Systems, apparatuses, and methods are described herein for a power storage system, including a power storage configured to store electric power, a power output device operatively coupled to the power storage, wherein the power output device is configured to provide the electric power stored in the power storage to one or more power-consuming devices, a first power transfer component configured to receive the electric power from a power source, a second power transfer component configured to transfer the electric power to another power storage system, and a housing structurally supporting the power storage, the power output device, the first power transfer component, and the second power transfer component.

A battery module for a vehicle, in particular for an aircraft, comprises two end plates and a cell stack comprising an arrangement of several interconnected battery cells, in particular pouch cells, that are arranged in a row along a stacking direction, wherein the cell stack is sandwiched between the two end plates in the stacking direction, wherein the battery module further comprises a separate tube-like enclosure comprising a heat insulating material, the tube-like enclosure having a front opening and a back opening that are closed by the end plates, so that the tube-like enclosure and the two end plates form a housing in which the cell stack is accommodated.

A battery pack includes a housing and electrochemical cells disposed in the housing. The housing includes a container and a lid that closes an open end of the container. The container has a base, an outer wall the surrounds the base, and a first and a second inner wall disposed inside the outer wall. The first inner wall extends between, and is fixed to, a first portion and a third portion of the outer wall, and is spaced apart from a second portion and a fourth portion of the outer wall. The second inner wall extends between the first portion and the third portion, and is disposed between the first inner wall and the fourth portion. The second inner wall is movable relative to the outer wall such that spacing of the second inner wall from the first inner wall can be changed.

Batteries, battery components, and related methods and apparatus for mitigating a thermal runaway event of a battery are disclosed. Examples disclosed herein include a battery including an enclosure defining a cavity, the enclosure including a first end wall and a second end wall opposite the first end wall, a battery cell disposed in the cavity of the enclosure, a load spreader disposed in the cavity of the enclosure, the load spreader spaced from the first end wall, the battery cell disposed between the load spreader and the second end wall of the enclosure, the load spreader at least partially compressing the battery cell between the load spreader and the second end wall.

Batteries, battery components, and related methods and apparatus for mitigating a thermal runaway event of a battery are disclosed. Examples disclosed herein include a battery including an enclosure defining a cavity, the enclosure including a first end wall and a second end wall opposite the first end wall, a battery cell disposed in the cavity of the enclosure, a load spreader disposed in the cavity of the enclosure, the load spreader spaced from the first end wall, the battery cell disposed between the load spreader and the second end wall of the enclosure, the load spreader at least partially compressing the battery cell between the load spreader and the second end wall.

A battery cell, a battery, an electrical device, a manufacturing method, and a manufacturing device are. In some embodiments, the battery cell includes: a shell, where the shell includes a wall; and a pressure relief mechanism, where the pressure relief mechanism is disposed on the wall, the pressure relief mechanism includes a body portion and a fragile portion connected to the body portion, the body portion is configured to connect to the wall, and the pressure relief mechanism is configured to break the fragile portion when an internal pressure or temperature of the battery cell reaches a threshold, so as to release the pressure. The pressure relief mechanism further includes a reinforcement portion disposed in the body portion in a thickness direction of the body portion. The reinforcement portion is configured to reduce deformation of the body portion.

A battery cell, a battery, an electrical device, a manufacturing method, and a manufacturing device are. In some embodiments, the battery cell includes: a shell, where the shell includes a wall; and a pressure relief mechanism, where the pressure relief mechanism is disposed on the wall, the pressure relief mechanism includes a body portion and a fragile portion connected to the body portion, the body portion is configured to connect to the wall, and the pressure relief mechanism is configured to break the fragile portion when an internal pressure or temperature of the battery cell reaches a threshold, so as to release the pressure. The pressure relief mechanism further includes a reinforcement portion disposed in the body portion in a thickness direction of the body portion. The reinforcement portion is configured to reduce deformation of the body portion.

A lightweight battery housing for an automobile and method of assembling same. The lightweight battery housing comprises an upper cover, a tub, and a protection frame whereon the upper cover and lower tub sit. The upper cover and tub may comprise at least one of a steel material, an aluminum material, and/or a fiber-reinforced composite. The protection frame comprises at least one of steel material and aluminum material. The tub includes pockets for holding battery modules and seals against the cover to provide a leak-resistant battery holder. Fasteners connect the tub, cover, and protection frame and a seal is placed between the tub and the cover. The cover and other components of the battery housing may be integrated directly into a body-in-white of the vehicle.

Disclosed is a battery pack with improved durability and inner space efficiency to increase energy density. The battery pack includes a plurality of battery cells; a battery management unit configured to manage charging and discharging of the plurality of battery cells and including at least two printed circuit boards electrically connected to each other and arranged such that such that surfaces of the at least two printed circuit boards face each other; and an electrically insulating pack housing having an inner space in which the plurality of battery cells are accommodated and having a fixing unit being configured to fix the at least two printed circuit boards.

Disclosed is a battery pack with improved durability and inner space efficiency to increase energy density. The battery pack includes a plurality of battery cells; a battery management unit configured to manage charging and discharging of the plurality of battery cells and including at least two printed circuit boards electrically connected to each other and arranged such that such that surfaces of the at least two printed circuit boards face each other; and an electrically insulating pack housing having an inner space in which the plurality of battery cells are accommodated and having a fixing unit being configured to fix the at least two printed circuit boards.