There is provided a multi-layered glass in which two glass plates are placed such that they form a space via a spacer placed in a peripheral part of glass plates, wherein at least one low-emissivity film, which includes a plastic film and a Fabry-Perot interference filter formed on one side or both sides of the plastic film, is placed in the space, whereby space is divided; each of gaps between the glass plates and the spacer, and between the low-emissivity film and the spacer is sealed with a primary sealing material; a gap between the glass plates outside of the primary sealing material and the spacer is sealed with a secondary sealing material; and a reinforcement material is placed inside of the secondary sealing material. The multi-layered glass has a good appearance and excellent heat-insulating properties.

A glass unit including a spacer, a front glass pane attached to a front side of the spacer, a back glass pane attached to a back side of the spacer, and a pressure equalization conduit defined by and within the spacer, wherein the pressure equalization conduit has a first end and a second end, wherein the pressure equalization conduit contains a desiccant and is in fluid communication with an exterior of the glass unit at a first end port adjacent to the first end and with an interior space of the glass unit at a second end port adjacent to the second end. The glass unit may further include one or more intermediate layers contained within the interior space and one or more floating suspension systems for supporting the intermediate layers.

An insulating glazing unit, having a first pane, a second pane, and a third pane and a circumferential spacer is described. The spacer includes a polymeric main body described as a first pane contact surface and a second pane contact surface, a first hollow chamber and a second hollow chamber, an outer surface a groove to accommodate a pane where the lateral flanks of the groove are formed by the walls of the first hollow chamber and of the second hollow chamber, the outer surface is divided into a first outer surface, a second outer surface, and a bearing edge, the bearing edge runs substantially perpendicular to the pane contact surfaces and connects the first outer surface and the second outer surface to one another, the first outer surface and the second outer surface enclose in each case an angle α (alpha) of 100°<α<160° with the bearing edge, where wherein the panes are connected via one seal each to the pane contact surfaces, the third pane is inserted into the groove of the spacer (I).

The present invention provides an energy-saving plate and a method for manufacturing the same. The energy-saving plate of the present invention includes: at least one upper plate, at least one lower plate, at least one inner plate, and a plurality of support structures; a top edge of the upper plate and a bottom edge of the lower plate appear as a straight line; the inner plate is provided between the upper plate and the lower plate, and adjacent plates are separated by the plurality of support structures; an exhausting opening is provided at a lateral side of the inner plate, which is a through-groove inter-penetrating upper and lower surfaces of the inner plate; the periphery of the upper plate, the lower plate, and the inner plate are sealed via a sealing material, so as to form vacuum layers between the plate layers; an exhausting pipe is arranged in the exhausting opening, with which the exhausting opening is sealed together via the sealing material, an open-end of the exhausting pipe is located inside the exhausting opening, and a closed-end of the exhausting pipe is located outside the exhausting opening and is located in the space formed between the upper plate and the lower plate. In the present invention, a total flat surface of the energy-saving plate is achieved without structure defects, thus enhancing the strength of the energy-saving plate.

The problem of using cames for assembling stained glass pieces into a decorative window is solved by mounting the stained glass pieces in retaining channels and by using spacers in the retaining channel for maintaining gaps between adjacent stained glass pieces. The resulting stained glass assembly includes at least two stained glass pieces mounted within a frame and being secured in at least one retaining channel that is mounted to the frame so as to extend at least partially along the inner periphery thereof; and spacers in the retaining channel between each pair of the at least two stained glass pieces that are adjacent so as to create an opened gap therebetween. Such a stained glass assembly can be used as a decorative window in a door or as a dividing wall for example.

The invention relates to a process for manufacturing a vacuum insulated glazing wherein the glazing is assembled in a single stage by supplying glass panes, metallic spacers and corner and frame metallic seal elements which are brazed onto adhesion layers previously deposited onto the edge region areas of the glass panes.

Insulating glass unit comprising at least one pair of glass panes and at least one partition member therebetween for dividing the space between the glass panes into insulating chambers, and a spacer (4) which is fixed between the two glass panes (3) along their circumferences and into which the partition member is anchored. The method for manufacturing the insulating glass unit comprises the following steps: a) preparing two glass panes (3) and a partition member, b) preparing a spacer (4) by bending a hollow profile and adapting the inner sides of the spacer (4) for anchoring the partition member to at least two portions of the spacer, c) preparing the partition member, c) anchoring the partition member into the spacer, d) fixing the spacer (4) between the two glass panes (3) so that one side of the spacer circumferentially adjoins the first glass pane (3) and the other side of the spacer circumferentially adjoins the second glass pane (3) and the partition member is straightened and/or tensioned.

A spacer for insulated glazing units having at least one polymeric main body with a wall thickness d having a first pane contact surface and a second pane contact surface running parallel thereto, one first glazing interior surface, one second glazing interior surface, one outer surface, one first hollow chamber, and one second hollow chamber. A groove for receiving a pane runs parallel to the first pane contact surface and the second pane contact surface between the first glazing interior surface and the second glazing interior surface. The first hollow chamber adjoins the first glazing interior surface and the second hollow chamber adjoins the second glazing interior surface. The lateral flanks of the groove are formed by the walls of the first hollow chamber and the second hollow chamber, and the wall thickness d′ in the region of the lateral flanks is less than the wall thickness d of the polymeric main body.

A spacer for insulating glass units, includes a U-shaped main body extending in the longitudinal direction including a first metallic side section, a second metallic side section arranged parallel thereto, a polymeric connecting piece extending in the transverse direction, which connects the two metallic side sections and forms the lower limit of the main body, and an intermediate space arranged above the polymeric connecting piece between the metallic side sections. The first and second metallic side sections each include a side wall for connecting to a glass pane and a retaining arm, which protrudes into the intermediate space, and the retaining arm forms an assembly groove with the side wall, which groove runs substantially parallel to the side wall. The polymeric connecting piece is U-shaped and its two legs are inserted into the assembly grooves of the two metallic side sections.

A spacer is provided that is shapable into a spacer frame, and during manufacture of an insulating glass unit, can be mounted on the glass panes. The spacer is formed having an inner surface, an outer surface and two lateral surfaces extending at either side of the spacer from the inner surface to the outer surface, and comprises a profiled body. The profiled body comprises two mutually spaced lateral faces running parallel to its longitudinal direction and a base body that extends between the lateral faces and has an outer and an inner face. The profiled body comprises at least in one part of its volume a quantity of particulate desiccant that is embedded in a plastics material. The spacer is coilable about an axis, perpendicularly to the lateral surfaces, and takes a flexurally rigid form in a plane perpendicular to the lateral surfaces.