Patent Grant
8739475
Foldable building units have previously mostly been described in the literature. Reasons that hinder commercialization of previously described foldable building units include the large extent of work that needs to be performed at the building site, the difficulty of ensuring that prefabricated finished interior and exterior surfaces can be transported without substantial damage, and the generally increased complexity of constructing a foldable building unit.
There is, therefore, a need for foldable building units with new structural frame and connection assembly designs enabling greater construction efficiency and flexibility, in particular, structural frame and connection assembly designs allowing for easier connection of frame elements in the prefabrication process and at the building site, allowing for more finish in the factory, and less and faster work at the building site, while providing a tight building envelope with reduced heat transfer, particularly, through the edges of the foldable building unit.
A first embodiment of the present invention is a foldable building unit. The foldable building unit includes (a) a first frame element having a first structural load carrying member that is a hollow structural metal section, a metal C-channel, a metal I-beam, a metal T-beam, a metal angle beam, or a metal wide-flange beam; (b) a second frame element having a second structural load carrying member that is a hollow structural metal section, a metal C-channel, a metal I-beam, a metal T-beam, or a metal wide-flange beam; provided that the first structural load carrying member and the second structural load carrying member are not both hollow structural metal sections; and (i) the first structural load carrying member and the second structural load carrying member are lengthwise connected to form a fixed connection between the first frame element and the second frame element, or (ii) the first structural load carrying member and the second structural load carrying member are lengthwise foldably connected to allow folding of the first frame element and the second frame element relative to each other.
A second embodiment of the present invention is a foldable building envelope that is substantially entirely formed by panels that are connected through structural load carrying members of the panels, which are, independently, a hollow structural metal section, a metal C-channel, a metal I-beam, a metal T-beam, a metal angle beam, or a metal wide-flange beam, the structural load carrying members being part of a metal structural frame of the foldable building envelope, the panels including interior and exterior finishing material attached to blocking members, the blocking members being attached to the structural load carrying members; and structural load carrying members in at least some of the edges of the foldable building envelope having blocking members directly lengthwise attached to one or more interior surfaces of the structural load carrying members in a manner that allows exterior finishing material to be affixed to blocking members in the edges of the foldable building envelope.
A third embodiment of the present invention is a foldable building unit, comprising a first panel including a first structural frame having a first structural load carrying member and a second panel including a second structural frame having a second structural load carrying member; wherein the first structural load carrying member and the second structural load carrying member are lengthwise affixed to each other such that the first and second panel form an exterior edge; at least one of the first or second structural load carrying member having a blocking member lengthwise affixed to one or more of its interior surfaces, and the blocking member positioned such that exterior finishing material is directly attachable to the blocking member in unfolded configuration.
The foldable building units of the present invention have one or more of the following advantages. They can be easily prefabricated, allow precision unfolding, allow easy fastening of foldably connected frame elements in unfolded configuration, allow to insulate metal structural load carrying members in the edges and corners of the foldable building units thereby reducing heat transfer, they allow easy fastening of finish material in the edges and corners, and they allow foldable building units that are more compact in the folded configuration thereby allowing larger foldable building units to be transported more easily.
The foregoing will be apparent from the following more particular description of example embodiments of the invention, as illustrated in the accompanying drawings in which like reference characters refer to the same parts throughout the different views. The drawings are not necessarily to scale, emphasis instead being placed upon illustrating embodiments of the present invention.
Foldable building units of the present invention are based on new structural frame and connection assembly designs enabling greater construction efficiency and flexibility. The structural frame and connection assembly designs allow for easier connection of frame elements in the prefabrication process of the foldable building units and for easier connection of frame elements at the building site, for example, of foldably connected frame elements after unfolding. They also allow for more finish in the prefabrication process and/or less and faster work at the building site while providing a tight building envelope with reduced heat transfer, particularly, through the edges of the foldable building unit.
A description of example embodiments of the invention follows.
The foldable building units of the present invention can be prefabricated such that the foldable buildings, after unfolding on the building site, are substantially in finished condition. That is, they do not require or significantly reduce the addition of further building sections such as wall panels, floor and roof sections, or the addition of interior and exterior finish materials with the exception of minor, non-structural finishing in areas required for folding movement. Further, foldable building units of the present invention can include roof sections that are panelized but can be easily installed at the building site. The prefabrication process can be reduced substantially, even to the extent that merely a foldable structural frame of the present invention is prefabricated and unfolded at the building site.
Further, all necessary mechanical and electrical systems for the residential or commercial foldable building, for example, all the required appliances and plumbing fixtures, can be installed in a core structure (i.e., a part of the structural frame of the foldable building that is made of frame elements that are not unfolded at the building site). Flexible piping and wiring can also be chased throughout both fixed and foldably connected panels of the foldable building units of the present invention.
