JP5278380B2 - Polymer battery packaging materials - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a packaging material for a polymer battery having high physical properties for protecting a polymer battery body and high productivity in an embossing process or the like, as a material used for the packaging of the polymer battery, and also to provide a method for manufacturing the packaging material. <P>SOLUTION: The packaging material for the polymer battery is composed of at least: a base material layer; an adhesive layer; a chemical conversion treatment layer 1; aluminum; a chemical conversion treatment layer 2; a heat sealing layer; and a liquid paraffin layer, and the heat sealing layer is made of polyolefin. The chemical conversion treatment is chromate phosphate treatment. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

  The present invention relates to a polymer battery packaging material having a liquid or solid organic electrolyte (polymeric polymer electrolyte) having moisture resistance and content resistance.

  The polymer battery is also referred to as a lithium secondary battery, and is a battery that has a polymer electrolyte and generates a current by the movement of lithium ions, and includes a positive electrode / negative electrode active material made of a polymer. The structure of the lithium secondary battery is as follows: positive electrode current collector (aluminum, nickel) / positive electrode active material layer (polymeric positive electrode material such as metal oxide, carbon black, metal sulfide, electrolyte, polyacrylonitrile) / electrolyte layer (propylene) Carbonate electrolytes such as carbonate, ethylene carbonate, dimethyl carbonate, ethylene methyl carbonate, inorganic solid electrolytes made of lithium salts, gel electrolytes) / negative electrode active substances (lithium metals, alloys, carbon, electrolytes, polymers such as polyacrylonitrile) Negative electrode material) / negative electrode current collector (copper, nickel, stainless steel) and an outer package for packaging them. Polymer batteries are used for personal computers, portable terminal devices (cell phones, PDAs, etc.), video cameras, electric vehicles, energy storage batteries, robots, satellites, and the like. As the exterior body of the polymer battery, a metal can formed by pressing a metal into a cylindrical or rectangular parallelepiped container, or a laminate made of a base material layer, aluminum, and a sealant layer in a bag shape Was used.

However, there have been the following problems as the outer package of the polymer battery. In a metal can, since the outer wall of the container is rigid, the shape of the battery itself is determined. Therefore, since the hardware side is designed to match the battery, the size of the hardware using the battery is determined by the battery, and the degree of freedom in shape is reduced. Accordingly, a pouch type has been developed in which the laminated body is formed into a bag shape and the polymer battery body is accommodated, or an embossed type in which the laminated body is press-molded to form a recess and the polymer battery body is accommodated in the recess. The embossed type provides a more compact package than the pouch type. Regardless of the type of exterior body, strength, insulation, and the like such as moisture resistance or puncture resistance as a polymer battery are indispensable as an exterior body of a polymer battery. And as a packaging material for polymer batteries, it is set as the laminated body which consists of a base material layer, a barrier layer, and a heat seal layer at least. And it has been confirmed that the adhesive strength between the above-mentioned layers affects the properties required for the exterior body of the polymer battery. For example, inadequate adhesive strength between the barrier layer and the heat seal layer may cause moisture to enter from the outside, and hydrogen fluoride generated by the reaction between the electrolyte in the components forming the polymer battery and the moisture The aluminum surface is corroded by the acid, and delamination occurs between the barrier layer and the heat seal layer. Further, when forming the embossed type exterior body, the laminate is press-molded to form a recess, and delamination may occur between the base material layer and the barrier layer during the molding. . Therefore, the present inventors apply an acid-modified polypropylene emulsion to the aluminum surface and baked to form a film, and the adhesive resin layer made of the acid-modified polypropylene resin and the heat seal layer made of the polypropylene resin are both used. Although it was confirmed that the adhesive strength as a laminate was improved if the laminate was formed by extrusion, the baking after the acid-modified polypropylene emulsion coating was time consuming and the production efficiency was not good. In addition, when random polypropylene resin is used for the heat seal layer, the coefficient of friction between the molded male mold and the heat seal layer is large in emboss molding, and the heat seal layer may be whitened or minor cracks may be generated on its surface. In addition, molding stability was poor, and molding wrinkles and cracks sometimes occurred. An object of the present invention is to provide a polymer battery packaging material having good productivity in an embossing molding process and the like as well as protective properties of the polymer battery main body as a material used for polymer battery packaging .

The above problems can be solved by the following present invention. That is, the invention described in claim 1 is formed by laminating at least a base material layer, an adhesive layer, a chemical conversion treatment layer 1, aluminum, a chemical conversion treatment layer 2, a heat seal layer, and a liquid paraffin layer in this order. It comprises a polymer battery packaging material for embossing, which is a polyolefin. The invention described in claim 2 is characterized in that the chemical conversion treatment is a phosphoric acid chromate treatment. The invention described in claim 3, in which the heat seal layer according to claim 1 or claim 2 and a random polypropylene. According to a fourth aspect of the present invention, the heat seal layer according to the first or second aspect is a linear low density polyethylene.

  The chemical conversion treatment performed on both sides of aluminum in the polymer battery packaging material of the present invention can prevent delamination between the base material layer and aluminum during embossing and heat sealing, and When the heat seal layer is formed by the sandwich lamination method or coextrusion lamination method, the fluorination generated by the reaction between the electrolyte of the polymer battery and moisture by heating at the time of forming the laminated body or by heating after forming the laminated body Since the corrosion of the aluminum surface by hydrogen can be prevented, a remarkable effect of preventing delamination between the aluminum and the content layer is exhibited. By coating liquid paraffin on the innermost surface of the heat seal layer, the embossability is good, and even if it is a non-slip layer such as random polypropylene or polyethylene, the molding process can be stabilized, and cracks in the heat seal layer Etc. can be suppressed.

