A low-cost high-performance Vacuum Insulated Glass is produced with three glass panes and bonding fiber mesh structures embedded between the glass panes. Each mesh structure is configured with elongated bonding fiber elements arranged in a grid configuration. The bonding fiber elements are formed with a fiber core covered with a low melting temperature material. The low melting temperature material melts upon heating and creates numerous vacuum sealed cells between the glass panes. The fiber core does not melt, and remains intact bonded to the glass panes, thus creating a support mechanism for supporting the glass panes at a spaced apart relationship.

Disclosed herein are embodiments of a curved glass article. The curved glass article includes a glass sheet having a first major surface and a second major surface. The second major surface is opposite to the first major surface, and the first major surface and the second major surface define a thickness therebetween. The curved glass article also includes a carrier having a curvature and being made of a carrier material. The carrier material has a coefficient of thermal expansion (CTE) of from 8(10.sup.−6)/° C. to 40(10.sup.−6)/° C. The glass sheet is adhered to the carrier such that the glass sheet conforms to the curvature of the carrier.

The present disclosure provides a headliner for a vehicle. The headliner includes a foam; a hot melt film positioned on a surface of the foam; a reinforcement sheet positioned on the hot melt film; and a heat shielding layer coated with a thermal barrier material on the reinforcement sheet. In particular, the heat shielding layer includes a carbon nanotube.

Exemplary air amplifiers described herein can utilize a high-pressure stream of gas to accelerate a low-velocity stream of gas to provide a high-velocity, high-volume stream of gas. This high-velocity, high-volume stream of gas can generate unwanted noise as the high-velocity, high-volume stream of gas propagates through the air amplifier. The exemplary air amplifiers described herein can include can passively and/or actively suppress, for example, diminish, re-tune, or even completely cancel, the unwanted noise as the high-velocity, high-volume stream of gas propagates through these exemplary air amplifiers. The exemplary air amplifiers described herein can include one or more absorption materials to passively suppress the unwanted noise generated by the high-velocity, high-volume stream of gas. The exemplary air amplifiers described herein can generate multiple noise suppression waves to actively suppress the unwanted noise generated by the high-velocity, high-volume stream of gas. The multiple noise suppression waves can destructively combine with the unwanted noise generated by the high-velocity, high-volume stream of gas to suppress the unwanted noise.

The present invention is directed to an acoustical baffle that has use in vehicle interiors, such as an interior headliner. In particular, the baffle can provide improved acoustics while maintaining a desired airflow resistance and can be configured to provide for different sound attenuation characteristics at selected locations of the baffle construction.

Electromagnetically shielding an enclosable structure having a floor, walls, a ceiling, and at least one closeable opening by applying a shielding wallcovering to at least a portion of one of the walls and applying a second type of shielding material to at least a portion of the enclosable structure, wherein the second type of shielding material differs from the shielding wallcovering. The shielding wall covering is wallpaper comprising a metal-coated broad good and a resin. Other types of shielding material may include a transparent, shielding window covering such as NiCVD coated screen of woven silk fibers; shielded flooring such as a layered combinations of Kevlar non-woven as a base layer, nickel-coated non-woven layers, and a PCF toughened polymer; and a transition shielding strip made of a base layer of the shielding wallpaper with a PCF toughened polymer coating over a portion of the strip.

Proposed is a flexible composite cover window including a transparent glass-fabric reinforced plastic film that adheres to a rear surface or a front surface of the glass, in order to improve the pen-drop impact resistance of a glass cover window used in a flexible display. An effect of the embodiment is to provide a flexible cover window in which the glass-fabric reinforced plastic film protects the glass against impact applied to the glass or offsets the impact such that the pen-drop impact resistance is improved and strength and flexibility are secured.

A floor element for forming a floor covering, wherein the floor element comprises a decorative layer made of a ceramic material; a support layer arranged below the decorative layer; and a reinforcing layer arranged in between the decorative layer and the support layer, wherein the support layer comprises edges provided with coupling elements configured to realize a mechanical coupling with coupling elements of an adjacent floor element.

Disclosed herein are articles comprising: (a) a glass micro sheet having top and bottom surfaces and a thickness of about 0.001 to about 0.040 inches; and (b) a layer comprising a plurality of composite layers, the layer having top and bottom surfaces, wherein the bottom layer of the glass micro sheet is bonded to the top surface of the layer comprising a plurality of composite layers; and wherein the (Ra) of the top surface of the glass micro sheet is 1 nm<Ra<1 μm, and methods of making same.

A laminate according to an embodiment of the present invention includes at least one glass sheet and at least one resin layer, a relative dielectric constant of the glass sheet at 25° C. and a frequency of 2.45 GHz being 5 or less, and a dielectric loss tangent of the glass sheet at 25° C. and a frequency of 2.45 GHz being 0.003 or less.