Embodiments herein relate to pre-manufactured wall panels and methods for erecting a building using said wall panels in a perimeter and joining floors therebetween.
Various attempts have been made to reduce construction costs for buildings using modular components. Although various forms of modular panels are known, known modular panels still employ relatively conventional building methodologies. Namely a building is erected one floor or story at a time by forming a first perimeter wall with the modular panels, supporting a floor thereon and then forming a next story of modular panels on the floor. This manner of construction is relatively inefficient.
U.S. Pat. No. 4,514,950 to Goodson Jr. and U.S. Pat. No. 7,665,251 to Lang et al disclose examples of multi-story construction using steel studs erected onsite and which span multiple stories, however, the erection method still requires complex placement of many individual components which is time consuming and inefficient.
U.S. Pat. No. 5,048,257 to Luedtke and U.S. Pat. No. 7,562,500 to Siu disclose examples of concrete incorporated into steel framed structures for increasing the strength thereof, however such systems also require placement of many individual components in stories so as to be somewhat inefficient.
Generally, a method is provided for erecting a multi-story building on a foundation. A plurality of perimeter wall panels can be prepared using spaced-apart vertical studs and exterior sheathing material spanning an outer side of the studs. The wall panels are erected about a perimeter on the foundation such that at least some of the perimeter wall panels comprise multi-story panels which span two or more stories of the building. Opposing multi-story panels are joined together using a plurality of floor joists joined at an intermediate location between opposing top and bottom ends thereof. On another aspect the spaces between the studs of at least the lower portion of said multi-story panels, such as those below grade, or the entirely of the height of wall panel, can be filled with concrete. In another aspect hollow channels, formed between the joists, are also filled with concrete while forming an upper floor surface of concrete spanning over the joists. Concrete and appropriate reinforcing members can extend continuously between the floor and the wall panels.
By forming multi-story panels including studs which span multi-stories within the panels, several stories of a building can be erected quickly and efficiently with a single row of panels about the perimeter of the foundation. Floor joists can then be joined to the studs spanning the multiple stories of the panels at an intermediate location thereon with the loads from each floor thereabove being transferred directly through the studs instead of being stacked on the floors between the stories of the building as in conventional construction.
When a portion of the wall panels extends below grade, that portion can be filled with concrete for added strength and the balance can be fit with conventional insulation including fiberglass batting. Likewise, the entire multi-story panel can be filled with concrete to allow greater strength for building more stories, again with the simple construction of multi-story panels which can be quickly erected.
A floor system is also readily adaptable to the perimeter wall panels in which floor panels are formed with sheathing on the bottom side so that at least an upper recess of the hollow channels between the joists can be filled with concrete together with an upper floor surface spanning over top of the joists to strengthen the joists and the floor structure as a whole, which permits a much longer span than conventional construction techniques.
Accordingly, in one broad aspect a multi-story wall panel is provided for arranging about a perimeter with a plurality of additional multi-story wall panels for erecting a multi-story building. Each wall panel comprises a plurality of spaced apart studs extending vertically to span two or more stories of the building. Exterior sheathing material spanning at least an exterior side of the studs and at least one floor location at an intermediate location between top and bottom ends thereof for receiving floor joists of at least one floor of the multi-story building.
Further, a system and a method is provided for erecting a multi-story building on a foundation comprising forming a plurality of the multi-story wall panels. The wall panels are erected on the foundation to form a perimeter of wall panels, at least some of the perimeter wall panels being multi-story wall panels extending vertically to span two or more stories of the building. A plurality of floor joists are joined to the multi-story wall panels to extend generally horizontally therefrom, the floor joists being joined to the multi-story wall panels at an intermediate location between top and bottom ends thereof. Concrete can be applied between the studs, either at lower portion below grade, or along the height of the wall panels. Concrete can be applied between and over the floor joints to form concrete flooring. Concrete applications can include spacer or furring on the exterior, the interior or both sides of the studs to enable concrete encasing of the studs. The exterior sheathing material can be supplemented with base layers of finishing and further supplemented with a finishing layer.
With reference to the accompanying figures, a building system and method is provided for erecting a multi-story building 10 using multi-story wall panels 12 supported on a suitable foundation 14. The foundation 14 can be conventional including footings. The foundation 14 can be located either at or below grade, or combination thereof.
