion of the roller body 31 facing the non-magnetized region 31b, and a dust cover 34 is disposed to cover the non-magnetized region 31b. The magnetic roller 30 adsorbs and removes magnetic metal impurities from the surface of the negative electrode material 51, the positive electrode material 52, or the separators 53 and 54 in the magnetized region 31a to the outer peripheral portion of the roller body 31, and this outer peripheral portion becomes the non-magnetized region 31b. By rotating, the holding force due to the magnetic force of the magnet 32 is lost and the magnet 32 is allowed to fall naturally into the dust cover 34.
[0048]
  The magnetic roller 30 is peeled off from the outer peripheral portion of the roller body 31 in the non-magnetized region 31b in order to prevent the magnetic metal impurities that did not fall naturally from reattaching to the negative electrode material 51, the positive electrode material 52 or the separators 53 and 54 A cleaning member 33 to be removed is attached. The cleaning member 33 is made of a cloth such as a brush or felt that wipes off magnetic metal impurities by rubbing the entire length of the roller body 31 without damaging the outer peripheral portion of the roller body 31. Further, the cleaning member 33 is made of a magnet that is arranged to face the outer peripheral portion of the roller body 31 with a minute interval and adsorbs magnetic metal impurities. As for the collection mechanism, a vacuum mechanism that discharges from the inside of the dust cover 34 to the outside or reliably holds it in order to more reliably suppress reattachment to the negative electrode material 51, the positive electrode material 52, or the separators 53 and 54. You may make it attach a magnet etc. to do.
[0049]
  About the lithium ion secondary battery 50 manufactured through the process mentioned above, you may make it confirm presence of the magnetic metal impurity which remained further inside using a detection apparatus. As the inspection device, for example, a device that performs non-destructive detection by performing high-frequency induction heating processing as described below may be used. Such a detection device performs high-frequency induction heating treatment on the negative electrode material 51 and the positive electrode material 52 to heat and heat only the remaining metal impurities, and identifies the presence or absence of the metal impurities and the location thereof by detecting the high temperature portion. The detection device efficiently and accurately detects the presence / absence of a metal impurity and the location thereof by so-called nondestructive inspection. Since the detection device uses a general high frequency induction heating device including a high frequency power source and an induction heating unit used for heating / dissolving metal, it does not impose a burden on equipment investment and is easy to operate. .
[0050]
  In addition, the detection device is a thermocouple or generator as means for detecting a high temperature region.BrightnessA contact thermometer such as a thermometer, a non-contact thermometer such as a radiation thermometer, a thermography, an infrared camera, or the like is used. Since the detection device detects the presence / absence of the metal impurity and the presence location based on the temperature difference, the detection device can perform highly accurate detection without being affected by external noise.
[0051]
  Next, a specific inspection content using the above-described inspection apparatus will be described. The target lithium ion secondary battery has a negative electrode active material of 100 μm made of a mixture of 97% by weight of artificial graphite and 3% by weight of PVdF as a binder with respect to a copper foil surface having a width of 200 mm and a thickness of 30 μm. After coating at a thickness of 10 mm, a negative electrode material in which 10 pieces of iron powder and nickel powder each having a diameter of about 50 μm were embedded was used. Lithium ion secondary batteries have a LiCoO2 surface with an aluminum foil surface of 200 mm wide and 30 μm thick.₂After applying a positive electrode active material consisting of 95% by weight, a mixture of acetylene black of 2% by weight of conductive auxiliary agent and 3% by weight of PVdF as a binder to a thickness of 100 μm, iron powder and nickel powder having a diameter of about 50 μm are applied. 10 positive electrode materials each embedded were used.
[0052]
  For high-frequency induction heating, a high-frequency induction heating apparatus having a spiral induction coil having a diameter of 300 mm is used, and the induction coil is disposed opposite to the negative electrode material and the positive electrode material with an interval of about 50 mm, with a frequency of 200 KHz, Induction heating was performed by irradiating a high frequency output of 3 KW for about 20 seconds. The inspection apparatus detects the infrared rays emitted from the heated metal object by photographing the negative electrode material and the positive electrode material subjected to the induction heating with an infrared camera, and performs monitor confirmation.
