A door includes a door frame, first and second door skins having rectangular outer peripheries and inner openings, and a frameless glazed unit received at the openings. The door skins include exterior surfaces facing away from the door frame and opposite interior surfaces facing and secured to opposite sides of the door frame. The exterior and interior surfaces of the first and second door skins establish integral lips and grooves of the first and second door skins. Opposite sides of the frameless glazed unit directly contact and are sealed by the integral lips and sealant and/or adhesive contained in the grooves of the first and second door skins.

A window glazing assembly that can convert an existing or already-installed window, or be used to assemble new construction windows as a multi-pane or multi-glazed window unit, is provided herein. In particular, the glazing assembly includes an attachment assembly (e.g., peel-and-stick double-sided adhesive tape) and one or more glazing layers. Some embodiments further include a spacer assembly comprising a plurality of spacer bars that may be individually installed, e.g., one by one, around the perimeter of the window such as, to the window sash, window frame, or glass window pane, itself. The glazing layer(s) can then be secured or adhered to the spacer assembly, for example, around the perimeter thereof. Some embodiments may include additional or intermediate glazing layers, providing additional insulating airspaces and enhanced performance.

Various embodiments herein relate to methods, structures, tools, installation systems, etc. for retrofitting a new electrochromic window in a pre-existing window recess. In many cases, the new electrochromic window is installed parallel to a lite of a pre-existing window, with the resulting structure including the new electrochromic window, the pre-existing window, and a pocket that forms between them. Installation of a new electrochromic window in tandem with a pre-existing window results in many benefits including improved insulation (e.g., due to the presence of the additional air pocket(s) and lite(s)), improved climate control (e.g., due to the ability to control the amount of sunlight entering the building via the electrochromic window), and enhanced aes thetics.

A window glazing system includes an elongate elastomeric element having a right triangular cross section defining two leg surfaces and a hypotenuse surface with chamfers on the legs at the hypotenuse. A window pane is placed in a window frame and the interior frame and the window pane are appropriately coated with construction adhesive. The legs of the elongate element are forced into the intersection of the pane and the interior frame to spread and to be retained by the adhesive. The adhesive is then additionally forced into the chamfers and the entire assembly cleaned with solvent.

A retrofit adaptor is provided for retrofitting a glazing structure comprising an inner frame body and an outer frame body with windowpanes therebetween forming a glazed window. The retrofit adaptor comprises outer and inner connecting elements and a thermal break interposed therebetween and connected thereto. The outer connecting element for being connected to the outer frame body and defines an outer clearance hole therethrough. The inner connecting element for being connected to the inner frame body. The thermal break defines a cavity for receiving insulation therein. A mechanical fastener is insertable through the outer clearance hole of the outer connecting element when unconnected to the outer frame body and through the inner connecting element when mounted to the inner frame body, via the cavity, for being fastened to the inner frame body. The outer frame body is connectable to the outer connecting element for closing the outer clearance hole. The cavity is filled with the insulation thereby plugging the outer clearance hole.

Embodiments of an article comprising a cold-formed glass substrate in a curved shape, a plurality of separate mechanical retainers, and a frame are disclosed. The cold-formed glass substrate has a first major surface, and a second major surface opposing the first major surface. In one more embodiments, the plurality of separate mechanical retainers are attached to the second major surface of the cold-formed glass substrate. The mechanical retainers may be attached to the frame to define a position for each of the plurality of mechanical retainers, such that the mechanical retainers define the curved shape. Embodiments of processes to form such articles are also provided. Such processes can include attaching a plurality of separate mechanical retainers to a flexible glass substrate such that the glass substrate maintains its flexibility, and attaching the mechanical retainers to a frame, such that the mechanical retainers attached to the frame define a cold-formed curved shape for the flexible glass substrate.

A retrofit adaptor is provided for retrofitting a glazing structure comprising an inner frame body and an outer frame body with windowpanes therebetween forming a glazed window. The retrofit adaptor comprises outer and inner connecting elements and a thermal break interposed therebetween and connected thereto. The outer connecting element for being connected to the outer frame body and defines an outer clearance hole therethrough. The inner connecting element for being connected to the inner frame body. The thermal break defines a cavity for receiving insulation therein. A mechanical fastener is insertable through the outer clearance hole of the outer connecting element when unconnected to the outer frame body and through the inner connecting element when mounted to the inner frame body, via the cavity, for being fastened to the inner frame body. The outer frame body is connectable to the outer connecting element for closing the outer clearance hole. The cavity is filled with the insulation thereby plugging the outer clearance hole.

A window frame insert for an existing window frame can comprise: a window pane comprising a thermoplastic polymer, wherein a length of the window pane is divided into a first portion and a second portion by a living hinge mechanism formed into the window pane that extends across a width of the window pane from one edge to an opposite edge such that the first portion can bend at the living hinge mechanism toward the second portion, and wherein an outer edge of the window pane removably attaches to the existing window frame, and preferably wherein the first portion and the second portion have a haze value of less than or equal to 5% as determined in accordance with ASTM D1003-13, preferably less than or equal to 2%.

A door includes a door frame, first and second door skins having rectangular outer peripheries and inner openings, and a frameless glazed unit received at the openings. The door skins include exterior surfaces facing away from the door frame and opposite interior surfaces facing and secured to opposite sides of the door frame. The exterior and interior surfaces of the first and second door skins establish integral lips and grooves of the first and second door skins. Opposite sides of the frameless glazed unit directly contact and are sealed by the integral lips and sealant and/or adhesive contained in the grooves of the first and second door skins.

The invention is a photovoltaic system mounted with brackets to the inside surface of a window. The brackets are adhesively attached to the window. The system comprises photovoltaic modules on a substrate along with a sheet of material which is visually similar to the substrate which are both attached by the brackets to the interior surface of a window, facing towards the outside of the building. The light incident side of the substrate with photovoltaic cells faces the exterior of the building facing the sun. Electrical connectors are integrated into the substrate and connected to solar cells within the photovoltaic modules, thus providing electrical connection of the system to external electrical devices or electrical systems near the window that require power.