A substrate, such as a windshield, includes: a first glass element; a second glass element; and a light absorptive element that is disposed directly between the second glass element and the first glass element, that is configured to receive and absorb light output by an image source.

A vehicle pane has a first substrate and at least one first electrically conducting layer, wherein an antenna structure is formed in the electrically conducting layer, wherein the antenna structure provides a Vivaldi-antenna-like structure, wherein the antenna structure has two substantially identical antenna elements, wherein the two antenna elements are arranged at an angle relative to one another, wherein the angle is greater than 0° and less than 180° such that the antenna elements appear substantially as mirror images at the angle bisector.

A pivoting cursor for a frameless window of a vehicle door, including: a main body portion; a pivoting plate pivotally secured to the main body portion for pivotal movement about an axis; a glass clamping plate; a seal; a first adjusting screw for pivoting the pivoting plate with respect to the main body portion; and a second adjusting screw adjusting a location of the main body portion with respect to the pivoting plate.

A slide An Original Equipment Manufacturer (OEM) window extension for a vehicle, the OEM window extension comprising: a window opening in at least one of a body, a door, and a wall of the vehicle; an extension, wherein the extension uses as least one extension fastener; an OEM window; wherein the extension is installed on the vehicle; and wherein the OEM window is installed in the extension.

A laminated glass having an interlayer between a glass plate on an exterior side of a vehicle and a glass plate on an interior side of the vehicle, includes a heat generator on a principal surface on a vehicle-exterior side of the glass plate that is on the interior side of the vehicle, wherein at least one of the glass plate on the exterior side of the vehicle and the glass plate on the interior side of the vehicle has a wedge shape in cross section, and wherein a maximum value of a layer thickness of the interlayer is less than or equal to 1 mm.

Due to the increased glazed area of modern vehicles, especially the large panoramic glass roofs, we have seen a substantial growth in the use of anti-reflective coatings. Unfortunately, these types of coatings accentuate fingerprints and smudges. The invention provides an automotive glazing which is substantially resistant to fingerprints, and a method of manufacture thereof through the application of an anti-fingerprint coating based on low surface energy silanes.

A vehicle window glass (10) includes a first glass sheet (1), a second glass sheet (2) and an interlayer film (3) sandwiched between a second surface (S2) of the first glass sheet and a third surface (S3) of the second glass sheet. For weight reduction, at least one of the glass sheets (1, 2) has a thickness of 2.0 mm or smaller. The interlayer film (3) has a main part (4) provided with a rigid layer and a peripheral part (5) formed of a non-rigid layer. The peripheral part (5) is disposed along an upper side of the vehicle window glass (10) which is exposed to air. Contact of water with the rigid layer of the main part (4) is prevented by the non-rigid layer of the peripheral part (5). The rigid layer has a water content controlled to 0.5% or lower as measured by near-infrared spectroscopy.

Aspects of the disclosure relate to vehicle window subassemblies for initial bonded and subsequent roped installation. In certain embodiments, a vehicle body of a vehicle includes a window mount with a flange having a bonding space for bonded installation of a window and a replacement space for roped installation of a replacement window. A bonded window subassembly includes a window, bonding agent, and bonded window trim configured to, upon attachment of the window to the window mount, preserve the replacement space from the bonding agent for roped installation of a replacement window. A roped window subassembly includes a replacement window and a roped window trim configured to, upon attachment of the window to the window mount, create a seal in the replacement space and not create a seal in the bonding space. Such configurations provide increased quality of an initial bonded installation and reduced cost of a roped installation.

Provided is an automotive glass setting apparatus, including a setting base supporting a glass having a plurality of edges, a plurality of alignment units allowing the glass to be aligned with the setting base; a scanning unit scanning the edges of the glass, a plurality of moving mechanisms moving the plurality of alignment units, and a controller controlling the moving mechanisms based on data scanned by the scanning unit to align a center of the glass with a center of the setting base.

A vehicle windshield triangulation assembly (11), and triangulation method using it with a railing (22) fixed to a vehicle (16) via sliding/rotatable/orientation-adjustable/height-adjustable mounts (18). A sliding seat (21) on railing (22) receives the telescoping end (1) of assembly (11) after its two connected 360-degree rotation swivel clamps (7), each having a suction cup (8), are secured against the old windshield's (17) exterior surface. Assembly (11) triangulation transfers to a new/replacement windshield (17) by releasing suction cups (8) and pairing them in the same manner with the new/replacement windshield (17), and making needed height adjustment to a top stop (12/13) and the swivel clamp (7) remote from top stop (12/13). The telescoping end (1) of assembly (11) is then engaged with sliding seat (21), allowing one person to easily and accurately move the new windshield (17) into the same positioning of the old windshield (17). This triangulation method accommodates windshields (17) having any size and curvature, and installation of windshields (17) occurs without a dry set step, measuring, templating, or educated guessing being required.