1 is a cross-sectional view showing the structure of a laminate in a packaging material for a polymer battery according to the present invention for each lamination method; (a) dry lamination method, (b) sandwich lamination method, (c) coextrusion lamination method, (d) thermal lamination. It is a structural example in the case of law. It is a perspective view explaining the pouch type exterior body of a polymer battery. It is a perspective view explaining the embossed type exterior body of a polymer battery. It is (a) perspective view, (b) embossed exterior body, (c) X ₂ -X ₂ part sectional view, (d) Y ₁ part enlarged view for explaining molding in the embossed type. It is a conceptual diagram explaining the sandwich lamination method which manufactures the packaging material for polymer batteries. It is a conceptual diagram explaining the coextrusion method which manufactures the packaging material for polymer batteries. It is a perspective view explaining the mounting method of the adhesive film in adhesion | attachment with the packaging material for polymer batteries, and a tab.

The present invention is a polymer battery packaging material that has good moisture resistance, content resistance, and productivity, and is less prone to cracks in the heat seal layer. The layer structure and manufacturing method of the laminate will be described in more detail with reference to the drawings. FIG. 1 is a cross-sectional view showing the structure of the laminate in the polymer battery packaging material of the present invention for each lamination method: (a) dry lamination method, (b) sandwich lamination method, (c) coextrusion lamination method, ( d) A configuration example in the case of the thermal laminating method. FIG. 2 is a perspective view illustrating a pouch-type exterior body of the polymer battery. FIG. 3 is a perspective view illustrating an embossed type exterior body of the polymer battery. Figure 4 illustrates the molding in embossed type, (a) a perspective view, (b) embossing the molded outer body, (c) X ₂ -X ₂ parts cross-sectional view, with (d) Y ₁ part enlarged view is there. FIG. 5 is a conceptual diagram for explaining a sandwich lamination method for producing a polymer battery packaging material. FIG. 6 is a conceptual diagram illustrating a coextrusion method for producing a polymer battery packaging material. FIG. 7 is a perspective view for explaining a method for attaching an adhesive film in the adhesion between the polymer battery packaging material and the tab.

  The polymer battery packaging material forms an exterior body for wrapping the polymer battery body. Depending on the form of the exterior body, the pouch type as shown in FIG. 2, and FIGS. 3 (a) and 3 (b) Alternatively, there is an emboss type as shown in FIG. Examples of the pouch type include three-side seals, four-side seals, and pillow types such as a pillow type. FIG. 2 illustrates a pillow type. The polymer battery packaging material of the present invention is a laminate particularly suitable for the embossed type exterior body. As shown in FIG. 3 (a), the embossed type may be formed with a recess on one side, or as shown in FIG. These four sides may be heat sealed. In addition, there is also a type in which concave portions are formed on both sides across a folding portion as shown in FIG. 3 (c), a polymer battery is accommodated, and three sides are heat sealed.

  When the polymer battery packaging material is formed of, for example, nylon / adhesive layer / aluminum / adhesive layer / heat seal layer, the heat seal layer is formed by a sandwich lamination method, a dry lamination method, a coextrusion lamination method, a heat lamination method, or the like. When the outer casing of the polymer battery is an embossed type, delamination often occurs between the aluminum and the base material layer in the side wall during press molding, and the polymer battery body is stored in the outer casing. Delamination also occurred at the portion where the periphery was heat sealed. Moreover, the surface of the inner surface of aluminum may be attacked by hydrogen fluoride generated by the reaction between the electrolyte, which is a component of the battery, and moisture, and delamination may occur. In addition, it is preferable to use random polypropylene as the heat seal layer from the viewpoint of polymer battery protection, heat seal stability, laminate processability, economy, and the like. When the ethylene content is increased, Although it has the effect of preventing cracks from occurring over time, slipping with the male mold during emboss molding has deteriorated and wrinkles have occurred, making stable molding difficult.

  Therefore, the present inventors have good embossing formability, and are a laminate in which delamination between the base material layer and the barrier layer does not occur at the time of embossing molding or heat sealing, and also have content resistance. As a result of diligent research on packaging materials that are satisfactory as exterior bodies for polymer batteries, both surfaces of aluminum were subjected to chemical conversion treatment, and unsaturated carboxylic acid grafted polyolefin and polyolefin (film or film) were formed on the chemical conversion treatment surface on the aluminum content side. The resin was laminated by the sandwich lamination method or the co-extrusion method, and then the obtained laminate was heated to find that the above problems could be solved, and the present invention was completed. Furthermore, in order to stabilize the embossing moldability, the inner surface of the heat seal layer is coated with liquid paraffin, which improves the slipping with the embossed male mold and stabilizes the molding process. Contains liquid paraffin, the tensile properties (Young's modulus) are reduced, and no cracks occur when molded.

  As shown in FIGS. 1 (a) to 1 (d), the layer structure of the polymer battery packaging material of the present invention includes at least a base material layer 11, an adhesive layer 16, a chemical conversion treatment layer 15 (1), aluminum 12, It is a laminate 10 composed of a chemical conversion treatment layer 15 (2), a heat seal layer 14, and a liquid paraffin layer 15. The adhesion between the heat seal layer 14 and the chemical conversion treatment layer (2) is a dry lamination method, a sandwich lamination method, Lamination is performed by either coextrusion lamination method or thermal lamination method. Fig.1 (a) is sectional drawing which shows the layer structure of the laminated body obtained using a dry lamination method. FIG.1 (b) is sectional drawing which shows the layer structure of the laminated body obtained using a sandwich lamination method. FIG.1 (c) is sectional drawing which shows the layer structure of the laminated body obtained using a coextrusion lamination method. FIG.1 (d) is sectional drawing which shows the layer structure of the laminated body obtained using a thermal laminating method. Further, when the sandwich lamination method or the co-extrusion lamination method is used among the lamination methods, the obtained laminate is improved in adhesive strength by preheating or postheating described later. Moreover, by providing the liquid paraffin layer 15, the moldability is improved and the crack resistance of the heat seal layer is improved.

