This invention relates to the field of prefabricated concrete building construction.
Current building methods are labor intensive, requiring on-site management of different kinds of contractors as well as facilitation of necessary building supplies. Project managers must coordinate with dozens of different skilled and unskilled tradesmen, while at the same time ensuring the proper building materials are available at any given jobsite at the correct time. Oftentimes certain contractors cannot meet the scheduled time slot and/or building supplies are either not delivered or are delivered in the incorrect form. As a result, on-site construction often suffers schedule delays plagued by cost overruns.
Even if everything goes according to plan, current on-site building methods are labor intensive. For example, in a typical residential build, first the foundation is laid by the foundation contractors. Then the framing and roofing contractors control the jobsite for several weeks. After that, different contractors build the exterior shell of the building. Then come the electricians, plumbers, and HVAC contractors. The insulator and sheet rock contractors follow. Then the electricians, plumbers, and HVAC contractors return to the job site to finish out their work. The work done by each trade must be inspected by inspectors on-site, leading to hold points and additional delays.
For at least these reasons, some on-site builders have turned to prefabricated construction techniques for portions of a building. For example, prefabricated deck trusses are often used in residential construction. Certain prefabricated building systems generally involve constructing portions of a building at a factory and shipping the fabricated piece to the jobsite.
A consistent problem with prefabricated building systems is weight. On the one hand, prefabricated pieces, in order to maintain structural integrity and load bearing capabilities, take on unnecessary shipping weight. On the other hand, to reduce weight for shipping, many prefabricated construction elements lack load bearing capabilities. Another problem with prefabricated building systems is shipping volume, where the maximum dimensions of a given room may be dictated by existing truck size. A need exists for a prefabricated system that incorporates both high structural integrity and lower shipping and assembly costs, as well as provides spacious room and building dimensions.
There is provided a reinforced concrete building system that includes foundations, walls, decks, and roof assemblies designed to be built out in a manufacturing facility and shipped to a job site for final assembly. Panel assemblies are completed as fully as possible in the largest dimensions possible within the controlled environment of a manufacturing facility prior to transfer to a construction site. According to one aspect of the present design, wall assemblies are manufactured to contain architectural interior/external finishes, windows/doors, and pre-installed utility distribution systems. Panel assemblies are then assembled onsite into structures such as private residential homes, commercial spaces such as office buildings and strip malls, or even stand-alone walls for noise abatement or security. In addition, the system and methods described herein are suitable for secure military base structures. Panel assemblies can also be used as skirt walls for high-rise buildings.
According to one aspect of the present design, there is provided a building panel system of steel reinforced cement fiberboard panels configured to accept liquid concrete on a jobsite. Interior and/or exterior rebar mats join to a structural column system to provide reinforcement to the concrete. Spacers and straps connect to the rebar mats to create a structurally rigid space frame. Skin panels then connect to the space frame to create the panel assembly. The structural column system and space frame maintain integrity and alignment for transportation and assembly purposes. After being placed, the panel assemblies can be filled with concrete to provide structural integrity to the building.
In one embodiment, there is provided a modular panel assembly comprising a first and second rebar mat having a top edge, a bottom edge, and a pair of side edges, a first skin panel connected to the first rebar mat and a second skin panel connected to the second rebar mat, a plurality of structural columns, wherein the first and second rebar mats are connected to the structural columns, and the structural columns are disposed within the rebar mats at defined intervals, and wherein the rebar mats and skin panels are configured to define a center region for accepting concrete, and a plurality of spacers connected to the skin panels at defined intervals, wherein the spacers are configured to provide resistance against skin panel deformation. The panel assembly can also comprise straps disposed between the spacers and skin panels. The first and second skin panels can comprise cement fiber board. In one embodiment, the panel assembly further comprises a foldout rebar frame. In another embodiment, the panel assembly further comprises a hinge connected to at least one skin panel, wherein a portion of the at least one skin panel protracts to form the shell of a spread footer foundation.
In one embodiment, the panel assembly comprises a mount for moving the panel assembly by crane. This mount can take many forms and can be connected to the structural column or the space frame. For example, in one embodiment the mount slides into the structural column like a stabbing splice, where it is bolted in from the outside or from the inside near the top of the mount. In an alternate embodiment, the mount attaches to the space frame by, for example, looping hooks under the rebar strings. In another embodiment, the panel assembly comprises attachment points for the same purpose. The panel assembly can also comprise a plurality of spacer bolts attached to the spacers and configured to provide resistance against skin panel deformation. In another embodiment, the panel assembly further comprises conduit for utilities.
