The accepted methods of constructing concrete structures designed with a plurality of tiered or stepped levels, such as seating for lecture halls, theaters or stadiums or stairways, is usually determined by the size of the project. Structures, like sports stadiums, are large enough in size to benefit from the ability of using large customized concrete ‘gang type’ forms that require external means of load transfer from one section of the form to another. Forming smaller structures, like a classroom lecture hall, will often typically be built ‘by hand’ one component at a time.
The use of ‘gang type’ forms to build the larger structures can usually provide greater control over dimensional accuracy and installed costs due to a faster cycle of setting the forms, placing the concrete and stripping the forms. Employing ‘hand built’ construction practices for smaller structures can provide dimensional accuracy but there is increased risk of failure due to the reduced size of the components and fasteners, though the construction cycle will be longer and the labor cost will be higher. The decision ultimately comes down to whether there is enough labor savings to offset the investment in the ‘gang type’ forms. If the reuse and the labor savings can't be realized with ‘gang type’ forming methods, then ‘hand built’ forms are used for the construction, with the acceptance of higher labor costs and associated risks.
It is known in the industry to utilize expanded polystyrene (EPS) foam blocks as a form that supports the tread portion of a tiered concrete floor, for example, for the seating area of a cinematic movie theater. This prior art method does not form a concrete riser, such that the structure does not have the integrity of a monolithic tiered concrete slab having interconnected concrete risers and treads. Typically, this prior art method utilizes a permanent steel plate as the riser. In the event of a fire, the steel plate transfers heat to the underlying foam blocks, which then can melt such that the concrete treads are not evenly supported and eventually fail.
Another prior art method of forming a tired concrete slab requires a base with compacted granular fill which must be retained in a sloped arrangement. Retaining walls are used for retention of the sloped fill material. The retaining walls add additional time and expense to these projects.
Therefore, it is a primary objective of the present invention to provide an improved assembly and method for forming a monolithic tiered concrete slab or stairway.
Another objective of the present invention is the provision of an assembly and method for forming a tiered concrete slab or stairway having a curved riser face.
Another objective of the present invention is the provision of an assembly and method for forming a monolithic tiered concrete slab or stairway for various uses, including auditorium and lecture hall seating.
Another objective of the present invention is the provision of an assembly and method for forming a tiered concrete slab or stairway having minimal heat transfer properties.
Still another objective of the present invention is the provision of an assembly and method for forming a tiered concrete slab or stairway having interconnected concrete treads and risers.
Yet another objective of the present invention is the provision of an assembly and method for forming a tiered concrete slab or stairway which is customized to each individual project.
A further objective of the present invention is the provision of an assembly and method for forming a tiered concrete slab or stairway which is easy to use.
Still another objective of the present invention is the provision of an assembly and method for forming a tiered concrete slab or stairway which is economical and durable.
These and other objectives will become apparent from the following description of the invention.
The invention is directed toward a riser interface assembly and method for constructing a monolithic tiered concrete slabs and stairways using a combination of components that will promote the accurate and efficient construction of a plurality of tiered levels involving riser faces and treads. The distinguishing characteristics of this construction system and method relate to its secure ‘interface’ between the supporting base, whether permanent or temporary, and the forms for the riser faces. Since very few projects have the same dimensional requirements, it is necessary for a system to be customizable, for example, to accommodate either straight or radial designs. This method uses pre-manufactured, project specific components that are supplied as a system. These ‘made to order’ parts are assembled at the jobsite more rapidly, more accurately, and with more stability than typical job built forming methods. The benefits of the ‘gang type’ forms can therefore be realized on smaller projects using the assembly and method of the present invention.
The system components include the following: 1) a permanent, engineered base material, such as, but not limited to, EPS foam that is configured to the lineal, radial, or tapered profile of the project, 2) structural interface elements such as boards (laminated wood veneers, oriented wood strands, or composites) or metal components that are bonded and/or mechanically attached to the engineered fill or base material, 3) special form ties (most often made of, but not limited to, welded steel wire) and 4) riser face forming element such as temporary, very smooth boards (laminated wood veneers, oriented wood strands, or composites with a plastic face to the concrete) or permanent riser faces such as concrete or metal, and 5) sufficient structural framing and forming hardware behind the riser face to control the desired configuration of the concrete riser, whether straight or radial.
The system, as described, is not intended to alter the design requirements of the structural, tiered concrete slabs or stairways. It should be noted that, the substitution of EPS blocks as a permanent base material, in lieu of compacted granular material, can eliminate the retaining walls that are needed to restrain the lateral pressure caused by compaction forces. EPS blocks are designed, tested and rated according to ASTM standards; specific live and dead loads can be permanently supported without the risk of settling. Structural reinforcing requirements should be engineered to meet the specific needs of the intended application.
The assembly and method of the present invention is intended for use in the construction of a monolithic, reinforced, tiered concrete slabs 10, or stairways 12, formed in straight rows or about a radius. Each row of the tiered concrete slabs or stairways has a riser 16 and a tread 18. The assembly begins with a plurality of EPS foam blocks 20 which are positioned adjacent each other, as seen in
The structural interface elements 34, shown in cross hatching in
The fixed length, or adjustable length, riser face form ties 38 are mechanically attached to the interface elements 34 using any convenient fastener, such as screws, extending through front and rear L-shaped angle feet 40. Typical methods of fabricating the angled feet 40 include steel clips welded to the wire tie 38 or a looped wire feature that is integral with the riser tie 38. As an alternative to feet 40, an integral looped wire 41 may be provided for receiving fasteners, as seen in
The method of forming the tiered concrete slabs 10 or stairways 12 of the present invention is schematically shown in
The next step in the method is to attach the structural interface elements 34 to the foam blocks 20, preferably using adhesive and/or mechanical anchors. In the best mode, the riser face form ties 38 are mounted on the structural interface elements 34. If required, shims can be placed under the mounting feet 40 to assure accurate positioning. Then, the riser face forms 46, walers and hardware are mounted on the riser ties 38. As required, the riser face forms 46 will create a smooth, curved riser surface when the blocks 20 are set in a radial alignment around the center point of the riser faces. Similarly, straight or lineal riser configurations will be parallel and accurately positioned. Steel reinforcement rods (not shown) can be positioned, as known in the industry. The concrete 52 is then poured, finished on the treads 18, and allowed to cure. The last step in the process is to remove the riser face forms 46 and framing lumber, unless the permanent face panel 48 is utilized. The structural interface elements 34 and the riser ties 38 remain buried in the concrete 52.
It is understood that this system and method can be used on sloped earth (or particulate material), or on decking (whether temporary or permanent), without the EPS foam blocks 20.
The invention has been shown and described above with the preferred embodiments, and it is understood that many modifications, substitutions, and additions may be made which are within the intended spirit and scope of the invention. From the foregoing, it can be seen that the present invention accomplishes at least all of its stated objectives.
This application claims priority under 35 U.S.C. § 119(e) to provisional application Ser. No. 60/914,909 filed Apr. 30, 2007, herein incorporated by reference in its entirety.
Number | Date | Country | |
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60914909 | Apr 2007 | US |