  When the polymer battery packaging material is an embossed type, as shown in FIG. 4, the laminated packaging material is press-molded to form the recess 7. At this time, if the slip between the press-molded male die 21 and the heat seal layer of the laminate 10 is poor, a stable molded product may not be obtained. When a random polypropylene resin is used as the heat seal layer 14 of the polymer battery packaging material for the embossed type outer package, it is stable against required properties such as heat resistance, no cracking, heat sealability, moisture resistance, etc. However, when the ethylene content of the random polypropylene is increased, the occurrence of cracks can be suppressed, but the sliding with the male mold 21 during molding becomes worse and the molding process becomes unstable. A scratch on the surface of the heat seal layer was generated, which became a fine scratch (light crack). Further, when polyethylene was used for the heat seal layer 14, the physical properties of the resin were softer than that of polypropylene, so the slipperiness was poor and a molded pinhole was likely to occur. As a result of diligent research, the present inventors have coated the liquid paraffin on the innermost surface of the random polypropylene layer or the linear low density polyethylene layer of the heat seal layer 14 so that the slip property is good, The present inventors have found that a packaging material that hardly generates cracks can be obtained, and have completed the present invention.

The liquid paraffin used in the present invention is a chain hydrocarbon oil, and its physical properties are a specific gravity of 0.83 to 0.87, a viscosity of 7.6 to 80 mm ^{2 /} S (37.5 ° C.), and a molecular weight of 300. The distillation temperature under the condition of 10 mmHg is about 140 to 245 ° C. As the liquid paraffin in the polymer battery packaging material of the present invention and the production method thereof, the distillation temperature under the conditions of specific gravity 0.83, viscosity 7.7 mm ^{2 /} S (37.5 ° C.), molecular weight 300, and 10 mmHg The thing of about 141 degreeC can be utilized suitably.

  By coating liquid paraffin on the heat seal layer of the polymer battery packaging material of the present invention, part or all of the liquid paraffin penetrates into the polypropylene layer or polyethylene layer of the heat seal layer and swells the polypropylene layer or polyethylene layer. It is considered that the heat seal layer becomes soft and easily stretched. That is, among the resin properties, the tensile properties (Young's modulus) change and become closer to the properties of polyethylene. When polyethylene is used as the heat seal layer, there are no problems such as whitening and cracking in molding, but heat resistance and slipperiness are poor. That is, according to the present invention, the heat resistance of polypropylene was maintained, and a heat seal layer having no problem in moldability could be obtained. Moreover, not only was the slipperiness improved by coating polyethylene with liquid paraffin, but the liquid paraffin penetrated into the polyethylene resin, so that the polyethylene became easier to stretch and its moldability was improved. As a result of coating liquid paraffin on the heat seal layer, the stress generated during emboss molding is dispersed, and cracks on the polypropylene surface layer (heat seal layer of polymer battery packaging material) generated during molding are reduced or eliminated. The liquid paraffin improved the surface slipperiness due to the effect as a lubricant.

As a method for coating liquid paraffin in the method for producing a polymer battery packaging material of the present invention, methods such as gravure coating (direct, reverse), three reverse roll coating, kiss touch coating, and spray coating can be used. For liquid paraffin, a coating amount in the range of ^{2 to} 6 g / m ² is appropriate. Next, the material etc. which comprise each layer of the laminated body which is a packaging material for polymer batteries of this invention are demonstrated with reference to FIG.1 (a)-FIG.1 (d).

  The base material layer 11 in the present invention is made of stretched polyester or nylon film. At this time, examples of the polyester resin include polyethylene terephthalate, polybutylene terephthalate, polyethylene naphthalate, polybutylene naphthalate, copolymer polyester, polycarbonate, and the like. Can be mentioned. Examples of nylon include polyamide resin, that is, nylon 6, nylon 6,6, a copolymer of nylon 6 and nylon 6,6, nylon 6,10, polymetaxylylene adipamide (MXD6), and the like.

  When the base material layer 11 is used as a polymer battery, the base material layer 11 is a part that comes into direct contact with the hardware. Considering the existence of pinholes in the film alone and the occurrence of pinholes during processing, the base material layer needs to have a thickness of 6 μm or more, and preferably 12 to 25 μm.

In the present invention, the base material layer 11 can be laminated in order to improve pinhole resistance and insulation when used as a battery outer package. When the base material layer is laminated, the base material layer includes at least one resin layer of two or more layers, and the thickness of each layer is 6 μm or more, preferably 12 to 25 μm. Examples of laminating the base material layer include the following 1) to 7) although not shown.
1) Stretched polyethylene terephthalate / stretched nylon 2) Stretched nylon / stretched polyethylene terephthalate Mechanical suitability of packaging materials (stability of conveyance in packaging machines and processing machines), surface protection (heat resistance, electrolyte resistance) Protecting the base material layer in the case of embossing the polymer battery exterior body as a secondary process when the embossing is used for reducing the frictional resistance between the mold and the base material layer In order to achieve this, it is preferable that the base material layer is multi-layered and a fluorine resin layer, an acrylic resin layer, a silicone resin layer, a polyester resin layer, or the like is provided on the surface of the base material layer. For example,
3) Fluorine resin / stretched polyethylene terephthalate (Fluorine resin is a film or formed by drying after liquid coating)
4) Silicone resin / stretched polyethylene terephthalate (silicone resin is a film or formed by drying after liquid coating)
5) Fluorine-based resin / stretched polyethylene terephthalate / stretched nylon 6) Silicone-based resin / stretched polyethylene terephthalate / stretched nylon 7) Acrylic resin / stretched nylon (Acrylic resin is film-like or cured after drying by liquid coating)