In yet another embodiment, a portable panel assembly comprises a plurality of structural columns spaced apart at intervals, a first space frame connected to the plurality of structural columns comprising, a first rebar mat connected to one side of the plurality of structural columns, a plurality of spacers connected to the first rebar mat, and straps connected to the spacers, the portable panel assembly also comprising a first skin panel connected to the external side of the first space frame. In still another embodiment, the portable panel assembly further comprises a second space frame connected to the plurality of structural columns comprising a second rebar mat connected to one side of the plurality of structural columns, a plurality of spacers connected to the second rebar mat, and straps connected to the spacers, and the assembly also comprises a second skin panel connected to the external side of the first space frame, and a center region disposed between the first and second skin panel for accepting concrete therein.
There is also disclosed a method of preparing a concrete wall for a building comprising connecting a first rebar mat to one side of a plurality of structural columns, connecting a second rebar mat to the opposite side of the plurality of structural columns, attaching spacers to the side of the first and second rebar mats distal to the plurality of structural columns, attaching straps to the side of the spacers distal to the plurality of the structural columns, attaching a skin panel to each side of the straps distal to the plurality of the structural columns so as to create a center region between the skin panels, and pouring concrete into the center region.
The subsequent description and the figures illustrate specific embodiments to enable one skilled in the art to practice the system and method herein described. Other embodiments may incorporate additional elements, whether structural, logical, process or so forth. Examples are provided merely as possible variations. Individual components and functions are generally optional unless explicitly required, and the sequence of operations may vary. Portions and features of some embodiments may be included in or substituted for those of others.
In general, the design contained herein includes a system and method for prefabrication of quality modularized building components for economical transport and onsite construction. Panel assemblies capable of being filled with concrete are manufactured in an offsite facility and shipped to a jobsite where they are connected to each other and concrete is poured therein. Panel assemblies can take the form of multiple components of a given building under the present disclosure, including assemblies configured for walls, floors, decks, foundation, and roofs. As described herein, the term “panel assembly” refers generically to wall assemblies, foundation assemblies, floor form assemblies, deck assemblies, interior wall assemblies, and roof assemblies.
Panel assemblies are fashioned to be lightweight yet still strong enough to maintain rigidity during transportation, installation, and during pouring and setting of concrete within the center region. According to one embodiment, structural columns connect with space frames formed with rebar mats, spaces, and straps to form the structural skeleton of a panel assembly for transportation and installation. Panel skins are connected to the space frames, which are attached to the structural columns. This forms a central region capable of holding and forming concrete. Because concrete can be poured on-site, the transportation weight of building supplies is significantly reduced. In addition, the building process is dramatically simplified.
Structural columns 114 serve in a structural capacity during transportation and lifting of wall assembly 100, and provide dimensional control during assembly. They can also assist in combating hydrostatic loads of liquid concrete during pour and setting. According to the preferred embodiment, structural column 114 comprises a steel member of length matching the height of wall assembly 114, having the dimensions of 3″×3″ at 1/16 gauge thickness. Bolt hole patterns are prefabricated at certain intervals, such as every four inches on each face of structural column 114. These dimensions and bolt hole pattern allow for structurally sound connections between structural columns 114 without adding too much weight, using stabbing splices to be described later in the present disclosure. Structural column 114 can, of course, have other dimensions and be formed from other types of metal, such as aluminum. In addition, structural column 114 can comprise plastics or composite material. It can also be fashioned out of formed rebar.
Rebar mats 112 and 116 and the attached straps 140 provide additional rigidity to wall assembly 100 during transportation, construction of building shell, and pouring of concrete. The rebar within the mats also serves as reinforcement of the concrete and to strengthen and hold the concrete in compression or tension. According to one embodiment, the rebar is ⅜ inch gauge. The rebar may be fashioned in other gauges, such as ¼ inch, ½ inch, ¾ inch, ⅝ inch, ⅔ inch, ⅞ inch or 1 inch. Other diameters can be employed.
Rebar mat 112, in the preferred embodiment, comprises two strings 122 of rebar at 2 feet intervals repeating in the x and y plane of wall assembly 100. Where the two sets of strings 122 cross, spacers 120 can be welded or clipped.
