An apparatus for selectively viewing a projection includes a first pane having a top margin and a bottom margin, an angled panel having a top edge and a bottom edge, wherein one of the top edge and the bottom edge is situated proximate the first pane; and a projector configured to project onto one of the first pane and the angled panel. The first pane and the angled panel are spatially connected by a rim at the top and bottom margins of the first pane and the top and bottom edges of the angled panel.

The invention relates to a glass panel (200), including: a first glass sheet (20) at least partially coated with an electrically conductive coating (21), the conductive coating including at least one stack consisting of a metal layer (212) and an insulating layer (213), the metal layer being arranged between the first glass sheet and the insulation layer; at least one electronic component (23) arranged on the first glass sheet (21), the electronic component including at least one connection terminal (231) electrically connected to the conductive coating. According to the invention, the insulation layer (213) in such a panel includes at least one first window (241) which opens onto the metal layer and which is located at the connection terminal.

The present disclosure relates to micro-optical assemblies containing at least one optical element adhered to a receptor substrate, e.g. a transparent receptor substrate, the receptor substrate contains at least one graphics layer. The micro-optical assemblies include both functional micro-optical structures that can alter, for example, incident light, and a graphic layer, which includes at least one graphic, e.g. a graphic design, which may include color, patterns, imagery, indicia and the like. The combination of the micro-optical elements with the graphic of the graphics layer can provide unique light altering assemblies that have graphic designs that may be functional, e.g. to display a message, and/or have aesthetic value. The micro-optical assemblies of the present disclosure are useful in a variety of applications which include, but are not limited to, display and graphics applications and architectural glass applications. The present disclosure also provides a method of making the micro-optical assemblies of the present disclosure.

The insulating glass element is constructed for for doors, windows and fixed glass fronts. The insulating glass element includes a first glass pane and a second glass pane that is spaced from the first glass pane by a circumferential spacer element in an edge region. The glass panes each have a continuous recess; a first circumferential sealing element in the edge region of the glass panes, which seals the volume enclosed between the glass panes and the spacer element in the area of the spacer element in a gas-tight manner against the surroundings; and an insert introduced between the glass panes. The insert has a recess and is provided with a centering element that interacts with a recess of a glass pane for positioning the insert relative to the glass panes.

Disclosed is technology addressing lighting issues using a signature perforated design diffuser panel that provides a dual purposeartistic and artificial light source. Stated differently, the disclosed technology provides diffused lighting while creating a signature geometric perforated pattern. When turned off, the technology is wall art, and, when turned on, it is wall art that provides a signature lighting experience. Embodiments also include the same diffuser technology used to modify and condition natural light sources (e.g. sun light).

An insulated glass assembly includes a first pane of translucent, obscure, or transparent sheet material, a second pane of translucent, obscure, or transparent sheet material spaced apart from the first pane, a perimeter spacer positioned between the first and second panes and extending around the perimeter of the panes, and an internal divider disposed between the first and second spaced apart panes. The internal divider is spaced from the first pane and second panes of sheet material to form a first gap and a second gap therebetween. The insulated glass assembly further includes a first spring element and a second element within the gaps between the internal divider and the first and second spaced apart panes. The first spring element and the second element combine to bias the internal divider against contact with either of the first and second spaced apart panes.

A system for reducing the effect of a force includes a panel having a first side and a second side; a plurality of contact members disposed around a perimeter of the panel first side; and a biasing member positioned around a perimeter of the panel second side. The perimeter of the panel second side generally corresponds to the perimeter of the panel first side. The biasing member biases the contact members toward the panel first side. In a use configuration, a force received by the panel second side is at least partially transferred to the contact members causing at least one of the contact members to temporarily lose contact with the panel first side, whereby the return of the contact member into contact with the panel first side imparts a second force onto the panel first side, the second force being less than the force transferred to the contact members.

A system for reducing the effect of a force includes a panel having a first side and a second side; a plurality of contact members disposed around a perimeter of the panel first side; and a biasing member positioned around a perimeter of the panel second side. The perimeter of the panel second side generally corresponds to the perimeter of the panel first side. The biasing member biases the contact members toward the panel first side. In a use configuration, a force received by the panel second side is at least partially transferred to the contact members causing at least one of the contact members to temporarily lose contact with the panel first side, whereby the return of the contact member into contact with the panel first side imparts a second force onto the panel first side, the second force being less than the force transferred to the contact members.

Certain embodiments of this invention relates to a writable window (e.g., IG window unit), where images (e.g., advertisements, logos, designs, pictures and/or words) can be selectively written into the window and are designed to be viewed by humans and/or animals. A substrate (e.g., glass substrate) supports a solar coating such as a low emissivity (low-E) coating which may include at least one infrared (IR) reflecting layer of or including silver that is located on and directly contacting a contact/seed layer of or including a material such as zinc oxide and/or zinc stannate. A radiation source (e.g., laser(s) and/or lamp(s)) may be used to selectively expose certain areas of the coating to radiation (e.g., UV radiation). The exposed area(s) of the coating, after being exposed and heated, have different optical characteristic(s) (e.g., higher visible transmission) than the area(s) of the coating not exposed to the radiation, so that following the laser exposure the exposed area(s) form an image(s) designed to be viewed by humans and/or animals.

Glazings including first and second channel-section glazing elements are described. The first and second channel-section glazing elements are arranged to define a cavity in which an inner glazing element made of plastic is located. The inner glazing element includes a central portion and first and second edge portions running along opposite sides of the central portion. The first edge portion of the inner glazing element includes a first connection portion in mechanical communication with a first flange of the first channel-section glazing element. The first connection portion is integrally formed with the central portion of the inner glazing element. In preferred embodiments the second edge portion of the inner glazing also includes a second connection portion that is preferably integrally formed with the central portion of the inner glazing element.