The present disclosure relates generally to modular support systems, including those configured to provide load-bearing support to multi-story buildings.
The present disclosure relates generally to modular support systems for multi-story buildings. In particular, modular support systems that include a plurality of load-bearing structural units are described.
Known building support systems are not entirely satisfactory for the range of applications in which they are employed. Many buildings, for example, implement a concrete column-based support structure. Constructing buildings with concrete column-based support structures is inefficient. For example, constructing a building with a concrete column-based support system may require builders to iteratively pour the concrete structural elements of each floor individually.
In such a process, all of the structural work on a floor must be completed before any structural work can begin on a vertically adjacent floor. This iterative process often bottlenecks construction projects and delays progress.
Further, concrete column-based construction requires a large amount of work to be performed by on-site laborers, The large amount of on-site labor further increases costs and creates scheduling difficulties.
Constructing buildings with structural steel-based support systems are another conventional construction method, but structural steel-based methods do not adequately address many of the shortcomings of concrete-based methods. For example, structural steel drastically reduces the amount of concrete to be poured during construction. This decrease in labor, however, is offset by the need to individually weld a large number of structural steel elements. Indeed, structural steel supports often require builders to iteratively and labor-intensively construct each floor on site. Accordingly, conventional structural steel systems are often as labor intensive, expensive, and slow as conventional concrete-based projects.
Further, many buildings constructed with conventional structural steel-based support systems include irregular floor plans that require a variety of structural members to be used over the course of construction. At some times during production, stocks may be depleted due to one or more of delayed deliveries, depleted stocks, errors in ordering, or other causes of depleted supplies. Such shortfalls in supply may result in delays and additional labor costs.
Wood-based support systems address some of the shortcomings of conventional structural steel and concrete based support systems. For example, labor costs associated with some wood supported projects are dramatically reduced compared to structural steel and concrete supported projects. Further, wood-based support systems may, in some examples, be quicker and less labor-intensive to construct.
Many wood-based support systems, however are unable to adequately support multi-story buildings, particularly those that include more than two floors. Accordingly, wood-based support systems are only adequate for very small-scale construction projects and are inadequate for larger-scale projects including 3 or more floors. As a result, wood-based support systems are inadequate for larger-scale, multi-story applications. As a result, there exists a need for support systems that take advantage of the lower cost provided by wood-based support systems while supporting the multi-story structures that currently require steel or concrete-based support systems.
Thus, there exists a need for support systems that improve upon and advance the design of known support systems. In particular, there exists a need for support systems that are adequate to support larger-scale multi-floor projects that require less on-site labor than conventional concrete and/or structural steel-based projects. Examples of new and useful modular support systems relevant to these and other needs existing in the field are discussed below.
The present disclosure is directed to modular support systems for supporting multi-story buildings including plates having bottom major faces and top major faces, the plates defining bolt holes extending through the plates, vertical columns extending from bottom ends to top ends opposite the bottom ends, the bottom ends of the vertical columns being welded to the top major faces of the plates, and horizontal columns having bottom sides and top sides opposite the bottom sides, the bottom sides of the horizontal columns being welded to the top end of the vertical columns. In some examples, the horizontal column defines bolt holes being positioned to align with the bolt holes defined in the plate. Some examples include pluralities of structural units selectively fastened together in a vertical arrangement, with each structural unit configured to selectively couple with a vertically adjacent structural unit. Some examples define buildings including the disclosed support systems.
The disclosed modular support systems will become better understood through review of the following detailed description in conjunction with the figures. The detailed description and figures provide merely examples of the various inventions described herein. Those skilled in the art will understand that the disclosed examples may be varied, modified, and altered without departing from the scope of the inventions described herein. Many variations are contemplated for different applications and design considerations; however, for the sake of brevity, each and every contemplated variation is not individually described in the following detailed description.
Throughout the following detailed description, examples of various modular support systems are provided. Related features in the examples may be identical, similar, or dissimilar in different examples. For the sake of brevity, related features will not be redundantly explained in each example. Instead, the use of related feature names will cue the reader that the feature with a related feature name may be similar to the related feature in an example explained previously. Features specific to a given example will be described in that particular example. The reader should understand that a given feature need not be the same or similar to the specific portrayal of a related feature in any given figure or example.