  The barrier layer 12 is a layer for preventing water vapor from entering the inside of the polymer battery from the outside, stabilizing the pinhole and processability (pouching, embossing formability) of the barrier layer alone, and In order to provide pinhole resistance, a metal such as aluminum or nickel having a thickness of 15 μm or more, or a film on which an inorganic compound such as silicon oxide or alumina is deposited may be used. ˜80 μm aluminum. In order to further improve the generation of pinholes and to make the polymer battery exterior body type an embossed type, in order to prevent the occurrence of cracks and the like in the embossing molding, the present inventors When the material has an iron content of 0.3 to 9.0% by weight, and preferably 0.7 to 2.0% by weight, the ductility of aluminum is improved compared to aluminum that does not contain iron. It has been found that the occurrence of pinholes due to bending is reduced as a laminate, and the side walls can be easily formed when the embossed type exterior body is formed. When the iron content is less than 0.3% by weight, effects such as prevention of pinholes and improvement of embossing formability are not observed, and the iron content of the aluminum exceeds 9.0% by weight. In such a case, the flexibility as aluminum is hindered, and the bag-making property is deteriorated as a laminate.

  In addition, aluminum produced by cold rolling changes its flexibility, waist strength and hardness under annealing (so-called annealing treatment) conditions, but the aluminum used in the present invention is harder than the non-annealed hard-treated product. Aluminum which tends to be soft with some or complete annealing is preferred. The degree of flexibility, waist strength, and hardness of aluminum, that is, the conditions for annealing, may be appropriately selected in accordance with processability (pouching, embossing). For example, in order to prevent wrinkles and pinholes at the time of emboss molding, annealed soft aluminum according to the degree of molding can be used.

  As a result of diligent research, the inventors of the present invention, as a result of diligent research, made a laminated body that can be satisfied as the packaging material by subjecting the aluminum front and back surfaces of the barrier layer 12 of the polymer battery packaging material to chemical conversion treatment. And was able to. Specifically, the chemical conversion treatment is to prevent delamination between aluminum and the base material layer during embossing by forming an acid-resistant film such as phosphate, chromate, fluoride, and triazine thiol compound. In addition, the hydrogen fluoride generated by the reaction between the electrolyte and moisture of the polymer battery prevents the aluminum surface from being dissolved and corroded, especially the aluminum oxide present on the aluminum surface from being dissolved and corroded. Improves adhesion (wetting), prevents delamination between the base material layer and aluminum during embossing and heat sealing, and prevents delamination on the inner surface of aluminum by hydrogen fluoride generated by the reaction between electrolyte and moisture The effect was obtained. As a result of conducting chemical conversion treatment on the aluminum surface using various substances and studying the effect, it is composed of three components of phenolic resin, chromium fluoride (3) compound and phosphoric acid among the acid-resistant film-forming substances. The treatment with phosphoric acid chromate using the prepared product was good.

  In the case where the exterior body of the polymer battery is an embossed type, delamination between the aluminum and the base material layer at the time of embossing can be prevented by performing chemical conversion treatment on both sides of the aluminum.

  When the acid-modified polypropylene resin 13 and the heat seal layer (polypropylene film) 14 are laminated on the chemical conversion treatment layer 2 by a sandwich lamination method or a coextrusion method, the acid-modified polypropylene is extruded onto the chemical conversion treatment surface. The adhesiveness of the resin is poor, and as a countermeasure, the present inventors applied an acid-modified polypropylene emulsion solution to the chemical conversion treated surface by a roll coating method or the like, dried, and baked at a temperature of 170 to 200 ° C. After performing, it was confirmed that the adhesive strength was improved when the co-extrusion was made into a laminate, but the baking processing speed was extremely slow and the productivity was poor.

  Therefore, as a result of intensive studies on a lamination method that shows stable adhesive strength without applying or baking acid-modified polypropylene, the present inventors have determined that the base layer 11 and one side of the barrier layer 12 that has been subjected to chemical conversion treatment on both sides are obtained. When dry laminating and extruding the acid-modified polyolefin 13 on the other surface of the barrier layer 12 to sandwich the heat seal layer (polypropylene film) 14, the acid-modified polypropylene resin 13 and the heat seal layer (polypropylene resin) 14 are A laminate having a predetermined adhesive strength could be obtained by co-extrusion to obtain a laminate, and heating the laminate to a condition where the acid-modified polypropylene resin had a softening point or higher. Specific examples of the heating method include a hot roll contact method, a hot air method, a near or far infrared method, and any heating method may be used in the present invention, and the adhesive resin is softened as described above. What is necessary is just to be able to heat above the point temperature.

  As another method, the adhesive strength can also be increased by heating to a condition in which the surface temperature of the aluminum heat seal layer reaches the softening point of the acid-modified polypropylene resin during the sandwich laminate or coextrusion laminate. A stable laminate could be obtained. When an adhesive resin layer is required, acid-modified polypropylene resin is used when the heat seal layer is polypropylene resin, and acid-modified polyethylene or polyethylene resin is used when the heat seal layer is polyethylene resin. When polyethylene resin is used as the adhesive resin, the laminated surface of the extruded polyethylene molten resin film on the aluminum side is laminated while being treated with ozone.

