Patent Grant
10858220
Elevators include a car (also known as a cab) for transporting people or goods between two or more floors of a structure through a shaft (also known as a hoistway). Elevators enhance the convenience and accessibility of multi-story structures, and are a necessity in high-rise buildings such as skyscrapers. However, elevator shafts can become significant hazards in the event of a fire. Elevator shafts provide a fluid connection between floors of a structure, which allows air to travel between floors to fuel the fire and provides a pathway for smoke to spread throughout the structure.
Many building codes, such as the International Building Code, the Uniform Building Code and the International Fire Code, specify regulations to minimize the risks posed by elevator shafts during a fire. These codes often require that buildings include fire safety systems that automatically seal off openings to elevator shafts during a fire. Sealing off openings to elevator shafts reduces the airflow to a fire to prevent the fire from growing, and prevents smoke from spreading to unaffected floors of a building. Examples of fire safety systems include physical barriers such as fire curtains and fire doors.
Fire doors are doors that are formed from fire-resistant materials and that automatically close in the event of a fire to seal off elevator shafts. A fire door assembly includes one or more fire doors mounted to a fire-resistant door frame. The fire-resistant door frame is mounted to a wall near an elevator shaft.
A fire door frame must withstand the extreme conditions that are created by a fire. The high temperatures during a fire can deform or warp the metal of the frame. The load of the fire door on the frame can lead to torsion of the frame, resulting in the frame being pried away from the wall where it is mounted. In addition, a hot metal frame is subject to deformation due to the rapid cooling that occurs when water from a sprinkler system or a firefighters' hose contacts the frame. These actions can result in the failure of a fire door assembly during a fire, which can lead to greater structural damage and increased risk of harm to the occupants of the building.
In a first aspect, the invention is a door frame system comprising a wall and a door frame. The door frame includes (i) a sub-buck portion and (ii) a shell portion coupled to the sub-buck portion. The sub-buck portion includes a sub-buck mounting arm including at least one mounting aperture, a sub-buck rabbet arm coupled to one end of the sub-buck mounting arm, and a sub-buck support arm coupled to the sub-buck mounting arm opposite the sub-buck rabbet arm. The sub-buck portion is surface mounted to a single surface of the wall through the at least one mounting aperture.
In a second aspect, the invention is a surface mounted door frame kit comprising (a) a sub-buck portion and (b) a shell portion. The sub-buck portion includes a sub-buck mounting arm having at least one mounting aperture, a sub-buck rabbet arm coupled to one end of the sub-buck mounting arm, and a sub-buck support arm coupled to the sub-buck mounting arm opposite the sub-buck rabbet arm. The shell portion includes a shell support arm, a facing arm coupled to the shell support arm, a shell rabbet arm coupled to the facing arm, a stop coupled to the shell rabbet arm, a soffit coupled to the stop, a return coupled to the soffit, and a backbend coupled to the return. The shell portion is configured to fit around the sub-buck portion to form an enclosed quadrilateral when coupled.
In a third aspect, the invention is a sub-buck portion of a door frame consisting of a sub-buck mounting arm having at least one mounting aperture, a sub-buck rabbet arm coupled to one end of the sub-buck mounting arm, and a sub-buck support arm coupled to the sub-buck mounting arm opposite the sub-buck rabbet arm. The sub-buck mounting arm is capable of being surface mounted to a single surface of a wall.
In a fourth aspect, the invention is a shell portion of a door frame consisting of a shell support arm, a facing arm coupled to the shell support arm, a shell rabbet arm coupled to the facing arm, a stop coupled to the shell rabbet arm, a soffit coupled to the stop, a return coupled to the soffit, and a backbend coupled to the return. The shell rabbet arm and the stop define a rabbet.