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System 100 provides a structural steel-based support system configured to support a multi-story building. System 100 is configured to support at least a minimum load-bearing capacity of the building, the minimum load-bearing capacity being selected to support the structural elements and the expected contents of the building. Further, system 100 provides a modular structure constructed of parts that may be largely fabricated off-site at a production facility before being installed at a construction site.
Additionally, system 100 includes a substantially identical set of pre-fabricated structural units, thereby drastically reducing the number of unique parts that are required to be stocked and installed on-site during construction. System 100 further supports a method of installing the pre-fabricated structural units without welding at the construction site, which may reduce or eliminate the need for on-site welders.
As a result, system 100 provides a structural steel-based support system with efficiency gains through pre-fabrication and a simpler, weld-free install process. Further, by shifting a significant amount of the labor to off-site pre-fabrication, system 100 dramatically reduces on-site build times. Through these efficiency gains, system 100 allows construction of multi-story buildings at prices and build times that are dramatically lower than would be associated with conventional structural steel-based construction methods. Indeed, the disclosed systems allow multi-story structural steel-based projects to be constructed at times and costs typically associated with projects with wood-based structural supports.
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This disclosure notes, however, that all structural units that are horizontally aligned and vertically coupled with one another (e.g., those that are positioned on the same portion of the floor plan in each floor) are substantially identical. As a result, each floor utilizes substantially identical components for installation as every other floor in the building. This uniformity in construction assists supply management and parallel construction, as structural units and other parts available on-site may often be used at multiple parts of system 100.
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Likewise, third structural unit 110iii, which is vertically-coupled to first structural unit 110i, is substantially identical to first structural unit 110i. Similarly, fourth structural unit 110iv is vertically coupled to second structural unit 110ii, and is also substantially identical to second structural unit 110ii. As
Although third structural unit 110iii and fourth structural unit 110iv are the same height as the other illustrated structural units, this disclosure contemplates that structural units on different floors may define different heights as long as the height of structural units on the same floor all define a consistent height.
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While corridor 95 and corridor 98 are routed through spaces between structural unit sections, this is not specifically required. In fact some examples may lack distinct structural unit sections altogether. Indeed, structural units may, in some examples, be installed over the entire area of a building's floor plan and thereby essentially define only a single section of structural units. In such an example, the entire floor plan of the associated building may be defined by a single row of parallel structural units.
In examples lacking space between structural unit sections, corridors may be routed between the vertical columns of a floor's structural units. Indeed, by strategically placing non-load bearing walls, carefully routing corridors between vertical columns, and selectively placing walls and/or passageways between vertical columns of structural units, buildings with single structural unit sections may afford even greater flexibility in floor plan design than those with multiple sections.
First structural unit 110i, as displayed in
The number of columns on a particular structural unit is typically the maximum amount of columns that will fit along the length of the structural unit when spaced the predetermined column spacing distance. Some structural units, may additionally include an additional column at one or both end that is spaced from the adjacent column by less than the predetermined column spacing distance.
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Plate 112i does not necessarily bear any load, but rather acts as an interface allowing first structural unit 110i to be coupled with a vertically adjacent structural unit below first structural unit 110i. Specifically, as
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Each vertical column on a particular floor is often identical, which may increase the uniformity of the materials of system 100. Further, the vertical columns of each structural unit are often welded to the associated plate during an off-site pre-fabrication process. This may reduce on-site work and result in a cheaper, more efficient build process.
To avoid redundancy, this disclosure focuses on first vertical column 117i specifically to describe disclosed vertical columns generally. As
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Although all vertical columns 116i extend substantially straight vertically and perpendicularly to plate 112i, this is not specifically required. Some examples may include one or more vertical columns that extend from plate 112i toward horizontal column 125i at an angle other than 90 degrees. Additionally or alternatively, one or more supplemental vertical supports may extend between plate 112i and horizontal column 125i at an angle other than 90 degrees.
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Structural units on the upper floors of a building are required support a lessened portion of the building's expected minimum load-bearing capacity than those on lower floors. Accordingly, the layout of upper floors may have adjusted layouts that remove one or more structural units to accommodate larger rooms or housing units.
In some examples, vertical columns on different floors or at different horizontal positions may define different gauges. For example, columns on lower floors may define larger gauges to accommodate the larger share of load-bearing support that lower floors must provide.
