Provided is a secondary battery in which a single-layer secondary cell has an all-solid-state secondary cell structure with a storage layer sandwiched between a positive electrode layer and a negative electrode layer and which is superior to a conventional secondary battery with respect to at least one of volume, operation, and positioning. The present invention provides a secondary battery including a folded single-layer secondary cell formed by folding a sheet-shaped single-layer secondary cell, with a storage layer sandwiched between a positive electrode layer and a negative electrode layer, two or more times while alternately reversing the folding direction.

A plurality of unit cells is stacked on each other in a secondary battery, and each of the plurality of unit cells includes first and second collector layers, which are spaced apart from each other, and a 3-dimensional (3D) electrode structure provided between the first and second collector layers and having an outer side surface that is externally exposed and insulated, wherein, in the plurality of unit cells, the first collector layers are stacked to face each other and the second collector layers are stacked to face each other.

A three-dimensional (3D) electrode structure includes a current collecting layer, a plurality of plates including an active material and disposed on the current collecting layer, and a plurality of inner support layers disposed between the plurality of plates. The plurality of plates includes first, second, and third plates. An inner support layer of the inner support layers is disposed between the first and second plates, and another inner support layer of the inner support layers is disposed between the second and third plates. The inner support layer between the first and second plates and the another inner support layer between the second and third plates are arranged at different positions in a lengthwise direction of the second plate.

A method for manufacturing a solid-state cell battery having a support film, a separator, a cathode and a continuous collector film. The support film is placed on a work table. A first layer of the continuous collector film is supplied by a roller device. The separator, cathode, and a further separator are arranged in a stacking process to form a cell stack. A second layer of the continuous collector film is supplied via a roller device. The collector film is positioned by a horizontal displacement of the work table and/or by a horizontal displacement of at least one guide roller of the roller device relative to the cell stack, as a result of which a fold is made in the collector film. A system for manufacturing a solid-state cell battery and a solid-state cell battery are also provided.

An electrode assembly includes two separators, at least one first electrode plate between the two separators, the at least one first electrode plate being aligned with the two separators into a zigzag shape, and second electrode plates coupled to the zigzag shape opposite to the at least one first electrode plate, the second electrode plate being outside of the two separators.

Provided are a method and device for correcting positions of tabs of an electrode assembly. The electrode assembly includes anode electrode plates and cathode electrode plates stacked alternately in a first direction. The method includes: determining whether there are a plurality of consecutive tabs misaligned with each other in a first electrode plate assembly; and adjusting, if there are a plurality of consecutive tabs misaligned with each other, a cutting position of the first electrode plate assembly to adjust a width of first electrode plates obtained after cutting, such that tabs of a plurality of first electrode plates obtained after cutting the first electrode plate assembly are aligned with each other, the first electrode plates being anode electrode plates or cathode electrode plates.

A thin film lithium-ion battery unit includes a positive current collecting substrate, a positive electrode active material layer on an inner surface of the positive current collecting substrate, a negative current collecting substrate, a negative electrode active material layer on an inner surface of the negative current collecting substrate, a separator between the positive electrode active material layer and the negative electrode active material layer, and electrolyte retained at least in the separator. The positive electrode active material layer, the separator and the negative electrode active material layer constitute a laminated electric core. An outer conductive frame is spaced apart from the positive current collecting substrate and encompasses the positive current collecting substrate.

The electrolyte material includes a polymer, a salt, and a solvent. The electrolyte material has a viscosity in the range from about 3.0 cP to about 20.0 cP such that the electrolyte material can be applied to a substrate using an ink jet print head.

A unit cell in which a first current collector layer, a first electrode active material layer, an electrolyte layer, a second electrode active material layer, and a second current collector layer are laminated in this order, wherein the first electrode active material layer is laminated only on the inner region, and the second current collector layer is folded so as to enclose the electrolyte layer and the second electrode active material layer, and is joined to the first current collector layer via an insulating sealing member on the peripheral region to form a joint portion, thereby sealing the first electrode active material layer, the electrolyte layer, and the second electrode active material layer with the first current collector layer, the insulating sealing member, and the second current collector layer.

This application provides a method, apparatus, and system for corner fold detection on a cathode electrode plate of a composite material strip, an electronic device, a laminator, a computer-readable storage medium, and a computer program product. The method includes: acquiring a to-be-inspected image of a composite material strip by using an image acquisition unit, where the to-be-inspected image includes an electrode plate body zone of the cathode electrode plate; extracting the electrode plate body zone from the to-be-inspected image; and performing corner fold detection on the electrode plate body zone. In the technical solutions of embodiments of this application, corner fold detection can be performed quickly and accurately on a cathode electrode plate of a composite material strip, thereby improving the production yield of laminated cell assemblies.