A glass sheet composite having two or more glass sheets and a liquid layer between at least a pair of glass sheets out of the glass sheets, wherein a thickness of the liquid layer is 1/10 or less of a total thickness of the pair of glass sheets when a total thickness of the pair of glass sheets is 1 mm or less, and 100 ?m or less when the total thickness of the pair of glass sheets is more than 1 mm.

A glass element having a thickness from 25 ?m to 125 ?m, a first primary surface, a second primary surface, and a compressive stress region extending from the first primary surface to a first depth, the region defined by a compressive stress ?I of at least about 100 MPa at the first primary surface. Further, the glass element has a stress profile such that it does not fail when it is subject to 200,000 cycles of bending to a target bend radius of from 1 mm to 20 mm, by the parallel plate method. Still further, the glass element has a puncture resistance of greater than about 1.5 kgf when the first primary surface of the glass element is loaded with a tungsten carbide ball having a diameter of 1.5 mm.

The invention relates to the use of a coating of a layer including an inorganic, glass-like matrix of an alkali silicate and/or alkaline earth silicate or a layer including an inorganic-organic hybrid matrix or of a double layer of a base layer including an inorganic, glass-like matrix of an alkali silicate and/or alkaline earth silicate or a base layer including an inorganic-organic hybrid matrix and an alkali silicate-free and alkaline earth silicate-free top layer including a matrix of an oxidated silicon compound as the anti-limescale coating on at least one metal surface or inorganic surface of an object or material. The anti-limescale coating can be used for storage or transport devices for water or media containing water. The anti-limescale coating is suitable for pipelines, sand control systems or safety valves in the conveyance of oil or gas or the storage of oil or gas.

The present invention is a glass sheet composite in which the loss coefficient is 1?10.sup.?2 or more and the longitudinal wave acoustic velocity in the sheet thickness direction is 5.5?10.sup.3 m/s or more.

A decorative panel has a first layer, a second layer, and a third layer. The first layer may be transparent, the second layer is fully or partially reflective, and the third layer is partially reflective or transparent. A cavity having an opening in the shape of a design is formed within a portion of the second layer. The opening is configured to allow light to enter the decorative panel through the second layer. The light entering the decorative panel will be outputted by the third layer in a shape substantially similar to the design.

A transparent conductive film includes a substrate having opposed first and second surfaces; a first hard coating layer formed on the first surface; a first optical adjustment layer formed on the first hard coating layer, the first optical adjustment layer comprising a second binder resin and a plurality of second particles distributed in the second binder resin; a first transparent conductor layer formed on the first optical adjustment layer, the first transparent conductor layer having a plurality of protrusions on a surface thereof corresponding to the plurality of second particles; a second hard coating layer formed on the second surface; a second optical adjustment layer formed on the second hard coating layer; and a second transparent conductor layer formed on the second optical adjustment layer.

An optimized display system for a vehicle using a glass assembly. The system includes a power source coupled to the processing unit for providing an input DC voltage. The processing unit is coupled to the power source. The processing unit is configured to receive input. The processing unit generates a command signal to interactively control a display unit in response to at least one input. A convertor is coupled to the processing unit. The convertor is configured to generate at least one of an output AC voltage or output DC voltage based on the command signal. The display unit includes one or more illumination devices sandwiched in the glass assembly.

An embodiment of the invention provides a method for low emission charge neutralization, comprising: generating a high frequency alternating current (AC) voltage; transmitting the high frequency AC voltage to at least one non-metallic emitter; wherein the at least one non-metallic emitter comprises at least 70% silicon by weight and less than 99.99% silicon by weight; wherein the at least one emitter comprises at least one treated surface section with a destroyed oxidation layer; and generating ions from the at least one non-metallic emitter in response to the high frequency AC voltage. Another embodiment of the invention provides an apparatus for low emission charge neutralization wherein the apparatus can perform the above-described operations.

Provided is a daylighting device (10) that is used by being attached to a window frame (110) supporting an existing window glass (100) and that includes a first base (11) being light-transmissive, a first spacer (12) provided at an outer edge of one surface (11a) of the first base (11) and attached to the window frame (110), and a daylighting member (13) provided on a side of the one surface (11a) of the first base (11), in which the daylighting member (13) includes a second base (14) that is light-transmissive and a plurality of protrusion daylighting portions (15) that are light-transmissive and provided to be adjacent to each other on a side of one surface (14a) of the second base (14).

A transparent conductive film includes a substrate having opposed first and second surfaces; a first hard coating layer formed on the first surface; a first optical adjustment layer formed on the first hard coating layer, the first optical adjustment layer comprising a second binder resin and a plurality of second particles distributed in the second binder resin; a first transparent conductor layer formed on the first optical adjustment layer, the first transparent conductor layer having a plurality of protrusions on a surface thereof corresponding to the plurality of second particles; a second hard coating layer formed on the second surface; a second optical adjustment layer formed on the second hard coating layer; and a second transparent conductor layer formed on the second optical adjustment layer.