A window system includes a frame, a glazing assembly held within the frame and including a glass stop attachable to the frame, wherein attaching the glass stop to the frame defines an air pocket between the glass stop and the frame, and a thermal dampening device positioned within the air pocket and defining one or more discrete cavities.

An exemplary door includes a door body and a light assembly. The door body includes a first door panel defining a first panel opening, a second door panel defining a second panel opening, and an internal cavity. The area of the first panel is greater than the area of the second panel opening. The light assembly includes a first trim, a second trim, and an impact-resistant pane positioned in the door cavity. The first trim includes an outer frame coupled to the first door panel and an inner frame positioned in the internal cavity. The pane has an area greater than the area of the second panel opening area, and includes an first outer layer adhered to the inner frame of the first trim, a second outer layer adhered to the door body, and at least one intermediate layer.

A window frame system for fixing at least a first panel, includes at least a first window frame structure which includes at least a first window frame profile having at least first and second holders, and at least a first thermally insulating element with sixth and seventh holders. The second holder and the sixth and/or the seventh holder of the first thermally insulating element include at least one internal corner with a radius smaller than 0.5 mm. In this way, the dimensions of the window frame profile may be smaller than in the known window frame profiles. This may be advantageous for the total insulation value of the window frame system and the quantity of material required/used for the window frame profiles. Also disclosed is a thermally insulating element, a method, a window frame structure, a flexible profile, a control system and a sun protection system.

Improved sliding window or sliding door with a leaf with a leaf frame that is composed of leaf profiles which each comprise two half-shells which are thermally connected to each other by an intermediate thermal insulator, whereby in the leaf frame a rebate is provided for a panel which is supported by one or more glazing bead supports in the rebate and whereby the leaf frame is supported by one or more roller cassettes with rollers, wherein at least one glazing bead support comprises a feed-through section for transmitting the weight of the panel or a part thereof to at least one concerned roller cassette and that this feed-through section extends through a bottom leaf profile of the leaf frame up to a roller cassette.

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 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 molded door skin with integral divided light bars. The divided light bars are either true divided light (TDL) bars simulated divided light (SDL) bars or decorative grilles. The door skin includes a body portion and a divided light bar portion. The body portion and divided light bar portion are of one-piece construction which is preferably compression molded from fiberglass or other synthetic materials. Once assembled into a door with door glass installed, the divided light bars form a number of small windows for either simulating the appearance of traditional divided light windows in SDL applications, holding individual panes of insulating glass units in TDL applications, or for decorative purpose only.

Embodiments described herein may be directed to the functional application and method of use of a jacking screw for adjusting a window frame. In accordance with the present disclosure, adjusting the jacking screw may cause a first portion of the window frame to be lifted or lowered with respect to a second portion of the window frame. In doing so, a desired alignment of a window installed in the window frame may be achieved. This process may eliminate the use of shimming the underlying surface, thereby making it easier to install the window frame on surfaces that are not perfectly level.

A window for an above-ground pool is provided. The window includes a window portion (200) and a retainer bracket (250). The window portion (200) includes a window pane (210) and a peripheral rim (220) around a perimeter of the window pane (210). The peripheral rim (220) defines grooves (230) between inner and outer flanges (245, 235) on opposite side of the peripheral rim (220). The retainer bracket (250) includes a peripheral rim junction (260), a peripheral plate (270) and a joint (265) connecting the peripheral rim junction (260) and the peripheral plate (270).

A bead for releasably securing a glazing unit to a frame member, comprising a body having a first end and a second end, and a resiliently deformable member secured to the body and having a first finger extending from the body to a first end, and a second finger extending from the first finger to a second end. The first end of the body and the first end of the first finger are configured to engage with respective first and second ends of a frame member so as to secure the bead to the frame member. The second end of the body is configured to releasably secure a gasket in a first position so as to secure a glazing unit against an opposed end of the frame member. In use, application of an external force to the gasket moves the gasket to a second position and deflects the second finger from a first position to a second position, and the first finger is configured to separate from the second end of the frame member upon deflection of the second finger to the second position, so as to release the bead from the frame member.