A battery includes a battery case including a housing having side walls defining a first open end and a second open end, the battery case including a separate top cover to cover the first open end of the housing and a separate bottom cover to cover the second open end of the housing; a first electrode located within the case; a second electrode located within the case; a first terminal coupled to the first electrode and exposed outside the case; and a second terminal coupled to the second electrode and exposed outside the case.

A battery includes a battery case including a housing having side walls defining a first open end and a second open end, the battery case including a separate top cover to cover the first open end of the housing and a separate bottom cover to cover the second open end of the housing; a first electrode located within the case; a second electrode located within the case; a first terminal coupled to the first electrode and exposed outside the case; and a second terminal coupled to the second electrode and exposed outside the case.

To provide a solid-state battery capable of achieving high capacity. A solid-state battery including a multilayer body including a stack of a plurality of electrode layers including positive electrode layers and negative electrode layers and solid electrolyte layers each disposed between the electrode layers, the multilayer body having a columnar shape; and the solid-state battery including a positive electrode terminal and a negative electrode terminal disposed at both end portions of the multilayer body; a positive electrode tab electrically connected to the positive electrode layer and the positive electrode terminal; and a negative electrode tab electrically connected to the negative electrode layer and the negative electrode terminal, wherein the positive electrode tab and the negative electrode tab are spirally wound on an outer peripheral surface of the multilayer body.

Disclosed herein is a battery cell including an insulator assembly, wherein, when a needle-shaped conductor passes through the insulator assembly, a part of the insulator assembly into which a needle-shaped end part of the needle-shaped conductor is inserted is fallen and pass through the electrode assembly together with the needle-shaped conductor, and a planar shape of a through-hole of the electrode assembly is determined by the fell-off part of the insulator assembly.

Disclosed herein is a battery cell including an insulator assembly, wherein, when a needle-shaped conductor passes through the insulator assembly, a part of the insulator assembly into which a needle-shaped end part of the needle-shaped conductor is inserted is fallen and pass through the electrode assembly together with the needle-shaped conductor, and a planar shape of a through-hole of the electrode assembly is determined by the fell-off part of the insulator assembly.

An alkaline battery includes a tubular battery case, a positive electrode filled in the battery case and including a stack of n pieces of hollow tubular pellets, a negative electrode disposed in hollow portions of the pellets, a separator disposed between the positive electrode and the negative electrode, and an alkaline electrolytic solution. The battery case includes a body portion having a thickness of 0.15 mm or less. The positive electrode contains manganese dioxide and a conductive agent, and n is an integer of 3 or more. First resistance is higher than second resistance, where the first resistance is resistance of at least one pellet positioned in a middle portion in a height direction of the stack, and the second resistance is resistance of at least one pellet positioned in end portions in the height direction of the stack.

An alkaline battery includes a tubular battery case, a positive electrode filled in the battery case and including a stack of n pieces of hollow tubular pellets, a negative electrode disposed in hollow portions of the pellets, a separator disposed between the positive electrode and the negative electrode, and an alkaline electrolytic solution. The battery case includes a body portion having a thickness of 0.15 mm or less. The positive electrode contains manganese dioxide and a conductive agent, and n is an integer of 3 or more. First resistance is higher than second resistance, where the first resistance is resistance of at least one pellet positioned in a middle portion in a height direction of the stack, and the second resistance is resistance of at least one pellet positioned in end portions in the height direction of the stack.

An electrode assembly, a rechargeable battery comprising the same, and a method for manufacturing the rechargeable battery are provided. The electrode assembly comprises an electrode stack in which a plurality of electrodes and a plurality of separators are alternately combined. The electrode assembly also comprises an electrode tab part including a plurality of electrode tabs respectively connected to the plurality of electrodes to extend from a side surface of the electrode stack. The electrode tab part comprises an inclined portion provided on a first side thereof and a tab collection portion provided on a second side thereof, the inclined portion extends from the side surface of the electrode stack and bent in a direction, in which the plurality of electrode tabs are collected, and the tab collection portion extends from the inclined portion and has a shape in which the plurality of electrode tabs are joined.

A LiO.sub.2 battery and method for fabricating the same are provided herein. The battery cathode comprises a carbon structure filled with a palladium nanoparticle catalyst, including palladium-filled carbon nanotubes (CNTs). The carbon structure provides a barrier between the catalyst and the electrolyte providing an increased stability of the electrolyte during both discharging and charging of a battery.

A LiO.sub.2 battery and method for fabricating the same are provided herein. The battery cathode comprises a carbon structure filled with a palladium nanoparticle catalyst, including palladium-filled carbon nanotubes (CNTs). The carbon structure provides a barrier between the catalyst and the electrolyte providing an increased stability of the electrolyte during both discharging and charging of a battery.