[0053]
  As a result of the confirmation, a total of 20 bright spots were displayed on the monitor on both the infrared images of the negative electrode material and the positive electrode material. In addition, from the negative electrode material and the positive electrode material, iron powder and nickel powder embedded in advance were collected from these bright spots. Therefore, the above-described inspection apparatus can accurately identify the presence / absence of a metal impurity mixed in or attached to the negative electrode material or the positive electrode material and the location of the metal impurity.
[0054]
  By the way, since the heating capability in the thickness direction of the electrode material improves as the induction heating condition lowers the frequency, such an inspection apparatus also applies to various electrode materials having different thicknesses by appropriately setting the frequency condition. Applicable. In addition, the inspection apparatus appropriately prevents the inconvenience that the temperature of the metal impurity is excessively increased and the electrode material is damaged by appropriately setting the high frequency output and the irradiation time.
[0055]
  The inspection apparatus is not limited to a configuration in which the inspection is performed with the electrode material and the high-frequency induction heating apparatus stationary at a certain position. For example, the inspection apparatus is configured to inspect while moving the electrode material with respect to the stationary high-frequency induction heating apparatus, or configured to perform induction heating while moving the high-frequency induction heating apparatus with respect to the electrode material. May be.
[0056]
  In the embodiment described above, an application example of the process of forming the battery element 55 by superimposing the negative electrode material 51, the positive electrode material 52, and the separators 53 and 54 on the winding roll 1 for the lithium ion secondary battery 50 is shown. However, it goes without saying that the present invention is not limited to such an embodiment. The present invention is widely applicable to the manufacture of not only the lithium ion secondary battery 50 but also other batteries.
[0057]
  In the battery manufacturing process, not only the negative electrode material 51, the positive electrode material 52, and the separators 53 and 54, but also a sheet-like or film-like web, for example, a copper foil or a positive electrode current collector used as a negative electrode current collector. Materials and parts such as aluminum foil or negative electrode lead 60, positive electrode lead 61, and insulating insulator used are also handled as a web conveyed through a guide roller. Therefore, in the present invention, magnetic metal impurities are similarly removed from the various webs using the magnetic rollers described above.
[0058]
【Example】
  The lithium ion secondary battery 50 manufactured by the lithium ion secondary battery 50 manufactured by the manufacturing process including the winding process including the magnetic roller 30 described above and the electrode material manufacturing process in which the material powder is magnetically selected. Regarding the secondary battery, the internal discharge characteristics were evaluated as follows.
[0059]
  (Preparation of negative electrode material)
  After firing in an inert gas atmosphere, 90 parts by weight of a carbon material pulverized to an average particle size of 20 μm was mixed with 10 parts by weight of polyvinylidene fluoride as a binder, and this mixture was mixed with n-methyl-2- A negative electrode active material slurry was prepared by dispersing in pyrodrine. This negative electrode active material slurry is uniformly applied on both sides of a negative electrode current collector made of a copper foil having a thickness of about 15 μm manufactured by rolling, dried, and then pressed by a roller press to be wound around a core as a band. A negative electrode material was prepared. In addition, the negative electrode material was produced using each material which performed magnetic selection and removed the magnetic metal impurity.
[0060]
  (Preparation of positive electrode material)
  LiCoO₂With respect to 91 parts by weight, 6 parts by weight of graphite powder as a conductive auxiliary agent and 3 parts by weight of polyvinylidene fluoride as a binder are mixed, and this mixture is dispersed in n-methyl-2-pyrodoline. An active material slurry was prepared. This positive electrode active material slurry is uniformly coated on both sides of a positive electrode current collector made of an aluminum foil having a thickness of about 20 μm manufactured by rolling, dried, and then pressed by a roller press to be wound around a core as a strip. A positive electrode material was produced. The positive electrode material was prepared using each material from which magnetic metal impurities were removed by magnetic sorting.
