Methods for preparing multi-layer optical laminates include placing an optical film that is free form an adhesive layer between first and second glass substrates that are free of an adhesive layer, placing this laminate under vacuum, and then heating the laminate under pressure to a temperature above the softening temperature of the optical film. The glass substrates are free of an adhesive layer but may include a silane surface treatment. The resulting multi-layer laminate is optically clear and does not show scattering of reflected light by the optical film.

The present invention relates to a movable laminator and a plastic flooring laminating device applied by same. A laminating mechanism, a driving mechanism and a conveying mechanism assembled on a rack compose the laminator which can make continuous reciprocating movements. The movable laminator is then disposed in an automatic production line for plastic flooring to cooperate with an extruder, a rolling unit and a drawing mechanism to laminate a plastic flooring material composed of a substrate layer, a printed layer and a wear-resisting layer into a finished plastic flooring product in an automatic operation manner. Because the time of the lamination of the material by the movable laminator can match the speed at which the material is conveyed and moved, the laminating mechanism is driven by the second power source to move from the front section position to the rear section position on the rack.

This application is generally directed to articles including cage structures and related systems and methods. The cage structures have utility in footwear and apparel (e.g., articles of clothing, braces, accessories). In some cases, the article is a footwear article. In some cases, the article is an article of apparel. In some embodiments, the article includes a textile. In some embodiments, the article includes a cage structure (e.g., comprising a polymer) attached to a substrate (e.g., a textile). In some embodiments, the interface of attachment between the substrate and the cage structure is substantially free of an adhesive.

A molding apparatus (10) for forming a retaining device. The molding apparatus (10) comprises a molding strip (12) and a molding support (24). The molding strip (12) has an inside face (14), an outside face (16), and a plurality of through cavities (18) extending from the outside face (16) to the inside face (14), the molding strip (12) extending in a longitudinal direction (X) and presenting both a transverse direction (Y) perpendicular to the longitudinal direction (X), and also a height direction (Z) perpendicular to the longitudinal direction (X) and to the transverse direction (Y). The inside face (14) is configured to press against a molding face (26) of the molding support (24), wherein the inside face (14) of the molding strip (12) and/or the molding face (26) of the molding support (24) includes an array of passages, the array of passages forming vents and connecting together the cavities (18) when the molding strip (12) is pressed against the molding support (24).

A substrate has an elastomeric film having surfaces and a nonwoven web having fibers, wherein a plurality of fibers is partially embedded in one surface of the film. In addition, a substrate has an elastomeric film and a nonwoven web having fibers, wherein a plurality of fibers is partially embedded in one surface of the film, and wherein the substrate is essentially free of adhesives and film-based microfibers. A method for making a film/nonwoven composite includes providing an elastomeric film traveling in a machine direction; providing a nonwoven web traveling in the machine direction in face-to-face contact with the film, wherein the nonwoven web includes fibers; and impinging the elastomeric film with hydro jets such that at least some of the fibers become embedded in the film.

Described herein are a bonded ceramic and a manufacturing method therefor. The bonded ceramic includes: a first ceramic substrate; and a second ceramic substrate, wherein the first ceramic substrate and the second ceramic substrate are bonded to each other without an adhesive layer therebetween and include pores, each of which is formed along a bonded surface therebetween and has a size of 0.01 to 50 μm.

A thermal lamination apparatus for manufacturing a film-laminated metal plate is disclosed. The thermal lamination apparatus includes an uncoiling unit from which a metal plate coil is uncoiled, a metal plate descent tower including a platform and a metal plate discharge portion formed in the platform, an ascent induction unit for guiding a metal plate unwound from the metal plate coil to a region above the platform, a vertical descent induction unit for inducing the metal plate to descend vertically through the metal plate discharge portion, a heating unit disposed below the platform to heat the metal plate, a film supply unit for supplying a film to at least one surface of the metal plate heated by the heating unit, a lamination unit for pressing the heated metal plate and the film to acquire a film-laminated metal plate, and a re-coiling unit for re-coiling the film-laminated metal plate.

A roofing membrane includes a thermoplastic polyolefin (TPO) layer and a polyvinyl chloride (PVC) layer. The TPO layer forms a bottom layer of the roofing membrane, and the PVC layer is positioned atop the TPO layer so that the PVC layer forms a top layer of the roofing membrane. The TPO layer and the PVC layer are configured to be chemically compatible so that the TPO layer and the PVC layer are chemically bonded and function as a single roofing membrane. Compatibilizing includes at least one of (i) adding a compatibilizing agent to at least one of the TPO material and the PVC material prior to extrusion and (ii) positioning at least one compatibilizing film, prior to bonding, between the TPO material and the PVC material.

A molding apparatus (10) for forming a retaining device. The molding apparatus (10) comprises a molding strip (12) and a molding support (24). The molding strip (12) has an inside face (14), an outside face (16), and a plurality of through cavities (18) extending from the outside face (16) to the inside face (14), the molding strip (12) extending in a longitudinal direction (X) and presenting both a transverse direction (Y) perpendicular to the longitudinal direction (X), and also a height direction (Z) perpendicular to the longitudinal direction (X) and to the transverse direction (Y). The inside face (14) is configured to press against a molding face (26) of the molding support (24), wherein the inside face (14) of the molding strip (12) and/or the molding face (26) of the molding support (24) includes an array of passages, the array of passages forming vents and connecting together the cavities (18) when the molding strip (12) is pressed against the molding support (24).

A disclosed method for manufacturing a floor covering includes the steps of vulcanising a support layer made of an elastomer and assembling an intermediate layer to the support layer during the step of vulcanising, wherein the intermediate layer is made of a material selected from the group that includes polyester, polyetheretherketone, polyetherimide, polysulfone, polyimide, polyamide, fluoropolymer, polyurethane, and paper. A print layer is printed either the intermediate layer or a transparent protective layer. When the print layer is printed on the intermediate layer, the protective layer is assembled to the print layer of a set that includes the print layer, the intermediate layer, and the support layer. When the print layer is printed on the protective layer, the print layer of a set that includes the print layer and the protective layer is assembled to the intermediate layer of a set that includes the intermediate layer and the support layer.