Abstract: In a film packaged body (11) formed by superimposing a pair of film molded articles (1) of the present invention, wherein the film molded article (1) in which a plurality of concave or convex embossed portions (3) disposed apart from each other are formed on a surface (2a) of a film (2), wherein the film (2) is made of a plastic material capable of adding a shape according to plastic deformation, wherein the plurality of embossed portions (3) are disposed on the surface of the film (2) to form an enclosed region (4) surrounded by the plurality of embossed portions (3) and imaginary lines (4a) that connect the plurality of embossed portions (3) is formed, and the plurality of embossed portions (3) are disposed at four areas on the surface (2a) of the film (2) to form the enclosed region (4) with rectangular shape, when an object is packaged by the film molded article (1), the plurality of embossed portions (3) and imaginary lines (4a) forming the enclosed region (4) are freely folded according to a shape or a

Abstract: A method for manufacturing a secondary battery having a film package by covering upper and lower sides of a laminate structure constituting a battery with a pair of film materials respectively and bonding the film materials together sequentially in a process direction from one end of the film materials to the other, the method including overlapping the film materials such that the laminate structure is sandwiched therebetween, and sealing one end of the overlapping part of the films, the one end being located at an upstream of the process direction, and bonding the overlapped film materials together at one or each of side portions thereof extending along the process direction sequentially in the process direction, while pressing a middle portion of the overlapped film materials sequentially in the process direction to thereby degas an internal space between the film materials, the middle portion being located between the side portions.

Abstract: An electricity storage system is provided that includes a plurality of cartridges connected together in parallel, each cartridge comprising a plurality of cells connected together, where each of the plurality of cartridges independently maintains a voltage convertible to a commercial voltage. The electricity storage system is configured to, upon receipt of a cartridge withdrawal signal input by a user and indicating a user's intention to withdraw any cartridge of the plurality of cartridges regardless of the operational state of a selected cartridge, including whether the selected cartridge is charging or discharging, disallow conductions with respect to the cartridge to be withdrawn and output a signal indicating that the selected cartridge is ready to be withdrawn.

Abstract: A sheet-laminated lithium ion secondary battery comprising: a membrane electrode assembly which comprises a cathode sheet comprising a cathode current collector having formed thereon a cathode active material layer, and an anode sheet comprising an anode current collector having formed thereon an anode active material layer, the cathode sheet and the anode sheet being laminated through a separator; and a sheet outer casing having accommodated therein the membrane electrode assembly, wherein, in the membrane electrode assembly, a sheet thermoplastic resin layer is inserted as at least one of an interlayer between the cathode sheet and the separator, and an interlayer between the anode sheet and the separator.

Abstract: An electricity storage system is provided that includes a plurality of cartridges connected together in parallel, each cartridge comprising a plurality of cells connected together, where each of the plurality of cartridges independently maintains a voltage convertible to a commercial voltage. The electricity storage system is configured to, upon receipt of a cartridge withdrawal signal input by a user and indicating a user's intention to withdraw any cartridge of the plurality of cartridges regardless of the operational state of a selected cartridge, including whether the selected cartridge is charging or discharging, disallow conductions with respect to the cartridge to be withdrawn and output a signal indicating that the selected cartridge is ready to be withdrawn.

Abstract: An electricity storage system comprising: a plurality of cartridges connected together in parallel, each cartridge comprising a plurality of cells connected together, and a circuit for preventing cross current, which restricts the current in each cartridge so as to cause the current to flow in one direction selected from a discharge direction and a charge direction, wherein said cartridges connected together in parallel are simultaneously charged with a direct current voltage converted from a commercial voltage, or said cartridges connected together in parallel are caused to discharge simultaneously so that said electricity storage system outputs a commercial voltage.