  In addition to the base material layer, barrier layer, adhesive resin layer, and heat seal layer (polypropylene or polyethylene), the laminate of the polymer battery packaging material of the present invention is a polyimide between the barrier layer and the adhesive resin layer. An intermediate layer made of a biaxially stretched film such as polyethylene terephthalate may be provided. The intermediate layer is laminated to improve strength as a packaging material for polymer batteries, to improve and stabilize barrier properties, and to prevent short circuit due to contact between the tab and the barrier layer during heat sealing of the polymer battery outer package. There is.

  For each layer in the laminate of the present invention, corona treatment, blasting is appropriately performed for the purpose of improving and stabilizing film forming properties, lamination processing, and suitability for final processing (pouching, embossing). Surface activation treatment such as treatment, oxidation treatment, and ozone treatment may be performed.

The heat seal layer 14 of the laminate in the packaging material for the polymer battery of the present invention, a polyolefin resin, i.e., a random polypropylene, homo polypropylene, a single layer film was formed as a film of a resin such as a block polypropylene, or the These are used as a single layer film formed from a resin blended with these resins and as a multilayer film thereof. The heat seal layer random polypropylene is preferably used. Alternatively, it can also be used as a single layer or multilayer film composed of a linear low density polyethylene, a medium density polyethylene single layer or multilayer, or a linear low density polyethylene, medium density polyethylene blend resin. Each type of polypropylene, i.e., random polypropylene, homo polypropylene, block polypropylene and linear low density polyethylene, a medium density polyethylene, low-crystalline ethylene - butene copolymer, low-crystalline propylene - butene copolymer, ethylene and butene and terpolymers consisting of ternary copolymer of propylene, silica, zeolites, antiblocking agent such as an acrylic resin beads (AB agent) be added to the slip agent of fatty acid amide-based Good. As the heat seal layer 14, it is preferable to use the above-mentioned random polypropylene, which is good in heat seal property between random polypropylenes, moisture-proof, heat-resistant, etc. 14 has the required protective properties, and also has good laminating properties and good embossing properties. As the random polypropylene used for the heat seal layer 14, (1) a density of 0.90 g / cm ³ or more, a Vicat softening point of 115 ° C. or more, and a melting point of 120 ° C. or more are desirable. The linear low density polyethylene or medium density polyethylene used for the heat seal layer 14 is preferably (1) a density of 0.91 g / cm ³ or more, a Vicat softening point of 70 ° C. or more, and a melting point of 110 ° C. or more.

  The random polypropylene may be a general random polypropylene having an ethylene content of 3 to 4%, but more preferably an ethylene-rich polypropylene having an ethylene content of 5 to 10%. By using random polypropylene as the heat seal layer 14, flexibility is imparted, and the effect of improving the bending resistance and preventing cracks during molding is also demonstrated. However, even if it is a random polypropylene, if the ethylene content increases, the slipperiness of the surface becomes worse. Therefore, in the present invention, as described above, the Young's modulus is increased by coating the innermost surface of the random polypropylene with liquid paraffin. It makes it easy to stretch by making it small, and improves slipperiness.

  As a laminating method for forming a laminate of polymer battery packaging material of the present invention, a dry laminating method, a sandwich laminating method using an apparatus 30 as shown in FIG. 5, a coextrusion laminating method using an apparatus 41 as shown in FIG. A heat laminating method or the like can be used.

  However, since random polypropylene, polyethylene, and liquid paraffin do not have heat-sealability with respect to metal, when heat-sealing a tab portion in a polymer battery, the process shown in FIGS. 7A, 7B, and 7C is performed. As shown, an adhesive film having heat sealability for both the metal and PE is interposed between the tab and the heat seal layer of the laminate to ensure sealing performance at the tab portion. . The adhesive film may be wound around a predetermined position of the tab as shown in FIGS. 7 (d), 7 (e), and 7 (f). As the adhesive film, the unsaturated carboxylic graft polyolefin, metal cross-linked polyethylene, a film made of a copolymer of ethylene or propylene and acrylic acid or methacrylic acid can be used.

  It is desirable that the base material 11 and the chemical conversion treatment surface of the barrier layer 12 in the polymer battery packaging material of the present invention are bonded together by a dry laminating method. Examples of the adhesive used for the dry lamination of the substrate 11 and the aluminum phosphate chromate-treated surface include polyester, polyethyleneimine, polyether, cyanoacrylate, urethane, organic titanium, and polyetherurethane. Epoxy, polyester urethane, imide, isocyanate, polyolefin, and silicone adhesives can be used.

The polymer battery packaging material of the present invention will be described more specifically with reference to examples. In each of the chemical conversion treatments, an aqueous solution composed of a phenol resin, a chromium fluoride (3) compound, and phosphoric acid was applied as a treatment liquid by a roll coating method, and baked under a condition that the film temperature was 180 ° C. or higher. The application amount of chromium is 10 mg / m ² (dry weight). Each of the following examples and comparative examples is an embossed type exterior body, both of which are of a single-sided embossed type, and the shape of the concave portion (cavity) of the mold is 30 mm × 50 mm and the depth is 3.5 mm, and is press molded. Was evaluated. In each example, a film made of unsaturated carboxylic acid graft linear low-density polypropylene having a thickness of 50 μm was wound around the sealing portion of the tab of the polymer battery as an adhesive film and heat-sealed.

