The present invention pertains to a method to manufacture a textile product comprising a first sheet having a width and a length, and polymer yarns fastened to this sheet to form a pile thereon, the method comprising providing the sheet, stitching the polymer yarns through the sheet to form the pile on a first surface of the sheet and loops of the yarns at a second surface of the sheet, transporting the sheet in a direction parallel to its length along a heating element, the heating element being directed to the second surface of the sheet, heating the second surface with the heating element to at least partly melt the loops of the yarns to fasten the yarns to the sheet, wherein the method comprises transporting the sheet in contact with the heating element, wherein the heating element is a stationary rigid plate-like element having a width corresponding to the width of the sheet, and a length that extends parallel to the length of the sheet, the plate being curved in its length direction, wherein the outer circumference of the plate is contacted with the sheet. The invention also pertains to a method to use a textile product obtained with the new method and a device for applying the said method.

A method of forming a laminated metallic structure includes steps of: (1) providing a first preformed-metallic sheet having a three-dimensional shape of a first graduated three-dimensional size; (2) providing a second preformed-metallic sheet having the three-dimensional shape of a second graduated three-dimensional size; (3) nesting the second preformed-metallic sheet in the first preformed-metallic sheet; and (4) bonding the first preformed-metallic sheet and the second preformed-metallic sheet together.

A method for quickly applying and spreading adhesive between substrates without leaving air bubbles. The method includes holding two substrates apart from each other with adhesive sides facing, a second substrate being positioned above a first substrate. The second substrate is suspended in a manner so as to cause a portion to warp towards the first substrate. After a liquid filler is applied between the two substrates, rollers are lowered onto the second substrate and moved so as to disperse the liquid filler between the first and second substrates. In accordance with the rolling of the rollers, end portions of the second substrate are lowered towards the first substrate.

A pipe insulation product including a core of insulating material and a laminate surrounding the core and bonded to the core. The core may include an outer surface; an inner surface; and a wall extending between the outer and inner surfaces. The laminate may include a foil or metallized polymeric film sheet, a scrim, a porous media sheet, and a polymeric film sheet bonded together via an adhesive. The laminate may include a closure flap that is configured to adhesively seal opposite ends of the laminate together to form a cylindrical tube with the core enclosed therein. The closure flap may be configured to include a curl that provides a greater closure flap adhesive seal.

The invention provides a method for manufacturing a curved surface shell of an electronic device, which comprises the steps of preparing a translucent base shell having a decorative film; fixed-point hot pressing the decorative film to attach and position the decorative film on an inner surface of the translucent base shell; placing the translucent base shell in a vacuum sealed space to tightly bonding the decorative film to the translucent base shell; and hydraulic pressing the decorative film by high pressure and high temperature so as to be smoothly bonded to the inner surface of the translucent base shell in a liquid solvent.

A lamination apparatus including a first stage including a first body portion and an accommodation portion disposed on a bottom surface of the first body portion, a second stage disposed to face the first stage, and a jig device disposed between the first stage and the second stage, the jig device including a second body portion and at least one jig portion, in which the at least one jig portion has one end fastened to the second body portion and the other end having a rounded shape.

A method of manufacturing the curved display device includes a process of manufacturing a cover glass assembly by attaching a transparent polymer film to the back surface of a thin film glass of a flat plate, a process of bending and inserting the cover glass assembly into a curved cavity of a mold and then molding an edge member so as to be integrated with an edge portion of the cover glass assembly to maintain the cover glass assembly in a bent state, and a process of attaching a flexible display panel to the back surface of the cover glass assembly in a curved state after molding the edge member. The curved display device includes a cover glass assembly, an edge member to maintain the cover glass assembly in a bent state, and a flexible display panel attached to the back surface of the cover glass assembly.

A helmet has inner and outer shells separated by a plurality of interconnected relatively soft columns or posts. The columns each have a middle post or pillar section, a capital that is of larger diameter than the post, and a base also of larger transverse dimension than the post. When an impact above a design threshold occurs on the outer shell, the columns, particularly the post sections thereof, near the impact location compress and buckle, dissipating impact kinetic energy, while columns spaced from the impact zone stretch and support more of the impact force. The applied force is therefore reduced and spread out over a relatively large area, and a resultant wave created within the column manifold disperses additional heat, further reducing the force and torque applied on the outer shell and transmitted to the inner shell and onto the skull of a helmet user. A method and mold for fabricating the column manifold are also disclosed.

A method of stably and precisely attaching substrates and an apparatus for stably and precisely attaching substrates, the method including: placing a substrate, attached with a release film, on a shuttle stage; peeling the release film from the substrate; a transferring unit lifting the substrate from the shuttle stage; a gas supplier spraying gas toward the substrate so that the substrate is convexly curved in a direction away from the gas supplier; the substrate transferred into a chamber by the transferring unit; placing the substrate on a main stage in the chamber; and attaching the substrate to an adherend.

A ballistic resistant panel can be configured to be quickly and easily installed in a vehicle door. The ballistic resistant panel can include a plurality of ballistic sheets arranged in a stack. The stack can have an outer perimeter sized to fit within a cavity of the vehicle door. The panel can include a cover disposed over the stack, and the cover can be sealed around a perimeter of the stack to form a waterproof barrier that prevents moisture from reaching and altering the performance of the ballistic sheets. At least one anti-wear strip can be adhered to an outer surface of the cover. The anti-wear strip can provide a low friction surface that protects the panel from damage caused by moving internal door components, such as moving window components that repeatedly rub against the panel.