A threshold has a substrate, a sill deck, an upstanding nosing, and an upstanding dam. An upwardly open sill channel is defined between the upstanding nosing and the upstanding dam. A threshold cap extends along and at least partially overlies the upwardly open sill channel. At least one holder is formed separate from the threshold cap and is located in the upwardly open sill channel between the upstanding dam and the upstanding nosing, the at least one holder at least partially supporting the threshold cap. The holder is removably disposed within the sill channel. The threshold cap is pivotably attached to the holder. The threshold cap is capable of rotating between a raised position and a lowered position. In at least the raised position, a highest point of the threshold cap is closer to the upstanding dam than the upstanding nosing.

The present invention relates generally to a universal strut for doors and window elements. More particularly, the invention encompasses a universal strut that mates with a first formed member, and a second formed member, and which assembly is used as windows, doors, window frames, and door frames. The invention also provides a method of using the inventive universal strut for applications that require different widths and lengths for a production or customized window, door, window frame, or door frame. The universal strut can also be used as a thermal barrier between the first formed member, and the second formed member. Preferably, the universal strut is made from a non-metallic or thermal barrier material, while the first formed substrate, and the second formed substrate are preferably made from a metallic material. The universal strut allows for the formation of various configurations for the shapes of window and/or door elements.

An energy-saving security composite window comprising a peripheral side frame and glass installed on the side frame, in which the side frame is of composite structure. A rectangular high strength metal pipe is located centrally to serve as a main body of the side frame and a cavity of the rectangular high-strength metal pipe is filled with a filling material. A plurality of non-metal profiles are respectively fixed on an outer surface of the rectangular high-strength metal pipe, and an installation groove for installing glass is formed between the rectangular high strength metal pipe and the non-metal profile. An external profile is a metal alloy material, a wooden material, a plastic material, or a glass material fixed on an outer surface of the non-metal profile. The performances of external windows of buildings, such as heat insulation, heat preservation, energy saving, sound insulation, and wind pressure resistance, is improved.

The present invention relates generally to a universal strut for doors and window elements. More particularly, the invention encompasses a universal strut that mates with a first formed member, and a second formed member, and which assembly is used as windows, doors, window frames, and door frames. The invention also provides a method of using the inventive universal strut for applications that require different widths and lengths for a production or customized window, door, window frame, or door frame. The universal strut can also be used as a thermal barrier between the first formed member, and the second formed member. Preferably, the universal strut is made from a non-metallic or thermal barrier material, while the first formed substrate, and the second formed substrate are preferably made from a metallic material. The universal strut allows for the formation of various configurations for the shapes of window and/or door elements.

An improved door rail system for holding a panel, such as a glass panel, is presented. The door rail system includes a core rail and clamping rails having a wedging geometry so that when the clamping rails are actuated with respect to the core rail, clamping force is applied to the glass panel to secure the panel within the core rail. The improved door rail system accommodates panels of varying thickness, features the use of modular side covers and incorporates a door to door jamb adjustment device allowing for angular adjustments.

A profile (e.g. an extrusion profile such as a monoextrusion or co-extrusion profile), for a door and/or window part may include a metal layer of less than 1.0 mm thickness laminated at least partially to an outer side of the profile using an adhesive.

Embodiments herein relate to fenestrations and components of the same exhibiting reduced thermal bowing and/or enhanced localized strength. In an embodiment, a fenestration assembly is included with a sash including a bottom rail, a top rail, a first side stile, and a second side stile, along with an insulating glazing unit, wherein the insulating glazing unit is disposed between the top rail and the bottom rail and between the first side stile and the second side stile. At least one of the rails or stiles includes a first lineal extrusion formed with a first composition including at least 5 wt. % fibers and a first polymer resin. At least one of the rails or stiles includes a second lineal extrusion formed with a second composition including a second polymer resin. Other embodiments are also included herein.

An improved door rail system for holding a panel, such as a glass panel, is presented. The door rail system includes a core rail and clamping rails having a wedging geometry so that when the clamping rails are actuated with respect to the core rail, clamping force is applied to the glass panel to secure the panel within the core rail. The improved door rail system accommodates panels of varying thickness, features the use of modular side covers and incorporates a door to door jamb adjustment device allowing for angular adjustments.

An astragal for a fenestration system includes at least first and second slots running along opposite sides of the astragal, each slot is configured to receive a stile of a panel of the fenestration system. The slots may be in different planes or in a common plane, and may be different depths or the same depth. In some embodiments, additional slots are provided in the astragal, on one or both sides of the astragal, and the astragal may be used in various placements and configurations within multi-panel door or window systems. A snap clip may be included within one or more of the slots to engage a stile when received in the slot and secure the panel to the astragal. Covers may fill slots that are not utilized in a particular panel configuration.

A composite profile includes a polymeric core and a side profile configured to be provided on an external surface of the core profile. The composite profile has a longitudinal direction Y, a depth direction X perpendicular to the Y-direction and a height direction Z, perpendicular to the X and Y directions. The polymeric core profile and the side profile include a first set of coupling means for attaching the side profile in a first position on the polymeric core profile and a second set of coupling means for attaching the side profile in a second position on the polymeric core profile. The side profile is repositioned over a distance D in the Z-direction when coupling the side profile and polymeric core profile with the second set of coupling means versus a coupling with the first set of coupling means.