According to the embodiment in
Straps 140, according to one embodiment are ⅛ inch steel, having a width greater than the width of the top of spacer 120. It is understood that straps 140 can have various widths (for example,
Rebar mat 112 is attached to structural columns 114. In the preferred embodiment, this is accomplished with spacer bolts 142, as shown in
Spacer bolts 142 can serve multiple purposes. For example,
Skin panels can attach to spacer bolts in several ways. In one embodiment, spacer bolts 142 thread through a threaded fitting attached to, or embedded in, skin panels 110 and 118. See
Wall assembly 100 is prefabricated in a manufacturing facility along with corresponding foundation assemblies, deck assemblies, and roof assemblies according to dimension specifications of the end building owner. Panel assemblies can be fashioned in multiple heights, lengths, and widths. For example, a prospective building owner may select wall assemblies 100 of 10′ height and 48′ length. Panel lengths (X axis) may be provided at 4′, 8′, 12′, 16′, 24′, 32′, 48′ and up to a maximum shipping length. Panel heights (Y axis) are contemplated at 1′, 2′, 4′, 8′, 10′, 12′, and up to a maximum shipping height. Panel widths can also be adjusted by changing the width of structural column 114 and by adjusting the Z-direction length of spacers 120. This provides for thicker walls, decks, and foundations for concrete pours.
Wall assemblies 100 are assembled at the manufacturing facility. Rebar mats 112 and 116 are attached to structural columns 114. According to one embodiment, Spacers 120 are put in place along rebar mats 112 and 116. Straps 140 are put in place, and then skin panels 110 and 118 are attached to straps 140 and spacers 120. For exterior walls, it may be advantageous to avoid holes in skin panel 118 exposed to the outdoor elements. In that case, skin panel 118 is attached to rebar mat 116 using spacers 120 before being attached to structural columns 114. Then rebar mat 112 and skin panel 110 is put in place to complete the wall.
The end result is wall assembly 100 in a structural configuration for transport and lifting. Structural columns 114 provide structural support during transport and they provide attachment points for a mount to lift the assembly into place by a small crane. In addition, structural columns 114 provide temporary positioning and attachment points for securing wall assemblies 100 during transport and during on-site construction. Rebar mats 112 and 116 give additional support during transport and lifting. Wall assemblies 100 can be lifted from the transport truck and positioned into place on site via a small crane. After being attached to other panel assemblies in the building and leveled as needed, construction crews pour concrete into center region 130. Rebar mats 112 and 116 are encapsulated in concrete and provide reinforcement for the concrete wall.
Skin panels 110 and 118 are designed to remain in place after the concrete pour. In one embodiment, skin panels 110 and 118 are cement fiberboard. Cement fiberboard can be finished according to present day design such that no further work is required on the interior or exterior of a building. This includes a smooth finish, wood-simulated finish, masonry finish, and concrete block finish. In addition, skin panels can be fashioned from other components. For example, exterior skin panel 118 can be made from wood, plastic, fiberglass or metal. Interior skin panel 110 can also take these forms and be fashioned from wood, plastic, or metal. For exterior skin panels 118, the cement fiber board is operable to accept additional finishes such as brick, stucco, wood, siding, and other exterior finishes known in the art of building construction.
Structural columns 114, according to one embodiment, are located within space frame 124 every 8 feet but can be placed at alternate intervals depending on the anticipated transportation and concrete stresses.
Structural columns 114 provide attachment points for wall assembly 100. For example, where panel assemblies attach to each other, brackets can bolt structural columns 114 together. In one embodiment shown in
Wall assemblies 100 can attach to each other in several ways, such as the embodiments shown in
Where wall assemblies 100 meet, there is provided corner rebar strings 406. Corner rebar string 406 is a string of rebar bent at 90 degrees. It is shipped within one of the wall assemblies and is rotated in plane with the assembly. Then, when the two wall assemblies are mated, corner rebar string 406 is rotated 90 degrees out of plane into the interior of the mating wall assembly, as seen in
Wall assemblies 100 can include doors and windows. Window forms are installed at the factory according to the specifications of the building owner. In one embodiment, shown in
As summarized, wall assembly 100 as disclosed herein is fabricated in a manufacturing facility according to the specifications requested by a building owner and shipped to an on-site location where it is attached to other panel assemblies. Concrete is then added to the center region 130 and allowed to set. Wall assemblies can be set in place quickly with a light-duty crane. Concrete is poured directly into the center region 130 through the top of the wall from a concrete truck. Thus, on-site labor costs are drastically reduced. Moreover, the reinforced concrete construction is much stronger than conventional wooden construction.