In a fifth aspect, the invention is a fire door assembly comprising a fire rated door frame, a fire rated hinge coupled to the fire rated door frame, and a fire rated door coupled to the fire rated hinge. The fire rated door frame includes (1) a sub-buck portion and (2) a shell portion coupled to the sub-buck portion. The sub-buck portion includes a sub-buck mounting arm including at least one mounting aperture, a sub-buck rabbet arm coupled to one end of the sub-buck mounting arm, and a sub-buck support arm coupled to the sub-buck mounting arm opposite the sub-buck rabbet arm. The sub-buck portion is capable of being surface mounted to a single surface of a wall through the at least one mounting aperture.
The term “fire rated” means that a component has been approved to withstand fire for a fixed amount of time.
The term “fire listed” means that a component has been tested and approved by a recognized listing organization to withstand fire for a fixed amount of time.
The term “fire labeled” means that a component has a visible label indicating that it has been tested and approved by a recognized listing organization to withstand fire for a fixed amount of time.
The term “surface mounted” means a door frame that abuts a single surface of a wall. The door frame, when mounted, extends perpendicularly from the wall.
The invention can be better understood with reference to the following drawings and description.
Conventional door frames are roughly U-shaped in cross-section and are configured to be mounted around three sides of an opening in a wall.
The protruding walls required by conventional fire door frames impose a number of costs and constraints on building owners. Protruding walls increase the costs of construction due to the need for additional materials and labor. Protruding walls also impact the design and aesthetics of buildings since they reduce the open space in elevator lobbies.
The present invention is a door frame that is capable of being surface mounted to a single surface of a wall. The door frame includes a sub-buck portion, for coupling the frame to the wall, and a shell portion, coupled to the sub-buck portion, for supporting a door. When used as a fire door frame, this design eliminates the need for a protruding wall. Eliminating the protruding wall reduces the cost and complexity of construction, provides more space in elevator lobbies and expands the design options available to architects and designers.
Surface mounted fire door frames offer a number of advantages as compared to conventional fire door frames that require three mounting surfaces. The sub-buck portion and the shell portion may be formed from thicker gauge steel, which increases the rigidity of the frame and increases its resistance to warpage. The use of thicker gauge steel also reduces the mechanical advantage of the sub-buck portion and the shell portion. Eliminating the need for three distinct attachment points also allows for a frame design that improves the performance of a fire rated door frame. The design of the sub-buck portion reduces the amount of the sub-buck that lacks support as compared to conventional fire door frames. The shell portion features more bends than a conventional fire door frame, which increases the strength of the frame at the critical point where the door is coupled to the frame and the load is the greatest. The overall design of the frame reduces the cantilever effect due to torsion and protects the frame from deformation during cooling. In addition, the design provides for more material overlap, which provides increased rigidity and reduced flexibility.
The sub-buck portion and the shell portion may each independently be formed from any suitable metal or alloy. Examples of suitable metals and alloys include iron and its alloys, such as steel. Preferably, the sub-buck portion and the shell portion are each formed from steel. A particularly preferred type of steel is cold rolled steel. The metal used to form the sub-buck portion and the shell portion may have a thickness of 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21 or 22 gauge. The sub-buck portion and the shell portion may have the same gauge, or may have different gauges. Preferably, the sub-buck portion has a thickness of at most 18 gauge, and the shell portion has a thickness of at most 21 gauge.
The sub-buck portion and the shell portion may be monolithic, or may be formed from multiple components. Preferably, the sub-buck portion and the shell portion are each monolithic.
The door frame may optionally be a fire rated door frame, a fire listed door frame or a fire labeled door frame. Preferably, the door frame is a fire rated door frame. The fire door frame may be fire rated for up to 20 minutes, 30 minutes, ¾ hour, 1 hour, 1½ hours, 3 hours or 4 hours (the fire rating may alternatively be reported using an equivalent one-letter rating, such as “A” to indicate a fire rating of 3 hours). Preferably, the fire door frame is fire rated for up to 3 hours. The frame may comply with one or more standards for fire rated door frames authored by various standard-setting organizations. Examples of standard-setting organizations include the National Fire Protection Association (NFPA), the Steel Door Institute (SDI), Underwriters Laboratories (UL), the American National Standards Institute (ANSI), the American Society for Testing and Materials (ASTM), the Door & Hardware Institute (DHI), the Construction Specifications Institute (CSI), the Builders Hardware Manufacturers Association (BHMA), Intertek (Warnock Hersey) and the Canadian Standards Association (CSA). Preferably, the frame complies with NFPA 80 Standard for Fire Doors and Other Opening Protectives.