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Because the horizontal bolt holes and plate bolt holes of structural units are aligned with one another, structural units are configured to be stacked on one another. In particular, the structural units are configured to be stacked with the horizontal beam and plate bolt holes aligned with one another as plates are engaged with horizontal beams of adjacent structural units. More precisely, the plate holes of an upper structural unit may be aligned with and proximate to the horizontal beam holes of a lower structural unit when the upper structural unit is stacked on the lower structural unit.
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Because of the bolt-based structural unit coupling methodology described above, the pre-fabricated structural units may be coupled to one another on-site without any welding. As a result, system 100 may be constructed at a construction site without performing any on-site welding. In fact, the bolt-based installation method may be relatively easy to attach without any substantial, heavy equipment.
Reducing the need for on-site welding to couple structural units from one another provides a myriad of benefits. For example, on-site welding is one of the most significant costs of constructing many conventional steel-based support systems; by reducing the amount of welding required, system 100 may drastically lower total construction costs. Additionally or alternatively, the bolt-based coupling methodology may be quicker and easier to perform than on-site welds.
When structurally units are installed and coupled, each structural unit may optionally support removable, non-load bearing walls that extend along structural units between adjacent vertical columns. This may afford designers and constructors great flexibility in laying out floor plans for housing units. In some portions of a constructed building, walls may extend along the entire length of a pair of horizontally adjacent structural units. In such portions, housing units may consist of only the space between horizontally adjacent structural units.
In other portions, however, one or more structural units may define doors or voids between some vertical columns. By defining a void or doorway between vertical columns, designers may be able to allow passage through the structural unit. This may allow for housing units that span across multiple structural units.
Further, non-structural walls or doorways may extend across a pair of horizontally adjacent structural units. Such non-structural walls may be useful, for example, to provide entrances for the housing units defined by horizontally adjacent structural units.
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Though system 100 is configured to bear the entire minimum load necessary to support the building, pouring concrete floors may provide additional lateral stability to structural units.
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As a result, system 100, when constructed, is configured to support independent of any additional load bearing supports, such as concrete columns. Indeed, this disclosure specifically contemplates that the disclosed modular, load-bearing support structures are capable of supporting at least the minimum load-bearing capacity selected to support structural elements of a multi-story building and the expected contents of the building.
The inventions described above may be alternatively described according to the following non-limiting embodiments.
In a first embodiment of a modular support system for supporting, a multi-story building, the modular support system may include a plate having a bottom major face and a top major face opposite the bottom major face, a vertical column extending from a bottom end to a top end opposite the bottom end, the bottom end of the vertical column being welded to the top major face of the plate, and a horizontal column having a bottom side and a top side opposite the bottom side, the bottom side of the horizontal column being welded to the top end of the vertical column.
In some examples of the first embodiment, the plate defines bolt holes extending from the top major face through the plate to the bottom major face.
In some examples of the first embodiment, the horizontal column defines bolt holes extending through the top side of the horizontal column being positioned to align with the bolt holes defined in the plate.
In some examples of the first embodiment, the plate, the vertical column, and the horizontal column collectively define a first structural unit. Some examples of the first embodiment further comprise a second structural unit coupled to the first structural unit with bolts. In some examples with a second structural unit, the second structural unit comprises a second plate having a bottom major face and a top major face opposite the bottom major face and the second plate defines bolt holes extending from the top major face of the second plate through the second plate to the bottom major face of the second plate. In some examples including a second plate, the bolt holes defined in the second plate align with the bolt holes defined in the top side of the horizontal column of the first structural unit. In some examples with a second structural unit, the second structural unit comprises a second vertical column extending from a bottom end to a top end opposite the bottom end and the bottom end of the second vertical column is welded to the top major face of the second plate. In some examples having a second structural unit, the second structural unit comprises a second horizontal column having a bottom side and a top side opposite the bottom side, the bottom side of the second horizontal column being welded to the top end of the second vertical column.
Some examples including a second structural unit further comprise bolts extending through the bolt holes defined in the second plate and through the bolt holes defined in the top side of the horizontal column of the first structural unit to selectively couple the first structural unit with the second structural unit.
In some examples including a second structural unit with second vertical columns, vertical column of the first structural unit defines a first load-bearing metallic beam, the second vertical column defines a second load-bearing metallic column, and the vertical column of the first structural unit defines a first column gauge that is greater than a second column gauge defined by the second vertical column.