Abstract: A method for producing a laminate battery includes: forming a membrane electrode assembly having a multilayer structure including a positive electrode plate, a negative electrode plate and an electrolyte layer, the electrolyte layer being provided between the positive electrode plate and the negative electrode plate, a tab attachment step including joining terminal tabs to end portions of the positive electrode plate and the negative electrode plate of the membrane electrode assembly on an outer packaging material, and covering the membrane electrode assembly with the outer packaging material. Each terminal tab is joined by bending at least a part of the end portion of the outer packaging material in a direction opposite to the membrane electrode assembly, and then joining the terminal tab to the positive electrode plate or the negative electrode plate at a portion corresponding to the bent part of the end portion of the outer packaging material.

Abstract: A method for manufacturing a secondary battery having a film package by covering upper and lower sides of a laminate structure constituting a battery with a pair of film materials respectively and bonding the film materials together sequentially in a process direction from one end of the film materials to the other, the method including overlapping the film materials such that the laminate structure is sandwiched therebetween, and sealing one end of the overlapping part of the films, the one end being located at an upstream of the process direction, and bonding the overlapped film materials together at one or each of side portions thereof extending along the process direction sequentially in the process direction, while pressing a middle portion of the overlapped film materials sequentially in the process direction to thereby degas an internal space between the film materials, the middle portion being located between the side portions.

Abstract: In a film molded article (1) of the present invention, a plurality of concave or convex embossed portions (3) disposed apart from each other are formed on a surface (2a) of a film (2), and the plurality of embossed portions (3) are disposed on the surface of the film (2) to form an enclosed region (4) surrounded by the plurality of embossed portions (3) and imaginary lines (4a) that connect the plurality of embossed portions (3).

Abstract: A power generation device provided with a secondary battery includes a photoelectric conversion module, a secondary battery electrically connected to the photoelectric conversion module, and an outer casing in which the photoelectric conversion module and the secondary battery are installed. A low heat conducting material or a heat reflector is installed on at least a part of the space between the photoelectric conversion module and the secondary battery to be interposed between the photoelectric conversion module and the secondary battery.

Abstract: A sheet-laminated lithium ion secondary battery comprising: a membrane electrode assembly which comprises a cathode sheet comprising a cathode current collector having formed thereon a cathode active material layer, and an anode sheet comprising an anode current collector having formed thereon an anode active material layer, the cathode sheet and the anode sheet being laminated through a separator; and a sheet outer casing having accommodated therein the membrane electrode assembly, wherein, in the membrane electrode assembly, a sheet thermoplastic resin layer is inserted as at least one of an interlayer between the cathode sheet and the separator, and an interlayer between the anode sheet and the separator.

Abstract: A method for producing a laminate battery includes: forming a membrane electrode assembly having a multilayer structure including a positive electrode plate, a negative electrode plate and an electrolyte layer, the electrolyte layer being provided between the positive electrode plate and the negative electrode plate, a tab attachment step including joining terminal tabs to end portions of the positive electrode plate and the negative electrode plate of the membrane electrode assembly on an outer packaging material, and covering the membrane electrode assembly with the outer packaging material. Each terminal tab is joined by bending at least a part of the end portion of the outer packaging material in a direction opposite to the membrane electrode assembly, and then joining the terminal tab to the positive electrode plate or the negative electrode plate at a portion corresponding to the bent part of the end portion of the outer packaging material.

Abstract: An electricity storage system comprising: a plurality of cartridges connected together in parallel, each cartridge comprising a plurality of cells connected together, and a circuit for preventing cross current, which restricts the current in each cartridge so as to cause the current to flow in one direction selected from a discharge direction and a charge direction, wherein said cartridges connected together in parallel are simultaneously charged with a direct current voltage converted from a commercial voltage, or said cartridges connected together in parallel are caused to discharge simultaneously so that said electricity storage system outputs a commercial voltage.

Abstract: To make an arrangement so as not to give any damage to the central part of a substrate during the operation for removing unnecessary film coated on the outer peripheral part of the substrate. The stage is provided therein with a refrigerant chamber 41 as a heat absorber and a refrigerant such as water is filled in the chamber. A wafer 90 is contacted with and supported on the support surface 10a of the stage 10. A reactive gas for removing unnecessary film is supplied the outer periphery of the wafer 90 through a reactive gas jet port 30b while heating the outer periphery of the wafer 90. On the other hand, the area inside the outer peripheral part of the wafer 90 is heat-absorbed by the heat absorber.