The door frame may be coupled to any type of wall near an elevator shaft. For example, the wall may be drywall (gypsum), drywall supported by wood studs, drywall supported by metal studs, masonry, concrete, concrete block, brick, brick tile, stucco, precast gypsum tile, plaster, plaster on block, plaster on metal lath, solid plaster with gypsum board core, and combinations thereof.
The door frame may be coupled to a wall using any suitable fastener. Examples of suitable fasteners include screws, bolts and nails. Preferred fasteners include drywall screws, for coupling the frame to drywall, and masonry fasteners, for coupling the frame to masonry.
The fire door assembly may include one door or two doors. The door assembly may be configured to open the door 90 degrees or 180 degrees. The door assembly may be configured for a right hand reverse (RR) or a left hand reverse (LR) door.
The fire door may be formed from any suitable metal or alloy. Examples of suitable metals and alloys include iron and its alloys, such as steel. Preferably, the fire door is formed from steel. A particularly preferred fire door material is cold rolled steel.
The fire door may optionally be a fire rated door, a fire listed door or a fire labeled door. Preferably, the fire door is a fire rated door. The fire door may be fire rated for up to 20 minutes, 30 minutes, ¾ hour, 1 hour, 1% hours, 3 hours or 4 hours (the fire rating may alternatively be reported using an equivalent one-letter rating, such as “A” to indicate a fire rating of 3 hours). Preferably, the fire door is fire rated for up to 3 hours. The door may optionally be a temperature rise door and may have a temperature-rise rating of 250° F., 450° F. or 650° F. The fire door may comply with one or more standards for fire rated doors authored by various standard-setting organizations. Examples of standard-setting organizations include the National Fire Protection Association (NFPA), the Steel Door Institute (SDI), Underwriters Laboratories (UL), the American National Standards Institute (ANSI), the American Society for Testing and Materials (ASTM), the Door & Hardware Institute (DHI), the Construction Specifications Institute (CSI), the Builders Hardware Manufacturers Association (BHMA), Intertek (Warnock Hersey) and the Canadian Standards Association (CSA). Preferably, the fire door complies with NFPA 80 Standard for Fire Doors and Other Opening Protectives.
The hinge may be formed from any suitable metal or alloy. Examples of suitable metals and alloys include iron and its alloys, such as steel. Preferably, the hinge is formed from steel. The hinge may extend along a portion of the frame, or along the full length of the frame. Preferably, the hinge is a fire rated hinge and is fire rated for up to 3 hours. An example of a suitable hinge is the continuous hinge from TOTAL DOOR SYSTEMS® (Waterford, Mich.).
The holder (also known as a hold open or a release) may be an electromagnetic holder. The electromagnetic holder is coupled to the same wall as the frame and is in electrical communication with the building power supply and the building fire or smoke detection system. Under normal operation, an electric current magnetically couples the holder to a magnet, such as the TDH 100 Electromagnetic Holder from TOTAL DOOR SYSTEMS® (Waterford, Mich.), coupled to the door. If the fire or smoke detection system is triggered, the electric current to the holder is stopped, which interrupts the magnetic coupling of the door to the holder and releases the door. The released door may then move to a closed position against the frame to seal the elevator shaft. An example of a suitable holder is the TDH 200 Electromagnetic Holder from TOTAL DOOR SYSTEMS® (Waterford, Mich.).
