There is provided a heat insulating window film disposed on the inside of a window, including at least: a support; and a fibrous conductive particles-containing layer disposed on the support, in which the fibrous conductive particles-containing layer is disposed on a surface of the support on a side opposite to the surface of the window side, and the heat insulating window film contains a near infrared shielding material. The heat insulating window film; a heat insulating window glass; an building material; a window; a building; and a vehicle which are manufactured at low cost, easily manufactured to have a large area, and have excellent visible light transmittance, shielding properties for near infrared light, heat insulating properties, and light resistance are provided.

Disclosed herein are embodiments of a method of forming a glass article having a glass cover sheet and a frame. The glass cover sheet includes a first major surface and a second major surface in which the second major surface is opposite the first major surface. The frame has a support surface. In the method, a pressure-sensitive adhesive tape is applied to a first region of the glass cover sheet or of the frame. A liquid adhesive is applied to a second region of the glass cover sheet or of the frame. Pressure is applied to the glass cover sheet and the frame to cause the pressure-sensitive adhesive to adhere the glass cover sheet to the frame at a first bond strength. The liquid adhesive is cured to adhere the glass cover sheet to the frame at a second bond strength that is greater than the first bond strength.

A load structure may include a first honeycomb layer, a second honeycomb layer, and a plurality of intermediate layers. The plurality of intermediate layers may be disposed between the first and second honeycomb layers. The intermediate layers may include one or more adhesive layers, a fiberglass layer, and a paper layer.

An optical laminate contains a glass substrate, a primer layer formed on the glass substrate to cover an upper surface and side surfaces of the glass substrate, a base resin layer formed on the primer layer to cover an upper surface and side surfaces of the primer layer, and a functional coating layer formed on the base resin layer, wherein the glass substrate is an ultra-thin glass having a thickness of less than 100 m, the optical laminate has a pencil hardness of 2H or more throughout the optical laminate, and the ratio of the total thickness of the primer layer, the base resin layer, and the functional coating layer to the thickness of the glass substrate is controlled in a certain range, and an image display device having the same.

An ultrathin chemically toughened and subsequently etched glass article is provided. The article has a thickness of less than or equal to 0.4 mm and a breakage height (given in mm) of more than 200 multiplied by the thickness (t given in mm)). Further, the article has a breakage bending radius (given in mm) of less than 100000 multiplied by the thickness (t given in mm) and divided by a surface compressive stress (in MPa) measured at a first surface.

A load structure may include a first honeycomb layer, a second honeycomb layer, and/or an attachment feature. The second honeycomb layer may be connected to the first honeycomb layer. The attachment feature may be connected to at least one of the first honeycomb layer or the second honeycomb layer. A method of manufacturing a load structure may include providing a first honeycomb layer, a second honeycomb layer, and an attachment feature, disposing an adhesive layer onto at least one of the first honeycomb layer or the second honeycomb layer, connecting an attachment feature to the first honeycomb layer or the second honeycomb layer, and/or disposing the first honeycomb layer onto the second honeycomb layer.

Embodiments disclosed herein include an apparatus that includes a first substrate, where the first substrate comprises a glass layer, a second substrate over the first substrate, and a third substrate under the first substrate. In an embodiment, a portion of the first substrate extends past edge surfaces of the second substrate and the third substrate. In an embodiment, a layer surrounds the portion of the first substrate, where the layer comprises a tapered cross-sectional shape, and where a first sidewall that contacts the second substrate and the third substrate has a first height that is greater than a second height of a second sidewall that faces away from the second substrate and the third substrate.

Embodiments disclosed herein include an apparatus that includes a first substrate, where the first substrate comprises a glass layer, a second substrate over the first substrate, and a third substrate under the first substrate, where the second substrate and the third substrate comprise an organic dielectric material, and where a first edge of the first substrate is offset from a second edge of the second substrate and a third edge of the third substrate. In an embodiment, a layer contacts the first substrate, the second substrate, and the third substrate, where a portion of an outer sidewall of the layer is substantially parallel to the first edge of the first substrate.