Additional panel assemblies are disclosed herein. According to one embodiment, there is disclosed a foundation assembly. Conventional foundation forming is a labor intensive and time consuming process. For example, in standard residential construction, contractors must build a wooden frame onsite that is both level and can withstand the hydraulic load of wet concrete. Then the contractors must lay out reinforcing bars and individually strap them together, raising additional potential for human error. After the concrete is poured and set, the wooden forms are removed and the remaining ground space is backfilled with soil. Apart from the number of workers on the jobsite, this process can take 6-8 days to complete. Using the system and method disclosed herein, the process is cut to less than 1-2 days, and the number of workers required is dramatically reduced.
The wall foundation assembly 200 portion has a cutout of space frame 124 of a certain dimension, such as 16 inches as shown in the figures. In one embodiment, the interior rebar mat 112, interior spacers 120, interior straps 140, and interior skin panel 110 are not present, so that foldout rebar frame 204 can be swiveled into place after positioning of wall foundation assembly 200. In an alternate embodiment, the interior portion of space frame 124 remains in place in the lower portion of wall foundation assembly 200, and foldout rebar frame is attached on the interior side of space frame 124, where interior skin panel 110 would normally exist.
Wall foundation assembly 200 includes a leveling apparatus 208. In one embodiment, the leveling apparatus is placed within the interior of structural column 114. Reach rods from the top of the column engage the leveling devise for raising/lowering the wall/foundation. In another embodiment, standard manual torque gears are accessed through one of the bolt holes of structural column 114. In the alternative, leveling apparatus 208 can take the form of traditional jack systems known in the art.
For load bearing walls in the center portion of a building, wall foundation assembly 200 can be outfitted with dual foldout rebar frames 204 as shown in
In colder climates, the bottom of the foundation must be placed below the frost line to prevent frost heave, where the pressure created by water freezing forces the foundation upwards. In one embodiment, spread footer wall foundation assembly 220 has a spread footer design shown in
Spread footer wall foundation assembly 220 can occupy the lower portion of wall assembly 100 or can be a separate attachment that is attached to the bottom of wall assembly 100 onsite via a stabbing splice 144 described earlier. The bell shape of the spread footer design allows more rigid control of foundation concrete and is optimal for below frost environments. More importantly, it enables dirt to be backfilled prior to concrete pouring/curing.
In one embodiment, multiple fold out rebar frames 226 (not shown) can be located on each side of spread footer wall foundation assembly 220 so that additional rebar is distributed through the bell shape lower foundation housing form demonstrated in
Floor form assemblies 260 are attached to wall foundation assemblies 200 by use of deck mount 206. Deck mount 206, according to one embodiment, is a triangular truss piece that clips or bolts on to structural column 114 or interior rebar mat 112 of wall foundation assembly 200. Floor form assembly 260 then rests on or clips to deck mount 206. The center portions of floor form assemblies 260 rest on the sub-foundation soil and therefore do not need to be suspended. Floor form assemblies 260 can be leveled as discussed above. In an alternate embodiment, floor form assemblies 260 can contain exterior skin panels 118 and/or exterior spacers 120 and straps 140.
Floor form assemblies 260 can be attached together with quick connectors that provide accurate dimensional control. Connectors are contained within one of the floor panels and can be extended to the next panel, for quick assembly. In the alternative, connectors can be contained in all floor panels and extended to mate with each other. Systems include tongue and groove clips, bolt systems, and other mating systems known in the art. In addition, floor form assemblies 260 can include prefabricated receptacles for accepting external coupling members. These can be specially formed brackets that bolt or clip into the receptacles and may contain floor finishes to match the external skin panel floor.