The operating grip may be coupled to one or both sides of the door to facilitate the manual movement of the door by a user. The operating grip may be formed from any suitable metal. Preferably, the operating grip is formed from steel. Preferably, the operating grip is a fire rated operating grip and is fire rated for up to 3 hours. Examples of suitable operating grips include the M32, M33, M35 and M52 grips from TOTAL DOOR SYSTEMS® (Waterford, Mich.).
The closer is coupled to the door and closes the door after the door has been released by the holder. Preferably, the closer is a fire rated closer and is fire rated for up to 3 hours. Examples of suitable closers include the TDC 96, TDC 96P, TDC 5051 and TDC 8907 closers from TOTAL DOOR SYSTEMS® (Waterford, Mich.).
The fire door assembly may optionally include additional fire and smoke prevention components. For example, a gasket or smoke seal may optionally be coupled to the frame. Similarly, a sweep may optionally be coupled to the bottom of the door. Preferably, any additional fire and smoke prevention components comply with the Underwriters Laboratories (UL) standards for fire doors.
The fire door assembly may be used with a passenger elevator or with a freight elevator. The fire door assembly may be included in any multi-story structure that contains an elevator. For example, the fire door assembly be included in an office building, hotel, condominium, apartment tower, hospital, factory, airport, train station, shopping mall, amusement park, casino or cruise ship.
The sub-buck portion of a surface mounted door frame (as shown in
The shell portion of a surface mounted door frame (as shown in
The attachment points for a surface mounted door frame were compared to the attachment points for a door frame configured to be mounted to three sides of a wall.
| Number | Name | Date | Kind |
|---|---|---|---|
| 2435779 | Guilbert, Jr. | Feb 1948 | A |
| 4748771 | Lehnert | Jun 1988 | A |
| 7621083 | Smith | Nov 2009 | B2 |
| 10087674 | Rochon | Oct 2018 | B2 |
| 20050098388 | Studhalter | May 2005 | A1 |
| 20050193652 | Cornell | Sep 2005 | A1 |
| 20060048466 | Darnell | Mar 2006 | A1 |
| 20060175147 | Morotome | Aug 2006 | A1 |
| 20060207199 | Darnell | Sep 2006 | A1 |
| 20100083598 | Smith | Apr 2010 | A1 |
| 20150135596 | Cooper | May 2015 | A1 |
| 20180119472 | Hucker | May 2018 | A1 |
| 20190336801 | Edwards | Nov 2019 | A1 |
| Entry |
|---|
| American National Standard ANSI/SDI A250.7-1997, “Nomenclature for: Standard Steel Doors and Frames”, Steel Door Institute, pp. 1-21, (1997). |
| Technical Data Series SDI 118-01, “Basic Fire Door Requirements”, Steel Door Institute, pp. 1-9, found at www.steeldoor.org/res/118.pdf, (2001). |
| Total Door Systems, “Total Door Systems Product Guide”, available online at www.totaldoor.com/product-guide/ (2015). |
| “NFPA 80 Standard for Fire Doors and Other Opening Protectives”, National Fire Protection Association, pp. 80-1-80-95, (2016). |
| “NFPA 105 Standard for Smoke Door Assemblies and Other Opening Protectives”, National Fire Protection Association, pp. 105-1-105-23, (2016). |
| Greene, L., “Questions about fire doors: Everything you always wanted to know”, found at www.constructionspecifier.com/questions-about-fire-doors-everything-you-always-wanted-to-know-but-were-afraid-to-ask/, pp. 1-8, (2013). |
| UL Product Category, “Fire Doors, GSNV”, UL Product Spec, pp. 1-4, (2012). |
| Technical Data Series SDI 111-09, “Recommended details for Standard Steel Doors, Frames, Accessories and Related Components”, found at https://www.steeldoor.org/wp-content/uploads/2020/02/SDI_111-1.pdf, 23 pages, (2014). |
| Product description “SafeFrame”, Total Door Systems, 3 pages, (Jul. 1, 2020). |
| Number | Date | Country | |
|---|---|---|---|
| 20200270099 A1 | Aug 2020 | US |
