A novel and useful frameless supplemental window for fenestration incorporating infiltration blockers suitable for use with existing windows. The supplemental window, in one embodiment, comprises plastic sheet material with bullnose edging around it. Corner braces add rigidity and strength to corners in several embodiments. An attachment mechanism secured either to the sheet material or the bullnose edge functions to fasten and/or seal the supplemental window to an existing window. Infiltration blockers fastened to the sheet or bullnose prevent or minimize air leakage around various window elements. The bullnose edging and infiltration blockers function to substantially enclose (i.e. trap) a volume of air between the window pane and the plastic sheet material. The supplemental window is configured such that the layer of air enclosed is of an optimum thickness within a preferred range of 0.15 to 0.75 inches to maximize thermal insulation properties of the supplemental window.

A spacer, window assembly, method of manufacturing a window assembly, and method of manufacturing a spacer is described herein involving window assemblies having three sheets of material, which will be referred to as a triple pane assembly. Two interior spaces are defined within the window assembly: a first air space between the first sheet and intermediary sheet and a second air space between the second sheet and the intermediary sheet.

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.

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.

An apparatus, method and manufacture utilizes additive manufacturing techniques to produce architectural manufactures such as windows and doors. The manufactures may have a composite construction and may feature inclusions like metal plates and reinforcements. The model used for controlling the manufacturing process may be derived from digital scanning of the structure on which the manufacture is used. Optionally, a finite element analysis is used to test the model and alter it in response to stress and/or thermal requirements.

An apparatus, method and manufacture utilizes additive manufacturing techniques to produce architectural manufactures such as windows and doors. The manufactures may have a composite construction and may feature inclusions like metal plates and reinforcements. The model used for controlling the manufacturing process may be derived from digital scanning of the structure on which the manufacture is used. Optionally, a finite element analysis is used to test the model and alter it in response to stress and/or thermal requirements.

A window includes a vacuum insulating glass (VIG) window unit in a window frame. The window frame includes at least one vacuum insulated structure (VIS) for improving the insulating functionality of the frame, so that the frame can adequately insulate the periphery of the VIG unit. Such windows may be used in residential and/or commercial window applications for buildings. The use of a window frame having at least one VIS is advantageous in that allows for improved window frame thermal performance and a narrow frame design if desired for improved aesthetics.

A metal profile (1) for door/window frame structure (S, S) provided with a metal frame (A), an insulating element (C) and/or a linear gasket (G) arranged inside said frame (A). The profile (1) comprises an elongated body (6) that extends along a longitudinal extension direction (L), a first end portion (8) and a second end portion (9) of the elongated body (6). The first end portion (8) of the body (6) is suited to interact with the frame (A) and/or the linear gasket (G) of the door/window frame structure (S, S) and the second end portion (9) of the body (6) is suited to be coupled with the insulating body (C) of the door/window frame structure (S, S) to promote its holding with respect to a substantially transverse direction (T) and form a unitary assembly with it. A method for making a metal profile (1) for door/window frame structure (S, S).