Abstract: A building component includes an insulated glass unit including a first glass pane and a second glass pane defining a pocket therebetween, and a frame supporting the insulated glass unit. A central plane extends through the pocket and is spaced equal distances from the first glass pane and the second glass pane. The building component further includes an insulating material in the middle portion of the frame. The insulating material defines a continuous frame thermal break circumscribing the insulated glass unit and extending through the frame. The central plane extends through a center of the frame thermal break and forms a common central plane of the building component with substantially equal portions of the frame thermal break extending on each side of the common central plane when the building component is in a closed position.

Abstract: Composite components and methods for adding a composite material to a composite component are provided. For example, a method comprises positioning a composite material segment against the composite component to form a component layup; applying an insulating material around at least a portion of the component layup to form an insulated layup; and densifying the insulated layup, where the composite component was previously densified before positioning the composite material segment against the composite component. In some embodiments, the composite material is ceramic matrix composite (CMC) and the composite material segment is a plurality of CMC plies. The composite component may be a CMC gas turbine engine component that comprises an original CMC component and a new CMC material segment joined to the original CMC component through the transfer of silicon between the original CMC component and the new CMC material segment during melt infiltration.

Abstract: A building component includes a first glass pane connected to a second glass pane to form an insulated glass unit. The first glass pane and the second glass pane define a pocket therebetween. The insulated glass unit is positioned in a frame. The building component includes an insulating material in the middle portion of the frame. The insulating material defines a continuous frame thermal break extending through the frame. The frame thermal break is aligned with the pocket. The frame thermal break has a width of at least 1 inch. The pocket has a width that is less than the width of the frame thermal break.

Abstract: A fenestration unit includes a first glass unit, a first panel frame, a second glass unit, a second panel frame, a sill flashing, and a frame. The frame includes a header, jambs, and a frame sill including a first track and a second track. The first panel frame and the first glass unit are slidable along the first track when positioned in the frame. The second panel frame and the second glass unit are slidable along the second track when positioned in the frame. The sill flashing includes a base extending under the first and second tracks and a wall extending upward from the base to inhibit moisture intrusion through the fenestration unit. The frame sill is removable from the frame without disassembling the sill flashing, the jambs, and the header.

Abstract: A fenestration unit includes a first glass unit, a first panel frame, a second glass unit, a second panel frame, a sill flashing, and a frame. The frame includes a header, jambs, and a frame sill including a first track and a second track. The first panel frame and the first glass unit are slidable along the first track when positioned in the frame. The second panel frame and the second glass unit are slidable along the second track when positioned in the frame. The sill flashing includes a base extending under the first and second tracks and a wall extending upward from the base to inhibit moisture intrusion through the fenestration unit. The frame sill is removable from the frame without disassembling the sill flashing, the jambs, and the header.

Abstract: A thermally enhanced extrudate includes a channel, a first wall, and a second wall. The channel extends along a longitudinal axis from a first end to a second end of the thermally enhanced extrudate and is shaped to receive glass or a frame. The second wall is spaced from the first wall. The first wall and the second wall partially enclose a thermal break extending along the longitudinal axis. The thermal break has a first width defined between the first wall and the second wall at an upper end of the thermal break and a second width defined between the first wall and the second wall at a lower end of the thermal break. The thermally enhanced extrudate further includes a solid insulation material in the thermal break between the first and second walls and formed by curing a flowable material.

Abstract: A thermally enhanced extrudate includes a channel, a first wall, and a second wall. The channel extends along a longitudinal axis from a first end to a second end of the thermally enhanced extrudate and is shaped to receive glass or a frame. The second wall is spaced from the first wall. The first wall and the second wall partially enclose a thermal break extending along the longitudinal axis. The thermal break has a first width defined between the first wall and the second wall at an upper end of the thermal break and a second width defined between the first wall and the second wall at a lower end of the thermal break. The thermally enhanced extrudate further includes a solid insulation material in the thermal break between the first and second walls and formed by curing a flowable material.

Abstract: A fenestration unit includes a first glass unit, a first panel frame, a second glass unit, a second panel frame, a sill flashing, and a frame. The frame includes a header, jambs, and a frame sill including a first track and a second track. The first panel frame and the first glass unit are slidable along the first track when positioned in the frame. The second panel frame and the second glass unit are slidable along the second track when positioned in the frame. The sill flashing includes a base extending under the first and second tracks and a wall extending upward from the base to inhibit moisture intrusion through the fenestration unit. The frame sill is removable from the frame without disassembling the sill flashing, the jambs, and the header.

