Abstract: A method of manufacturing an electric power storage device includes a connection step of connecting an exposed portion, which is provided at one end in a direction of width of an electrode and constructed without a composite material layer being provided in a current collector, and a collector terminal provided on an outer side relative to the exposed portion in the direction of width of the electrode to each other. In the connection step, while a metal layer composed of a second metal higher in melting point than a first metal which forms the collector terminal lies between the exposed portion and the collector terminal, at least a portion of contact of the collector terminal with the metal layer is irradiated with energy.

Abstract: A secondary-battery collector terminal to be welded to an edge portion of an electrode body includes: a flat portion having a front surface and a back surface; and a welding projection portion having a linearly extending shape, the welding projection portion being formed by projecting a part of the flat portion. The welding projection portion has a shape projecting relative to the flat portion so that a front-surface side thereof exhibits a projecting shape and a back-surface side thereof exhibits a recessed shape. When a sectional shape of the welding projection portion in a direction perpendicular to an extending direction thereof is viewed, a surface shape of that first region of the welding projection portion which is placed on the front-surface is curved, and a surface shape of that second region of the welding projection portion which is placed on a back-surface side relative to the first region is flat.

Abstract: Provided are a laminated electrode-type battery having high joint strength and mechanical strength around a connecting portion between a positive-electrode current collector and a positive-electrode core member and around a connecting portion between a negative-electrode current collector and a negative-electrode core member, a manufacturing method therefor, a vehicle, and a device. The leading end of a positive-electrode core member and a positive-electrode current collector are joined by a connecting material. The melting point of the connecting material for positive-electrode is lower than that of the positive-electrode core member. Meanwhile, the leading end of a negative-electrode core member and a negative-electrode current collector are joined by a connecting material. The melting point of the connecting material for negative-electrode is lower than that of the negative-electrode core member.

Abstract: A secondary battery has an electrode laminated body and a collector member. The laminated body is formed of a laminated electrode sheet. The collector member is bonded to a collector foil laminated portion of the electrode sheet not formed with an active material layer. The collector foil laminated portion and the collector member are bonded at overlapped portions by resistance welding using electrodes. When a pressure welding direction is a projection direction, an area ratio (Yd)/(Xd) is 1.2-4, in which Xd is a projection area of a surface of the electrode made contact with the collector foil laminated portion and Yd is a projection area of a surface of the electrode made contact with the collector member.

Abstract: Provided are a laminated electrode-type battery having high joint strength and mechanical strength around a connecting portion between a positive-electrode current collector and a positive-electrode core member and around a connecting portion between a negative-electrode current collector and a negative-electrode core member, a manufacturing method therefor, a vehicle, and a device. The leading end of a positive-electrode core member and a positive-electrode current collector are joined by a connecting material. The melting point of the connecting material for positive-electrode is lower than that of the positive-electrode core member. Meanwhile, the leading end of a negative-electrode core member and a negative-electrode current collector are joined by a connecting material. The melting point of the connecting material for negative-electrode is lower than that of the negative-electrode core member.

Abstract: A secondary battery includes an electrode group 4 in which a positive electrode plate 1 and a negative electrode plate 2 are wounded with a porous insulation layer interposed therebetween, wherein an electrode plate end portion 1a protrudes from the porous insulation layer and abuts the current collector plate 5, and the current collector plate 5 is placed in relation to the electrode group 4 so as to entirely cover the end portion 1a of the electrode group 4. Parts of the electrode plate end portion 1a abutting the current collector plate 5 are welded to the current collector plate 5 at discrete joint portions 6 on the current collector plate 5, and the joint portions 6 are discretely provided on a surface of the current collector plate 5 so that a current flowing from the electrode plate 1 to the current collector plate 5 is uniformly distributed.

Abstract: A nonaqueous electrolyte secondary battery has a positive electrode including an active material of complex oxides capable of storing and emitting lithium ions, a negative electrode, a separator, and an electrolytic solution made of a nonaqueous solvent. A discharge curve of this battery when being discharged with a constant power has two or more points of step-like flections near the end of electrical discharge in a range of 5% to 20% of a discharge capacity thereof as determined from an initial discharge voltage in a state of full charge to a discharge-end voltage.

