A battery includes: a cell having a first surface and a second surface opposite to each other along a first axis; and a first electrode tab on the first surface of the cell. The first electrode tab includes: a first coupling piece including a first coupling portion coupled to the first surface of the cell; and a first lead-out piece extending from the first coupling piece outside a periphery of the cell along a second axis. The first coupling portion has a convex arc shape toward the first lead-out piece.

In solid-state lithium-ion battery cells, electrolyte-infiltrated composite electrode includes an electrolyte component consisting of polymer matrix with ceramic nanoparticles embedded in the matrix to form networking structure of electrolyte. The networking structure establishes effective lithium-ion transport pathway in the electrode. Electrolyte-infiltrated composite electrode sheets and solid electrolyte membranes can be used in all solid-state lithium electrochemical pouch and coin cells. Solid-state lithium-ion battery is fabricated by: (a) providing an anode layer; (b) providing a cathode layer; (c) positioning a ceramic-polymer composite electrolyte membrane between the anode layer and the cathode layer to form a laminar battery assembly; (d) applying pressure to the laminar battery assembly; and (e) heating the laminar battery assembly. Pressure-aided co-curing strengthens the contacts between the electrodes and the solid electrolyte membrane thus creating stable electrode-membrane interfaces with fewer porous regions. Lithium electrochemical cells and batteries exhibit excellent rate performance and outstanding stability over wide temperature range.

A button-type secondary battery of the present invention comprises: a first can having a first side surface extending vertically from a circumference of a first base surface; a second can having a second side surface extending vertically from a second base surface; and a gasket disposed between the first side surface and the second side surface when the first can and the second can are coupled to each other. The second base surface has a greater diameter than the first base surface, and the first can and the second can are coupled to each other with the first side surface inserted inside the second side surface. The first and second cans are fixed together by deforming the gasket so as to extend into a vent hole punched in the second side surface of the second can. A method for manufacturing the button-type secondary battery is also provided.

A rechargeable battery includes: an electrode assembly including a first electrode, a second electrode, and a separator disposed between the first electrode and the second electrode; a case that is connected to the first electrode to accommodate the electrode assembly, and includes an opening exposing the electrode assembly and a first side wall forming the opening; a cap plate that is coupled to the case to cover an outer area of the opening, and includes a through-hole exposing a central area of the opening and a second side wall overlapping the first side wall in a horizontal direction; a terminal plate that is connected to the second electrode to be insulation-bonded to the cap plate and covers the through-hole; and a first bonding layer that is positioned between the first side wall of the case and the second side wall of the cap plate, and bonds the first side wall and the second side wall.

Embodiments provide a secondary battery and a preparation method thereof, and a battery module, battery pack, and apparatus containing such secondary battery. In those embodiments, a negative electrode plate includes a negative-electrode current collector and a negative-electrode film layer that is disposed on at least one surface of the negative-electrode current collector and that includes a negative-electrode active material. The negative-electrode active material contains graphite, and the negative electrode plate satisfies that, when the negative electrode plate and a lithium metal sheet constitute a button battery which is discharged to 5.0 mV at 0.05C, a capacity increment curve V-dQ/dV of the button battery has a third-order lithiation phase transition peak of graphite at position 0.055V-0.085V.

A coin cell having a hermetic design withstands high performance applications including high temperature missions from a drop in replacement envelope. The coin cell can include a container having a bottom wall and a surrounding wall that form an interior volume, and the surrounding wall can include an inner, upper peripheral edge, at a top of the surrounding wall. The coin cell can include an anode assembly; a cathode assembly; and a header ring including a header ring outer surface and a header ring inner surface that defines an opening. The coin cell can include an insulator ring that includes an insulator ring outer surface that extends along and inside of the header ring inner surface, and an insulator ring inner surface that defines an opening within the insulator ring. A pin can be provided in the opening of the insulator ring. The coin cell can include an electrolyte.

Disclosed is a rechargeable battery including: an electrode assembly wound with a separator between a first electrode and a second electrode; a first exterior material including an opening receiving the electrode assembly and facing a bottom side of the electrode assembly; a second exterior material covering the opening, and combined to the first exterior material to seal an internal side of the first exterior material; and a reinforcing member having greater rigidity than the first exterior material and the second exterior material, disposed between the electrode assembly and the first exterior material, and including a side wall for surrounding a lateral side of the electrode assembly.

The present disclosure provides a battery cell structure of a button battery and a manufacturing method thereof, and a button battery, where the battery cell structure of the button battery includes a winding core which is formed by winding a laminated structure and is provided with a hollow inner hole, the laminated structure includes at least one positive electrode sheet, at least one negative plate, and a separator which separates the at least one positive electrode sheet from the at least one negative electrode sheet, at least two ends of the winding core are provided with a separator bonding layer wrapping the winding core, and the separator bonding layer is used for fixing the positive electrode sheet and the negative electrode sheet.

An electrically conductive holder (1′) for holding a tablet electrode (4) of a button battery (11′) pressed into the holder. The holder includes a bottom portion (3) and at least three supports (20) protruding outward from the bottom portion, the supports being positioned along the circumference of the holder so that the holder is supported by the supports. A wall portion (2) rises upward from the circumference of the bottom portion with the supports protruding from the bottom portion in the direction opposite the wall portion. Also, an assembly including the holder (1′) and a battery electrode tablet (4) pressed into the holder, and to a button battery (11′) including the assembly, and a method for producing a holder/tablet assembly by a compression process that uses a stamp (6′) provided with depressions (22) configured for deforming the bottom portion (3) of the holder during the compression process.

A power storage device with high capacity is provided. Alternatively, a power storage device with excellent cycle characteristics is provided. Alternatively, a power storage device with high charge and discharge efficiency is provided. Alternatively, a power storage device with a long lifetime is provided. A negative electrode active material is provided over a negative electrode current collector, and the negative electrode active material layer is formed in such a manner that first layers and second layers are alternately stacked. The first layer includes at least an element selected from Si, Mg, Ca, Ga, Al, Ge, Sn, Pb, Sb, Bi, Ag, Zn, Cd, As, Hg, and In. The second layer includes oxygen and the same element as the one included in the first layer.