Abstract: A blow-off part 152 is provided with a blow-off port 1a? which is dimensioned small enough so as not to allow a blow-off stream to be blown off directly to a part of a wafer W which part is located at the more internal side of the wafer than the outer edge of the wafer W and not to be subjected to plasmatizing process. A suction part 151 is provided with a suction port 81A in associating with the blow-off part 152. The suction port 81A is disposed proximate to the blow-off port 1a? and forms a suction stream oriented generally in the reverse direction with respect to the blow-off stream.

Abstract: An inner medium passage 17 is formed between an inner peripheral surface 12a of an annular inner electrode 11 and an annular inner passage formation member 15 received in the electrode 11. An annular first seal member 18 is interposed between upper peripheral sides of the electrode and the member 15. An annular second seal member 19 is interposed between a bottom flat surface 15b of the member 15 and a flange part 13 of the electrode 11. Bottom peripheral sides of the electrode 11 and the member 15 are confronted with each other substantially without the interposition of any gap. The inner electrode 11 is surrounded by an annular outer electrode 21 via a gap 1p as a gas passage in which a processing gas is plasmatized. An outer medium passage 27 is formed between an outer peripheral surface 22a of the electrode 21 and an annular outer passage formation member 25. Third and fourth seal member 28, 29 are interposed between the electrode 21 and the member 25 respectively.

Abstract: A blow-off part 152 is provided with a blow-off port 1a? which is dimensioned small enough so as not to allow a blow-off stream to be blown off directly to a part of a wafer W which part is located at the more internal side of the wafer than the outer edge of the wafer W and not to be subjected to plasmatizing process. A suction part 151 is provided with a suction port 81A in associating with the blow-off part 152. The suction port 81A is disposed proximate to the blow-off port 1a? and forms a suction stream oriented generally in the reverse direction with respect to the blow-off stream.

Abstract: To make an arrangement so as not to give any damage to the central part of a substrate during the operation for removing unnecessary film coated on the outer peripheral part of the substrate. The stage is provided therein with a refrigerant chamber 41 as a heat absorber and a refrigerant such as water is filled in the chamber. A wafer 90 is contacted with and supported on the support surface 10a of the stage 10. A reactive gas for removing unnecessary film is supplied the outer periphery of the wafer 90 through a reactive gas jet port 30b while heating the outer periphery of the wafer 90. On the other hand, the area inside the outer peripheral part of the wafer 90 is heat-absorbed by the heat absorber.

Abstract: A nozzle head NH of a plasma processing apparatus comprises an annular inner holder 3, an annular inner electrode 11 surrounding this holder 3, an annular outer electrode 21 surrounding this electrode 11, and an annular outer holder 4 surrounding this electrode 21. The inner holder 3 is provided with a plurality of bolts 7 spacedly arranged in the peripheral direction and adapted to push the inner electrode 11 radially outwardly. The outer holder 4 is provided with a plurality of bolts 8 spacedly arranged in the peripheral direction and adapted to push the outer electrode 21 radially inwardly. Owing to this arrangement, the operation for disassembling, assembling and centering the annular electrodes 11, 21 can be carried out with ease.

Abstract: To enhance a removing efficiency of unnecessary matters on a peripheral part of a substrate (90) such as wafer and to prevent particles from adhering to the substrate (90). A reactive gas is jetted out from a jet nozzle (75) toward a target spot (P) of the peripheral part of the substrate (90) in such a way that the reactive gas is made to flow approximately along a circumferential direction at the target spot (P) of the substrate (90) as viewed from a direction orthogonal to the substrate (90). Gases near the target spot (P) are sucked by a suction nozzle (76) along approximately the circumferential direction at a downstream side of the target spot (P).