Chemical conversion treatment was performed on both sides of aluminum 40 μm, and a stretched nylon film (thickness 25 μm) was bonded to one side of the chemical conversion treatment by a dry laminating method. By using the acid-modified polypropylene resin (20 μm) as the adhesive resin, the random polypropylene film (ethylene content 4%, 30 μm) serving as the heat seal layer is heated to a temperature higher than the softening point of the acid-modified polypropylene resin that is the adhesive resin. Sandwich lamination was performed to form a primary laminate. The primary laminate was coated with liquid paraffin (4 g / m ² , wet) on the innermost surface of the random polypropylene by a gravure reverse method using a separate apparatus to obtain Sample Example 1.

Chemical conversion treatment was performed on both sides of aluminum 40 μm, and a stretched nylon film (thickness 25 μm) was bonded to one side of the chemical conversion treatment by a dry laminating method. By using the acid-modified polypropylene resin (20 μm) as an adhesive resin, a random polypropylene film (ethylene content 7%, 30 μm) serving as a heat seal layer is heated to a temperature higher than the softening point of the acid-modified polypropylene resin that is an adhesive resin. Sandwich lamination was performed to form a primary laminate. The primary laminate was coated with liquid paraffin (4 g / m ² , wet) on the innermost surface of the random polypropylene by the gravure reverse method in the same apparatus to obtain Sample Example 2.

Chemical conversion treatment was performed on both sides of 40 μm aluminum, and a stretched nylon film (thickness 25 μm) was bonded to one side of the chemical conversion treatment by a dry laminating method. Next, acid-modified polypropylene was applied to the other side of the chemical conversion treatment aluminum. A random polypropylene film (ethylene content 4%, 30 μm) was sandwich-laminated as an adhesive resin (thickness 20 μm) to form a primary laminate. The primary laminate is heated to a temperature equal to or higher than the softening point of the acid-modified polypropylene resin with hot air, and then liquid paraffin (4 g / m ² , wet) is coated on the innermost surface of the random polypropylene by a gravure reverse method using a separate device. Thus, Sample Example 3 was obtained.

Both sides of aluminum 40 μm are subjected to chemical conversion treatment, and a stretched nylon film (thickness 25 μm) is bonded to one side of the chemical conversion treatment by a dry laminating method. Next, the other side subjected to chemical conversion treatment is subjected to acid conversion on the other side. Using a modified polypropylene as an adhesive resin (thickness 20 μm), a random polypropylene film (ethylene content 7%, 30 μm) was sandwich-laminated to form a primary laminate. The primary laminate is coated with liquid paraffin (4 g / m ² , wet) on the innermost surface of the random polypropylene by the gravure reverse method, and then heated to a temperature equal to or higher than the softening point of the acid-modified polypropylene resin by hot air in the same apparatus. Heated to obtain Sample Example 4.

Chemical conversion treatment was applied to both sides of 40 μm aluminum, and a stretched nylon film (thickness 25 μm) was bonded to one side of the chemical conversion treatment by a dry laminating method, and then acid-modified polypropylene was bonded to the other side of the chemical conversion treatment. As a (thickness 20 μm), a random polypropylene resin (ethylene content 4%, 30 μm) was co-extruded to obtain a primary laminate. The primary laminate is heated to a temperature equal to or higher than the softening point of the acid-modified polypropylene resin with hot air, and then liquid paraffin (4 g / m2) is applied to the innermost surface of the random polypropylene by a gravure reverse method using a separate apparatus. ² , Wet) to obtain specimen Example 5.

Both sides of aluminum 40 μm are subjected to chemical conversion treatment, and a stretched nylon film (thickness 25 μm) is bonded to one side of the chemical conversion treatment by a dry laminating method. Next, the other side subjected to chemical conversion treatment is subjected to acid conversion on the other side. A modified polypropylene was used as an adhesive resin (thickness 20 μm), and a random polypropylene resin (ethylene content 10%, 30 μm) was co-extruded to obtain a primary laminate. The random propylene resin layer of the primary laminate is coated with liquid paraffin (2 g / m ² , wet) by a post-gravure reverse method, and then heated to a temperature equal to or higher than the softening point of the acid-modified polypropylene resin with hot air in the same apparatus. Sample 6 was obtained.

Chemical conversion treatment was applied to both sides of 40 μm aluminum, and a stretched nylon film (thickness 25 μm) was bonded to one side of the chemical conversion treatment by a dry laminating method. After dry laminating (4%, 30 μm), liquid paraffin (6 g / m ² , wet) was coated on the innermost surface of the random polypropylene by the gravure reverse method to obtain Sample Example 7.

Chemical conversion treatment is applied to both sides of 40 μm aluminum, and a stretched nylon film (thickness 25 μm) is bonded to one side of the chemical conversion treatment by a dry laminating method. Next, acid-modified polypropylene resin is roll-coated on the other side of the chemical conversion treatment After coating by 180 ° C. and heating and drying at 180 ° C. for 3 seconds to form a 3 μm film as an adhesive resin, a random polypropylene film (ethylene content 7%, 30 μm) serving as a heat seal layer is heat laminated to form a primary laminate. Obtained. The primary laminate was coated with liquid paraffin (4 g / m ² , wet) on the innermost surface of random polypropylene by the gravure reverse method in the same apparatus to obtain Sample Example 8 .

A base layer composed of two layers obtained by subjecting both surfaces of 40 μm of aluminum to chemical conversion treatment and dry laminating a biaxially stretched polyester film of 12 μm and a biaxially stretched nylon film of 15 μm on one side of the chemical conversion treatment is performed by a dry lamination method (stretched nylon surface Next, the other surface subjected to chemical conversion treatment is coated with an acid-modified polypropylene resin by a roll coating method, and heated and dried at 180 ° C. for 3 seconds to form a 3 μm film as an adhesive resin. A random polypropylene film (ethylene content 7%, 30 μm) serving as a heat seal layer was heat-laminated to obtain a primary laminate. Using a separate apparatus, the primary laminate was coated with liquid paraffin (4 g / m ² , wet) on the innermost surface of random polypropylene by the gravure reverse method to obtain Sample Example 9.