In some cases, a building owner may wish to improve the thermal insulation properties of the building. One embodiment, shown in
For multiple story structures, decks may be used with the present design. Unlike the floor forms, decks are suspended and become both floors and ceilings. Deck assemblies 280, shown in
According to one embodiment, lower rebar mat 116 is formed of heavier gauge rebar, which provides additional reinforcement for the lower portion of deck assembly 280 Likewise, lower skin panel 118 is thicker and stronger than upper skin panel 110, according to this embodiment. This provides additional strength during pouring and setting of the concrete. For large spans, it is contemplated that temporary supports are provided during pouring and until the concrete sets. The supports rest under the lower skin panel 118.
In one embodiment, lower skin panel 118 is geometrically formed to handle additional loads, such as through corrugation Like in wall assemblies 100, lower skin panels 118 are attached to space frame 124 by spacer bolts 142. Lower skin panel 118 forms the ceiling of a given room. In one embodiment, spacer bolts are threaded into lower skin panel without punching through the skin panel, so that the ceiling portion of the structure does not need to be patched. Upper skin panel 110 forms the floor of a given room. Bolt holes are patched and the finished floor is installed over upper skin panel. In one embodiment, bolts are installed from the lower skin panel 118 side, so that upper skin panel 110 can be a finished floor with no patches.
Depending on the structural requirements, deck assemblies can be filled in part with foam.
Deck assemblies are attached to wall assemblies 100 in several ways. In one embodiment, deck assembly support mount 282 is bolted into selected structural columns 114 of wall assemblies 100, as seen in
In one embodiment, deck assembly support mount 282 is attached to space frame 124 of wall assembly 100. As shown in
Deck assemblies 280 can be placed on the outside of interior skin panel 110. In the alternative, interior skin panel 110 of wall assembly 100 can be removed prior to placement of deck assembly, as shown in
Like floor form assemblies 260, multiple deck assemblies 280 can be put into place within a structure. Deck assemblies 280 can be attached together in the same fashion as floor form assemblies 280 (see above). In addition, receptacles can be placed on the underside of deck assemblies 280.
The versatility of the method and system as disclosed herein provides additional capability for interior walls. For example, buildings can be formed with concrete interior walls for sound proofing and thermal control. In the alternative, non-load bearing interior wall assemblies 290 can be filled with foam rather than concrete. In this embodiment, foam can be added either at the manufacturing facility or onsite. According to one embodiment, wall assemblies presented for interior use can be reduced in structure. For example, structural columns 114 can be substituted with wood or plastic. In the alternative, low gauge conduit can be used in place of structural columns 114. For interior wall assemblies 290 that need not bear the load of liquid concrete, structural columns 114 can be removed altogether, as seen in
In one embodiment, interior wall assemblies 290 can be attached to floor forms assembly 260 through stabbing floor mounts 296 that stab into structural columns 114 or the substitute for the columns. In one embodiment, upper clip floor mounts 292, bolted to the floor form assembly, have upper clips that clip automatically into the lower portion of rebar mats 112 and 116 of interior wall assembly 100 when the wall assemblies are put in place. See
In one embodiment, interior wall assemblies 290 are mounted by sliding the assembly 100 over slide clips that are premounted to floor form assembly 260. In this embodiment, interior wall assemblies 290 can be bolted to the non-load bearing wall or partially filled with concrete to reinforce the connection between interior wall assembly 290 and sliding clip floor mount 294. In the alternative, self-tapping screws can be drilled between straps 140 of interior wall assemblies 290 and straps 140 of floor form assemblies 260 or deck assemblies 280 according to conventional building methods known in the art.
In conventional residential construction, the roof support is usually formed by wood roof trusses that provide strong support in a basic triangle shape. The trusses are then decked with plywood or wood planks, and then covered with an architectural roof covering to shed water and moisture. This requires framing contractors to complete the truss construction and installation. Roofing contractors come behind to install the roofing material. According to the present disclosure, prefabricated roof assemblies are shipped to the jobsite already configured for installation, with architectural roof coverings already in place. Moreover, these roof assemblies can be manufactured according to the same or similar design as the other assemblies disclosed herein.
