A method to manufacture, on one or more production or manufacturing lines, an integrated roofing product, such as a roofing panel or roofing plank. A blank panel of engineered wood is cut or sawn into a plurality of raw planks or raw panels, each with an outer face, an inner face, a top edge, and a bottom edge. Each raw plank or panel is then processed by cutting or routing a profile into the top edge, the bottom edge, or both; affixing a gasket seal to the profile in the top edge or the bottom edge, or both; coating at least some or all of the outer face with a silicone-based or silicone-containing coating; applying a mix of granules and/or sand to the silicone-based coating while wet; and curing the coated plank or panel. A plurality of panels or planks can then be installed on a roofing structure.

A material deposition device for decorating an object. The device has a housing as a structural framework, an object holder, and a container releasably coupled to the housing. The housing has an object support for supporting the object to be decorated. The container creates a volumetric enclosure with the housing. The device is configured to deposit decoration materials onto the object.

A construction material includes a base material. The base material includes a low-gloss region having a 60° gloss value of smaller than and a high-gloss region having a 60° gloss value of larger than or equal to 8. The 60° gloss value of the low-gloss region and the 60° gloss value of the high-gloss region are different from each other by 5 or greater.

The present disclosure discloses a device and a method for preparing a high-density aligned carbon nanotube film. The device includes a container main body, a buffer partition plate and a solvent lead-out part. The buffer partition plate is located at a lower part of the container main body. The solvent lead-out part communicates with an interior of the container main body through a through hole in a side wall of the container main body and extends to an outside of the container main body. The method includes injecting a carbon nanotube solution into a container; immersing a substrate in the carbon nanotube solution; injecting a sealing liquid that is immiscible with the carbon nanotube solution along the substrate or the side wall of the container main body; and leading the solvent out or pulling the substrate such that the liquid surface of the substrate undergoes relative motion.

An optically variable device may be manufactured by aligning magnetic flakes on a surface of an adhesive layer by applying the flakes onto the adhesive layer surface in presence of a magnetic field, and curing the adhesive layer having magnetic flakes adhered to the adhesive layer. When cured, the adhesive layer holds the magnetic flakes oriented, enabling subsequent encapsulation of the oriented magnetic flakes in a coating layer on the adhesive layer, without a substantial loss of orientation of the magnetic flakes.

An optically variable device may be manufactured by aligning magnetic flakes on a surface of an adhesive layer by applying the flakes onto the adhesive layer surface in presence of a magnetic field, and curing the adhesive layer having magnetic flakes adhered to the adhesive layer. When cured, the adhesive layer holds the magnetic flakes oriented, enabling subsequent encapsulation of the oriented magnetic flakes in a coating layer on the adhesive layer, without a substantial loss of orientation of the magnetic flakes.

A process for the large-scale manufacturing vertically standing hybrid nanometer scale structures of different geometries including fractal architecture of nanostructure within a nano/micro structures made of flexible materials, on a flexible substrate including textiles is disclosed. The structures increase the surface area of the substrate. The structures maybe coated with materials that are sensitive to various physical parameters or chemicals such as but not limited to humidity, pressure, atmospheric pressure, and electromagnetic signals originating from biological or non-biological sources, volatile gases and pH. The increased surface area achieved through the disclosed process is intended to improve the sensitivity of the sensors formed by coating of the structure and substrate with a material which can be used to sense physical parameters and chemicals as listed previously. An embodiment with the structures on a textile substrate coated with a conductive, malleable and bio-compatible sensing material for use as a biopotential measurement electrode is provided.

A preform coating device is provided with: a conveyance part that conveys a preform; a dispenser that discharges a coating liquid toward the preform; a drier that is disposed along the conveyance route of the conveyance part so as to be separated from the dispenser, and that dries the coating liquid applied to the preform by irradiating, with infrared rays, the coating liquid applied to the preform; and a first air sending mechanism that sends air, toward the preform, for inhibiting the temperature of the preform from rising at the position where the preform is irradiated with infrared rays by the drier.

A wire coating device and method are provided. The wire coating device includes a wire holder unit fixing both ends of a wire, a fiber forming unit including a first fiber forming module and a second fiber forming module that are applied with a polymer solution, face each other, and form fibers while approaching each other and retreating from each other, and a control unit adjusting a tension of the wire by controlling the wire holder unit and crossing the wire and the fibers by controlling the fiber forming unit. The fiber forming unit spins the wire using a longitudinal direction of the wire as an axis. The fibers are attached and coated on the wire when the wire and the fibers cross each other. The wire coating method can improve an adsorption state of coated fibers by including a post-processing step.

Applying aerogel-containing insulation layer(s) to an article. The insulation layer comprising: aerogel particles; and at least one binder, comprising the steps of: providing the article to be coated; mixing the aerogel particles with the particles of a pulverulent binder and/or a pulverulent solid, for example expanded glass, to give a particle mixture; applying the particle mixture to the article to be coated by scattering the particle mixture onto the article to be coated; and activating the at least one binder of the at least one insulation layer, in order to provide a bond of the particle mixture to the article, wherein the aerogel particles are present in the particle mixture in a proportion of 5 to 95 percent by weight of the particle mixture.