Abstract: A thermally enhanced extrudate includes a channel, a first wall, and a second wall. The channel extends along a longitudinal axis from a first end to a second end of the thermally enhanced extrudate and is shaped to receive glass or a frame. The second wall is spaced from the first wall. The first wall and the second wall partially enclose a thermal break extending along the longitudinal axis. The thermal break has a first width defined between the first wall and the second wall at an upper end of the thermal break and a second width defined between the first wall and the second wall at a lower end of the thermal break. The thermally enhanced extrudate further includes a solid insulation material in the thermal break between the first and se cond walls and formed by curing a flowable material.

Abstract: A method of forming a thermally enhanced extrudate for a door or window includes providing an extrudate including a channel shaped to receive glass or a frame and having a completely enclosed cavity. The method further includes forming openings in a first flange of the extrudate. The remaining portion of the first flange form bridges that extend between a first wall and a second wall. The method further includes position a flowable material into the cavity through the openings. The flowable material cures to create a solid insulation material in the cavity and the bridges resist warping of the extrudate as the flowable material cures.

Abstract: A method of assembling a building component includes connecting a first glass pane to a second glass pane to form an insulated glass unit. The first glass pane and the second glass pane define a pocket therebetween. The method also includes positioning the insulated glass unit in a frame including a first material. The method further includes connecting cladding including a second material to the frame. The frame defines a cavity that extends between a first side and a second side and is configured to inhibit moisture from the first side contacting the second material. The method also includes aligning a thermal break defined by the frame and the pocket such that the central plane extends through a middle portion of the thermal break. The thermal break and the pocket define a continuous thermal break extending through the building component.

Abstract: A building component includes a frame including a first material and cladding connected to the frame. The building component also includes a thermal break defined by the frame intermediate a first side and a second side of the building component and an insulating material within the thermal break. The building component further includes an insulated glass unit including a first glass pane and a second glass pane spaced from the first glass pane. The first glass pane and the second glass pane define a pocket therebetween. The thermal break and the pocket define a continuous thermal break when the building component is in a closed position.

Abstract: A method of assembling a window includes positioning an insulating material in a frame thermal break defined by a middle portion of a frame intermediate a first side and a second side of the window. The method also includes connecting a cladding to the frame. The frame includes a first material visible on the first side of the window. The cladding includes a second material visible on the second side of the window. The method also includes connecting a first glass pane to a second glass pane to form an insulated glass unit and positioning the insulated glass unit in the frame. The method further includes aligning the frame thermal break and a pocket of the insulated glass unit such that a central plane of the pocket extends through a middle portion of the frame thermal break. The frame thermal break and the pocket define a continuous thermal break extending through the window.

Abstract: A method of assembling a window includes positioning an insulating material in a frame thermal break defined by a middle portion of a frame intermediate a first side and a second side of the window. The method also includes connecting a cladding to the frame. The frame includes a first material visible on the first side of the window. The cladding includes a second material visible on the second side of the window. The method also includes connecting a first glass pane to a second glass pane to form an insulated glass unit and positioning the insulated glass unit in the frame. The method further includes aligning the frame thermal break and a pocket of the insulated glass unit such that a central plane of the pocket extends through a middle portion of the frame thermal break. The frame thermal break and the pocket define a continuous thermal break extending through the window.

Abstract: A building component includes a frame including a first material and cladding connected to the frame. The building component also includes a thermal break defined by the frame intermediate a first side and a second side of the building component and an insulating material within the thermal break. The building component further includes an insulated glass unit including a first glass pane and a second glass pane spaced from the first glass pane. The first glass pane and the second glass pane define a pocket therebetween. The thermal break and the pocket define a continuous thermal break when the building component is in a closed position.

Abstract: A window includes an insulated glass unit and a frame supporting the insulated glass unit. The insulated glass unit includes a first glass pane and a second glass pane spaced from the first glass pane. A central plane extends through a pocket defined between the first glass pane and the second glass pane. The frame includes a first material visible on a first side of the window. The window also includes cladding connected to the frame. The cladding includes a second material visible on a second side of the window. The frame defines a cavity that extends between the first side and the second side and inhibits moisture from the first side contacting the second material. The window includes a thermal cavity defined by the frame and aligned with the pocket.