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.

Arrangements for retaining coiled battery internals in a coiled orientation within a cell casing, in which end caps and/or sleeves are provided with at least one inward-facing protuberance for engaging and securing the coiled battery internals, and means for securing and aligning pouch cell batteries within a sleeve.

The present invention discloses an integrally-formed rechargeable battery and a production method thereof. The integrally-formed rechargeable battery includes an integrally-formed metal sleeve, which serves as a negative electrode conductor of the lithium battery. The integrally-formed metal sleeve is a cylindrical case, an end surface of one side of the integrally-formed metal sleeve is of a closed structure, and an end surface of the other side of the integrally-formed metal sleeve is an annular portion with a hole in the middle, A cell assembly is installed within the integrally-formed metal sleeve. The cell assembly includes a cell, a circuit board, an exposed charging interface and a positive electrode conductor. The positive electrode conductor is exposed from the hole in the middle of the annular portion.

A flexible hybrid electronics (FHE) device includes a common flexible substrate with a first surface and a second surface opposite the first surface. A printed circuit is coupled to the first surface of the common flexible substrate. A battery is coupled to the second surface of the common flexible substrate. At least one via connects the battery to the printed circuit through the common flexible substrate.

Disclosed herein is an electronic device including a substrate, with an active layer stack on the substrate. A cover is on the active layer stack and has a surface area greater than that of the active layer so as to encapsulate the active layer stack. A conductive pad layer is on the cover. At least one conductive via extends between the active layer stack and the conductive pad layer.

A sealing body for sealing an upper opening of a battery can having a tube shape with a closed bottom includes an electrode terminal, a sealing plate, and gaskets. The electrode terminal includes a flat plate-shaped stepped portion in an area of a lower surface of a flat plate-shaped terminal portion. The electrode terminal has an inserting portion extending downward in a columnar shape on a lower surface of the stepped portion, and a protrusion in a non-circular planar shape that goes around the inserting portion. The sealing plate has an opening, and has an upper surface and a lower surface on which a non-circular sealing-plate recessed portion and a sealing-plate protruding portion are formed. The gaskets have a shaft portion inserted through the opening of the sealing plate, and a protruding portion that engages the sealing-plate recessed portion and a recessed portion that engages the sealing-plate protruding portion.

Disclosed is a pouch-type secondary battery, which includes an electrode assembly having a positive electrode plate and a negative electrode plate disposed to face each other and a pouch case having a concave groove formed to accommodate the electrode assembly, wherein the pouch case includes a first pouch film and a second pouch film thermally fused to the first pouch film, and wherein a concave groove is formed in at least one of the first pouch film and the second pouch film, and the concave groove has a bottom surface on which the electrode assembly is placed so that the bottom surface has an area equal to or greater than an area of a reference surface that covers an opening of the concave groove.

A stretchable composite electrode comprising a carbon nanotube active material composite layer is provided. The stretchable composite electrode comprises a plurality of carbon nanotube film structures and a plurality of active material layers. Each of the plurality of active material layers is located between adjacent carbon nanotube film structures. Each of the plurality of carbon nanotube film structures comprises a plurality of super-aligned carbon nanotube films stacked with each other. A surface of the carbon nanotube active material composite layer comprises a plurality of wrinkles. A stretchable composite electrode using the stretchable composite electrode is also provided.

A battery cell includes a battery element, a front lid member covering one end portion of the battery element in a predetermined direction, and an exterior film at least partially wrapped around the predetermined direction of the battery element. The exterior film is rounded along the battery element in at least one corner of the battery element around the predetermined direction.

A bipolar battery includes N battery cores each comprising a cathode electrode, an anode electrode, and a separator, where N is an integer greater than one. N?1 bipolar plates include a first layer made of a first material, a second layer made of a second material, a center portion, and first and second sides extending transversely relative to the center portion. A battery enclosure including a cover and a lower portion including sides defining a cavity. The N?1 bipolar plates are arranged in the cavity between adjacent ones of the N battery cores and the N battery cores are connected in series by the N?1 bipolar plates. The first and second sides of the N?1 bipolar plates are one of inserted into L-shaped slots in the sides of the lower portion, and molded into the sides of the lower portion.