Abstract: An electrode 13 has an active material layer 12 formed on each of two whole main surfaces of a current collector 11. A part of an electrode lead 14 overlaps the electrode 13. One end face of the electrode 13 in the width direction of the electrode 13 is flush with one end face of the electrode lead 14. Joints 15 are formed at the one end of the electrode 13 in the width direction. The joints 15 join the electrode 13 and the electrode lead 14 so as to provide electrical continuity between the exposed part of the current collector 11 at the one end face of the electrode 13 in the width direction and the electrode lead 14. The joints 15 are formed, for example, by plasma welding.

Abstract: An electrode group 4 having a positive electrode plate and a negative electrode plate arranged with a porous insulating layer interposed therebetween and end portions of the positive and negative electrode plates protruding from the porous insulating layer is prepared, and current collector plates 10 and 11 each of which is provided with a projection 12 having a gap 12a formed therein is prepared. With the end portion 2a of the electrode plate protruding from the porous insulating layer 3 kept in contact with a principle surface of the current collector plates 10 and 11, the projection 12 is locally heated to join the end portion 2a of the electrode plate and the current collector plates 10 and 11. the end portion 2a of the electrode plate is welded to the current collector plates 10 and 11 with a fused material obtained by fusing the projection 12.

Abstract: An electrode group 4 having a positive electrode plate and a negative electrode plate arranged with a porous insulating layer interposed therebetween and end portions of the positive and negative electrode plates protruding from the porous insulating layer is prepared, and current collector plates 10 and 11 each of which is provided with a projection 12 having a gap 12a formed therein is prepared. With the end portion 2a of the electrode plate protruding from the porous insulating layer 3 kept in contact with a principle surface of the current collector plates 10 and 11, the projection 12 is locally heated to join the end portion 2a of the electrode plate and the current collector plates 10 and 11. the end portion 2a of the electrode plate is welded to the current collector plates 10 and 11 with a fused material obtained by fusing the projection 12.

Abstract: A method includes: preparing an electrode group 4 in which a positive electrode 1 and a negative electrode 2 are arranged with a porous insulating layer interposed therebetween, with an end 1a, 2a of at least one of the positive and negative electrodes protruding from the porous insulating layer; preparing a current collector 10 on a first principal surface of which a plurality of protrusions having vertexes are formed; bringing the end 1a, 2a of the at least one of the positive and negative electrodes into contact with a second principal surface of the current collector 10; and generating an electric arc toward the vertexes of the protrusions 11 to melt the protrusions 11, thereby welding the end 1a, 2a of the at least one of the positive and negative electrodes to the current collector 10 by a molten material 12 of the protrusions 11.

Abstract: A current collector terminal plate comprising a plate-shaped conductive material is used. The conductive material has an expected welding portion that melts with priority. The conductive material has, for example, a bent portion forming a protrusion on one side and a depression on the other side and a flat portion, and the expected welding portion includes the bent portion. The bent portion has a pair of upstanding portions raised from the flat portion and a bent top portion extending continuously from the pair of upstanding portions.

Abstract: An electrode group 4 having a positive electrode plate and a negative electrode plate arranged with a porous insulating layer interposed therebetween and end portions of the positive and negative electrode plates protruding from the porous insulating layer is prepared, and current collector plates 10 and 11 each of which is provided with a projection 12 having a gap 12a formed therein is prepared. With the end portion 2a of the electrode plate protruding from the porous insulating layer 3 kept in contact with a principle surface of the current collector plates 10 and 11, the projection 12 is locally heated to join the end portion 2a of the electrode plate and the current collector plates 10 and 11. the end portion 2a of the electrode plate is welded to the current collector plates 10 and 11 with a fused material obtained by fusing the projection 12.

Abstract: An electrode 13 has an active material layer 12 formed on each of two whole main surfaces of a current collector 11. A part of an electrode lead 14 overlaps the electrode 13. One end face of the electrode 13 in the width direction of the electrode 13 is flush with one end face of the electrode lead 14. Joints 15 are formed at the one end of the electrode 13 in the width direction. The joints 15 join the electrode 13 and the electrode lead 14 so as to provide electrical continuity between the exposed part of the current collector 11 at the one end face of the electrode 13 in the width direction and the electrode lead 14. The joints 15 are formed, for example, by plasma welding.

Abstract: A laser beam 21 outputted by a laser oscillator 3 is collected by a machining head 4, so that the surface of a roller 2 is irradiated with the laser beam. An encoder 5c outputs a signal in accordance with a rotational position of the roller 2. A control portion 24 controls the laser oscillator 3 to irradiate the roller 2 at the same spots on the surface with the laser beam 21 per rotation of the roller 2, the irradiation being repeated a plurality of times, thereby forming recesses in the surface of the roller.

Abstract: The invention relates to a battery current collector including a metal foil for carrying at least a positive electrode active material or a negative electrode active material. At least one side of the metal foil has a compressed base plane and non-compressed protrusions arranged at a predetermined interval, and the non-compressed protrusions are formed at the same time as formation of the base plane. The surface roughness of the base plane is different from the surface roughness of the protrusions, and the surface roughness of the base plane is preferably an arithmetic mean roughness of 0.8 ?m or less.

Abstract: An objective is to improve the mechanical strength and the durability of a current collector for a non-aqueous electrolyte secondary battery and to allow an active material layer to be efficiently carried on the surface of the current collector with high adhesion. This objective is achieved with the use of a pair of processing means being disposed such that the surfaces thereof are in press contact with each other to form a press nip for passing a sheet material therethrough and having a plurality of recesses formed on the surface of at least one of the processing means, by passing a metallic foil for current collector through the press nip between the processing means to perform compression, thereby to form a plurality of projections on at least one surface of the metallic foil for current collector by partial plastic deformation associated with the compression.

Abstract: An electrode group 4 having a positive electrode plate and a negative electrode plate arranged with a porous insulating layer interposed therebetween and end portions of the positive and negative electrode plates protruding from the porous insulating layer is prepared, and current collector plates 10 and 11 each of which is provided with a projection 12 having a gap 12a formed therein is prepared. With the end portion 2a of the electrode plate protruding from the porous insulating layer 3 kept in contact with a principle surface of the current collector plates 10 and 11, the projection 12 is locally heated to join the end portion 2a of the electrode plate and the current collector plates 10 and 11. the end portion 2a of the electrode plate is welded to the current collector plates 10 and 11 with a fused material obtained by fusing the projection 12.

Abstract: A method of manufacturing a multicell battery by connecting a plurality of cells in series, with the purposes of improving the charge/discharge characteristics and enhancing the productivity of the manufacturing process. A convex electrode terminal formed in the upper part of one cell is welded to one end of a lead tab, and another cell is disposed above the cell connected to the lead tab so that the center lines of the two cells are parallel. A flat electrode terminal formed in the lower part of the other cell and another end of the lead tab are welded indirectly.