A flexible glass laminate structure includes a flexible glass substrate having a thickness of no more than 0.3 mm. The flexible glass laminate structure includes a flexible glass layer including the flexible glass substrate. A property control layer is laminated to the flexible glass layer. A neutral axis of the flexible glass laminate is located outside the flexible glass layer when the flexible glass layer is in a compressive bend configuration.

The present disclosure relates generally to methods for the integration of electrochromic films onto a substrate, such as a glass window, and the systems/structures formed via such methods.

A method include: providing a cylindrical mold made of metal, a shaped structure having a cylindrical shape, a rotation mechanism configured to rotatably support the cylindrical mold, and an electromagnetic induction coil configured to heat the cylindrical mold through electromagnetic induction; setting the shaped structure inside the cylindrical mold; and molding a cylindrical belt slab by heating the cylindrical mold by the electromagnetic induction coil, while the cylindrical mold is rotated by the rotation mechanism and the shaped structure is pressurized from inside and pressed against the cylindrical mold.

A heat-ray shielding lamination structure composed of two laminated plates of plate glass, plastic, or plastic containing particles having a heat-ray shielding function and metal compounds, interposing an interlayer containing particles having a heat-ray shielding function and metal compounds, wherein the particles are composite tungsten oxide particles of formula M.sub.YWO.sub.Z (0.001Y1.0, 2.2Z3.0), wherein M is at least one of Cs, Rb, K, and Tl, having a hexagonal crystal structure, with a particle size between 1 and 800 nm, the metal compounds are metal salts of carboxylic acids, metal carbonates, metal carbonate hydroxides, or metal hydroxides, and are contained in an amount between 1 pts.wt. and 100 pts.wt. based on 100 pts.wt. of the composite tungsten oxide particles.

A protective case for mobile device includes a bottom case and a top case. The top case includes a protective case frame and a protective film. The protective case frame includes a side wall and a flange. The protective film includes a first explosion-proof film, a first adhesive disposed on a front surface of the first explosion-proof film, and a tempered glass fixed to the front surface of the first explosion-proof film by the first adhesive. The periphery of the first explosion-proof film exceeds the periphery of the tempered glass and the periphery of the first adhesive to form a protruding periphery, and the front surface of the protruding periphery is provided with a second adhesive to adhere to the back surface of the flange of the protective case frame.

A vehicle pane for a head-up display having an outer face that faces external surroundings in the installed state and an inner face that faces a vehicle interior, includes at least one transparent pane; at least one masking strip in an edge region of the pane, and at least one reflection layer for reflecting light which is applied by printing, which is arranged in the region of the masking strip, on the vehicle-interior side of the masking strip.

A resin composition for a laminated glass interlayer film or a solar cell encapsulant contains an ethylene-unsaturated ester copolymer (A) and a crosslinking agent (B). When the torque of the resin composition is measured over time at 130? C. using a moving die rheometer, the torque value 60 minutes after the start of measurement is defined as T.sub.100 [dN.Math.m], the torque value of 10% of T.sub.100 is defined as T.sub.10, the torque value of 50% of T.sub.100 is defined as T.sub.50, the minimum torque value during measurement is defined as T.sub.min, the time to reach T.sub.10 from the start of measurement is defined as X [min], and the time to reach T.sub.50 from the start of measurement is defined as Y [min], the crosslinking rate represented by (T.sub.50?T.sub.10)/(Y?X) (where T.sub.50=(100?T.sub.min)?0.5+T.sub.min, T.sub.10=(T.sub.100?T.sub.min)?0.1+T.sub.min) exceeds 0.01 dN.Math.m/min and 0.25 dN.Math.m/min or less.

Provided is a laminated glass including, in order: a first glass sheet; a first interlayer film; a transparent film laminated with a heat reflection film; a second interlayer film; and a second glass sheet, wherein the first interlayer film and the second interlayer film are formed of a modified hydrogenated block copolymer [E], the modified hydrogenated block copolymer [E] is a hydrogenated block copolymer [D] in which an alkoxysilyl group is incorporated, the hydrogenated block copolymer [D] being a block copolymer [C] in which 90% or more of all unsaturated bonds is hydrogenated, the block copolymer [C] is composed of at least two polymer blocks [A] including a repeat unit derived from an aromatic vinyl compound, and at least one polymer block [B] including a repeat unit derived from a linear conjugated diene compound, and the ratio of weight fraction [A]:[B] is 30:70 to 60:40.

The present application discloses novel polyesteramides comprising cycloalkyl diols and/or cycloalkyl dialkanols with tunable properties based on the monomers and monomerratios used to prepare the polyesteramides and varying the reaction conditions. The present application also discloses compositions and articles.

A laminated glass includes first and second glass plates to be arranged on a vehicle inner side and outer side, respectively; and an intermediate film positioned between the first and second glass plates and bonded to the glass plates. The laminated glass includes a first region, a transition region, and a second region, from a lower side of the laminated glass. Each of the first and second regions includes a region having a wedge-shaped cross section, in which an upper edge side thickness is greater than a lower edge side thickness, or having a thickness that is constant. The transition region connects the first and second regions, and includes a region having a wedge-shaped cross section, in which an upper edge side thickness is greater than a lower edge side thickness. At least one of the first and second regions includes a region used for a head up display.