This present application relates to a battery assembly and an electronic cigarette. The battery assembly comprises a battery including a first battery electrode and a second battery electrode. The battery assembly further includes a first charging electrode and a second charging electrode electrically connected to the first battery electrode and the second battery electrode correspondingly, and the battery assembly defines a first insertion hole and a second insertion hole at positions corresponding to the first charging electrode and the second charging electrode respectively; the first charging electrode and the second charging electrode are electrically connected to an external charger to supply charging power to the battery. By implementing the battery assembly and the electronic cigarette, the electronic cigarette can be directly inserted into the external charger to be charged, and the battery assembly and the atomization assembly do not need to be separated from each other.

A flexible secondary battery includes: an electrode assembly including a first electrode layer, a second electrode layer, and a separator between the first electrode layer and the second electrode layer; a gasket having flexibility and surrounding edges of the electrode assembly; a first sealing sheet attached to a first surface of the gasket; and a second sealing sheet attached to a second surface of the gasket facing away from the first surface, wherein an uneven pattern is at a bendable area of the gasket.

A flexible electrochemical device in which a plurality of electrode assemblies is electrically connected to each other so that the flexible electrochemical device may be repeatedly bent, includes at least two electrode assemblies that are arranged separate from each other and a casing member that packs the at least two electrode assemblies and includes at least two accommodation portions in which electrode assemblies are individually received, and a connecting portion that connects the at least two adjacent accommodation portions where a path between a conductive line that electrically connects at least two electrode assemblies together and an electrolyte is defined in the connecting portion.

A thermal runaway containment apparatus for a battery includes an enclosure base configured to receive a battery therein, an enclosure lid, and a lid constraining structure. The enclosure base has an interconnected floor and side walls, with a top rim defining an open top. The enclosure lid is seatable on the top rim in a seated position that closes the enclosure base. The lid constraining structure is positioned above the lid such that vertical movement of the lid is constrained between the seated position and a maximum partially separated position. When the lid is in the maximum partially separated position, a tortuous flow path into the base is defined; the tortuous flow path allows for venting of pressurized gases out of the enclosure base while impeding inflow of gases at a lower pressure than the pressurized gases into the enclosure base.

The present invention relates to a battery package attached to an external substrate, which includes an electronic circuit and a power terminal electrically connected to the electronic circuit, to supply power to the electronic circuit, or to accumulate energy by collecting power. A battery package, according to an exemplary embodiment, comprises: a battery unit that has one or more secondary battery cells and leads that are connected to the secondary battery cells and exposed; a flexible encapsulation body that accommodates the battery unit therein; exposed electrodes that are exposed on the surface of the flexible encapsulation body and are electrically connected to the leads to electrically connect to the electronic circuit; and a first Velcro part mounted on the surface of the flexible encapsulation body.

Provided is a flexible battery. A flexible battery according to an exemplary embodiment of the present invention includes: an electrode assembly; and an exterior material in which the electrode assembly is encapsulated together with an electrolyte, in which the electrode assembly and the exterior material are formed such that patterns for contraction and extension in a longitudinal direction have the same directionality when the flexible battery is bent. As such, the patterns for contraction and extension in the longitudinal direction are formed on both of the exterior material and the electrode assembly, thereby preventing or minimizing deterioration in the required physical properties even though the flexible battery is bent.

This electricity storage device is provided with an electrode assembly. The electrode assembly is constructed by laminating two electrodes of different polarities and a separator disposed between the electrodes with the electrodes being insulated from each other. Each of the electrodes has a metal foil and active material layers that are formed by coating an active material on the metal foil in a coating direction. The elongation rate of the separator varies in different directions, and the separator has a direction in which the elongation rate is higher than in the other directions. The higher elongation rate direction of the separator intersects the coating direction of the active material on at least one of the electrodes.

These present disclosure provides a flexible battery comprising a top layer and a bottom layer coupled at a number of attachment points to form chambers within the battery to retain a shape of the battery under an increase in internal pressure. The flexible battery can include an anode and separator and a cathode, where the separator is a flexible polymer.

Provided are a lithium secondary battery, which includes an electrode assembly, a battery case accommodating the electrode assembly, a surface layer comprising an engineering plastic located on the outer side of the battery case, and lead terminals connected with the electrode assembly and drawn out of the battery case, and a method of fabricating the same.

A method of sealing together two elements of a bipolar battery, the method comprising: interposing an inductive heating element between the two elements; applying a current to the inductive heating element to generate localized heat to melt material in the vicinity of the heating element to seal the two elements together.