The present invention relates to a method for manufacturing an electrode assembly, an electrode manufactured therethrough, and a secondary battery. The method for manufacturing the electrode assembly according to the present invention comprises: a stacking process of stacking a plurality of unit cells, each of which comprises an electrode and a separator, and a separator sheet, wherein the separator sheet is folded in a zigzag shape to locate the unit cells between the folded separator sheets, thereby forming an electrode assembly in the separator sheet is stacked in the zigzag shape; and a lamination process of heating and pressing both surfaces of the electrode assembly through a pair of heating presses to bond the plurality of unit cells and the separator sheet to each other, wherein, in the lamination process, each of the pair of heating presses are formed in a rounded shape to form the electrode assembly in a rounded shape when pressing the electrode assembly.

A battery system includes a plurality of battery cells abutting one another to form a battery cell stack. An optical communication link is connected to each of the plurality of battery cells. A battery management system (BMS) connected to the optical communication link configured and adapted to receive information from the optical communication link. A method of controlling heat transfer in a battery system includes monitoring at least one characteristic of at least one battery cell of a plurality of battery cells with at least one sensor, and sending information from the at least one sensor to a battery management system (BMS) with an optical communication link. The optical communication link is connected to each of the plurality of battery cells. The method includes selectively varying a fluid circulation rate in the battery system with the BMS depending on the at least one characteristic.

A battery module and a method of assembling the battery module are provided. The battery module includes a cooling plate having a cooling surface, an adhesive standoff disposed on a first portion of the cooling surface, and a securing adhesive disposed on a second portion of the first cooling surface. The securing adhesive is disposed on the cooling surface after the adhesive standoff is substantially cured. The battery module further includes a plurality of battery cells. A first end of each of the plurality of battery cells is secured to the cooling surface by the securing adhesive. The adhesive standoff maintains the first end of each of the plurality of battery cells a distance away from the cooling surface while the securing adhesive cures.

A battery module and a method of assembling the battery module are provided. The battery module includes a cooling plate having a cooling surface, an adhesive standoff disposed on a first portion of the cooling surface, and a securing adhesive disposed on a second portion of the first cooling surface. The securing adhesive is disposed on the cooling surface after the adhesive standoff is substantially cured. The battery module further includes a plurality of battery cells. A first end of each of the plurality of battery cells is secured to the cooling surface by the securing adhesive. The adhesive standoff maintains the first end of each of the plurality of battery cells a distance away from the cooling surface while the securing adhesive cures.

A battery module according to one embodiment of the present disclosure comprises: a plurality of battery cells, a housing accommodating the plurality of battery cells, a cooling part disposed on an outer surface of the housing, and a first heat transfer part disposed on an inner surface of the housing in contact with an end of each of the plurality of battery cells, wherein the housing may have a curved portion having a curved shape conforming to a curved shape of the ends of the plurality of battery cells.

A battery module according to one embodiment of the present disclosure comprises: a plurality of battery cells, a housing accommodating the plurality of battery cells, a cooling part disposed on an outer surface of the housing, and a first heat transfer part disposed on an inner surface of the housing in contact with an end of each of the plurality of battery cells, wherein the housing may have a curved portion having a curved shape conforming to a curved shape of the ends of the plurality of battery cells.

An electrical energy storage device includes prismatic energy storage cells arranged adjacent to one another such that interfaces of adjacent storage cells run at a distance from one another such that the interfaces of the adjacent storage cells form an intermediate space. A respective first layer is arranged between the interfaces of adjacent storage cells, the first layer abutting one of the two interfaces of the adjacent storage cells under pressure. Either the respective first layer also abuts the second of the two interfaces of the adjacent storage cells under pressure, or a second layer is arranged between the interfaces of adjacent storage cells, the second layer abutting the second of the two interfaces of the adjacent storage cells under pressure. A heat-conducting device is arranged in or between the first layer and the second layer is conducted out of the intermediate space between the adjacent storage cells.

Disclosed is a battery module, as well as a battery pack and a vehicle comprising the same. The battery module includes a plurality of battery cells arranged side by side to face each other in at least one direction, a cooling plate located below the plurality of battery cells, and a heat transfer tape adhered to the battery cells to transfer heat of the battery cells to the cooling plate.

Energy storage systems, battery cells, and batteries of the present technology may include a heat exchanger or fluid delivery structure that may transfer heat from a battery cell or cell block to a heat exchange fluid. The heat exchanger or fluid delivery structure may substantially maintain an interfacial temperature during a temperature increase from the battery cell or cell block.

Energy storage systems, battery cells, and batteries of the present technology may include a heat exchanger or fluid delivery structure that may transfer heat from a battery cell or cell block to a heat exchange fluid. The heat exchanger or fluid delivery structure may substantially maintain an interfacial temperature during a temperature increase from the battery cell or cell block.