A method for deposition of solid electrolyte material on electrode active material, comprising the steps of a feed of electrode active material from a first storage unit to a first dosing means with a simultaneous feed of solid electrolyte material from a second storage unit to a second dosing means, a feed of inert gas to the first dosing means and to the second dosing means via an inert gas feed means, a feed of the electrode active material via the first dosing means into a reaction space with simultaneous feed of the solid electrolyte material via the second dosing means into the reaction space, wherein the electronic structure of the electrode active material and of the solid electrolyte material is influenced during the feed to the reaction space via the first and second dosing means, such that the electrode active material and the solid electrolyte material bond to one another at least in part while retaining the crystal structure of the solid electrolyte material.

A coating apparatus and method are disclosed for coating tablets with a film, in which the tables transit through a drilled first container where they are coated, then exit the first container and are removed from a rotating element provided on the periphery of a plurality of removal members that are spaced angularly apart from one another, in which each removal member removes a quantity of tablets, raises the removed tables as far as a certain height and then discharges the tablets into a chute that conveys the tablets into a second rotating drilled container, with delicate transfer of the coated tablets from one container to the next.

Method for coating bulk material comprises: starting a coating apparatus (1; 101) according to a start procedure on a discrete load of bulk material to be coated; operating the coating apparatus (1; 101) in stationary mode, by introducing a continuous flow of uncoated bulk material into the coating apparatus (1; 101) and obtaining at the outlet of said coating apparatus (1; 101) a continuous flow of coated bulk material having a predetermined stationary coating weight gain (W %); in which the coating apparatus (1; 101) comprises a first rotatable tubular container (2; 102) provided with a first dispensing device (5; 105) for dispensing coating material on the bulk material (M) in a plurality of internal successive adjacent spray zones between a first inlet and a first outlet of the first container (2; 102); a second rotatable tubular container (6; 106) arranged to receive bulk material (M) coming from the first container (2), the second rotatable tubular container (6; 106) being provided with a second dispensing device (9; 109) for dispensing coating material on the bulk material (M) in a plurality of internal successive adjacent spray zones between a first inlet and a second outlet of the second container (6, 106); conveying means arranged to convey the bulk material (M) from the first container (2; 102) to said the second container (6, 106); and in which the start procedure comprises in succession: dispensing coating material onto the load, maintaining the coating material inside the first container (2; 102) until coated bulk material is obtained with said predetermined stationary coating weight gain (W %); a transition phase to the stationary mode in which a flow of the load of coated bulk material is transferred from the first container (2; 102) to the second container (6; 106) and is supplied with an equal flow rate of bulk material to be coated to the first container (2; 102); dispensing coating material on the same flow rate of bulk material to be coated entering the first container (2; 102) activating in sequence the spray zones inside first container (2; 102) to obtain at the first outlet a coated bulk material with an established weight gain (U %); dispensing coating material on the same flow rate of bulk material to be coated having the established weight gain (U %) entering the second container (6; 106), activating in sequence the spray zones inside the second container (6; 106) to obtain a coated bulk material with the predetermined stationary coating weight gain (W %).

A method for forming a pelletised evaporite mineral product, the method comprising: pulverising an evaporite mineral feedstock to form a dry powder, mixing the dry powder with a binder in the presence of a liquid to form an intermediate blend; and processing the intermediate blend using a pelletiser to form pellets principally composed of the evaporite mineral.

Process for the preparation of layered particles are provided. Layered particles prepared by such processes are also provided

Process for the preparation of layered particles are provided. Layered particles prepared by such processes are also provided.

A method for monitoring a nozzle mouthpiece for placing on a nozzle for spraying materials, in particular dispersions, emulsions or suspensions.

A production line of a CA abrasive, including: a belt mold, the belt mold being provided with a cavity; a transmission device, configured to drive the belt mold to run; a slurry coating mechanism, configured to coat a slurry on a surface and into the cavity of the belt mold; a slurry scraping mechanism, configured to scrap the slurry coated on the surface of the belt mold into the cavity; a drying mechanism, configured to dry the belt mold so that the slurry is dried and precipitated into abrasive grains; a separation mechanism, arranged below the drying mechanism and configured to shake down the abrasive grains in the cavity of the belt mold by vibrating; a sweeping mechanism, configured to sweep slurry fragments of the belt mold after separation; and a release agent coating mechanism, configured to spray a release agent to the swept belt mold.

The present invention relates to a fluidized bed apparatus and a method for particle-coating or granulating, the fluidized bed apparatus includes a swirl generator which is mounted on a sprayer body in the fluidized bed apparatus and extends throughout an air distribution plate and is connected to a source of compressed air. The swirl generator comprises a tubular sleeve extending circumferentially around the sprayer body, and an air chamber is defined between the sleeve and the sprayer body, wherein the sleeve comprises a plurality of guiding slots. The air from the source of compressed air via the air chamber is directed by said guiding slots to rotate outwardly, so as to provide a swirling air stream circumferentially outwardly relative to the sprayer. The present invention can facilitate the development of the spray pattern and the particle flow pattern and allows the particles to spin respectively due to slight friction with the inner wall of the partition, thereby opportunities for the particles to obtain a more uniform spray when subsequently passing through the spray zone above the nozzle are increased, so that performance of the fluidized bed apparatus is improved.

A method for coating the surface of a substrate, such as inorganic particles, with a metal oxide. A suspension is formed containing the substrate, a polyvalent anion and a metal ion where the molar ratio of the polyvalent anion to the metal ion is greater than three and the metal ion is precipitated onto the substrate as a metal oxide. Preferably, the method is used to coat titanium dioxide pigment particles with aluminum oxide.