Disclosed herein is an insulated door which is thermally insulating, low maintenance and easy to operate, even where the door is large and/or constitutes multiple panels. The insulated door is surrounded by a door frame. The door may comprise one or more insulated panels, where each of the panels has four edges, and at least one edge is insulated with a thermal seal. The door has at least one lower lifting hinge and at least one upper sliding hinge connecting the door to the door frame. An exterior mounted first latch may be included for maintaining the insulated door in a closed position.

A fire rated door includes a core, a first decorative panel and a second decorative panel. The core includes: (a) a gypsum-based fire resistant center panel having a bottom, a top, a first side, a second side, a first end and a second end, wherein the gypsum-based fire resistant center panel is made of a first gypsum-based fire resistant material, and (b) an extruded gypsum-based fire resistant border attached to the first side, the second side, the first end and the second end of the gypsum-based fire resistant center panel, wherein the extruded gypsum-based fire resistant border is made of a second gypsum-based fire resistant material having a higher density than the first gypsum-based fire resistant material. The first decorative panel is attached to the top of the gypsum-based fire resistant center panel and the extruded gypsum-based fire resistant border. The second decorative panel is attached to the bottom of the gypsum-based fire resistant center panel and the extruded gypsum-based fire resistant border.

Systems and methods for rectifying excessive bottom or head clearances of door assemblies are disclosed. An example system may comprise a door sweep installed on a first side of a fire door; a door shoe installed on a second opposite side of the fire door; an intumescent seal in an opening between a bottom edge of the fire door and the door shoe or a floor surface; and end caps installed on two narrow side ends of the fire door.

Systems and methods for rectifying excessive bottom or head clearances of door assemblies are disclosed. An example system may comprise a door cap straight component installed on a first side of a fire door; a door cap L-shaped component installed on a second opposite side of the fire door; at least one intumescent strip seal fitted with the door cap L-shaped component; and end caps installed on two narrow ends of the fire door.

An emergency entryway system that provides for the detection of occupants in a room, fires outside of a door, and sealing the entryway during a fire emergency is disclosed. The emergency entryway system includes a door enclosed by a door frame, at least one display unit mounted in one side of door and at least one camera mounted in the door frame on the opposite side of the door, whereby the display unit in the door displays an image transmitted from the camera from the other side of the door frame and door. The door frame of the emergency entryway system may include at least one of a smoke detector, a carbon monoxide detector, or a radon detector, at least one fire extinguisher, an oxygen sensor, an alarm, a gas inflator canister, and an inflatable tubing configured to seal a space between the door and the door frame during a fire emergency.

A fire-blast resistant door assembly comprises a door frame and a door leaf. The front part of the door leaf comprises a front panel and a front stiffener that delimits a cavity from the inside of the front panel, wherein a sheet refractory material is installed in said cavity. The rear part of the door leaf comprises a rear panel and a rear stiffener that delimits a cavity from the inside of the rear panel. A support structure made of metal is installed in said cavity. The front and the rear parts of the door leaf are mutually connected through the layer of the refractory material, forming the thermal break therebetween, so that said support structure abuts against said sheet refractory material. The door frame, in its turn, comprises a front part and a rear part mutually connected through a layer of the refractory material forming a thermal break.

A smoke barrier system includes a bracket, a glass panel and a fastener. The glass panel defines a hole. The fastener is equipped to fasten the bracket to the hole of the glass panel. The bracket is fixed to a supporting construction on which the smoke barrier system is installed. The smoke barrier system also includes a first washer, wherein the washer is arranged between the fastener and the glass panel. The washer is an intumescent washer that expands under thermal influence of a fire, hot smoke and/or hot gas. Under thermal influence, the washer can form a thermally insulating layer. Furthermore, under thermal influence the intumescent washer can build up additional pressure between the fastener and the glass panel.

Systems and methods for rectifying excessive bottom or head clearances of door assemblies are disclosed. An example system may comprise a door cap straight component installed on a first side of a fire door; a door cap L-shaped component installed on a second opposite side of the fire door; at least one intumescent strip seal fitted with the door cap L-shaped component; and end caps installed on two narrow ends of the fire door.

A sliding door system may satisfy the requirements of, and be fire-rated in accordance with, UL10B (Standard for Fire Tests of Door Assemblies), and/or satisfy the requirements of, and be pressure-rated in accordance with, UL10C (Standard for Positive Pressure Fire Tests of Door Assemblies).

A sliding fire door is disclosed with an improved tightness of the closure by the door main body. The sliding fire door includes an opening frame, a fire door, and a guiding mechanism. The guiding mechanism includes a guide roller group which includes a plurality of guide rollers arranged one adjacent to another along the slide direction and which is configured to guide the door main body. The guiding mechanism is configured to guide the door main body such that the door main body is moved from an opening position to a closing position. The door main body has a first opposing surface which is oriented toward the wall. The opening frame has a second opposing surface which is oriented toward the first opposing surface of the door main body in the closing position. The guiding mechanism moves the door main body to cause the first opposing surface to be moved closer to the second opposing surface when the door main body is moved from the opening position to the closing position.