Structural columns 114 of roof assemblies 300 are connected to structural columns of wall assemblies 100 through roof mounts 302, 304, and/or 306. The lower portion of these roof mounts are stabbing splices, such as stabbing splice 144 described above. Mid-roof aligned roof mount 302 is used where the bolt holes of structural columns 114 of roof assembly 300 line up with structural column 114 of wall assembly 100, such as for certain pitched roofs. Mid-roof aligned roof mount 302 comprises a stabbing splice at the lower portion, an angled upper portion according to the preferred pitch of the roof, and a threaded bolt hole for receipt of a bolt from the exterior of the roof. In one embodiment, the bolt connecting mid-roof aligned roof mount 302 to roof assembly 300 does not pierce roof assembly 300. Instead, the bolt is threaded and torqued down from the underside of mount 302. In one embodiment, the bolt only threads to structural column 114 of roof assembly 300. In another embodiment, the bolt traverses roof assembly 300 all the way to exterior skin panel 118, as shown in
In some situations, wall assembly 100 will not line up with the bolt holes of structural column 114 of roof assembly 300. For these situations, mid-roof misaligned roof mount 304 can be used. Mount 304 shifts the bolt pattern to align with the bolt holes on structural columns 114. This can be predetermined, or the bolt plate of mount 304 can slide into place and be torqued down. In another embodiment (not shown), mid-roof misaligned roof mount simply attaches to rebar mat 116 by way of cinch down clips known in the industry.
In some embodiments, it is desired to connect wall assembly 100 to a portion of roof assembly 300 in between structural column 114 of roof assembly 300. Where this occurs, it is possible to connect wall assembly 100 to rebar mat 116 of roof assembly 300 using a mid-roof misaligned rebar roof mount 312 as seen in
Where two roof assemblies 300 meet at the apex of a roofline, apex roof mount 306 is used. See
With the design herein, roofs can be placed, bolted, and finished in a matter of hours. The panels are installed in complete lengths that span from the roof apex or roof peak to the exterior walls plus overhang 310, as shown in
Roof assembly panels 300 can be fabricated in the widest panel sizes consistent with shipping restraints. Roof panels are designed to be installed with several slopes, such as 12/12, 9/12, 6/12, 3/12, 2/12, or other slopes. In severe weather areas such as those with heavy snow seasons, roof assembly 300 can be fashioned with heavier gauge components such as heavier rebar strings 122, exterior skin panels 118, and/or straps 140. In addition, knee braces known in the industry can be installed that extend from the center bearing walls to intermediate support. In situations where a cathedral ceiling is desired, roof assembly 300 can contain an interior skin panel 110, as described above. Roof assemblies 300 can be filled with expandable foam for additional insulation in cathedral ceiling situations. Where applications call for increased structural integrity, such as in areas prone to hurricanes or tornados, concrete can be used within roof assembly panels 300 as an inclined beam.
Roof assembly panels 300 can accommodate several structural and architectural features, such as dormers, chimneys, exhaust vents, ridge vents, and gutters. Where exterior skin panel 118 cannot structurally bear the load of the architectural feature, it can be affixed to any component of space frame 124—such as structural column 114, exterior rebar mat 116, spacers 120, or straps 140—using clips or bolts.
According to the present disclosure, predesigned utility distribution systems can be prebuilt into the wall, deck, and roof assemblies in order to minimize onsite installation times and cost. The utility distribution systems available include electrical distribution, water distribution, sewage collection systems, low-voltage wiring distribution, and HVAC (Heating, Ventilation, and Air Conditioning) distribution.
In conventional residential construction, the utilities are completed by licensed subcontractors according to acceptable building codes and construction timelines. These are subject to inspection at certain hold points, which add delays and cost to a building's construction. The licensed subcontractors traditionally install the distribution utilities at three different time frames in the building cycle. After clearing of the building site but prior to placement of the foundation, contractors install sewer outlets, water inlets, and underground electrical conduits. Next, after completion of the wood framing and the outside sheathing, contractors run electrical wiring, low voltage wiring, internal plumbing, and HVAC lines. To do this, contractors must drill or cut holes through the existing framing and plant cut protectors on the punch through studs, making it a time consuming and expensive process. Work must be halted at each stage for local inspections to occur. Finally, after closure of outside siding and inside sheetrock, installation of exterior fixtures and outlet covers occurs.
The system and method disclosed herein reduces both the time and cost of utility installation because the majority of the process can occur in the controlled environment of the manufacturing facility. In addition, much can be completed by robotic assistance. This means that distribution utilities are completed onsite in less time by less expensive semi-skilled labor. It also eliminates subcontractor interfaces that can dramatically lengthen or disrupt the construction schedule because each phase of building need not be delayed due to individual subcontractors. Furthermore, many hold points can be eliminated because the inspections can be verified at the manufacturing facility en masse.
