High-performance metal matrix composites of copper, aluminum, and/or titanium are produced by embedding nanocarbon reinforcement into metal foil or sheet which is concurrently laminated into a multilayer structure to produce high- performance materials for thermal management, enhanced electrical conductivity, armor products and high-strength composite structures.

A manufacturing method for a nail art sticker includes laminating and adhering a polyethylene terephthalate film to an upper surface of a base layer formed of elastic polyurethane; forming a first design layer by coating a UV paint on a lower surface of the base layer; depositing a mirror layer or a thin metal layer on an upper surface of the first design layer; coating a transparent pressure sensitive adhesive on an upper surface of the mirror layer or the thin metal layer and attaching a release liner film onto an upper surface of the transparent pressure sensitive adhesive; and forming a second design layer by removing the polyethylene terephthalate film from the base layer and coating the UV paint on the polyethylene terephthalate film removal surface.

A manufacturing method for a nail art sticker includes laminating and adhering a polyethylene terephthalate film to an upper surface of a base layer formed of elastic polyurethane; forming a first design layer by coating a UV paint on a lower surface of the base layer; depositing a mirror layer or a thin metal layer on an upper surface of the first design layer; coating a transparent pressure sensitive adhesive on an upper surface of the mirror layer or the thin metal layer and attaching a release liner film onto an upper surface of the transparent pressure sensitive adhesive; and forming a second design layer by removing the polyethylene terephthalate film from the base layer and coating the UV paint on the polyethylene terephthalate film removal surface.

Compositions-of-matter comprising a matrix made of one or more, preferably two or more elastic layers and one or more viscoelastic layer are disclosed. The compositions-of-matter are characterized by high water-impermeability and optionally by self-recovery. Processes of preparing the compositions-of-matter and uses thereof as tissue substitutes or for repairing damaged tissues are also disclosed.

A marine deck member with enhanced surface traction and the process for forming the same. The marine deck member comprises a sandwich-type composite panel made by a compression molding process. In such a process, the panel is made by subjecting a heated stack of layers of material to cold-pressing in a mold. The cellular core has a 2-D array of cells, each of the cells having an axis substantially perpendicular to the outer surfaces, and extending in the space between the layers or skins, with end faces open to the respective layers or skins. The surface traction of this type of composite panel can be enhanced for marine deck applications by controlled debossing, or embossing, of the first skin while it cools in the compression mold. The debossing effect can be effected by applying pressurized gas, e.g., pressurized air, onto the outer surface of the first skin while in the compression mold. The embossing can be effected by applying vacuum pressure on the outer surface of the first skin while in the compression mold.

A marine deck member with enhanced surface traction and the process for forming the same. The marine deck member comprises a sandwich-type composite panel made by a compression molding process. In such a process, the panel is made by subjecting a heated stack of layers of material to cold-pressing in a mold. The cellular core has a 2-D array of cells, each of the cells having an axis substantially perpendicular to the outer surfaces, and extending in the space between the layers or skins, with end faces open to the respective layers or skins. The surface traction of this type of composite panel can be enhanced for marine deck applications by controlled debossing, or embossing, of the first skin while it cools in the compression mold. The debossing effect can be effected by applying pressurized gas, e.g., pressurized air, onto the outer surface of the first skin while in the compression mold. The embossing can be effected by applying vacuum pressure on the outer surface of the first skin while in the compression mold.

A system for manufacturing waterproofing membranes, including: a laminating machine; a textile belt moveable through the laminating machine; and a pair of edge strips positioned adjacent to opposite sides of the textile belt. A first polymer is unrolled onto the textile belt and positioned between a pair of edge strips positioned adjacent to opposite sides of the textile belt and then moved through the laminating machine to heat and cure the first polymer into a first waterproofing membrane. The edge strips are preferably endless loops of material that pass continuously through the laminating machine. A second polymer can also be unrolled onto an opposite side of the textile belt such that two different waterproofing membranes can be manufactured simultaneously.

A method for producing a laminated embossed web includes the steps of: (a) providing a first web and at least a further web, (b) embossing the first web with a first pattern of embossments, each embossment comprising a top and a side, (c) providing an adhesive with an electrostatic charge, (d) directing the adhesive to the tops of the embossments, and (e) combining the webs.

A method for producing a laminated embossed web includes the steps of: (a) providing a first web and at least a further web, (b) embossing the first web with a first pattern of embossments, each embossment comprising a top and a side, (c) providing an adhesive with an electrostatic charge, (d) directing the adhesive to the tops of the embossments, and (e) combining the webs.

Disclosed are an undercover for vehicles with high elasticity and rigidity and a method of manufacturing the same. The undercover for vehicles with high elasticity and rigidity may include a needle-punched nonwoven fabric having a multi-layer structure of felt layers including a first PET fiber and a low-melting-point PET fiber, and each of the felt layers may have improved tensile strength and have optimized fiber alignment, to thereby improve the binding between fibers, mechanical rigidity and elasticity, as well as to reduce the weight of components, improve durability and secure harmlessness and inline workability.