A light transmitting panel assembly includes a first panel, a second panel, a frame, a gap between the first panel and the second panel, and a first active component located between the first panel and the second panel.

Certain example embodiments relate to electric-potential driven shades usable with insulating glass (IG) units, IG units including such shades, and/or associated methods. In such a unit, a dynamic shade is located between the substrates defining the IG unit, and is movable between retracted and extended positions. The dynamic shade includes on-glass layers including a transparent conductor and an insulator or dielectric film, as well as a shutter. The shutter includes a resilient polymer, a conductor, and optional ink. If shutter coil skew is detected, voltage(s) may be applied one or more areas of the on-glass transparent conductor to compensate for or otherwise attempt to correct the detected coil skew.

The present invention is directed towards a window sill flashing comprising a base having a substantially rectangular shape. A front flange projects perpendicularly downward from a front edge of the base and at least one side flange extends vertically from a side edge of the base. The side flange includes a front surface. The window sill flashing is made from a rigid homopolymer vinyl film.

Machines are provided for removing masking from regions of glazing panes. Also provided are methods of removing masking from regions of glazing panes. The machines can include a head assembly and a processing station. The head assembly can have various combinations and/or configurations of features, including one or more of a plurality of cutters, a plurality of belts, and at least one pressurized gas nozzle.

Machines are provided for removing masking from regions of glazing panes. Also provided are methods of removing masking from regions of glazing panes. The machines can include a head assembly and a processing station. The head assembly can have various combinations and/or configurations of features, including one or more of a plurality of cutters, a plurality of belts, and at least one pressurized gas nozzle.

A vacuum insulating glazing unit comprising a planar area, first and second glass panes, k discrete spacers distributed over the planar area and positioned between the first and second glass panes, wherein k∈ and k>8, and a peripheral bonding seal hermetically sealing the distance between the first and second glass panes defining an internal volume under vacuum, enclosed between the first and second glass panes and bounded by an inner perimeter of the peripheral bonding seal defining the planar area. The inner perimeter has a substantially rectangular geometry with a length, L, a width, W, with L≥W. The discrete spacers are arranged according to the stress field lines of the combination of atmospheric pressure stresses, σp, applied by the atmospheric pressure on the surface of the vacuum insulating glazing, and of thermal stresses, σt, resulting from a temperature difference between exterior and interior environments.

Disclosed are novel forms of operable and fixed windows capable of at least one or more of: producing an electrical current utilizing a transparent or semi-transparent solar collecting coating or film on a pane, and selectively changing one or more of opacity and tint of one or more electrochromatic layers in the window. Some embodiments also disclose a robust scaffold assembly utilized to enclose the perimeter of the substrate and one or more transparent solar cells or electrochromatic layers, or transparent solar cells and electrochromatic layers. Various structural and electrical configurations are disclosed to satisfy the kinematic demands of operable windows. Wired and wireless configurations of the windows are contemplated as are self-powered versions whereby the transparent solar collector or wireless power powers the electrochromatic function. Also disclosed are self-powered and self-contained glaze units with wireless control or control from user interface controls on an indoor facing pane.

The present disclosure provides a device for generating electricity. The device comprises a panel having an area that is transparent for at least a portion of visible light and having a light receiving surface. The panel comprises at least one series of solar cells, each solar cell having opposite major surfaces having opposite electrical polarities, each solar cell overlapping another one of the solar cells and being electrically connected in series. The at least one series of solar cells is positioned along and in the proximity of an edge of the panel, along the area that is transparent for at least a portion of visible light and substantially parallel the light receiving surface of the panel.

A spacer is interposed between a pair of glass substrates facing each other. The spacer is disposed in contact with the pair of glass substrates. The spacer includes a center portion having a plate shape or a columnar shape, and both end portions protruding from both end surfaces of the center portion. At least any one of the both end portions has a spherical cap shape, or a spherical zone shape or a truncated conical shape. A radius A of a base portion at each of the both end portions is equal to a radius B of the center portion, or is smaller than the radius B.

A method of vacuum sealing a sacrificial panel to a structural panel, such as to form a walkway, is disclosed. The method comprises providing a sacrificial panel having a first side and a second, opposing side, providing a plurality of dots, applying the plurality of dots in a spaced relationship onto the first side of the sacrificial panel, applying a double-sided tape about the periphery of the first side of the sacrificial panel, providing a structural panel, placing the structural panel onto the first side of the sacrificial panel, wherein the dots create a gap between the sacrificial layer and the structural layer, and the double-sided tape provides an airtight seal between the sacrificial layer and the structural layer. The method further comprises providing a needle coupled to a vacuum device, inserting the needle into the gap between the sacrificial layer and the structural layer and operating the vacuum device to remove air from the gap between the sacrificial layer and the structural layer.