The present application relates to an insulating glass (1) having at least two glass panes (2, 3) spaced apart from one another. The insulating glass (1) comprises at least one marginal join arranged between the glass panes (2, 3) in the region (8, 9, 10, 11) of edges (4, 5, 6, 7) of said glass panes (2, 3), said marginal join consisting of a spacer (12) and also at least one adhesive. The marginal join comprises a first adhesive at least in the region (8, 9) of two mutually opposite edges (4, 5), said adhesive having a rigidity in the cured state of at least 50 N/mm.sup.2, preferably of at least 100 N/mm.sup.2.

A display case door assembly for a temperature-controlled storage device includes a frame defining an opening into the temperature-controlled storage device and a transparent unit coupled to the frame. The transparent unit includes a first vacuum pane, a second vacuum pane, and an evacuated gap between the first and second vacuum panes. The evacuated gap has a predetermined thickness within which a vacuum is drawn, thereby providing a thermal insulation effect for the transparent unit. The transparent unit further includes a plurality of spacers disposed within the evacuated gap and configured to maintain the predetermined thickness of the evacuated gap when the vacuum is drawn therein.

A sash for doors or windows includes two spaced apart glass sheets, a spacer element interposed between the sheets to define a closed inner perimeter zone and an outer perimeter zone. A structural sealing/adhesion component runs along the outer perimeter zone and occupies a volume to permit contact with the spacer element and the glass sheets. An element for housing accessory components for supporting and/or operating the sash is associated with the structural component, for each side of the glass sheets. Each element includes a rigid profile associated with the structural component and having a closed base side, two flaps each formed by a stretch perpendicular to the base side and a recessed stretch, parallel to the base side, to form a channel with an opening. A rigid plate is adhesively associated with one of the glass sheets to cover an outer edge thereof.

A sash for doors or windows includes two spaced apart glass sheets, a spacer element interposed between the sheets to define a closed inner perimeter zone and an open outer perimeter zone. A structural sealing/adhesion component runs along the outer perimeter zone and occupies a volume to permit contact with the spacer element and the glass sheets. An element for housing accessory components for supporting and/or operating the sash is associated with the structural component for each side of the glass sheets. Each element includes a rigid profile having, in cross section, at least one closed base side and two flaps each formed by a stretch perpendicular to the base side and a recessed stretch, parallel to the base side, to form a channel with an opening The rigid profile is associated with the structural component along the outer surface of the base side.

An insulating glass unit suitable for a refrigeration unit is presented. The insulating glass unit includes a first pane, a second pane spaced at a distance from the first pane, a peripheral spacer frame between the first pane and the second pane, and an inner interpane space. According to one aspect, the spacer frame includes four hollow-profile polymeric spacers, which are secured between the first pane and the second pane along one of the four sides of the insulating glass. According to another aspect, the two first hollow-profile polymeric spacers are arranged along two opposing first sides of the insulating glass unit and the two second hollow-profile polymeric spacers are arranged along two opposing second sides of the insulating glass unit. According to yet another aspect, the first polymeric hollow-profile spacers contain 5% to 50% and the second polymeric hollow-profile spacers contain 0% to 0.5% reinforcement fibers.

A display case door assembly for a temperature-controlled storage device includes a vacuum panel, a hinge rail, and a lighting element. The vacuum panel includes a first vacuum pane, a second vacuum pane, and an evacuated gap between the first and second vacuum panes. The evacuated gap provides thermal insulation for the vacuum panel. The hinge rail is coupled to an edge of the vacuum panel and configured to rotate along with the vacuum panel between an open position and a closed position. The lighting element is coupled to at least one of the edge rail and the vacuum panel and configured to emit light toward an interior of the temperature-controlled storage device when the hinge rail and vacuum panel are in at least the closed position.

A vacuum insulated glass (VIG) unit frame assembly (10) is disclosed comprising: a rectangular vacuum insulated glass unit (1) comprising two glass sheets (2a, 2b) separated by a sealed gap (11), wherein a plurality of support structures (12) are distributed in said gap (11), and a frame arrangement (20) comprising elongated frame profile arrangements (20a-20d) which frames said vacuum insulated glass unit (1) in a frame opening (21), and wherein said frame arrangement (20) comprises a fixation system (40, 45a, 45b, 80, 28a, 28b, 22, 23, 40) fixating the vacuum insulated glass unit (1) at the frame arrangement (20), wherein said frame (20) is arranged so as to allow edges (8a-8d) of said vacuum insulated glass unit (1) to thermally deflect (DIS4) in a deflection direction (D1, D2) perpendicular to said frame opening plane (P2) due to a temperature difference (?T=T1?T2) between the two glass sheets (2a, 2b), and to provide a restriction of said thermal deflection (DIS4) of the edges (8a-8d), so as to reduce the magnitude of the thermal deflection compared to an unrestricted thermal deflection of the edges (8a-8d) at said temperature difference (?T=T1?T2).

A display case door assembly for a temperature-controlled storage device includes a vacuum panel, a hinge rail, and a lighting element. The vacuum panel includes a first vacuum pane, a second vacuum pane, and an evacuated gap between the first and second vacuum panes. The evacuated gap provides thermal insulation for the vacuum panel. The hinge rail is coupled to an edge of the vacuum panel and configured to rotate along with the vacuum panel between an open position and a closed position. The lighting element is coupled to at least one of the edge rail and the vacuum panel and configured to emit light toward an interior of the temperature-controlled storage device when the hinge rail and vacuum panel are in at least the closed position.

A spacer element for a double glazed article, a kit for assembling the spacer element, and a double glazed article including the spacer element. The spacer element includes a frame section. The frame section has a first substantially planar mounting surface located on a first side of the frame section for mounting a first sheet of glass on the spacer element at a periphery of the first sheet of glass. The frame section also has a second substantially planar mounting surface located on a second side of the frame section opposite the first side, for mounting a second sheet of glass on the spacer element at a periphery of the second sheet of glass. The spacer element also has a cavity located in-between the first and second mounting surfaces for accommodating a lock and/or roller mechanism of the double glazed article at a periphery of the double glazed article.

A vacuum insulated glass (VIG) unit frame assembly is disclosed comprising: a rectangular vacuum insulated glass unit comprising two glass sheets separated by a sealed gap, wherein a plurality of support structures are distributed in the gap, and a frame arrangement comprising elongated frame profile arrangements which frames the vacuum insulated glass unit in a frame opening, and wherein the frame arrangement comprises a fixation system fixating the vacuum insulated glass unit at the frame arrangement, wherein the frame is arranged so as to allow edges of the vacuum insulated glass unit to thermally deflect in a deflection direction perpendicular to the frame opening plane due to a temperature difference (T=T1T2) between the two glass sheets, and to provide a restriction of the thermal deflection of the edges, so as to reduce the magnitude of the thermal deflection compared to an unrestricted thermal deflection of the edges at the temperature difference (T=T1T2).