A battery module in an energy storage device used with a plurality of battery modules in a battery rack and including a rack fuse that cuts off a circuit when an overcurrent occurs includes a battery cell and a module fuse for cutting off a circuit when overcurrent occurs, the module fuse starts to melt later than a melting completion time point of the rack fuse.

A high-voltage energy module includes an insulating shell, a plurality of bare cells connected in series inside the insulating shell, one positive terminal and one negative terminal. The minimum number of bare cells is two. Each bare cell is formed by a positive film, a negative film and a separating film sandwiched between the positive film and the negative film. The positive film, the negative film and the separating film form a one-piece structure by conductive resin glue. Each two bare cells are connected by an insulating layer of flame-retardant composite insulating materials. The positive film is electrically connected to a positive conductive lug. The negative film is electrically connected to a negative conductive lug. There is only one electrical connection in the positive film, and there is only one electrical connection in the negative film.

Provided is a secondary battery including an electrode assembly and an exterior body that houses the electrode assembly. In the secondary battery, the exterior body includes a metal plate joined via an insulating material interposed therebetween, and the exterior body has a cavity, and one of a peripheral edge of the cavity and an outer edge of the metal plate is bent so as to be separated from the insulating material.

Provided is a secondary battery including an electrode assembly and an exterior body that houses the electrode assembly. In the secondary battery, the exterior body includes a metal plate joined via an insulating material interposed therebetween, and the exterior body has a cavity, and one of a peripheral edge of the cavity and an outer edge of the metal plate is bent so as to be separated from the insulating material.

A secondary battery includes a positive electrode, a negative electrode, and an electrolytic solution. The positive electrode includes a positive electrode active material layer. The positive electrode active material layer includes a lithium-nickel composite oxide of a layered rock-salt type.

A secondary battery includes a positive electrode, a negative electrode, and an electrolytic solution. The positive electrode includes a positive electrode active material layer. The positive electrode active material layer includes a lithium-nickel composite oxide of a layered rock-salt type.

The present application relates to a battery module, which includes a first type of battery cells and a second type of battery cells electrically connected in series. The first type of battery cells and the second type of battery cells are battery cells with different chemical systems. The first type of battery cells includes N first battery cells, and the second type of battery cells includes M second battery cells, where N and M are greater than or equal one. The present application also relates to a battery pack and an electric apparatus including the battery module, and method and device for manufacturing the battery module.

A method for forming a treated sintered composition includes: providing a slurry precursor including a lithium-, sodium-, or magnesium-based compound; tape casting the slurry precursor to form a green tape; sintering the green tape at a temperature in a range of 500° C. to 1350° C. for a time in a range of less than 60 min to form a sintered composition; and heat treating the sintered composition at a temperature in a range of 700° C. to 1100° C. for a time in a range of 1 min to 2 hrs in an oxygen-containing atmosphere to form the treated sintered composition.

A method for forming a treated sintered composition includes: providing a slurry precursor including a lithium-, sodium-, or magnesium-based compound; tape casting the slurry precursor to form a green tape; sintering the green tape at a temperature in a range of 500° C. to 1350° C. for a time in a range of less than 60 min to form a sintered composition; and heat treating the sintered composition at a temperature in a range of 700° C. to 1100° C. for a time in a range of 1 min to 2 hrs in an oxygen-containing atmosphere to form the treated sintered composition.

A manufacturing method of a battery includes: an injection step of injecting the electrolytic solution into the intermediate member via an unsealed portion; and a permeation step of causing the electrolytic solution to permeate the intermediate member. The electrode body includes a power generation element and a first collector terminal and a second collector terminal. The power generation element has a first side and a second side corresponding to long sides in the rectangular shape of the power generation element, and a third side and a fourth side corresponding to short sides in the rectangular shape of the power generation element. The first collector terminal and the second collector terminal are placed on the first side and on the second side, respectively. In the permeation step, the intermediate member is placed such that the first side is placed on a vertically lower side as a first arrangement state.