The present invention relates generally to building components and more particularly to an apparatus for supporting a concrete floor and composite floor systems constructed therewith.
Many commercial buildings and some larger, multi-story residential complexes, such as apartment buildings or condominiums, utilize concrete floor decking or concrete floors in their construction. Concrete floor decking has also become increasingly popular in residential and smaller constructions over the last decade. Concrete floor support systems have several advantages over traditional decking materials, such as strength, rigidity, durability, mold resistance, sound attenuation, suitability for in-floor radiant heating and the availability of decorative concrete finishes.
Traditional concrete flooring systems were adapted from commercial construction, and generally constructed by spanning steel or wood joists between structural walls or primary structural members, spacing or bridging the joists with rebar or blocking members to provide lateral support to the joists, and laying plywood, steel, aluminum, or fiberglass decking on or between the joists and pouring a thick concrete layer over the decking. The resulting flooring systems are heavy and require significant time to install. Further, in order to bear the additional weight of the decking and concrete layer during curing, the decking panels must be shored (or braced), adding to the cost of the systems. In smaller constructions, such as residential applications, these traditional systems were generally too expensive and logistically challenging to install.
Further, in application, conventional concrete flooring systems are subject to significant horizontal and vertical forces, and in particular, horizontal shear occurring along the longitudinal top of primary and secondary joist members. Indeed, these systems ultimately fail because of loss of interfacial force in the shear span.
Composite concrete floor support systems offer a solution to traditional concrete floor systems. Composite systems utilize steel joists having a top chord or portion that is embedded into the poured concrete deck. The top chord then forms a shear connector to prevent slippage from occurring between the concrete slab and the joist, due to horizontal shear along the joist, which can reduce the amount of reinforcement required over the traditional systems.
Various forms of shear connectors have been developed, including elongated studs welded to the top chord of the joist member. The studs are embedded in the concrete, thereby transferring horizontal shear forces from the slab to the beam. However, these studs are welded to the joist after the joist has been connected to the structure during erection, requiring significant labor and time, and they can be hazardous to crew members after installation, but before the concrete has been poured. Other types of shear connectors include, joists having an irregular or S-shaped tap chord, such as the Hambro™ joist, or alternatively, a shear connector of the type disclosed in U.S. Pat. No. 7,013,613 to Boellner et al., which teaches an extended length shear connector including protrusions and indentations on the surface thereof
Regardless of the shear connector used in the prior art systems described above, these systems still require reinforcement of the concrete layer. In particular, rebar (reinforcing bar), metal mesh, decking or cross braces are placed over or in between the joists to reinforce the concrete layer before the concrete is poured. Accordingly, this type of composite system, while having increased strength over non-composite systems, can be heavy and expensive due to the added cost of reinforcement material. However, rebar and other metal reinforcements are subject to corrosion and deterioration of the floor. Further, in systems where the reinforcement is positioned on top of the top chord or shear connector, these systems are subject to failure due to tearing of the deck near the shear connector.
In addition, many of the prior art systems require removable framing systems to be in place before construction and removed after the concrete has cured, adding to the cost of installation of these types of composite systems.
Accordingly, there is a need for a lighter floor support system for use with concrete floor decking, in particular, for use in above-grade and residential constructions, while also offering decreased costs and ease of installation on-site.
A composite flooring system and method for supporting a concrete flooring system in accordance with one embodiment of the present invention can be used in situations where conventional wood, masonry, or light gauge steel framing materials are used. The system includes a plurality of joist assemblies having a shear connector secured thereto, the joist assemblies arranged in a spaced apart and substantially parallel configuration, with a panel supported between each pair of adjacent joist assemblies, and a concrete layer provided over the panel and shear connector components.
The joist assembly includes a first frame member having a top flange, a web portion and a bottom flange and a second frame member of mirror image construction. The frame members are arranged in a back-to-back fashion, providing the joist assembly with a two layered and reinforced web portion. The web portions of each of the frame members include a plurality of space-apart clips and tabs which can secure a support angle in place on the web portion of the frame member along the length thereof for supporting sections of polystyrene foam in between the frame members. The web portions of each of the frame members can also include openings to permit plumbing, electrical wiring, ductwork or other building utilities to run through the support system.
A shear connector is secured to the top chord of each joist assembly and extends the entire length thereof The shear connector extends vertically upwards from the top chord of the joist, having an arcuate end or bend. This bend provides additional surface area to which the concrete layer may bond and can be used to stiffen the shear connector. The shear connector also includes a plurality of openings that also provide additional surface area of contact between the shear connector and the concrete layer, further strengthening the resulting steel-concrete composite flooring system. The shear connector can include attachment portions including downwardly extending tabs for engaging slots provided in the top chord of the joist assembly. By providing a shear connector with attachment tabs and a top chord with corresponding attachment slots, the time it takes to assemble the joist and shear connector members is minimized.
The system may also include a method for supporting a concrete floor by providing at least two joist assemblies, as described above, and each having a shear connector secured to the top chord thereof, and permanently securing at least one foam panel between a pair of adjacent joist assemblies. The method can include forming a composite floor of the present invention by additionally pouring a layer of concrete over the foam panel and to a height above the top of the shear connector.