In some examples of the first embodiment, the horizontal column defines a wide-flange beam including a top flange defining the top side, a bottom flange spaced from the top flange, the bottom flange defining the bottom side, and a web extending between the top flange and the bottom flange. In some examples wherein the horizontal column defines a wide-flange beam, the bolt holes extend through the top flange.
In some examples of the first embodiment, the vertical column defines a wide-flange beam including a first side flange, a second side flange spaced from the first side flange, and a web extending between the first side flange and the second side flange.
In some examples of the first embodiment, the horizontal column extends horizontally to a predetermined structural unit length, and the plate extends horizontally to the predetermined structural unit length.
In some examples wherein the horizontal column and plate extend to a predetermined structural unit length, the plate, the vertical column, and the horizontal column collectively define a first structural unit and the structural unit includes a plurality of supplemental vertical columns extending between the plate and the horizontal column, the supplemental vertical columns positioned to be equally spaced along the length of the structural unit.
Some examples defining a plurality of vertical columns, further comprise a second structural unit horizontally spaced from the first structural unit by a predetermined wall spacing distance and vertically aligned with the first structural unit. In some examples with a second structural unit, the second structural unit includes a second plate having a bottom major face and a top major face opposite the bottom major face, the second plate defines bolt holes extending from the top major face of the second plate through the second plate to the bottom major face of the second plate. In some examples including a second structural unit, the second structural unit includes a second vertical column extending from a bottom end to a top end opposite the bottom end, the bottom end of the second vertical column being welded to the top major face of the second plate. In some examples including a second structural unit, the second structural unit includes a second horizontal column having a bottom side and a top side opposite the bottom side, the bottom side of the second horizontal column being welded to the top end of the second vertical column. In some examines with a second structural unit, the second horizontal column defines bolt holes extending through the top side of the second horizontal column being positioned to align with the bolt holes defined in the second plate.
In some examples including a second structural unit, the second structural unit is horizontally aligned with the first structural unit.
In some examples including a second structural unit, the second plate extends horizontally to the predetermined structural unit length and the second horizontal column extends horizontally to the predetermined structural unit length.
Some examples including a second structural unit further comprise a third structural unit, the third structural unit being coupled to the first structural unit with bolts. In some examples including a third structural unit, the third structural unit includes a third plate having a bottom major face and a top major face opposite the bottom major face, the third plate defining bolt holes extending from the top major face of the third plate through the third plate to the bottom major face of the third plate. In some examples including a third plate, the bolt holes defined in the third plate align with the bolt holes defined in the top side of the horizontal column of the first structural unit. In some examples including a third structural unit, the third structural unit includes a third vertical column extending from a bottom end to a top end opposite the bottom end, the bottom end of the third vertical column being welded to the top major face of the third plate. In some examples including a third structural unit, the third structural unit includes a third horizontal column having a bottom side and a top side opposite the bottom side, the bottom side of the third horizontal column being welded to the top end of the third vertical column.
Some examples including a third structural unit further comprise a fourth structural unit, the fourth structural unit being spaced from the third structural unit by the predetermined wall spacing distance, being coupled to the second structural unit with bolts. In some examples with a fourth structural unit, the fourth structural unit includes a fourth plate having a bottom major face and a top major face opposite the bottom major face, the fourth plate defining bolt holes extending from the top major face of the fourth plate through the fourth plate to the bottom major face of the fourth plate. In some examples with a fourth plate, wherein the bolt holes defined in the fourth plate align with the bolt holes defined in the top side of the horizontal column of the second structural unit. In some examples with a fourth structural unit, the fourth structural unit includes a fourth vertical column extending from a bottom end to a top end opposite the bottom end, the bottom end of the fourth vertical column being welded to the top major face of the fourth plate. In some examples with a fourth structural unit, the fourth structural unit includes a fourth horizontal column having a bottom side and a top side opposite the bottom side, the bottom side of the fourth horizontal column being welded to the top end of the fourth vertical column.
Some examples including a fourth structural unit further comprise a first set of bolts extending through the bolt holes defined in the third plate and through the bolt holes defined in the top side of the horizontal column of the first structural unit to couple the first structural unit with the third structural unit and a second set of bolts extending through the bolt holes defined in the fourth plate and through the bolt holes defined in the top side of the second horizontal column to selectively couple the second structural unit with the fourth structural unit.