Use of structural steel in the form of appropriately dimensioned I-beams, c-channels, wide-flange beams, and hollow structural sections allows for large frame geometries as part of the structural frame of the foldable building unit, for example, rectangular frame elements spanning the entire side of a foldable building, reducing prefabrication cost and/or simplifying unfolding at the building site.
Further, foldable structural frames substantially made of metal frame elements (e.g., made from hot-formed steel such as I-beams, c-channels, wide-flange beams, and hollow structural sections) can be prefabricated to superior tolerances such that a respective foldable building unit in substantially finished condition upon unfolding exhibits reduced or no gaps in the seam areas between foldably connected frame elements thereby reducing the work associated with on-site finishing of these seam areas.
Foldable building units, for example, the foldable buildings shown in
The foldable building units of the present invention can be several stories high. For example, multi-story structures can be built on-site by stacking separate foldable building units with a crane. In this arrangement, ceiling frame elements of the lower unfolded foldable building unit lie directly below floor frame elements of the upper foldable building unit. During prefabrication, appropriate openings can be included in the ceiling of the lower foldable building unit and in the floor of the upper foldable structure to accommodate a staircase, which can be installed in the lower foldable building unit during prefabrication.
Steel frame elements of the present invention are typically combined with wooden or light-gauge metal intermediate elements to form lightweight steel and wood/light-gauge metal hybrid structures in which the frame elements provide structural stability and the wooden or light-gauge metal intermediate elements provide substantial lateral structural resistance and/or are used to attach interior and exterior finishing material using standard construction approaches, reducing labor training and associated costs.
In certain embodiments of the present invention, structural load carrying members connecting different frame elements of the structural frame allow blocking material (e.g. wood or light-gauge metal studs) to be connected to inside areas of the structural load carrying members, and the structural load carrying members are positioned such that the blocking members face the outside of the foldable building unit. This allows structural frames that have a continuous conventional structural grid (e.g., 16 inch wood lumber grid) through the edges/corners of the foldable building unit, thereby allowing attachment of exterior finishing material through the edges/corners using standard construction approaches, reducing labor training and associated costs, and work at the building site.
Use of these strong and lightweight structures can also substantially reduce the amount of required building material and the weight of the frame elements, which in turn facilitates the transport of larger folded building units for a given maximal allowed weight according to given road regulations.
Indirect connections of interior and/or exterior finishing materials to metal frame elements (particularly, frame elements made of structural steel sections) are one aspect of a “multi-tolerance” building approach that disaggregates and cushions brittle or otherwise fragile finish materials from the vibrational, kinetic and settling forces applied to the structural frame during shipping, setting, unfolding and settling of the prefabricated foldable building units. A second aspect of a multi-tolerance building approach is provided by the offset hinges (in particular, L-shaped offset hinges) of the present invention which are specifically engineered to safely nest hingedly (i.e., foldably connected with one or more hinges) connected frame elements at a designed distance away from its neighboring frame element, allowing, for example, for thicker wall depths and thus the prefabricated inclusion of finish materials. This is associated with a significant reduction in the scope of work to be completed on-site, where costs and scheduling are far less manageable. Thus, foldable building units of the present invention can include final interior finishing, such as trim, gypsum board, paint or wallpaper.
Structural load carrying members of the present invention can be foldably connected with hinges to foldably connect frame elements and respective panels. More typically, structural load carrying members of the present invention can be foldably connected with offset hinges, and preferably, L-shaped offset hinges (such as those shown in
Foldable building units if the present invention can provide part of a building (commercial or residential) or can be an entire foldable building (commercial or residential) when unfolded.
A foldable building unit in “unfolded configuration” is a foldable building unit in which the foldably connected frame elements have been unfolded into positions that can be maintained in the finished condition of the foldable building unit. A foldable building unit in “folded configuration” is a foldable building unit in which foldably connected frame elements are folded into positions suitable for uploading, transport, and/or unloading of the building unit.
A “structural frame” as used herein, refers to the totality of structural load carrying members of a foldable building unit that are primarily responsible for providing structural stability of the foldable building unit in folded, partially unfolded and unfolded configuration, and which transmit loads (e.g., static, dynamic, and/or vibrational loads) to the ground. Structural frames can include members that are made of a plurality of materials in various forms and dimensions. Suitable materials that can be used include but are not limited to metal (e.g., aluminum or steel), wood and polymers. Suitable structural load carrying members include but are not limited to hollow structural sections, C-channels (with or without return), I-beams (including S and W type), T-beams, angle beams, and wide-flange beams. Preferably, the structural load carrying members are commercially available American standard structural load carrying members. Typically, two connected structural load carrying members are not both hollow structural steel sections. The selection of a material, form and dimension for a given structural part or member of a structural frame is interdependent and depends on factors such as the position of the structural part or member in the structural frame, and whether the member is part of a frame element that is foldably connected.