With reference to
A plurality of wall panels 12 are erected in a vertical orientation about an exterior perimeter 16 on the foundation 14. In an embodiment, each of the modular panels is a multi-story panel 12 which, when placed on the foundation 14, extends vertically two or more stories S in elevation, separated by one or more floors F. Thus, in an embodiment, a plurality of vertically-extending modular wall panels 12,12, . . . are arranged side-by-side about the perimeter 16 in a generally horizontal direction and extend about the height of the building 10. A horizontal dimension or width of the wall panels is typically dictated by local transport dimensional restrictions. For transport on most highways in North America, the maximum transport width, without the need for special permits or pilot vehicles, is generally 2.6 m or 8′-6″. Other widths can be shipped as required. The wall panels 12 may also be assembled onsite if the width of the wall panels 12 exceeds the maximum transport width. After assembly the assembled panels 12 are erected.
The wall panels 12 are thus manufactured to span at least two stories S, at least one intermediate floor F forming a ceiling for a first story and a supporting floor for a second story S. The wall panels 12 typically span the full height of the building 10 including levels below grade.
In embodiments, each wall panel 12 is formed of a plurality of vertical studs 18, spaced laterally, and which span the full height of the panels 12 such that each stud 18 spans multi-stories with the exception of studs having cut-outs for window and door openings. Additional framing is provided about window and door openings in the conventional manner (not shown). Where no windows or door openings are present, the studs 18 span the full height between a header 20 spanning a top end 21 of the wall panel 12 and a footer 22 spanning a bottom end 23 of the panel 12. The studs 18 can therefore accommodate attachment and support of at least one floor F at an intermediate location between top and bottom ends 21,23 thereof. Each floor F comprises a plurality of floor joists 24, the studs 18 receiving the floor joists 24 of at least one floor F of the multi-story building 10.
In one embodiment, each of the studs 18, the header 20 and the footer 22 of each wall panel 12 comprise a metal channel typically C-shaped in cross-section having two side flanges and a main flange connected therebetween.
In one embodiment, the studs 18 and the floor joists 24 may be made of wood.
The studs 18 are joined together to form preassembled wall panels 12 using a layer of an exterior sheet or sheathing material 26 which fully spans an exterior side 18e of the studs 18 for forming an exterior side of the wall panel 12. The exterior sheathing material 26 may be various wood materials such as oriented strand board (OSB) or plywood, as well as any other suitable construction board such as cement board and the like. The exterior sheathing material 26 may be joined directly to the studs 18.
Prior to erecting the wall panels on the foundation, the wall panels can be finished on the exterior side by various means. In the illustrated embodiment, the exterior side is finished using at least a base layer of finishing material known in the art as an Exterior Insulation Finishing System (EIFS). The finishing material may further include an exterior finish such as an acrylic stucco finish. The finishing is resistant to damage during handling between manufacture, transport and erection on site.
Alternate or additional finishing includes using siding over the exterior sheathing material or using a base layer of EIFS having a stone or brick veneer exterior finish.
Best shown in
A base layer 29 of finishing materials such as a base layer of the EIFS can then be applied to the exterior of the rigid insulation in a conventional manner using a supportive mesh material or other suitable method to minimize steps required to complete construction subsequent to erecting the wall panels. A final finishing layer 30 is then applied to the base layer 29 such as a finished stucco layer which forms the finished exterior appearance of the completed building. The finishing layer 30 can be applied prior to, or after, erecting the wall panels 12.
As shown in
Pre-manufacturing, which can further include the base layer 29 or finishing layer 30 results in a superior finish, reduced time and expense. Further, such pre-manufacture minimizes or eliminates the need for scaffolding on site during erection of the wall panels 12. Further the perimeter walls of the multi-story building are quickly assembled to enclose the building interior. Further, wall panels for a particular multi-story building can be varied in dimensions and exterior finishing, being adapted or designed for the particular building's structural aspects and aesthetics. As shown in
After erecting the wall panels 12, opposing panels 12,12 are joined with one another with one or more floors F of the multi-story building 10. The floors F are formed and supported from the wall panels 12,12 using a plurality of floor joists 40,40 . . . or the floors F may comprise preassembled floor panels comprising the floor joists 40. The joists 40 are joined to the studs 18 at joist end portions 41 using fasteners, such as screw or bolts.
