Provided is an organic solvent-free method for producing a plurality of microsphere having an average diameter of less than 500 μm in diameter and having average contact angle θc greater than 140°, consisting essentially of a biocompatible hot-melt carrier vehicle and a payload substance to be delivered, including melting and mixing a polymer carrier vehicle which is solid at room temperature and at least one payload substance, and dispensing microportions of the molten mixture through a droplet-forming space onto a cooled solid superoleophobic surface.

An installation and method for production of nanopowders by spray pyrolysis by capture, grind, and temperature exposure of nanoparticles, wherein efficiency of particle retention in the cyclone in the suspended state is achieved.

A device for spherification of a liquid includes a first device for storing a first liquid; and a spherification tank for storing a second liquid, arranged so that a dripper or entry funnel controls a level of the second liquid in the spherification tank. A device meters the first liquid coming from the first tank into the spherification tank. An extraction device extracts spheres generated in the spherification tank as a result of the metering. The extraction device includes a worm screw located in the spherification tank, the worm screw being arranged at an angle to the level, and a motor for rotating the worm screw.

A device for spherification of a liquid includes a first device for storing a first liquid; and a spherification tank for storing a second liquid, arranged so that a dripper or entry funnel controls a level of the second liquid in the spherification tank. A device meters the first liquid coming from the first tank into the spherification tank. An extraction device extracts spheres generated in the spherification tank as a result of the metering. The extraction device includes a worm screw located in the spherification tank, the worm screw being arranged at an angle to the level, and a motor for rotating the worm screw.

The present disclosure relates to an apparatus and to a method for production, especially continuous production, of nanoparticles, including a line to convey water with a predeterminable flow velocity and a system arranged orthogonally to the line for introducing at least one dissolved substance into the line for producing the nanoparticles.

The present disclosure relates to an apparatus and to a method for production, especially continuous production, of nanoparticles, including a line to convey water with a predeterminable flow velocity and a system arranged orthogonally to the line for introducing at least one dissolved substance into the line for producing the nanoparticles.

An apparatus is described. The apparatus comprises a liquid dispenser comprising a liquid outlet, the liquid dispenser being configured to generate a droplet stream. The apparatus also comprises a first fluid flow device configured to generate a confinement fluid flow for confining a trajectory of the droplet stream therein, the first fluid flow device comprising an outlet arranged to allow the droplet stream to exit therefrom, wherein the fluid outlet is arranged within the confinement fluid flow device. Furthermore, the apparatus comprises a second fluid flow device configured to generate a reaction fluid flow for reacting with droplets in the droplet stream, wherein the outlet of the first fluid flow device is arranged within the second fluid flow device. A method is also described.

An apparatus is described. The apparatus comprises a liquid dispenser comprising a liquid outlet, the liquid dispenser being configured to generate a droplet stream. The apparatus also comprises a first fluid flow device configured to generate a confinement fluid flow for confining a trajectory of the droplet stream therein, the first fluid flow device comprising an outlet arranged to allow the droplet stream to exit therefrom, wherein the fluid outlet is arranged within the confinement fluid flow device. Furthermore, the apparatus comprises a second fluid flow device configured to generate a reaction fluid flow for reacting with droplets in the droplet stream, wherein the outlet of the first fluid flow device is arranged within the second fluid flow device. A method is also described.

A process for forming cubic LLZO through the use of atomic mixing of metal salts used in an aerosol process. The cubic LLZO is formed at temperatures below 1000 C.

A process for forming cubic LLZO through the use of atomic mixing of metal salts used in an aerosol process. The cubic LLZO is formed at temperatures below 1000 C.