According to one embodiment, utility distribution conduits are preinstalled in wall assemblies 100, floor form assemblies 260, deck assemblies 280, interior wall assemblies 290, and roof assemblies 300. Certain conduits can also be run in wall foundation assemblies 200 and spread footer wall foundation assemblies 220. Conduits are mounted to the space frame 124 using clips, mounts, straps, or bolts. Where two panel assemblies are connected, conduits are provided with couplers either preinstalled, or the conduits are coupler ready. Because concrete is to be poured into most panel assemblies, connections are usually made prior to pouring. However, for time savings, because concrete pouring can be done in stages, conduit connections can be made at various levels as the concrete is soft setting.
According to one embodiment, conduits are run at various levels within the panel assemblies, and at various depths. For example, electrical conduit may be run closer towards the interior skin panel 110, while the water conduit can be run behind, closer to the plane of structural column 114. In one embodiment, utility conduits are run in the space between the plane of structural column 114 and exterior skin panel 118. For ease of connections, utility conduits can be run at the top and bottom sections of wall assemblies 100, or the comparable side sections of other panel assemblies. For bottom-run utility conduits, the conduits are connected while the wall assembly sections are suspended in place by a light-duty crane. Top-run connections do not require suspension. It is contemplated that some utilities will have secondary conduits for backup purposes.
In one embodiment, skin panel punch out plates are contemplated, where conduit connections can be made through the skin section of a panel assembly after the assemblies have been placed and connected. The punch out section is then patched accordingly after the conduit is connected. In one story buildings, top-run conduits are left exposed above the concrete line. This provides easy access to the conduit lines for maintenance purposes. For conduits submerged in concrete, junction box access panels may be used. This allows for wiring repair and updates, or water line/sewer clean out as necessary.
The designs disclosed herein can be used to fashion entire structures on-site in a fraction of the time of conventional builds and with lower installed costs. In addition, wall assemblies 100 can also be used as curtain walls for larger structures like large office buildings and skyscrapers. In one embodiment, wall assembly 100 is used as a load bearing, or non-load bearing outer cover of a building. The lightweight preassembled wall is lifted into place and tied to the supporting columns and then concrete poured to complete the skirt wall. The reinforced concrete design disclosed herein provides exceptional resistance to horizontal wind loads, while the air-tight nature of the present disclosure resists air and water infiltration. In one embodiment, reinforced concrete in wall assembly 100 provides some structural capability. Interior wall assemblies 290 can also be used in larger structures, via at least the methods described above.
As mentioned, the offsite prefabrication of the panel assemblies saves both time and construction costs. The panel assemblies are constructed at a manufacturing facility under robotic control. According to one embodiment, rebar strings 122 are laid in place horizontally. Robotic arms weld spacers 120 to rebar string 122 cross points to create a rebar mat. The rebar mat is then placed retracted 90 degrees into a vertical position where it is slid into place around spaced apart structural columns 114. Skin panels 110 and 118 having thermal insulation panels 270 and straps 140 already attached are slid into place on either side of the rebar mats 112 and 116. Robotic drills then pierce the panel assembly and insert spacer bolts 142 to complete the framing. In one embodiment, robotic cutters then remove sections of the panel assembly for insertion of window frames and door frames. In an alternate embodiment, the exterior fiber cement form is attached to the steel mat to form a complete panel, and then added to vertical columns.
As disclosed herein, preassembled panel assemblies are transported on truck, train, or barge to the jobsite, where they are lifted into place by light duty crane. Several panel assemblies can be transported on one truck, the dimensions of the panel assembly restricted only by the dimensions of the truck and local transport regulations. One truck, for example, can bring to a jobsite enough panel assemblies to build a small structure, such as a one-story home. A larger home may require only two or three trucks. In one embodiment, transportation dimensions of the apparatus of the present disclosure can be reduced still further. For example, it is contemplated that components of panel assemblies 100 can be stacked within shipping containers. In this design, preassembled rebar mats 112 are combined with spacers 120 to form a space frame segment. Because the spacers are angled in a somewhat triangular shape in one embodiment, as seen in
Although the present disclosure and its advantages have been described in detail, it should be understood that various changes, substitutions and alterations can be made herein without departing from the spirit and scope of the design as defined by the appended claims. Moreover, the scope of the present application is not intended to be limited to the particular embodiments of the process, machine, manufacture, composition of matter, means, methods and steps described in the specification. As one of ordinary skill in the art will readily appreciate from the present disclosure, processes, machines, manufacture, compositions of matter, means, methods, or steps, presently existing or later to be developed that perform substantially the same function or achieve substantially the same result as the corresponding embodiments described herein may be utilized according to the present disclosure. Accordingly, the appended claims are intended to include within their scope such processes, machines, manufacture, compositions of matter, means, methods, or steps.