[0061]
  (Configuration of magnetic roller)
  A pair of the negative electrode material, the positive electrode material, or the separator is disposed across the traveling path, and the magnetic metal impurities adhering to the front and back main surfaces are collectively removed by adsorption. About 10,000 Gauss magnets were fixed inside the roller body made of aluminum, a felt cleaning member was used, and a vacuum cleaner was installed in the dust cover.
[0062]
  (Experimental adhesion of magnetic metal impurities to the cathode material)
  While the above-described positive electrode material was installed in a winder and the rewinding operation was performed, two iron powders were adhered per battery. In addition, 1000 positive electrode materials subjected to the iron powder adhesion treatment were produced, and 500 positive electrode materials not subjected to the iron powder adhesion treatment were produced as a positive electrode material A.
[0063]
  (Removal of magnetic metal impurities from positive electrode material)
  About 1000 positive electrode materials subjected to the iron powder adhesion treatment, 500 pieces of the positive electrode material were subjected to the rewinding treatment while performing the above-described iron powder adsorption removal processing by the magnetic roller, thereby obtaining a treated positive electrode material B. Further, the remaining 500 positive electrode materials were treated as non-treated positive electrode materials C with the iron powder attached.
[0064]
  (Production of battery)
  Using the 500 positive electrode materials A, the treated positive electrode material B, and the untreated positive electrode material C, respectively, the negative electrode material and the separator made of a microporous polypropylene film having a thickness of 25 μm are used. -A positive electrode material-a separator were stacked in this order and rolled into a cylindrical shape to produce a spiral battery element A, a battery element B, and a battery element C. Further, the battery element A, the battery element B, and the battery element C were respectively stored in nickel-plated battery cans with insulating plates disposed above and below. The positive electrode lead made of aluminum is led out from each positive electrode material of the battery element A, the battery element B and the battery element C, and this is welded to the safety valve of the battery lid, and the negative electrode lead made of nickel is led out from each negative electrode material. Each was welded to the bottom of the battery can. In each battery can, LiPF is mixed in a non-aqueous solvent in which ethylene carbonate and dimethyl carbonate are mixed at a volume ratio of 1: 1.₆A nonaqueous electrolyte solution in which 1 mol / liter was dissolved was injected. Battery A, battery B, and battery C each having a diameter of 18 mm and a height of 65 mm were prepared by caulking a battery lid to the opening of each battery can via a sealing gasket and sealing the inside.
[0065]
  (Evaluation of internal discharge characteristics)
  Each of the 500 batteries A, B, and C described above was evaluated by measuring a voltage change after charging to 4.2 V and leaving it at room temperature for 30 days in a no-load state. In the evaluation, a battery whose voltage battery was 4.15 V or less was determined as an internal discharge increase failure, and the number thereof was counted.
[0066]
  (Evaluation results)
  The number of defective batteries A, B and C is
  Battery A: 22/500
  Battery B: 0/500
  Battery C: 498/500
Met.
[0067]
  (Evaluation)
  As the battery C, the battery element C in which the iron powder is mixed is used, and the internal discharge increase failure occurs in almost all the batteries. Despite the fact that the battery A was processed for magnetic selection at the material stage, the battery A was still manufactured in a laboratory level environment, and 22 internal discharge increase failures still occurred. In the battery A, not only the positive electrode material but also the negative electrode material or the separator undergoes a winding process or the like, so that magnetic metal impurities adhere to the respective surfaces and the like, thereby causing an increase in internal discharge.
[0068]
  On the other hand, in the battery B, the number of occurrences of increased internal discharge defects was zero. The battery B performs the magnetic sorting process at the material stage, and in the winding process, the magnetic metal impurity is surely removed by the magnetic sorting by the magnetic roller before the winding roll. Occurrence of an increase in internal discharge due to this is reduced.
[0069]
【The invention's effect】
  As described above in detail, according to the present invention, a magnetic roller is provided on the travel guide roller constituting the conveyance path of the web fed from the supply unit, and the web travels on the outer peripheral portion of the magnetic roller. Since the adhering magnetic metal impurities are removed by adsorption, there is no need for a new process or large-scale capital investment, and the production of batteries with improved yield by reducing the contamination of magnetic metal impurities is produced with high yield. .