In
With reference also to
With reference to
The floor joists 40 can be manufactured of metal channels which are hollow and may have a C-shaped cross section for example. In this instance, each floor joist top side 44 includes a top flange, and each underside 43 includes a bottom flange and a side web 45 therebetween so as to be open along the opposing side thereof. Opposing ends 41,41 of the joists 40 are joined directly to the studs 18 at an intermediate location along the length thereof by laying the side web of the channel flat against the base flange of the corresponding stud and joining the two flanges with suitable fasteners. Alternatively, the flanges of the vertical studs 18 can be notched out to receive a joist therein. Standard wooden beams as joists 40 can implement the ledger 52, hangers or other standard means for connection to the vertical studs. If the floors comprise pre-assembled panels, end portions 41 of the joists 40 protrude beyond the floor sheathing 42b to define a fastening portion at the end portion 41 which overlaps the studs 18 for joining thereto and mounting the floors in place.
Having reference to
Returning to
The depth of the barrier members 48 can be sized such that their upper surface 54 is recessed downwardly and spaced below the top side 44 of the joists 40 so to define the upper space or upper recess 46 therebetween. In the case of C-shaped metal joists, the upper recess 46 is in open communication with an open side 56 of at least one of the adjacent joists 40 as well as being open above the joists 40 prior to pouring concrete 50 therein. For preassembled floor panels, the barrier member 48 may be already installed in the preassembled floor F or may be subsequently installed after the floor joists 40 are already connected to the studs 18.
Once the floor joists 40 are in place, the concrete is then poured over the joists such that the concrete flows into the upper recess 36 of each joist 40 to form a continuous concrete floor surface layer spanning across and overtop of the joists. At least the upper recesses are filled with concrete to encase at least the top of the joists. A typical thickness of concrete surface is 2 inches over the top of the joists. In this embodiment, the upper recesses expose the top of the joists to be at least partially embedded in the concrete. Again, for embodiments using metal joists, having a C-shape, the concrete further encroaches into the interior of the joist.
Appropriate reinforcing material 60 such as rebar, mesh, wire screening or other strengthening members may span overtop of the joists to connect the concrete in each of the spaces between joists as a continuous concrete floor integral with the joists. In this manner, the floor is much stronger than conventional wooden joist construction to accommodate longer spans.
As stated earlier, the wall panels 12 can also be partially or completely filled with concrete 50. In an embodiment, only that lower portion below grade, if any is filled with concrete.
As shown in
A layer of interior sheathing 53 of suitable sheet material across the interior side 18i of the studs 18 substantially encloses spaces between the studs 18,18 for forming a suitable cavity to receive the concrete. The layer of interior sheathing 53 may be applied prior to erecting the wall panels, however, it is preferred that the wall panels 12 remain open between the studs 18,18 on the interior side 18i thereof until subsequent to the walls being erected and the floor joists 40 being joined thereto. In some instances only a lower portion of the wall panel and space between the studs of the wall panel is filled with concrete when the lower portion corresponds to the portion of the panel extending below grade. In this instance, the spaces between the studs are typically filled together with pouring of a basement floor 54.
Alternatively, the entire height of the wall panels 12 can be filled with concrete to strengthen the wall sufficiently such that a greater number stories can be formed in the building. In this instance, the cavities between the studs of each wall panel 12 can be filled with concrete 50 together at the same time as pouring the concrete between and over the floor joists 40 and forming the upper floor surfaces of each floor F.
As shown in
With reference to
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As stated, the exterior sheathing materials 26 may be joined directly to the studs 18. Alternatively, the exterior sheathing material 26 may be joined to the studs 18 through a plurality of intermediate furring or elongate support members 72,72 . . . spanning perpendicularly across a plurality of the studs 18. Each support member 72 is arranged perpendicular to the studs 18,18 and span therebetween, each support member 72 being spaced vertically from each other support member. The support members 72 may comprise a suitable strapping or furring member, such as a 4″ wide elongate metal channel member, the channel being from about ⅞″ to about 2″ deep.
