A method for producing a positive electrode active material for a lithium ion secondary battery containing lithium-nickel composite oxide, includes: mixing a nickel compound, a lithium compound, and organic compound particles to obtain a lithium mixture; molding the lithium mixture to obtain a molded body; firing the molded body to obtain a fired body; and crushing the fired body to obtain lithium-nickel composite oxide powder.

A solid-state battery cell is provided, which contains a sintered metal oxide cathode, in which a surface of the cathode has an array of cavities extending about 60-90% into a depth of the cathode; a glass or glass ceramic electrolyte separator forming a smooth layer on the cathode surface and extending into the depths of the cavities of the cathode; and a lithium-based anode in contact with the electrolyte on a side opposite the cathode. A method of making the solid-state battery cell is also described.

An apparatus for manufacturing an all-solid-state battery includes: a mold unit which includes a first hole extending vertically so as to have a shape and a width identical with a shape and a width of the all-solid-state battery, and a second hole extending horizontally so as to horizontally communicate with the first hole; a first pressing unit which includes a first protrusion member corresponding to the first hole, which is coupled with an upper part of the mold unit, and which presses downwards raw materials of the all-solid-state battery filling the first hole, and a second pressing unit which includes a second protrusion member corresponding to the first hole, which is coupled with a lower part of the mold unit, and which presses upwards the raw materials of the all-solid-state battery filling the first hole.

The present disclosure provides a method of manufacturing a formed body for an electrode comprising in order: a step of preparing an electrode material containing an electrode active material; a step of supplying the electrode material to a forming mold which has a frame-shaped side wall portion defining a space portion accommodating the electrode material and has a first support placed on a bottom surface of the forming mold; a step of forming the electrode material along an internal shape of the forming mold; and a step of taking out the electrode material from the forming mold.

The disclosed technology relates to a battery that utilizes a casted-in-place busbar to connect tabs of a battery cell with tabs of an adjacent cell. The busbar includes a first conductive material that is in direct contact with the tabs. The first conductive material is different from at least one of a material of the cathode tabs and a material of the anode tabs.

A current collector for a lithium ion battery includes a first conductive resin layer and a second conductive resin layer. The first conductive resin layer includes a first conductive filler. The second conductive resin layer is formed on the first conductive resin layer and includes a second conductive filler. The first conductive filler is a conductive carbon. The second conductive filler contains at least one kind of metal element selected from the group consisting of platinum, gold, silver, copper, nickel, and titanium. A volume % of the second conductive filler in the second conductive resin layer on a first surface side, which is a first conductive resin layer side, is higher than that on the second surface side that is opposite to the first conductive resin layer.

A flat-shaped all-solid battery described in this application includes a battery container constituted by an outer can and a sealing can and a stack which a positive electrode, a solid electrolyte layer, and a negative electrode are stacked W form. The stack is housed in the battery container. A conducive porous member constituted by a molded body of graphite and having flexibility is disposed between the stack and an inner bottom surface of the outer can or an inner bottom surface of the sealing can. Moreover, in the above flat-shaped all-solid battery, the conductive porous member can be disposed between the stack and the inner bottom surface of the sealing can, and between the stack and the inner bottom surface of the outer can.

A method for manufacturing a composite electrolyte includes steps as follows. A eutectic mixture is provided. The eutectic mixture includes a lithium salt and a hydrogen-bond donor. The lithium salt includes a hydrogen-bond acceptor. A polymer material is provided. The polymer material includes a polymer. A mixing step is conducted. The eutectic mixture and the polymer material are mixed and heated to form an electrolyte precursor. A molding step is conducted. The electrolyte precursor is cooled to obtain the composite electrolyte.

Aspects relate to patterned nanostructures having a feature size not including film thickness of below 5 microns. The patterned nanostructures are made up of nanoparticles having an average particle size of less than 100 nm. A nanoparticle composition, which, in some cases, includes a binder material, is applied to a substrate. A patterned mold used in concert with electromagnetic radiation function to manipulate the nanoparticle composition in forming the patterned nanostructure. In some embodiments, the patterned mold nanoimprints a suitable pattern on to the nanoparticle composition and the composition is cured through UV or thermal energy. Three-dimensional patterned nanostructures may be formed. A number of patterned nanostructure layers may be prepared and suitably joined together. In some cases, a patterned nanostructure may be formed as a layer that is releasable from the substrate upon which it is initially formed. Such releasable layers may, in turn, be arranged to form a three-dimensional patterned nanostructure in accordance with suitable applications.

A new type of battery electrode plate preparation method is described. The method can include the following steps: a) a mixing process; b) a milling and polishing process; c) an extrusion shearing and extending process; d) cutting to obtain an electrode membrane; and e) pressing at a high temperature and a high pressure to obtain a battery electrode plate. The method can adopt the active material of different electrochemical batteries as the main body to prepare a thick type battery electrode plate with a high conductivity, a high capacity and a high active material loading, which has a viscoelastic body. The electrode plate can have a flexible organic network structure and an excellent mechanical strength, and can still exist in a variety of electrolytes after hundreds of times or even thousands of times of deep charge and discharge cycles. The thick electrode plate prepared by using the method can be applied to a variety of batteries such as lead-acid battery positive and negative electrode plates, a lead carbon battery electrode plate, a lithium ion battery electrode plate, a supercapacitor electrode plate, a Ni-MH battery electrode plate, and others.