[Brief description of the drawings]
FIG. 1 is a schematic explanatory diagram of an electrode material winding process in a battery manufacturing process.
FIG. 2 is a perspective view of a magnetic roller used in the electrode material winding process.
FIG. 3 is a partially cutaway perspective view of another magnetic roller.
FIG. 4 is a partial cutaway perspective view of a lithium ion secondary battery.
FIG. 5 is a schematic explanatory diagram of an electrode material winding process in a conventional battery manufacturing process.
[Explanation of symbols]
  DESCRIPTION OF SYMBOLS 1 Winding roll, 2 Negative electrode material supply roll, 3 Positive electrode material supply roll, 4,5 Separator supply roll, 6, 7, 9, 10 Guide roller, 8, 11 Superposition roller, 12 Magnetic roller mechanism, 20 Magnetic roller , 21 Magnet, 22 Tube, 30 Magnetic roller, 31 Roller body, 32 Magnet, 33 Cleaning member, 50 Lithium ion secondary battery, 51 Negative electrode material, 52 Positive electrode material, 53, 54 Separator, 55 Battery element

Claims (5)

In a battery manufacturing apparatus comprising a guide roller that constitutes a conveyance path by running a sheet-shaped battery part or intermediate body, a separator or a web made of a material around the outer periphery,
At least one of the guide rollers includes a cylindrical roller body having a longer axis than the width of the web, and magnetic means provided in the roller body so as to be held in non-contact with the web. Comprising a magnetic roller
The magnetic roller is formed of a non-magnetic material, and a cylindrical roller main body on which the web slides on the outer periphery, and a cross section provided inside the roller main body and having a radius of curvature substantially equal to the radius of curvature is substantially semicircular. The magnetic means exhibiting an arc shape,
An apparatus for manufacturing a battery, wherein the magnetic metal impurities adhering are removed by adhering the web to a region magnetized by the magnetic means on the outer peripheral portion of the roller body facing each other. . The magnetic roller is formed by stacking a sheet-like negative electrode material and a positive electrode material, which are coated with an electrode active material on a film-like current collector fed from each supply unit and cut into a predetermined width, and a sheet-like separator. Used for each traveling guide roller arranged in the previous stage of the winding roll forming the element,
The adhering removal of the said magnetic metal impurities adhering to the front | former stage of each said winding roll is carried out by making the said negative electrode material, a positive electrode material, and a separator run to the outer peripheral part of each said magnetic roller. Battery manufacturing equipment.   Cleaning that removes and collects the magnetic metal impurities adhering to the outer peripheral portion of each roller body by adsorbing and removing from the web in the magnetized region facing the non-magnetized region where the magnetic means of the magnetic roller is not disposed. The battery manufacturing apparatus according to claim 1, further comprising means. In a battery manufacturing method in which a sheet-shaped battery part or intermediate body, a separator or a web made of a material is wound around the outer periphery of a guide roller and conveyed,
At least one of the guide rollers includes a cylindrical roller body having a longer axis than the width of the web, and magnetic means provided in the roller body so as to be held in non-contact with the web. A magnetic roller is used,
The web is caused to slid and run on the outer peripheral portion of the roller main body facing the magnetic means disposition area to adsorb and remove the magnetic metal impurities, and the web of the roller main body facing the non-magnetic area of the magnetic means is removed. A method for producing a battery, characterized in that the magnetic metal impurities adsorbed and removed by a cleaning means arranged in a magnetized region are removed and recovered. The magnetic roller is a battery in which a sheet-like negative electrode material and a positive electrode material, which are coated with an electrode active material on a film-like current collector fed from each supply unit and cut into a predetermined width, are overlapped with each other. For each traveling guide roller arranged in the previous stage of the winding roll forming the element,
The negative electrode material, the positive electrode material, and a separator are caused to travel on the outer peripheral portion of each magnetic roller, thereby adsorbing and removing the attached magnetic metal impurities at the front stage of each take-up roll to form a battery element. The battery manufacturing method according to claim 4 .

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