In some examples including a fourth structural unit, the vertical column defines a first vertical column, the first structural unit includes a fifth vertical column horizontally spaced from the first vertical column, the fifth vertical column extending perpendicularly between the plate of the first structural unit and the horizontal column of the first structural unit, and the third structural unit includes a sixth vertical column horizontally aligned with the fifth vertical column, the sixth vertical column extending perpendicularly between the third plate and the third horizontal column.
In some examples of the first embodiment, the horizontal column longitudinally extends substantially perpendicularly to the vertical column.
In some examples wherein the horizontal column longitudinally extends substantially perpendicularly to the vertical column, the plate longitudinally extends substantially parallel to the horizontal column.
In a second embodiment of a modular support system for supporting a multi-story building, the modular support system may include a plurality of structural units selectively fastened together in a vertical arrangement, each structural unit configured to selectively couple with a vertically adjacent structural unit. In the second embodiment of the modular support system, each structural unit may include a plate having a bottom major face and a top major face opposite the bottom major face, the plate being configured to receive a fastener through the plate to secure the plate to the lower structural unit. In the second embodiment of the modular support system, each structural unit may include a vertical column extending from a bottom end to a top end opposite the bottom end, the bottom end of the vertical column being welded to the top major face of the plate. In the second embodiment of the modular support system, each structural unit may include a horizontal column having a bottom side and a top side opposite the bottom side, the bottom side of the horizontal column being welded to the top end of the vertical column, the horizontal column being configured to receive the fastener to secure the horizontal column to the upper structural unit.
A third embodiment may define a multi-story building defining a minimum load-bearing capacity selected to support structural elements of the building and expected contents of the building, including a modular support system. In the third embodiment of a modular support system for supporting a multi-story building, the modular support system may include a plurality of structural units. In modular support systems including a plurality of structural units, each structural unit may include a plate having a bottom major face and a top major face opposite the bottom major face, the plate defining bolt holes extending from the top major face through the plate to the bottom major face. In modular support systems including a plurality of structural units, each structural unit may include a vertical column extending from a bottom end to a top end opposite the bottom end, the bottom end of the vertical column being welded to the top major face of the plate. In modular support systems including a plurality of structural units, each structural unit may include a horizontal column having a bottom side and a top side opposite the bottom side, the bottom side of the horizontal column being welded to the top end of the vertical column. In modular support systems including a plurality of structural units, the horizontal column defines bolt holes extending through the top side of the horizontal column being positioned to align with the bolt holes defined in the plate. In modular support systems including a plurality of structural units, each vertical column defines a column load-bearing capacity, wherein a combined load-bearing capacity of each vertical column is at least as eat as the minimum load-bearing capacity.
In some examples of the third embodiment including vertical columns, each vertical column defines a steel column adapted for structural load beating.
The disclosure above encompasses multiple distinct inventions with independent utility. While each of these inventions has been disclosed in a particular form, the specific embodiments disclosed and illustrated above are not to be considered in a limiting sense as numerous variations are possible, The subject matter of the inventions includes all novel and non-obvious combinations and subcombinations of the various elements, features, functions and/or properties disclosed above and inherent to those skilled in the art pertaining to such inventions. Where the disclosure or subsequently filed claims recite “a” element, “a first” element, or any such equivalent term, the disclosure or claims should be understood to incorporate one or more such elements, neither requiring nor excluding two or more such elements.
Applicant(s) reserves the right to submit claims directed to combinations and subcombinations of the disclosed inventions that are believed to be novel and non-obvious. Inventions embodied in other combinations and subcombinations of features, functions, elements and/or properties may be claimed through amendment of those claims or presentation of new claims in the present application or in a related application. Such amended or new claims, whether they are directed to the same invention or a different invention and whether they are different, broader, narrower or equal in scope to the original claims, are to be considered within the subject matter of the inventions described herein.
This application claims priority to the following copending applications, each of which are incorporated by reference for all purposes: U.S. Provisional Application, Ser. No. 61/744,016, filed on Sep. 18, 2012;U.S. Provisional Application, Ser. No. 61/957,900, filed on Jul. 15, 2013; andPatent Cooperation Treaty Application, No. PCTUS2013060357, having an international filing date of Sep. 18, 2013.
Number | Date | Country | |
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Parent | PCT/US2013/060357 | Sep 2013 | US |
Child | 14579671 | US |