Provided is an inkjet application device (1) including a distribution flow path for the liquid material, the distribution flow path including a first flow channel (4) configured to supply the liquid material pumped with a pump (2) to a supply tank (3) and a second flow channel (6) configured to supply the liquid material in the supply tank (3) to the inkjet head (5), wherein the supply tank (3) accommodates a filter (40), which is configured to allow the particles in the liquid material to pass therethrough without allowing air bubbles in the liquid material, which are generated by the pumping of the pump (2), to pass therethrough.

A method of manufacturing a component having a porosity-controlled lithium metal coating includes setting up an aerosol spray apparatus having a material feeder and a confinement conduit in fluid communication therewith. The confinement conduit has an inlet end and a nozzle end. The method also includes setting up a substrate having an exposed surface on a moveable tooling plate and directing the nozzle end at the exposed surface. The method additionally includes loading a lithium metal into the material feeder. The method also includes feeding a high-pressure gas into the inlet end of the confinement conduit to thereby form an aerosol spray of lithium metal. The method further includes moving the tooling plate to regulate a thickness and a pattern of deposition of the lithium metal onto the exposed surface through the nozzle end to thereby generate a porous lithium metal coating on the substrate.

A method for manufacturing a lithium secondary battery including a pre-lithiated negative electrode. A composite of lithium and a negative electrode active material is formed through a lamination process which is a process of manufacturing a battery. In the case of the lithium secondary battery to which the negative electrode having the composite formed by lithium and the negative electrode active material is applied, when the battery starts to operate, the negative electrode active material is pre-lithiated, and thus the charging/discharging process proceeds in the state where the lithium alloy is already formed on the negative electrode, thereby showing an effect of reducing initial irreversible phases.

An electrode comprises carbon nanoparticles and at least one of metal particles, metal oxide particles, metalloid particles and/or metalloid oxide particles. A surfactant attaches the carbon nanoparticles and the metal particles, metal oxide particles, metalloid particles and/or metalloid oxide particles to form an electrode composition. A binder binds the electrode composition such that it can be formed into a film or membrane. The electrode has a specific capacity of at least 450 mAh/g of active material when cycled at a charge/discharge rate of about 0.1 C.

A method for manufacturing a secondary battery by coating an electrode slurry on an object for a secondary battery. A step of pressurizing and transferring the slurry to the next step; a step of transferring pressurized carbon dioxide gas or liquefied carbon dioxide or supercritical fluid of carbon dioxide gas to the next step; a step of merging and mixing the slurry and the carbon dioxide gas or liquefied carbon dioxide or supercritical fluid of carbon dioxide gas; and a step of coating the mixed mixture or layered coating a plurality of layers thereof on the object with a coating device. As a result, the total length of a drying device is extremely short, and the desired thick film of the positive electrode can be easily formed. In addition, a solid electrolyte layer can be formed in a short time.

An aerosol including an active material powder, a binder, and a gas is prepared. An electric field is formed between a substrate and a porous electrode. The aerosol is electrically charged. The aerosol after the electrically charging is introduced into the electric field. The aerosol passes through the porous electrode and thereby the aerosol is introduced into the electric field. At the time of the aerosol passing through the porous electrode, the aerosol comes into contact with the porous electrode and thereby the aerosol is electrically charged. In the electric field, the aerosol after the electrically charging flies toward the substrate due to electrostatic force. The aerosol adheres to a surface of the substrate and thereby an active material layer is formed.

A carbon-coated cathode material and a preparation method thereof. The carbon-coated cathode material includes a lithium metal phosphate particle and a carbon coating layer. The carbon coating layer is coated on the lithium metal phosphate particle. The carbon coating layer is formed by a first heat treatment and a second heat treatment. A first carbon source is added in the first heat treatment, and a second carbon source is added in the second heat treatment. The first carbon source has a first weight percentage relative to the lithium metal phosphate particle. The second carbon source has a second weight percentage relative to the lithium metal phosphate particle. The first weight percentage of the first carbon source is equal to or less than the second weight percentage of the second carbon source.

The present disclosure relates to anode compositions, methods of preparing the anode compositions via cold spray, and batteries having an anode comprising the anode compositions, a cathode, a separator, and an electrolyte. Preferably, the anode compositions comprise a metalloid and/or metal added in its elemental form. Preferably the batteries are lithium ion batteries.

A liquid composition containing a solvent, an inorganic solid electrolyte, and a dispersant is provided. The dispersant is soluble in the solvent. A 10% volume fraction-component's particle diameter (D.sub.10), a 50% volume fraction-component's particle diameter (D.sub.50), a 90% volume fraction-component's particle diameter (D.sub.90), and a mode diameter (D.sub.m) of solids contained in the liquid composition satisfy D.sub.90/D.sub.10>10, D.sub.50<1 μm, and D.sub.m<2 μm, where D.sub.10, D.sub.50, D.sub.90, and D.sub.m are measured by a laser diffraction method.

Disclosed are a cathode for metal-sulfur batteries which includes a cathode active material layer, which contains nitrogen-doped carbon, and a protective layer and a method of manufacturing the same. The cathode for lithium-sulfur batteries according to the present invention includes a cathode active material layer including a sulfur-containing material, a binder, and a nitrogen-doped carbon material; and a protective layer that is disposed on the cathode active material layer and is composed of a nitrogen-doped carbon material, wherein the nitrogen-doped carbon material of the cathode active material layer has a form wherein spherical particles and linear structures are mixed and the nitrogen-doped carbon material of the protective layer has a linear structure.