A battery case, a battery, and an electronic device include a case body, a first cover body, a first insulating part, and a second cover body, where the case body includes a bottom wall and a side wall connected to the bottom wall; the first cover body includes a first surface and a second surface disposed opposite to each other; the second cover body includes a third surface and a fourth surface disposed opposite to each other; the first surface of the first cover body is connected to one end of the side wall away from the bottom wall, and the second surface of the first cover body is connected to the third surface of the second cover body by the first insulating part.

A battery case, a battery, and an electronic device include a case body, a first cover body, a first insulating part, and a second cover body, where the case body includes a bottom wall and a side wall connected to the bottom wall; the first cover body includes a first surface and a second surface disposed opposite to each other; the second cover body includes a third surface and a fourth surface disposed opposite to each other; the first surface of the first cover body is connected to one end of the side wall away from the bottom wall, and the second surface of the first cover body is connected to the third surface of the second cover body by the first insulating part.

A system for a pouch cell casing configured for use in an electric aircraft includes at least a pouch cell. The at least a pouch cell includes at least a pair of cell tabs, a battery cell, a pouch substantially encompassing the battery cell and the at least a pair of cell tabs. The at least a pouch cell includes at least a first side, a cell casing configured to substantially encompass the at least a pouch cell and including a first face disposed parallel and adjacent to the at least a first side, a second face disposed perpendicular and affixed to the first face, and at least an opening disposed on the first face opposite and adjacent to the at least a first side.

The present invention discloses a flame-retardant and explosion-proof battery pack for an electric vehicle and a manufacturing method thereof, the battery pack comprising: at least one battery brick consisting of batteries, which are electrically connected to define a positive electrode welding sheet and a negative electrode welding sheet; a battery brick positive electrode conducting wire and a battery brick negative electrode conducting wire, which are electrically connected to the positive electrode welding sheet and the negative electrode welding sheet, respectively; and a cover and a battery of brick container, which define a first storage space that is sufficient to accommodate the batteries, wherein the first storage space is filled with a flame-retardant oil so that the batteries are immersed in the flame-retardant oil, and the positive electrode conducting wire and the negative electrode conducting wire are exposed outside the first storage space to form a battery brick assembly.

The present invention discloses a flame-retardant and explosion-proof battery pack for an electric vehicle and a manufacturing method thereof, the battery pack comprising: at least one battery brick consisting of batteries, which are electrically connected to define a positive electrode welding sheet and a negative electrode welding sheet; a battery brick positive electrode conducting wire and a battery brick negative electrode conducting wire, which are electrically connected to the positive electrode welding sheet and the negative electrode welding sheet, respectively; and a cover and a battery of brick container, which define a first storage space that is sufficient to accommodate the batteries, wherein the first storage space is filled with a flame-retardant oil so that the batteries are immersed in the flame-retardant oil, and the positive electrode conducting wire and the negative electrode conducting wire are exposed outside the first storage space to form a battery brick assembly.

This application is applicable to the technical field of lithium batteries, and provides a full-tab cylindrical lithium battery cap and a full-tab cylindrical lithium battery, including an explosion-proof valve, an isolation ring, a connecting plate and a sealing ring, and the isolation ring is arranged between the explosion-proof valve and the connecting plate, the sealing ring is sleeved on an edge of the explosion-proof valve; the explosion-proof valve includes a connecting portion and an explosion-proof portion, the connecting portion is arranged along a circumference of the explosion-proof portion, and the edge of the connecting portion abuts on the sealing ring, the explosion-proof portion is provided with a rupture line, and the connecting portion is thicker than the explosion-proof portion. The full-tab cylindrical lithium battery cap provided in this application is formed by combining an explosion-proof valve, an isolation ring, a connecting plate and a sealing ring.

This application is applicable to the technical field of lithium batteries, and provides a full-tab cylindrical lithium battery cap and a full-tab cylindrical lithium battery, including an explosion-proof valve, an isolation ring, a connecting plate and a sealing ring, and the isolation ring is arranged between the explosion-proof valve and the connecting plate, the sealing ring is sleeved on an edge of the explosion-proof valve; the explosion-proof valve includes a connecting portion and an explosion-proof portion, the connecting portion is arranged along a circumference of the explosion-proof portion, and the edge of the connecting portion abuts on the sealing ring, the explosion-proof portion is provided with a rupture line, and the connecting portion is thicker than the explosion-proof portion. The full-tab cylindrical lithium battery cap provided in this application is formed by combining an explosion-proof valve, an isolation ring, a connecting plate and a sealing ring.

A pouch-type battery cell includes a battery case including a metal layer and polymer resin layer, and an electrode assembly disposed within the battery case, the battery case further including an electrode assembly receiving part formed in at least one of an upper case and a lower case of the battery case, and a venting member disposed on an outer surface of the electrode assembly receiving part at a location adjacent to a sealing part of the battery case, wherein the venting member is made of a shape memory alloy that is deformed to penetrate the battery case when a temperature of the venting member increases to a value above a transition temperature of the shape memory alloy. A battery module including the pouch-type battery cell, and a battery pack are also provided.

An energy storage system includes: stacked battery modules; and a rack accommodating the battery modules. The rack includes a sidewall disposed on one side of the battery modules, and the sidewall includes a fire-resistant member opposing the battery modules.

An energy storage system includes: stacked battery modules; and a rack accommodating the battery modules. The rack includes a sidewall disposed on one side of the battery modules, and the sidewall includes a fire-resistant member opposing the battery modules.