The composite floor system and methods for supporting a concrete floor eliminate the need for reinforcement provided within the concrete layer, such as rebar, metal mesh or cross braces, thus rendering the system lighter, easier to install and less expensive. In addition, without the necessity to reinforce the concrete, the concrete layer is more suitable for installation of radiant heating systems. Furthermore, construction processes are simplified because cross blocking, special tools and skills required for framing the system during the curing period are not require due to the reduced weight of the system, and the drilling and cutting associated with traditional wood products are all unnecessary. Further, the system provides a composite concrete floor that does not require framing material to be removed, significantly shortening set up and construction time.
The composite concrete floor support systems disclosed herein have all the advantages of concrete flooring system, such as strength, rigidity, durability, mold resistance and sound attenuation, with the added benefit of utilizing a foam insulation layer to provide a durable and energy-efficient construction. Because of benefits, such as sound attenuation, impact resistance, and high R-value, the foam layer enhances the advantages of the concrete decking to provide a lighter, more durable composite system over traditional composite concrete flooring systems.
Various other features, objects, and advantages of the invention will be made apparent to those skilled in the art from the accompanying drawings and detailed description thereof
Turning first to
The web portion 44 of the channel member 36 includes a plurality of clips 52 and corresponding tabs 56. The clips 52 are located near the top of the web portion 44 and are spaced apart along the length 47 of the channel member 36. As best illustrated in
The support angle 59 includes a leg 66 that is inserted into the clips 52 and a leg 68 that rests on the tabs 56, securing the support angle 59 along the length of the channel 36. The legs 66 and 68 may further be secured to the channel member 36 by welding or using screws, rivets, pins or another fastener that secures the support angle in place.
Similarly, the web portion 50 of the channel member 38 includes a plurality of clips 54 and corresponding tabs 58. The clips 54 are located near the top of the web portion 50 and are spaced apart along the length 49 of the channel member 38. Each of the tabs 58 is vertically aligned with one of the clips 54 for retaining a support angle 61 (shown in
The support angle 61 includes a leg 70 that is inserted into the clips 54 and a leg 72 that rests on the tabs 58, securing the support angle 61 along the length of the channel 38. The legs 70 and 72 may further be secured to the channel member 38 by welding or using screws, rivets, pins or another fastener that secures the support angle in place.
It will be appreciated by those skilled in the art that the clips and tabs provided within the web portions of each of the channel members may be replaced by another support mechanism that adequately retains the support angles in place. Such a mechanism can include using screws, rivets, pins or alternatively by welding the support angle to the channel members.
The web portions 44 and 50 of each of the channel members 36 and 38 also include a plurality of apertures 60 and 62, respectively, to permit plumbing, electrical wiring, ductwork or other building utilities to run through the support system. As will be recognized by those skilled in the art, the size of the channel members 36 and 38, including but not limited to, the span of their corresponding web portions 44 and 50, the number of clips 52 and tabs 56 provided, and the size and number of apertures 60 and 62 provided within the web portions 44 and 50, will depend on the given construction application, and is determined by, among other factors, the span of the flooring system to be installed, loading considerations of the floor, use and location of the building and applicable ANSI, ASTM, and/or governmental design and safety standards.
As best illustrated in
It will be appreciated from
As best shown in
The attachment portions 86 and 88 are short, substantially planar members formed on alternating sides of the vertical portion 90. Each of the attachment portions 84 and 86 includes downwardly extending tabs 94 and 96, respectively, for engaging the top chord 80 of the joist assembly 34. In particular, the top chord 80 is provided with a plurality of spaced apart slots 102 and 104 (shown in
The vertical portion 90 of the shear connector 84 includes an arcuate end or bend 110 located at the top thereof This bend 110 can be used to stiffen the vertical portion 90 of the shear connector and also provides additional surface area to which the concrete layer 35 may bond. The bend 110 can be formed in either direction, as is not limited to the direction indicated in
Turning now to
An alternative embodiment of the present invention is shown in
As illustrated in
The concrete layer 35 is poured on top of the panels 32, to a height above the bend 110 in the shear connector 84. The panels 32 remain in place after the concrete layer cured. The amount of concrete utilized, and therefore the height of the concrete layer is determined, at least in part, by the particular type of concrete utilized, the particular construction application, the ultimate live and dead loads, including the weight of additional flooring, the size of the joist assemblies utilized, and the type of panel selected. It will be appreciated that materials other than concrete, such as concrete-fiberglass composites, or treated concrete materials can be used for the layer 35.
It can be seen that the composite floor system 30 and methods of the present invention provides a lighter and compact composite floor support system compared to conventional composite systems by eliminating the need for concrete reinforcement. By including foam panels 32 that remain in place after construction of the system, in combination with a joist assembly 34 that includes a reinforced web portion (the web portions 44 and 50 of the channel members) and a shear connector 84 provided with a plurality of openings 100 to increase the surface area for contact with the concrete layer, the composite system of the present invention does not require use of rebar or other concrete reinforcements. Without regard to any particular theory or mode of installation, the present invention provides a composite system 30 that utilizes a novel construction, allowing the concrete 35 and foam panels 32 to act as a compression flange, distributing horizontal shear forces from the slab to the primary structural members. As such, by eliminating the need for concrete reinforcement, the present invention can provide a less expensive and easier to assemble system.
While the invention has been described with reference to preferred embodiments, those skilled in the art will appreciate that certain substitutions, alterations and omissions may be made to the embodiments without departing from the spirit of the invention. Accordingly, the foregoing description is meant to be exemplary only, and should not limit the scope of the invention as set forth in the following claims.