Abstract: It is possible to ensure welding of an exposed portion of an electrode core member protruding from one end surface of an electrode group to a desired connection portion of a current collector plate by constituting a battery wherein an end portion of a first electrode is protruding from an end portion of a second electrode and an end portion of a separator on one end surface of an electrode group, the protruding end portion of the first electrode includes an exposed portion of a first electrode core member, the exposed portion of the first electrode core member is welded to a connection portion on one surface of the first current collector plate, and an insulating layer is formed in an area except for a reverse face portion of the connection portion on the other surface of the first current collector plate.

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 lithium ion secondary battery of the invention includes an electrode structure including an electrode group composed of a strip-shaped laminate or winding including a positive electrode in which a positive electrode active material layer is attached to a positive electrode current collector, a negative electrode, and a separator; a positive electrode current collector plate including aluminum foil; and a negative electrode current collector plate electrically connected to the negative electrode. The positive electrode has, at one longitudinally extending end edge of the laminate, a positive electrode current collector-exposed portion protruding beyond the negative electrode.

Abstract: A secondary battery has a so-called tabless structure. An electrode group (4) includes an exposed end (1a) and a body portion (5). In the exposed end (1a), a current collector is exposed. In the body portion (5), an active material is provided on a surface of the current collector. A current collector plate (10) includes a principal surface (11) to which the electrode group (4) is connected, and projections (13) provided on the periphery of the principal surface (11). Moreover, in a direction in which a positive electrode plate (1), a porous insulating layer (3) and a negative electrode plate (2) are sequentially arranged, a width of the current collector plate (10) is equal to or smaller than a width of the body portion (5). Furthermore, the projections (13) sandwich the exposed end (1a) in a direction perpendicular to a longitudinal direction of the exposed end (1a).

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: It is possible to ensure welding of an exposed portion of an electrode core member protruding from one end surface of an electrode group to a desired connection portion of a current collector plate by constituting a battery wherein an end portion of a first electrode is protruding from an end portion of a second electrode and an end portion of a separator on one end surface of an electrode group, the protruding end portion of the first electrode includes an exposed portion of a first electrode core member, the exposed portion of the first electrode core member is welded to a connection portion on one surface of the first current collector plate, and an insulating layer is formed in an area except for a reverse face portion of the connection portion on the other surface of the first current collector plate.

Abstract: The electrochemical element includes an electrode assembly accommodated in a case with an electrolyte. The electrode assembly is formed into a flat shape by winding positive and negative electrodes with a separator interposed therebetween. The positive electrode includes an exposed positive current collector portion uncoated with an active material and formed in one end in the width direction of a strip-shaped positive current collector, and a positive lead is attached to the exposed positive current collector portion. The negative electrode includes an exposed negative current collector portion uncoated with an active material and formed in the other end in the width direction of a strip-shaped negative current collector, and a negative lead is attached to the exposed current collector portion. The exposed positive current collector portion on the one end is pressed and welded, and the exposed negative current collector portion on the other end is pressed and welded to form the electrode assembly.

Abstract: Positive and negative electrodes include exposed current collector portions at both lengthwise ends, and these exposed current collector portions are bent such as to protrude from the widthwise edge of the electrodes to form welding pieces. The positive and negative electrodes and a separator interposed therebetween are wound around into a flat shape having an ellipsoidal cross section. The welding pieces of the positive and negative electrodes protruding from opposite sides of the wound electrodes are welded together with respective leads. According to this configuration, a simple but high-quality current collector design capable of stable electrical connection in a high power output prismatic electrochemical element is provided.

Abstract: A sealed rechargeable battery has an electrode group formed by winding together a positive electrode and a negative electrode via a separator. A plurality of radial slits are provided in a welding section that is formed by an exposed section of a collector of at least one of the positive electrode and the negative electrode exposed at both ends of the electrode group. In the welding section, the exposed section is folded from the winding axis side toward the outer periphery to form a flat welding face.

Abstract: A secondary battery includes an electrode group 4 in which a positive electrode plate 1 and a negative electrode plate 2 are wounded with a porous insulation layer interposed therebetween, wherein an electrode plate end portion 1a protrudes from the porous insulation layer and abuts the current collector plate 5, and the current collector plate 5 is placed in relation to the electrode group 4 so as to entirely cover the end portion 1a of the electrode group 4. Parts of the electrode plate end portion 1a abutting the current collector plate 5 are welded to the current collector plate 5 at discrete joint portions 6 on the current collector plate 5, and the joint portions 6 are discretely provided on a surface of the current collector plate 5 so that a current flowing from the electrode plate 1 to the current collector plate 5 is uniformly distributed.