Systems and devices for continuous, high-throughput production of electrically conductive yans, fibers or fabrics. In one embodiment, the system comprises a first process chamber for coating the yarn, fiber or fabric with an electrically conductive material and a second process chamber for encapsulating the electrically conductive yarn, fiber or fabric with an encapsulating material. In another embodiment, device for printing an encapsulated electrically conductive material on a yarn, fiber or fabric, includes print head(s) for coating and encapsulating a yarn, fiber or fabric.

A device for depositing paste patterns on the surface of the channel of a tube, the device comprising a frame supporting a first mechanical assembly for holding, positioning and moving the tube, and a second mechanical assembly for extruding paste for depositing said paste patterns, the assemblies cooperating with one another.

Provided is an apparatus for treating a substrate including: a processing vessel having a processing space; a support unit for supporting the substrate in the processing space and rotating the substrate; a liquid supply unit for supplying a processing liquid to the substrate; and a heating unit for heating the substrate, wherein the support unit includes: a spin chuck; a driver for rotating the spin chuck; a chuck pin installed on the spin chuck to be rotated together with the spin chuck; and a chuck pin moving unit for moving the chuck pin between a contact position wherein the chuck pin is in contact with a side portion of the substrate and an open position wherein the chuck pin is spaced apart from the side portion of the substrate.

A modified technology of spin coating which is named Two-Axis spin coating is disclosed. The innovative Two-Axis spin coating apparatus is a rotary device that spins the substrate horizontally the same as conventional spin coaters while the whole horizontal spinning system can be rotated vertically. The vertical rotation of the substrate generates a vertical centrifugal force perpendicular to the surface of the substrate which allows the coating face with an elevated artificial gravity acceleration. The elevation of gravity acceleration adjusts and normalizes the local high and low surface tension stresses on the surface of the coated film. This elevation of gravity also increases the weight of coating elements artificially and obliges the wavy surface convex regions to flow toward the concave areas. The elevation of gravity also obliges the lighter probable air bubbles inside the layer, immediately before the coating surface skinning process, move toward the surface and drain out from the layer. The invention provides a method to level the layer's edge beads, level the coated surface, drain out probable micro sized air bubbles inside the layer and form denser film simultaneously.

The present application describes apparatus (100) for colouring an additively manufactured polymer part, comprising a chamber (106) for locating at least one additively manufactured polymer part (105) to be coloured, a first reservoir (102) for containing dye pigment particles to be suspended in a gas, and fluidly coupled to the chamber, and a further reservoir (104) for containing a solvent vapour, and fluidly coupled to the chamber. A method of colouring an additively manufactured polymer part is also described.

Disclosed herein are coated gemstones, coatings for gemstones, methods of coating gemstones, and methods of using coatings on gemstones to avoid blemishes on gemstones. In some embodiments, diamonds are functionalized with anchor molecules that bind hydrophilic cyclodextrin molecules to confer hydrophilicity on the diamond. In some embodiments, the diamonds resist dirt and grime build-up.

A substrate processing apparatus including: a processing container; a stage installed in the processing container and configured to place a substrate thereon; a ceiling plate installed at a position facing the stage in the processing container; a driver configured to raise and lower the stage; an exhaust port formed in a side wall of the processing container and configured to exhaust a gas in the processing container; and a controller configured to control conductance of a space between the exhaust port and a processing space between the stage and the ceiling plate by controlling the driver to adjust a distance between a peripheral edge portion of the stage and a facing member disposed at a position facing the peripheral edge portion in the processing container.

A method of coating a structure is disclosed. Method steps include providing a structure having a first portion of a first material having a first surface and providing a second portion of a second material having a second surface, wherein a mask is provided over the first surface. Another step includes exposing the mask and the second surface to a solution comprising a polymer and a solvent, wherein the solution dewets from the mask and the polymer collects onto the second surface to form a polymer coating over the second surface without forming a polymer coating on the first surface.

A hybrid halide perovskite film and methods of forming a hybrid halide perovskite film on a substrate are described. The film is formed on the substrate by depositing an organic solution on a substrate, heating the substrate and the organic solution to form an organic layer on the substrate, depositing an inorganic layer on the organic layer, and heating the substrate having the inorganic layer thereon to form a hybrid halide perovskite film. In some embodiments, the hybrid halide perovskite film comprises a CH[NH.sub.2].sub.2.sup.+MX.sub.3 compound, where M is selected from the group consisting of Sn, Pb, Bi, Mg and Mn, and where X is selected from the group consisting of I, Br and Cl. In other embodiments, the hybrid halide perovskite film comprises a FAMX.sub.3 compound. Methods of forming a piezoelectric device are also disclosed.

The present disclosure provides an aluminum alloy coating, an aluminum alloy wheel hub and a spraying method of an aluminum alloy wheel hub. The aluminum alloy coating includes a base powder layer, a main body layer and a transparent powder layer from inside to outside. The main body layer includes at least two prime coat layers and at least two colored paint layers which are superposed in a preset order.