Therefore, when the exterior sheathing material 26 is applied to an outer side of the support members 72, a substantially continuous gap 74 is formed along the inner side of the exterior sheathing layer, between the sheathing layer 26 and the studs 18. As shown in
In one embodiment, with reference to
With reference to
In an optional embodiment, a batten or trim member 80 (dotted lines) can be provided to span and cover the vertical seam 32. The trim member 80 spans vertically along the exterior of the vertical seam 32. Alternatively, the recessed corners may receive a mating cap which follows the profile of the recessed groove including side flanges overlapping the exterior of the two adjacent panels relative to which they are sealed to function as an expansion joist between the adjacent panels. In yet further arrangements, no recessed corner may be provided on the panels so that a suitable mesh or tape strip overlaps the exterior side of the two adjacent panels across the vertical seam for being coated with the finishing layer together with the exterior sides of the panels after they are erected.
In further embodiments, the studs 18 may comprise wood studs. In this instance, the studs similarly span the full height of the multi-story wall panel between the header 20 and footer 22 as described above. In this instance, a layer of the exterior sheathing material 26 is similarly applied to the outer side of the studs 18 to form the panel 12 prior to erecting on the foundation 14. As in the previous embodiment, each perimeter wall panel 12 thus spans at least two stories S,S and can span the full height of all of the stories of the building 10 between the foundation 14 and a roof at the respective mounting location thereof. Floor joists 40 are attached to the wooden studs by respective ledgers 52 joined across or between respective wooden studs of the wall panels using typical joist hangers.
In further embodiments, the finishing layer 30 may comprise other finishing materials such as siding or various forms of building veneer. In this instance, a base layer 29 comprising a suitable material is again bonded to the exterior side of the insulation layer 28 to span across the panel 12 and is wrapped about the ends 29 of the panels prior to erecting the panels 12 with their ends 29 in abutment with one another. The vertical seams 32 can then be taped or sealed with caulking as described above prior to applying the finishing material 29,30 across the vertical seams.
In some applications, no concrete fill is required in the walls, even at the lower portion below grade. In this instance an inner side of the studs is typically lined with a suitable vapour barrier member prior to sheathing the inner side with drywall or another suitable interior finishing panel.
As the adjacent wall panels 12,12, and wall panels 12 to floor joists 18, are interconnected to each other using fasteners such as screws or bolts, the building structure can be easily mounted and dismounted, particularly before concrete is poured. Should the wall panels 12 be filled with concrete, the weight is significantly greater. Should both floors and wall panels be filled with concrete, some demolition is required at the concrete and reinforcing members extending therebetween. This renders the building structure reusable and the structure need not be discarded after a single use. The wall panels 12 and the floor joists may also be made of recyclable and environment friendly materials. The proposed building structure is rigid, economical, very easy to mount and dismount, stackable, reusable and recyclable, while allowing one to reduce costs associated with transportation and assembly of the structure.
Accordingly, a method of erecting a multi-story building 10 on a foundation 14 comprises forming a plurality of wall panels 12, each wall 12 panel comprising spaced apart vertical studs 18 and exterior sheathing material 26 spanning at least an exterior side 18e of the studs 18; erecting the wall panels 12 on the foundation 14 to form a perimeter of wall panels 12,12 . . . , at least some of the perimeter wall panels 12 being multi-story wall panels extending vertically to span two or more stories S,S of the building 10; joining adjacent wall panels 12,12; and joining a plurality of floor joists 40,40 . . . to the multi-story wall panels 12 to extend generally horizontally therefrom, the floor joists 40 being joined to the multi-story wall panels at an intermediate location between top and bottom ends 21,23 thereof. Adjacent wall panels can be secured to one another using fasteners.
Since various modifications can be made in my invention as herein above described, and many apparently widely different embodiments of same made within the scope of the claims without department from such scope, it is intended that all matter contained in the accompanying specification shall be interpreted as illustrative only and not in a limiting sense.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/CA2012/050215 | 4/4/2012 | WO | 00 | 9/6/2013 |
Publishing Document | Publishing Date | Country | Kind |
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WO2012/135954 | 10/11/2012 | WO | A |
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3107755 | Thibert | Oct 1963 | A |
5524400 | Schmechel | Jun 1996 | A |
7712270 | Guevremont | May 2010 | B2 |
8186128 | Way | May 2012 | B2 |
20100058700 | LeBlang | Mar 2010 | A1 |
20110225905 | Kusuma | Sep 2011 | A1 |
Number | Date | Country | |
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20140013684 A1 | Jan 2014 | US |
Number | Date | Country | |
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61471767 | Apr 2011 | US |