Disclosed here is a battery including: an exterior body having a bottom wall; and a winding electrode body in which positive electrode, negative electrode and separator are wound about a winding axis. The winding electrode body has a flat shape having a pair of curvature parts having a curved outside surface and a flat part that connects the pair of curvature parts to each other and has a flat outside surface. When a line perpendicular to the winding axis of the winding electrode body and perpendicular to the bottom wall of the exterior body is assumed as L1, a portion positioned at an outermost periphery of the negative electrode in at least one of the pair of the curvature parts faces a portion positioned on a winding inner peripheral side of the negative electrode via the separator and not via the positive electrode on the line L1.

A battery cell includes: an electrode unit including a positive electrode, a negative electrode, a current collector, and a separator; a housing unit accommodating the electrode unit; a first insulator disposed inside the housing unit and between the electrode unit and the housing unit, an internal terminal disposed inside the housing unit and electrically connected to the current collector; a second insulator disposed inside the housing unit and between the internal terminal and the housing unit; and an external terminal disposed outside the housing unit. A contact surface of the first insulator with the electrode unit has indented shape. The first insulator is fixed to the housing unit.

An electrode packing device includes: a transferring unit that transfers a wound electrode; and a packaging unit for packaging the electrode transferred by the transferring unit, wherein the packaging unit includes: a packaging bag supporting part for supporting the inlet of the packaging bag in an opened state; an electrode supporting part that supports the electrode from the outside the packaging bag, after the electrode is put into the packaging bag; and a sealing part that seals the inlet of the packaging bag, and the electrode supporting part includes a gripper that presses the core of the electrode and a side pad that presses the side of the electrode in a state in which the electrode is put in the packaging bag.

An electrode packing device includes: a transferring unit that transfers a wound electrode; and a packaging unit for packaging the electrode transferred by the transferring unit, wherein the packaging unit includes: a packaging bag supporting part for supporting the inlet of the packaging bag in an opened state; an electrode supporting part that supports the electrode from the outside the packaging bag, after the electrode is put into the packaging bag; and a sealing part that seals the inlet of the packaging bag, and the electrode supporting part includes a gripper that presses the core of the electrode and a side pad that presses the side of the electrode in a state in which the electrode is put in the packaging bag.

To achieve the above objects, a battery case for a secondary battery, the battery case being a pouch type battery case that is configured to accommodate an electrode assembly therein, the electrode assembly including stacked electrodes and separators therein, the battery case according to an embodiment of the present invention including a first cup part and a second cup part each formed as a respective recess extending downward from a top surface of a pouch film; a bridge formed between the first cup part and the second cup part and having a constant width and height; and two complement parts disposed outside of respective first and second longitudinal ends of the bridge, each of the complement parts protruding upward from the top surface of the pouch film.

This disclosure provides a secondary battery, including: a case including an opening; an electrode assembly disposed within the case and including a main body and two tabs, the two tabs being both disposed facing the case; and a cap assembly including a cap plate, a lower insulating member and an explosion-proof valve, the cap plate sealing the opening, the explosion-proof valve being disposed on the cap plate, the lower insulating member being disposed on a side of the cap plate close to the electrode assembly, the lower insulating member including an inner side surface facing the main body, an outer side surface facing the cap plate, and a concave portion recessed from the inner side surface toward the outer side surface, the concave portion being in position corresponding to the explosion-proof valve, and the concave portion being used to buffer expansion and deformation of the main body.

A battery having an electrode assembly including a positive-electrode and a negative-electrode terminal attached to a sealing plate. The electrode assembly has surfaces parallel to a direction in which the positive and the negative electrode plates are stacked, the surfaces including one surface that faces the sealing plate. The positive and the negative electrode plate respectively include positive-electrode and a negative-electrode tabs respectively electrically connected to the positive-electrode and the negative-electrode terminals through positive-electrode and negative-electrode current collectors disposed between the electrode assembly and the sealing plate. The positive-electrode and the negative electrode tabs are welded to the respective positive-electrode and negative-electrode current collectors. A porous body that is electrically insulative is disposed between the one surface and the positive-electrode current collector and between the one surface and the negative-electrode current collector.

A metal-air battery includes a metal electrode, a positive electrode, an electrolyte, and an outer housing for housing them. A spacer is disposed between the metal electrode and the positive electrode. The spacer has a frame-shaped portion constituting an outer periphery, and an opening portion penetrating in a thickness direction. The frame-shaped portion has a communication portion that communicates with an outer edge of the frame-shaped portion and the opening portion, so that the electrolyte can flow inside and outside the frame-shaped portion, and the electrolyte can be preserved in the opening portion.

A molten sodium battery includes molten sodium making an anode active material, a cathode active material, a sodium container accommodating the molten sodium therein, a partition wall including an anode chamber in an interior thereof, and a cathode container air-tightly accommodating the cathode active material and the partition wall therein. The molten sodium battery further includes the cathode container including a joint having an Opening communicating an inside of the cathode container with an outside thereof, and the partition wall containing a partition-wall body within the cathode container having a plate shape which contains the anode chamber at around central site thereof in a thickness direction, and a through bore connecting the anode chamber with an outside of the anode chamber, and a head fitted into the opening in the joint and bonded integrally with the partition-wall body which is communicated with the anode chamber by the through bore.

A method for manufacturing an energy storage device according to one aspect of the present invention includes inserting an electrode assembly into a case while causing an insulating member having a sheet-like shape to follow a surface of the electrode assembly in which electrodes are layered. The insulating member includes a first portion corresponding to a first surface of the electrode assembly in a first direction which is a direction of a short side surface of the case and a thickness direction of the electrode assembly, a second portion corresponding to a first end surface which is an end surface of the electrode assembly in a second direction orthogonal to the first direction, a third portion corresponding to a second surface of the electrode assembly in the first direction, and a first extending portion extending from the first portion.