A screw smelting machine melts raw materials with a different chemical ratio in a mixing funnel in a feeding order to prevent the long-range diffusion of a melt, and controls outflow at a suitable speed. A centrifugal casting machine solidifies the melt with the ingredients gradient varying into a radial ingredient gradient material by a centrifugal casting style. A temperature sensor monitors temperature of an outer surface of a centrifuge cavity of the centrifugal casting machine during centrifugal casting, and transmits the temperature to a control platform. The control platform determines an optimal flow rate of the melt at an end of screw rod according to ingredient gradient of ingredient radial-gradient pipe materials and a thickness of each component gradient material required with preparation, in combination with a real-time data fed back from the temperature sensor, and feeds back to a feeding end.

A screw smelting machine melts raw materials with a different chemical ratio in a mixing funnel in a feeding order to prevent the long-range diffusion of a melt, and controls outflow at a suitable speed. A centrifugal casting machine solidifies the melt with the ingredients gradient varying into a radial ingredient gradient material by a centrifugal casting style. A temperature sensor monitors temperature of an outer surface of a centrifuge cavity of the centrifugal casting machine during centrifugal casting, and transmits the temperature to a control platform. The control platform determines an optimal flow rate of the melt at an end of screw rod according to ingredient gradient of ingredient radial-gradient pipe materials and a thickness of each component gradient material required with preparation, in combination with a real-time data fed back from the temperature sensor, and feeds back to a feeding end.

A solid surface material apparatus and process is disclosed which comprises a first solid material comprising acrylic modified polyester resin, at least one natural mineral filler, and at least one colorant and/or at least one granule configured in a sheet with at least one channel cut into the top surface of it and a second solid surface material comprising an acrylic modified polyester resin, at least one natural mineral filler, and at least one colorant and/or at least one granule which at least partially fills the at least one channel of the first solid surface material.

A solid surface material apparatus and process is disclosed which comprises a first solid material comprising acrylic modified polyester resin, at least one natural mineral filler, and at least one colorant and/or at least one granule configured in a sheet with at least one channel cut into the top surface of it and a second solid surface material comprising an acrylic modified polyester resin, at least one natural mineral filler, and at least one colorant and/or at least one granule which at least partially fills the at least one channel of the first solid surface material.

A method of producing a plurality of parts includes placing a sol mixture into a cavity of a tool, optionally placing a metal foil over a top of the cavity and placing a graphite gasket over the metal foil, and securing the tool with the sol mixture to form a tooling capsule. Tooling capsules are placed within a conveyor system and are heated until the solvent of the sol mixture reaches at least supercritical conditions of the solvent. Pressure is released within each of the tooling capsules after the supercritical conditions are reached, and then the tooling capsules are cooled to approximately room temperature. The parts are removed from the tooling capsules, and the method is continuous.

A method of producing a plurality of parts includes placing a sol mixture into a cavity of a tool, optionally placing a metal foil over a top of the cavity and placing a graphite gasket over the metal foil, and securing the tool with the sol mixture to form a tooling capsule. Tooling capsules are placed within a conveyor system and are heated until the solvent of the sol mixture reaches at least supercritical conditions of the solvent. Pressure is released within each of the tooling capsules after the supercritical conditions are reached, and then the tooling capsules are cooled to approximately room temperature. The parts are removed from the tooling capsules, and the method is continuous.

A mold for building coating products obtained from composite liquid mixtures is described. The mold includes a base plate, having a plurality of through holes; and a die, configured for incorporating the base plate therein. On the upper surface of the die there are a plurality of shapes of the front surface in negative of each coating product to be manufactured and a molding grid open at the upper part, configured to be pressure applied above the die. The molding grid has side walls which define the perimeter edges of each coating product. Between the molding grid side walls separate bowls are formed for containing a single coating product. Each side wall is inclined at an acute angle with respect to a vertical plane, to confer to each side wall a sharp-pointed and tapered shape from top towards bottom with respect to the entire mold for facilitating the extraction of the finished coating products.

A composite film having a high dielectric permittivity engineered particles dispersed in a high breakdown strength polymer material to achieve high energy density.

A composite film having a high dielectric permittivity engineered particles dispersed in a high breakdown strength polymer material to achieve high energy density.

A touch substrate includes a base substrate, a common electrode and a wire electrode. The base substrate has a plurality of common electrode areas. A common electrode is disposed in each of the common electrode areas. The common electrode has a plurality of first electrode lines extended in a first direction and arranged in a second direction crossing the first direction and a plurality of second electrode lines arranged in the first direction. The wire electrode is connected to an end of the common electrode to apply a voltage to the common electrode. The common electrode and the wire electrode are simultaneously formed through a same process using a printing substrate.