An optically clear, siliconized plastic film(1) adhesively mounted on an architectural glass substrate(7) creates a highly efficient seat for adhere able plastic foam laminates. This will allow the plastic foam laminates to be seated on the siliconized plastic film creating complete removability and reusability. Additionally, numerous adhesives can be specified for the plastic foam laminates wherein adhesive residue left on the glass will not be a design factor. In one embodiment the siliconized plastic film allows double sided tape(2) to be placed on the periphery of the laminate to achieve an excellent, glass removable bond for seating the film on a glass substrate. This makes an excellent, impervious seal. Also, heat transfer reductions range from approximately 89-98% depending upon the temperature extremes in Winter and Summer. Further, this invention provides good light transmission, improves privacy for bedroom glass, creates a display for brilliant artwork, reduces dust accumulations and creates instant removability. The material cuts as easy as paper and will be very simple to fabricate; therefore, this invention can be constructed with simple kits and installed by unskilled, do-it-yourself users.

A metal door frame for a door opening comprising at least one first door frame segment for upper or side portions of the door opening, the at least one first door frame segment having a first molding flange, a first jamb face adjacent to the molding flange, and a first stop flange adjacent to the jamb face. The metal door frame includes at least one second door frame segment for upper and side portions of the door opening, the at least one second door frame segment having a second molding flange, a second jamb face adjacent to the molding flange, a second stop flange adjacent to the jamb face, a second stop face adjacent to the stop flange, and a third stop flange adjacent to the stop face. The metal door frame includes a thermally insulative layer between the first door frame segment and the second door frame segment.

A mullion-transom structure has a supporting profiled element on which at least one filling element is retained at an edge, and a pressing strip by which at least one filling element is pressed toward the supporting profiled element. The pressing strip is retained on the supporting profiled element by at least one fastener, which fastener engages in a groove on the supporting profiled element. The groove is formed with an undercut and the at least one fastener is displaceably retained with a head segment in the groove. Preferably, the fastener embodies a bolt connected to a head segment, which head segment is pivotably held in a pre-mounted position on the groove of the supporting profiled element.

Devices, systems, and methods related to a fenestration unit are described herein. The fenestration unit may include a frame including a plurality of frame members, wherein the plurality of frame members includes an upper rail member, a lower rail member, a first stile member, a second stile member, the lower rail member including two parallel metallic extrusions a space defined therebetween and a thermal break coupled to the lower rail member and located within the space. The thermal break may include a solid body of thermally insulating material defining a first side portion, a second side portion, and an intermediate portion between the first side portion and the second side portion, the solid body of thermally insulating material being asymmetrical about an X-Y plane.

An insulating body for multi-shell construction elements for spacing apart and thermally separating at least two profiled section elements relative to each other has a base member with a first side and a second side opposite the first side. Fastening projections are arranged on the first and second sides of the base member and secure the insulating body in receptacles of the profiled section elements. At least the first side has two of the fastening projections. The base member has a hollow chamber with an inner guiding contour for receiving and guiding fitting parts. A multi-shell construction element with at least two profiled section elements is provided with at least one such insulating body.

A thermally-broken ornamental door includes a thermally-broken door and a thermally-broken jamb through which thermal transfer is greatly minimized. The thermally-broken door includes an outer panel and an inner panel that are minimally connected through a plurality of door bridging strips. The thermally-broken jamb includes an outer jamb frame and an inner jamb frame that are minimally connected through a plurality of jamb bridging strips. An insulating foam panel is present between the outer panel and the inner panel while an insulating foam core is present between the outer jamb frame and the inner jamb frame. A window assembly is hingedly mounted into the thermally-broken door and includes a retaining spacer frame that minimizes thermal transfer from an exterior environment to an inner window frame through a glass panel of the window assembly. The retaining spacer frame additionally provides structural support to the glass panel.

A composite profile for doors, windows, or other facade elements includes a first and second metal profile between which at least one intermediate metal profile is provided. The first metal outer profile is connected to the intermediate metal profile in a first insulating web zone via one or more insulating web(s), and the second metal profile is connected to the intermediate profile in a second insulating web zone via one or more insulating web(s). Both the first and second insulating web zones have different shear strengths orthogonally in relation to the cross-sectional plane of the composite profile.

A metal door frame for a door opening comprising at least one first door frame segment for upper or side portions of the door opening, the at least one first door frame segment having a first molding flange, a first jamb face adjacent to the molding flange, and a first stop flange adjacent to the jamb face. The metal door frame includes at least one second door frame segment for upper and side portions of the door opening, the at least one second door frame segment having a second molding flange, a second jamb face adjacent to the molding flange, a second stop flange adjacent to the jamb face, a second stop face adjacent to the stop flange, and a third stop flange adjacent to the stop face. The metal door frame includes a thermally insulative layer between the first door frame segment and the second door frame segment.

An insulation system including a first retention member having a first channel, a second retention member having a second channel, and a thermal bridge. The thermal bridge includes a first finger and a second finger. The first finger is received into the first channel and the second finger is received into the second channel. The system further includes a first locking tab associated with the first channel for securing the first finger and a second locking tab associated with the second channel for securing the second finger. The thermal bridge substantially reduces conductive heat transfer between the first retention member and the second retention member.

An insulation system including a first retention member having a first channel, a second retention member having a second channel, and a thermal bridge. The thermal bridge includes a first finger and a second finger. The first finger is received into the first channel and the second finger is received into the second channel. The system further includes a first locking tab associated with the first channel for securing the first finger and a second locking tab associated with the second channel for securing the second finger. The thermal bridge substantially reduces conductive heat transfer between the first retention member and the second retention member.