The present invention provides a composite material of laminated curved glass and a manufacturing method thereof, the composite material of laminated curved glass includes a first glass plate, a prefabricated part, and an adhesive film configured between the first glass plate and the prefabricated part, the thickness of the first glass plate is 0.1 mm to 2.2 mm. The manufacturing method of the composite material of laminated curved glass includes processing the first glass plate with strengthening treatment, providing the adhesive film, laminating the first glass plate processed by the strengthening treatment, the adhesive film, and the prefabricated part in sequence, and then performing a low temperature press molding process to obtain the composite material of laminated curved glass. The method of the present bents the glass without high temperature to soften the glass.

The invention relates to compositions comprising composite materials comprised of discontinuous fibers and one or more polymers and/or oligomers. The invention relates to methods of making the same. The composite materials can be in the form of compositions, composite sheets, laminates, pellets, and/or shaped composite products.

The present disclosure relates to methods for assembling elastic laminates that may be used to make absorbent article components. Particular aspects of the present disclosure involve a spreader mechanism operating to activate an elastic material by stretching the elastic material in to a first elongation. The elastic material is then consolidated to a second elongation, wherein the second the elongation is less than the first elongation. The consolidated elastic material is then joined to one or more substrates. In some configurations, the substrates may be nonwovens, and the elastic material may be an elastic film and/or an elastic laminate.

The present invention aims to provide an interlayer film for a colored laminated glass which exhibits a visible light transmittance Tv of 5% or lower, small variation in visible light transmittance and an excellent appearance when incorporated in a laminated glass together with two clear glass plates in conformity with JIS R3202 (1996), and a colored laminated glass produced using the interlayer film for a colored laminated glass. Provided is an interlayer film for a colored laminated glass having, recesses on at least one surface, and exhibiting a visible light transmittance Tv of 5% or lower when incorporated in a laminated glass together with two clear glass plates in conformity with JIS R3202 (1996), the interlayer film for a colored laminated glass including a laminate of at least two layers including a first resin layer containing a thermoplastic resin and a colorant and a second resin layer containing a thermoplastic resin and no colorant, the elastic modulus E.sub.1 of the first resin layer and the elastic modulus B.sub.2 of the second resin layer having a ratio E.sub.1/E.sub.2 of 1.25 or more, the thickness t.sub.1 of the first resin layer and the thickness t.sub.2 of the second resin layer having a ratio t.sub.1/t.sub.2 of 2.0 or less.

A system and method for providing a screen protector to a portable handheld electronic device or cell phone with a user facing surface comprises a mold having an outer surface matching a user facing surface. A stack of layers including the screen protector is disposed over the outer surface of the mold. A vacuum bag receives and surrounds the stack of layers disposed over the mold. The vacuum bag is sealed and evacuated of air. The screen protector is heated and/or cured while in the vacuum bag to shape the screen protector over the mold to have curved lateral edges matching curved lateral edges of the outer surface of the mold and the user facing surface of the display screen of the cell phone. The vacuum bag maintains the curved lateral edges of the screen protector against the curved lateral edges of the outer surface of the mold.

An adhesive tape sticking apparatus includes a chamber includes a lower chamber and an upper chamber. The lower chamber includes a first inner space and the upper chamber includes a second inner space. An adhesive tape sheet is positioned between the upper chamber and the lower chamber. A substrate support is movable upward and downward within the lower chamber and is configured to support a substrate. A differential pressure generator is configured to generate a differential pressure between the first inner space and the second inner space. A tape support plate positioned between a first sidewall of the lower chamber and a circumferential edge of the substrate. The tape support plate is configured to contact at least a portion of the adhesive tape sheet when the adhesive tape sheet bends downward toward the first inner space when the differential pressure is generated between the first and second inner spaces.

An end effector comprises a plurality of vacuum ports. The plurality of vacuum ports is formed from a plurality of hollow protrusions extending from a face of the end effector. The plurality of vacuum ports is connected to a vacuum chamber receiving a vacuum from a vacuum source interface.

The present disclosure provides a bonding device for a flexible panel including: a transport element, a vacuum chamber, a cover jig, and a bonding jig; wherein the transport element is configured to move the flexible panel into the vacuum chamber or move the flexible panel out of the vacuum chamber; wherein both the cover jig and the bonding jig are disposed in the vacuum chamber, the cover jig is opposite to the bonding jig, and the cover jig is configured to secure thereon a cover plate to be bonded; and wherein the bonding jig has a curved hump protruding toward the cover jig, and the hump is configured to raise the flexible plate up to the cover plate to bond the cover plate with the flexible panel when the transport element transports the flexible plate to a location below the cover plate.

A method according to this disclosure includes stacking a first glass sheet, a first interlayer, a film, a second interlayer, and a second glass sheet to provide a lamination stack, wherein the film has a first film edge that is a first distance from a first edge of the lamination stack to provide a first film cutback; deairing the lamination stack; and autoclaving the lamination stack to provide the laminated glazing, wherein the film shrinks during autoclaving wherein a seal formed during deairing is sufficient such that no air is introduced to the lamination stack during autoclaving and no air is left in the laminated glazing.

The disclosure provides a method for forming a core layer for at least one information carrying card, and resulting products. The method includes forming an inlay layout, and dispensing a crosslinkable polymer composition over the inlay layout and contacting the inlay layer so as to form the core layer of the information carrying card. The inlay layout includes at least one inlay layer coupled with a first thermoplastic layer. The first thermoplastic layer comprises a thermoplastic material, and defines at least one hole therein. The at least one inlay layer is disposed at least partially inside a respective hole.