The present application is a continuation of U.S. patent application Ser. No. 14/479,049, filed on Sep. 5, 2014, and entitled “Modular Building System.”
Number | Name | Date | Kind |
---|---|---|---|
2653469 | Callan | Sep 1953 | A |
3238684 | Wood | Mar 1966 | A |
3383817 | Gregorl | May 1968 | A |
3555751 | Thorgusen | Jan 1971 | A |
4125981 | MacLeod | Nov 1978 | A |
4472919 | Nourse | Sep 1984 | A |
4481743 | Jellen | Nov 1984 | A |
4611450 | Chen | Sep 1986 | A |
4864792 | Andre | Sep 1989 | A |
5233810 | Jennings | Aug 1993 | A |
5528876 | Lu | Jun 1996 | A |
5608999 | McNamara et al. | Mar 1997 | A |
5611183 | Kim | Mar 1997 | A |
5741571 | Bowerman et al. | Apr 1998 | A |
5758463 | Mancini, Jr. | Jun 1998 | A |
5809725 | Cretti | Sep 1998 | A |
5950389 | Porter | Sep 1999 | A |
6098359 | Stodulka | Aug 2000 | A |
6151857 | Raschke | Nov 2000 | A |
6519904 | Phillips | Feb 2003 | B1 |
6701683 | Messenger et al. | Mar 2004 | B2 |
7143559 | Ritter | Dec 2006 | B1 |
8353078 | Bailey, Jr. | Jan 2013 | B2 |
20030167716 | Messenger | Sep 2003 | A1 |
20030177733 | Izquierdo | Sep 2003 | A1 |
20040035073 | Bravinski | Feb 2004 | A1 |
20040065034 | Messenger | Apr 2004 | A1 |
20040065043 | Foderberg | Apr 2004 | A1 |
20050055926 | Ben-Lulu | Mar 2005 | A1 |
20050117977 | Rasumussen | Jun 2005 | A1 |
20060137289 | Cotten | Jun 2006 | A1 |
20060254068 | Shotton et al. | Nov 2006 | A1 |
20070107341 | Zhu | May 2007 | A1 |
20080271401 | Grypeos | Nov 2008 | A1 |
20090007519 | Keshishian | Jan 2009 | A1 |
20110131911 | McDonagh | Jun 2011 | A1 |
20110168794 | Lee et al. | Jul 2011 | A1 |
20110272556 | Lin | Nov 2011 | A1 |
20120073227 | Urusoglu | Mar 2012 | A1 |
20130014458 | Boydstun, IV et al. | Jan 2013 | A1 |
20130036688 | Gosain | Feb 2013 | A1 |
20130074432 | Ciuperca | Mar 2013 | A1 |
20140013683 | Yin | Jan 2014 | A1 |
Number | Date | Country |
---|---|---|
2487000 | May 2005 | CA |
102009058691 | Jun 2011 | DE |
0381000 | Aug 1990 | EP |
1333129 | Aug 2003 | EP |
1347121 | Sep 2003 | EP |
1361319 | Nov 2003 | EP |
1504160 | Feb 2005 | EP |
1655421 | May 2006 | EP |
2151330 | Feb 2010 | EP |
2369086 | Sep 2011 | EP |
2495374 | Sep 2012 | EP |
788762 | Jan 1958 | GB |
2291900 | Feb 1996 | GB |
1988003204 | May 1988 | WO |
2003091506 | Nov 2003 | WO |
2004081310 | Sep 2004 | WO |
2007040412 | Apr 2007 | WO |
WO 2009118480 | Oct 2009 | WO |
2010033001 | Mar 2010 | WO |
2012024816 | Mar 2012 | WO |
2013061344 | May 2013 | WO |
Number | Date | Country | |
---|---|---|---|
20170152659 A1 | Jun 2017 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 14479049 | Sep 2014 | US |
Child | 15419666 | US |