Chemical conversion treatment was performed on both sides of 40 μm aluminum, and a stretched nylon film (thickness 25 μm) was bonded to one side of the chemical conversion treatment by a dry laminating method. Next, acid-modified polypropylene was applied to the other side of the chemical conversion treatment aluminum. As the adhesive resin (thickness 20 μm), the heat seal layers described in 1) to 7) below were sandwich-laminated to form a primary laminate. The primary laminate was heated to a temperature equal to or higher than the softening point of the acid-modified polypropylene resin with hot air, and then the innermost surface of the random polypropylene was coated with liquid paraffin (4 g / m ² , wet) by the gravure reverse method. 10 (7 types with different heat seal layers) was obtained.
1) Random polypropylene 25 / homo polypropylene 5
2) Random polypropylene 5 / homo polypropylene 20 / random polypropylene 5
3) homo polypropylene 25 / random polypropylene 5
4) Random polypropylene + terpolymer (100: 20)
5) random polypropylene + ethylene - butene copolymer (100: 15)
6) Random polypropylene + homo polypropylene (20:80)
7) Random polypropylene + homo polypropylene (80:20)
[Abbreviations /: Laminate, +: Blend, 1) to 3) indicate thickness μm, 4) to 7) () shows the blend ratio by weight) ]

Chemical conversion treatment was applied to both sides of 40 μm aluminum, and a stretched nylon film (thickness 25 μm) was bonded to one side of the chemical conversion treatment by a dry laminating method. A low-density polyethylene was used as an adhesive resin (thickness 20 μm), and a linear low-density polyethylene film (ethylene content 4%, 30 μm) was sandwich-laminated to form a primary laminate. The primary laminate is heated to a temperature equal to or higher than the softening point of the acid-modified polyethylene resin with hot air, and then liquid paraffin (4 g / m ² , wet) is formed on the innermost surface of the linear low density polyethylene by a gravure reverse method using a separate apparatus. ) Was coated to obtain Sample Example 11.

Chemical conversion treatment was applied to both sides of 40 μm aluminum, and a stretched nylon film (thickness 25 μm) was bonded to one side of the chemical conversion treatment by a dry laminating method. Next, medium density polyethylene was applied to the other side of the chemical conversion treatment aluminum. Extrusion was performed as an adhesive resin (thickness 20 μm), and the laminated surface on the aluminum side of the molten resin film was subjected to ozone treatment, and a linear low density polyethylene film 30 μm was sandwich-laminated to form a primary laminate. The inner surface of the linear low density polyethylene of the primary laminate is coated with liquid paraffin (4 g / m ² , wet) by the gravure reverse method, and then the temperature above the softening point of the acid-modified polyethylene resin by hot air in the same apparatus. The sample Example 12 was obtained.

[Comparative Example 1]
Chemical conversion treatment was performed on both sides of aluminum 40 μm, and a stretched nylon film (thickness 25 μm) was bonded to one side of the chemical conversion treatment by a dry laminating method. By using the acid-modified polypropylene resin (20 μm) as the adhesive resin, the random polypropylene film (ethylene content 4%, 30 μm) serving as the heat seal layer is heated to a temperature higher than the softening point of the acid-modified polypropylene resin that is the adhesive resin. Sample 1 was obtained by sandwich lamination.

[Comparative Example 2]
Chemical conversion treatment was applied to both sides of 40 μm aluminum, and a stretched nylon film (thickness of 25 μm) was bonded to one surface of the chemical conversion treatment by a dry laminating method. In a state heated above the softening point of the acid-modified polypropylene resin, which is a resin, an acid-modified polypropylene resin (20 μm) is used as an adhesive resin, and a random polypropylene film (ethylene content 7%, 30 μm) serving as a heat seal layer is sandwich-laminated. Thus, Sample Comparative Example 2 was obtained.

[Comparative Example 3]
Chemical conversion treatment was performed on both sides of 40 μm aluminum, and a stretched nylon film (thickness 25 μm) was bonded to one side of the chemical conversion treatment by a dry laminating method. Next, acid-modified polypropylene was applied to the other side of the chemical conversion treatment aluminum. As an adhesive resin (thickness 20 μm), a random polypropylene film (ethylene content 4%, 30 μm) is sandwich-laminated to form a primary laminate, and then the primary laminate is heated above the softening point of the acid-modified polypropylene resin by hot air. A sample comparative example 3 was obtained by heating to temperature.

[Comparative Example 4]
Chemical conversion treatment is applied to one side of 40 μm aluminum, and a stretched nylon film (thickness 25 μm) is bonded to the surface that has not been subjected to chemical conversion treatment by dry lamination, and then acid-modified polypropylene is adhered to the surface of the chemical-treated aluminum. As a resin (thickness 20 μm), a random polypropylene film (ethylene content 7%, 30 μm) is sandwich-laminated to form a primary laminate, and then the primary laminate is heated to a temperature higher than the softening point of the acid-modified polypropylene resin by hot air. To obtain Sample Example 4.

[Comparative Example 5]
One side of aluminum 40 μm is subjected to chemical conversion treatment, and a stretched nylon film (thickness 25 μm) is bonded to the surface not subjected to chemical conversion treatment by a dry laminating method. Next , acid-modified polypropylene is bonded to the surface subjected to chemical conversion treatment with an adhesive resin ( After forming a primary laminate by coextrusion laminating with a random polypropylene resin (ethylene content 4%, 30 μm) as a thickness 20 μm), the temperature of the primary laminate is higher than the softening point of the acid-modified polypropylene resin by hot air To Comparative Sample 5 was obtained.

