A battery array frame according to an exemplary aspect of the present disclosure includes, among other things, a frame body, and a thermal fin including a body embedded in the frame body and a leg that extends outside of the frame body. The thermal fin is flexible between a first position in which the leg is spaced farther from a surface of the frame body and a second position in which the leg is spaced closer to the surface of the frame body.

A lithium-ion battery thermal management system and method based on PCM and mutually embedded fins. The thermal management system includes a battery box, a lithium-ion battery pack and a temperature detection unit are arranged in the battery box; the lithium-ion battery pack at least includes two cells, the periphery of each cell is wrapped by a battery inner shell and a battery outer shell, and PCM is filled between the battery inner shell and the battery outer shell; a plurality of fins are arranged on the battery outer shell on the opposite sides of the two adjacent cells, the fins are arranged at intervals, the fins on the opposite sides of the two adjacent cells are arranged in a staggered manner, and heat-conducting plates are connected between each fin and the battery inner shell.

Provided are a battery module and an energy storage device. The battery module includes cylindrical cells arranged in at least two rows and a liquid-cooled assembly including at least one liquid-cooled unit each including a liquid-cooled tube and a cooling fin; the liquid-cooled tube includes a first tube arranged at an upper end of the cooling fin, a second tube, and a third tube arranged at a lower end of the cooling fin; the second tube connects one end of the first tube with one end of the third tube; the cooling fin is arranged between two adjacent rows and is connected to circumferential side surfaces of cells in the two adjacent rows; the first tube and the third tube each have an opening defined in another end thereof facing away from the second tube.

Provided are a battery module and an energy storage device. The battery module includes cylindrical cells arranged in at least two rows and a liquid-cooled assembly including at least one liquid-cooled unit each including a liquid-cooled tube and a cooling fin; the liquid-cooled tube includes a first tube arranged at an upper end of the cooling fin, a second tube, and a third tube arranged at a lower end of the cooling fin; the second tube connects one end of the first tube with one end of the third tube; the cooling fin is arranged between two adjacent rows and is connected to circumferential side surfaces of cells in the two adjacent rows; the first tube and the third tube each have an opening defined in another end thereof facing away from the second tube.

The present utility model discloses a battery pack and an energy storage device. The battery pack includes at least two battery modules and at least one cooling assembly. Each battery module includes a support having a splicing portion and a plurality of battery cells mounted in the support, and two adjacent battery modules are connected to each other by two splicing portions. The at least one cooling assembly is sandwiched between the two adjacent battery modules and is in contact with the battery cells located on opposite sides of the at least one cooling assembly. According to the battery pack, the battery modules and the cooling assembly can be spliced as needed, then battery packs with different numbers of battery cells can be conveniently achieved, and the cost of the battery pack is reduced.

The present utility model discloses a battery pack and an energy storage device. The battery pack includes at least two battery modules and at least one cooling assembly. Each battery module includes a support having a splicing portion and a plurality of battery cells mounted in the support, and two adjacent battery modules are connected to each other by two splicing portions. The at least one cooling assembly is sandwiched between the two adjacent battery modules and is in contact with the battery cells located on opposite sides of the at least one cooling assembly. According to the battery pack, the battery modules and the cooling assembly can be spliced as needed, then battery packs with different numbers of battery cells can be conveniently achieved, and the cost of the battery pack is reduced.

Disclosed herein is an apparatus for controlling the spacing of battery cells. The apparatus monitors the temperature of the battery cells, and when a battery cell temperature value exceeds a threshold, changes the configuration of the battery cell spacing from an initial closed configuration to an open configuration using a spacer mechanism. The spacing during the closed configuration is a first distance between the battery cells, and during the open configuration is a second distance between the battery cells. The second distance is substantially large than the first distance to position the lithium ion cells further apart, lowering the probability a thermal runaway event propagating from one cell to adjacent cells. The spacer mechanism may include a telescoping or expanding frame, a motor, one or more sensors, and a controller configured to operate the mechanical spacer.

A battery pack includes a cell block including battery cells electrically connected to each other, the cell block having a pair of long sides and a pair of short sides which surround lateral surfaces of the battery cells and are tangent to the lateral surfaces of the battery cells, and a flexible wiring surrounding the cell block in a direction parallel to the pair of long sides of the cell block, the flexible wiring including sensors to detect state information from the battery cells.

A battery pack includes a cell block including battery cells electrically connected to each other, the cell block having a pair of long sides and a pair of short sides which surround lateral surfaces of the battery cells and are tangent to the lateral surfaces of the battery cells, and a flexible wiring surrounding the cell block in a direction parallel to the pair of long sides of the cell block, the flexible wiring including sensors to detect state information from the battery cells.

A battery assembly according to an exemplary aspect of the present disclosure includes, among other things, a first cell stack including a plurality of battery cells and a structural assembly including a first pocket sized and shaped to receive the first cell stack. The structural assembly is configured to assert a compressive load on the first cell stack and at least partially enclose the first cell stack.