In the context of the shape of structural load carrying member, “inside”, “inside area”, “interior area”, “inside surface” or “interior surface” refers to the areas of the structural load carrying member that are inside of a box enveloping the structural load carrying member. That is, if a cross-sectional view of the structural load carrying member is considered (as shown, e.g., in
A “frame element” as used herein, refers to an element of a structural frame of a foldable building unit that includes a plurality of structural load carrying members that form a closed or open frame. Typically, the members form a closed frame. However, the members can also form an open frame, or have additional members. Some typical frame elements are shown in
Interior and exterior finish materials can be attached to the structural frame, typically, by attachment with intermediate elements affixed to frame elements of the structural frame. Interior and exterior finishing materials are typically attached (e.g., glued, nailed, screwed, welded and/or bolted, or otherwise affixed) to intermediate elements. Interior finish materials include but are not limited to wall finishing (for example, gypsum board and sheathing), ceiling finishing and floor finishing (for example, sheathing with Bamboo flooring on top). Exterior finishing elements include but are not limited to siding and roofing.
For finish materials, and, in particular, interior finish materials, it has been found that “indirect connection” to the frame elements to reduce contact, partially or entirely, of the interior finish materials with the frame elements is advantageous for one or more of the following reasons. Reduced contact can (a) reduce the transfer of structural stresses from one or more frame elements of the structural frame to the often fragile and brittle interior finish materials thereby reducing or eliminating significant damage (such as dry wall cracking) of the interior finish materials, in particular, during folding, uploading, transporting, unloading and/or unfolding of the foldable building unit, and settling, (b) reduce or eliminate the exposure of the interior finish materials to water, for example, water that can condensate on metal parts of the frame elements, and (c) reduce heat transfer between the inside of the finished building unit to the outside of the finished building unit.
Thus, generally, it is preferred to use indirect rather than direct connections of finish materials, particularly, interior finish materials with respective frame elements. However, even though indirect connections are typically preferred, not all connections between interior finish material and a respective frame element have to be indirect.
Typically, intermediate elements are made, at least in part, of materials that have a force cushioning effect, that is, force cushioning elements such as, for example, wood, sprayed foam, and light-gauge metal studs. Typically, an intermediate element is positioned and dimensioned such that it can connect or can be connected (e.g., using powder-actuated fasteners or self-tapping screws) to the frame element through one area of the intermediate element (e.g., through one side of the intermediate element) and that it can be connected to the finish material, particularly, the interior finish material (for example, using nails or screws) through another area of the intermediate element (e.g., through another side of the intermediate element). Even more preferably, intermediate elements are entirely made of force cushioning materials such as wood.
Foldable building units of the present invention typically include wall panels, roof and floor sections that are in substantially finished condition, that is, with the exception of unfinished areas dimensioned to accommodate folding of the frame elements, and unfinished areas due to wall connection seams (i.e., seams between walls that are not connected but upon unfolding jointly form a wall), these wall panels, roof and floor panels are finished.
“Finished panels” as referred to herein, are panels that include frame elements and interior finish materials connected (typically, indirectly) to them, and can also include elements such as doors and windows.
The foldable building units of the present invention are foldable to facilitate transport of the pre-fabricated building units. Preferably, the foldable building units in folded configuration are dimensioned such that transport with a transport vehicle is possible, preferably, with a semitrailer and without requiring a special transport permit. Regulations pertaining to the operation of trucks and trailers vary from country to country, and, in some instances from state to state.
While this invention has been particularly shown and described with references to example embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the scope of the invention encompassed by the appended claims.
This application is the U.S. National Stage of International Application No. PCT/US2011/029643, filed Mar. 23, 2011, which designates the U.S., published in English, and claims the benefit of U.S. Provisional Application No. 61,371,493, filed Aug. 6, 2010, U.S. Provisional Application No. 61/371,509 filed Aug. 6, 2010, U.S. Provisional Application No. 61/401,049, filed Aug. 6, 2010, U.S. Provisional Application No. 61/401,050, filed Aug. 6, 2010, U.S. Provisional Application No. 61/371,536, filed Aug. 6, 2010, U.S. Provisional Application No. 61/371,545, filed Aug. 6, 2010, U.S. Provisional Application No. 61/371,548, filed Aug. 6, 2010, U.S. Provisional Application No. 61/371,497, filed Aug. 6, 2010, and U.S. Provisional Application No. 61/371,506, filed Aug. 6, 2010. The entire teachings of the above applications are incorporated herein by reference.
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