A window system for use in windows, sliding glass doors, skylights, casement windows and other openings in a building. The window system enables different windows of the same building to be individually customized for different impacts of coastal area weather and security concerns and also have the same external appearance despite employing various window protection steps. Panels, interior or exterior, are secured to the header and sill. Windows may be covered with exterior panels or include interior panels or impact resistant glass when the window is high on the building, or where security is a concern Windows including casement windows and other building penetrations may also accommodate interior panels, in combination with exterior protection. The window framing may have a uniform exterior appearance, notwithstanding different levels of protection.

A window assembly for installing in a window framing (also referred to as a “window casing”) of a wall of a building. The window assembly is configured to have a frameless appearance when installed with the finish surround installed around the interior and/or exterior of the window. The window assembly also allows the glass panel to be removed with a minimum of removal of the finish surround, such as without removing any of the finish surround, or only removing the finish surround around several sides of the only one of the interior or exterior of the window. For example, in most cases, only the interior finish surround around the right side and left side of the installed window frame needs to be removed to remove and replace the glass panel. Furthermore, the window assembly includes an integrated drain for draining moisture which leaks into the window assembly.

A blended trim molding assembly can include a first layer of engineered wood material (e.g., medium-density fiberboard) having a first, generally rectangular cross-sectional thickness, and a second layer of wood material (e.g., lumber, particle board, fiberboard) having a second, generally rectangular cross-sectional thickness. The second layer of wood material is joined (e.g., glued) to the first layer of engineered wood material at a planar interface. Together, the first and second layers have a total thickness, with the first cross-sectional thickness being greater than or equal to at least about ten percent (10%) of the total thickness of the first and second layers. The blended trim molding assembly may also include a third layer of wood material having a third, generally rectangular cross-sectional thickness, where the third layer of wood material is joined to the first layer of engineered wood material at a second planar interface opposite the planar interface.

A modular glass door assembly includes a door, an inner frame, and an outer frame. The door has a glass door leaf and a doorframe mounted to the outer periphery of the glass door leaf. The inner frame is attached to the outer periphery of the doorframe and connected to the doorframe by two hinges up and down. The outer frame has four frame strips arranged around the outer periphery of the inner frame and each provided with a concave portion engaged with one respective convex portion of the inner frame. By this way, the inner frame and the outer frame can be directly assembled with each other or a fixed window panel can be added between the inner frame and the outer frame. Thus, the modular glass door assembly of the present invention has advantages of easy assembly and high scalability.

A modular glass door assembly includes a door, an inner frame, and an outer frame. The door has a glass door leaf and a doorframe mounted to the outer periphery of the glass door leaf. The inner frame is attached to the outer periphery of the doorframe and connected to the doorframe by two hinges up and down. The outer frame has four frame strips arranged around the outer periphery of the inner frame and each provided with a concave portion engaged with one respective convex portion of the inner frame. By this way, the inner frame and the outer frame can be directly assembled with each other or a fixed window panel can be added between the inner frame and the outer frame. Thus, the modular glass door assembly of the present invention has advantages of easy assembly and high scalability.

A system for managing opening and closing a pocket door includes a spindle, an actuator, and brackets. The spindle extends along a longitudinal axis between first and second ends, and is configured to be coupled to the pocket door. The actuator is coupled to the spindle and is configured to cause the spindle to move axially along the longitudinal axis. The brackets are connected to the spindle at each end and are constrained from longitudinal motion relative to the spindle. The brackets are configured to affix the spindle to the pocket door. A bushing system couples each bracket to the spindle and is configured to dampen impact between the spindle and the brackets. For example, the bushing system may include lobed elements, made of a rubber material, that engage each other to transmit azimuthal forces. In some embodiments, another actuator is included to improve cycle like and redundancy.

A system for managing opening and closing a pocket door includes a spindle, an actuator, and brackets. The spindle extends along a longitudinal axis between first and second ends, and is configured to be coupled to the pocket door. The actuator is coupled to the spindle and is configured to cause the spindle to move axially along the longitudinal axis. The brackets are connected to the spindle at each end and are constrained from longitudinal motion relative to the spindle. The brackets are configured to affix the spindle to the pocket door. A bushing system couples each bracket to the spindle and is configured to dampen impact between the spindle and the brackets. For example, the bushing system may include lobed elements, made of a rubber material, that engage each other to transmit azimuthal forces. In some embodiments, another actuator is included to improve cycle like and redundancy.

A system for managing opening and closing a pocket door includes a spindle, an actuator, and brackets. The spindle extends along a longitudinal axis between first and second ends, and is configured to be coupled to the pocket door. The actuator is coupled to the spindle and is configured to cause the spindle to move axially along the longitudinal axis. The brackets are connected to the spindle at each end and are constrained from longitudinal motion relative to the spindle. The brackets are configured to affix the spindle to the pocket door. A bushing system couples each bracket to the spindle and is configured to dampen impact between the spindle and the brackets. For example, the bushing system may include lobed elements, made of a rubber material, that engage each other to transmit azimuthal forces. In some embodiments, another actuator is included to improve cycle like and redundancy.

A system for managing opening and closing a pocket door includes a spindle, an actuator, and brackets. The spindle extends along a longitudinal axis between first and second ends, and is configured to be coupled to the pocket door. The actuator is coupled to the spindle and is configured to cause the spindle to move axially along the longitudinal axis. The brackets are connected to the spindle at each end and are constrained from longitudinal motion relative to the spindle. The brackets are configured to affix the spindle to the pocket door. A bushing system couples each bracket to the spindle and is configured to dampen impact between the spindle and the brackets. For example, the bushing system may include lobed elements, made of a rubber material, that engage each other to transmit azimuthal forces. In some embodiments, another actuator is included to improve cycle like and redundancy.

A novel and useful frame less supplemental window for fenestration 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. The bullnose edging functions 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 trapped air 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.