[Comparative Example 6]
Both sides of aluminum 40 μm are subjected to chemical conversion treatment, and a stretched nylon film (thickness 25 μm) is bonded to one side of the chemical conversion treatment by a dry laminating method. Next, the other side subjected to chemical conversion treatment is subjected to acid conversion on the other side. A modified polypropylene is used as an adhesive resin (thickness: 20 μm) and a random polypropylene resin (ethylene content: 7%, 30 μm) is coextruded to form a primary laminate, and then the primary laminate is acid-modified polypropylene resin with hot air Sample Comparative Example 6 was obtained by heating to a temperature equal to or higher than the softening point.

[Comparative Example 7]
One side of aluminum 40 μm is subjected to a chemical conversion treatment, and a stretched nylon film (thickness 25 μm) is bonded to the surface not subjected to chemical conversion treatment by a dry laminating method. Next, a random polypropylene resin (ethylene content) 4%, 30 μm) was dry-laminated to obtain Sample Comparative Example 7.

[Comparative Example 8]
Chemical conversion treatment is applied to both sides of 40 μm aluminum, and a stretched nylon film (thickness 25 μm) is bonded to one side of the chemical conversion treatment by a dry laminating method. Next, acid-modified polypropylene resin is roll-coated on the other side of the chemical conversion treatment After coating by 180 ° C. and heating and drying at 180 ° C. for 2 seconds to form a 3 μm film as an adhesive resin, a random polypropylene film (ethylene content 4%, 30 μm) serving as a heat seal layer is heat laminated and specimen examples 8 was obtained.

[Comparative Example 9]
A laminate was prepared under the same conditions as in Example 1 except that heating was not performed, and Sample Comparative Example 9 was obtained.

[Comparative Example 10]
Except not heating, the laminated body was created on the same conditions as Example 2, and the specimen comparative example 10 was obtained.

[Comparative Example 11]
A laminate was prepared under the same conditions as in Example 3 except that heating was not performed, and Sample Comparative Example 11 was obtained.

[Comparative Example 12]
A laminate was prepared under the same conditions as in Example 4 except that heating was not performed, and Sample Comparative Example 12 was obtained.

[Comparative Example 13]
A laminate was prepared under the same conditions as in Example 11 except that heating was not performed, and Sample Comparative Example 13 was obtained.

<Evaluation method>
1) Formability The presence or absence of pinholes was confirmed.
2) Surface change of heat-seal layer after molding Immediately after molding, whitening (slight cracks) on the surface of the heat-seal layer was visually confirmed.
3) Delamination between the base material layer and the aluminum layer Immediately after molding, after heat-sealing at 190 ° C., 5 seconds, 98 N / cm ² , after leaving at 90 ° C. for 24 hours, delamination of the aluminum and base material layer The presence or absence was confirmed.
4) Content-resistant property As storage conditions, each specimen was stored in a thermostat at 60 ° C. and 90% RH for 7 days, and then the presence or absence of delamination between the aluminum and the heat seal layer was confirmed.

<Result>
In all of Examples 1 to 12, no pinholes were generated during embossing, the heat seal layer after molding was not whitened, and delamination between the base material and aluminum was not generated. In addition, delamination due to the resistant materials was not observed. In Comparative Examples 1 to 13, pinholes occurred in 1-2 samples out of 500 samples. Further, among the 500 samples, mild whitening was observed on the heat seal layer surface of the molded part in 1 to 3 samples. In Comparative Examples 9 to 13, there was no generation of molding wrinkles at the time of molding, and no whitening of the heat seal layer surface, pinholes at the time of molding, and delamination between the base material layer and the aluminum layer were not observed, but the resistance to physical properties All of them became delaminated. In Comparative Examples 1 to 8, there was no delamination in content resistance, but in Comparative Examples 4, 5 and 7, there was delamination between the base material and aluminum.

1 Polymer Battery 2 Polymer Battery Body 3 Cell (Power Storage Unit)
4 Tab (electrode)
5 Exterior body 6 Adhesive film (tab part)
7 Concave portion 8 Side wall portion 9 Seal portion 10 Laminated body (polymer battery packaging material)
11 Base material layer 12 Aluminum (barrier layer)
13 Acid-modified polyolefin layer (extrusion)
14 Heat seal layer (polypropylene)
15 Liquid paraffin layer 16 Chemical conversion treatment layer 17 Adhesive layer 18 Acid-modified polypropylene (coating)
DESCRIPTION OF SYMBOLS 20 Press molding part 21 Male type 22 Female type 23 Cavity 30 Sandwich laminating apparatus 31 Extruder 32 Die 33 Molten resin film 34 Chill roll 35 Crimp roll 36 Heat seal layer film 37 Laminate 40 Coextrusion laminating apparatus 41 Extruder 42 Die 43 Melting Resin film 44 Chill roll 45 Pressure bonding roll 46 Laminate

Claims (4)

For emboss molding, wherein at least a base material layer, an adhesive layer, a chemical conversion treatment layer 1, aluminum, a chemical conversion treatment layer 2, a heat seal layer, and a liquid paraffin layer are laminated in this order, and the heat seal layer is a polyolefin . packaging material for the polymer battery. The polymer battery packaging material for emboss molding according to claim 1, wherein the chemical conversion treatment is a phosphoric acid chromate treatment. Packaging material for polymer batteries for embossing according to claim 1 or claim 2, wherein the heat seal layer is a random polypropylene. The polymer battery packaging material for emboss molding according to claim 1 or 2, wherein the heat seal layer is linear low density polyethylene.

Images