A film for laminating glass including: a first surface layer; a second surface layer disposed opposite to the first surface layer; and at least one sound insulating layer disposed between the first surface layer and the second surface layer, wherein the film for laminating glass has a L/F value reduction rate [G_L/F(A,B)] of 0.07/° C. or less at a temperature range of 20 to 35° C.

A multi-layer laminate includes a glass panel unit, an intermediate film, and a transparent plate. The transparent plate is assembled to the glass panel unit via the intermediate film. The glass panel unit includes a first and second glass panel, and an evacuated space. The evacuated space is interposed between the first and second glass panel. A method for manufacturing the multi-layer laminate includes a step. The step includes exhausting a gas from a bag, loaded with the glass panel unit, the intermediate film, and the transparent plate, to cause the bag to shrink and thereby assembling, using the bag thus shrunk, the glass panel unit and the transparent plate via the intermediate film. The step includes raising a pressure inside the bag from a pressure at an initial stage of heating while increasing a temperature of the intermediate film to a predetermined temperature at which the intermediate film softens.

A multilayered structure includes a plurality of laminated portions arranged on a base material, wherein the laminated portions each include a resin layer, a glass layer, laminated over the resin layer via an adhesive laver, and a metal layer formed on a surface of the glass layer, the surface being oriented toward the adhesive layer, wherein a thickness of the glass layer is 10 μm or more and 300 μm or less, and a thickness of the resin layer is 10 μm or more and 1000 μm or less.

A glass double-walled beverage container, having an inner body sidewall lower end portion in fluid-tight engagement with an inner body end wall to define an interior beverage cavity, an outer body sidewall lower end portion in fluid-tight engagement with an outer body end wall, the outer body sidewall extending fully about the inner body sidewall, an inner body sidewall upper end portion and an outer body sidewall upper end portion being rigidly connected together and in fluid-tight engagement, the inner body end wall being positioned above and spaced apart from the outer body end wall to provide an interior space therebetween, and a non-glass adhesive material positioned in the interior space adhered to both the inner and outer body end walls. A method of making same is provided.

A glass double-walled beverage container, having an inner body sidewall lower end portion in fluid-tight engagement with an inner body end wall to define an interior beverage cavity, an outer body sidewall lower end portion in fluid-tight engagement with an outer body end wall, the outer body sidewall extending fully about the inner body sidewall, an inner body sidewall upper end portion and an outer body sidewall upper end portion being rigidly connected together and in fluid-tight engagement, the inner body end wall being positioned above and spaced apart from the outer body end wall to provide an interior space therebetween, and a non-glass adhesive material positioned in the interior space adhered to both the inner and outer body end walls. A method of making same is provided.

There is provided a gas trapping material and vacuum heat insulation equipment where the gas trapping material can be activated in a sealing step of the vacuum heat insulation equipment, and production efficiency can be enhanced by maintaining a high gas trapping characteristic even when a gas is released in a baking step or in a sealing step under an air atmosphere. The gas trapping material contains porous metal oxide and silver particles having an average particle size of 0.5 nm to 100 nm inclusive.

Provided is a jig having a structure that differs from conventional jigs and enables flat plates to be bonded while suppressing an air bubble formation. A flat-plate bonding jig is provided with the following: a first surface; a second surface that is on the opposite side of the first surface, has a plurality of suction holes for sucking a flat-plate, and is curved outward in a substantially arc shape; a main body connecting the first surface and the second surface; and a communication means that is disposed in the main body and allows the suction holes to communicate with a suction means.

Provided is a jig having a structure that differs from conventional jigs and enables flat plates to be bonded while suppressing an air bubble formation. A flat-plate bonding jig is provided with the following: a first surface; a second surface that is on the opposite side of the first surface, has a plurality of suction holes for sucking a flat-plate, and is curved outward in a substantially arc shape; a main body connecting the first surface and the second surface; and a communication means that is disposed in the main body and allows the suction holes to communicate with a suction means.

A bent laminated glazing, in particular for a motor vehicle windscreen, includes a first glass sheet adhesively bonded to a second glass sheet by a lamination interlayer, the first glass sheet including a face, referred to as face 2, facing the lamination interlayer, and the second glass sheet including a face, referred to as face 4, opposite the lamination interlayer, wherein the face 2 includes a region, referred to as first region, coated with a layer of opaque mineral paint obtained from an aqueous paint composition including pigments and an aqueous solution of alkali metal silicate, and the face 4 includes a region, referred to as second region, coated with an enamel coating.

A substrate with coated edge surfaces, an apparatus for performing the coating, and a method therefor are described. The substrate may include edge surface electrical connectors, wherein the edge coating is coated overtop the edge surface electrical connectors. The apparatus for performing the coating operation includes a rotary fixture configured to facilitate coating of all edge surfaces of a stack of substrate prior to curing of the edge surface coating, wherein according to the method, edge surfaces of one group of corresponding edge surfaces in the stack are coated with a coating material, the rotary fixture is then rotated to position a second group of edge surfaces for coating, and so forth. The coating process is controlled to obtain a consistent overflow onto major surfaces of the stacked substrates.