The field of the present invention is generally the design and construction industry and specifically precast concrete and structural steel construction systems.
The advantages of reinforced concrete have long been known in the building industry and reinforced concrete raised floors have been commonly used in buildings. But pouring the concrete on site, also known as casting in place, to create a structure is slow, labor intensive, and costly.
Construction projects using the cast-in-place technique for raised floors require extensive use of formwork, steel floor beam installation, galvanized metal deck installation, slab reinforcing installation, and the installation of slab embedded mechanical, electrical, IT, and plumbing items (MEP). All of this must be completed prior to casting the floor slab. This makes them heavier and costlier than the modular structural building system of the present invention. Additionally, the pouring, curing, and drying of concrete is weather dependent as time, moisture, and temperature play a part in the process and the quality.
In addition to the quality and time issues associated with the cast-in-place process, there are additional project schedule issues because, even once poured, it can be weeks before the concrete raised floor is in a condition to be walked on by the construction trades. Therefore, the construction of cast-in-place concrete raised floor slabs is always on the leading edge, or critical path, of the project schedule. Any time that can be gained through an early release of these raised floor slabs to trades will result in quicker project schedules, safer jobsites, and more cost-effective projects.
Rather than the cast-in-place process, precast concrete panels set in place and joined together on-site to create a raised floor have gained acceptance as a method to reduce time, labor, and material costs. Precast systems also provide a solution for remote jobsites that lack access to raw concrete. But current precast concrete floor panel systems have a variety of limitations and disadvantages. These floors are typically made of solid concrete and are thus much heavier than cast-in-place floors, which incorporate lighter steel components. The heaviness results in larger and more costly foundations and lateral systems. Further, precast raised floor slabs are usually simply installed side by side, often requiring the additional, cast-in-place pouring of a topping slab, which adds time and money to a project. A topping slab is also often required in precast raised floor systems in order to resist the seismic loads induced in moderate to severe earthquake exposure areas. But topping slabs can have their own surface defect issues depending on how they are poured. There can be additional camber, deflection, levelness, and flatness issues due in part to transitions across pre-cast floor panel connections.
Precast hollow core planks are also commonly used in the industry. These planks are extruded from dies and constructed of concrete material with continuous circular hollow openings the full length of the floor plank. These planks are reinforced with either conventional or prestressed reinforcing. Due to the extrusion process associated with hollow core planks, the final finish is rough and not aesthetically pleasing if left exposed and also may be difficult for floor finishes to adhere to properly. The top of hollow core slabs often has a dimple defect because as the concrete is extruded the top shell deflects downwards prior to the hardening of the concrete.
U.S. Pat. No. 8,499,511 to Platt, et al, discloses a precast composite floor system that combines the use of double tees and wide flange steel beams but does not have the advantages of the present invention, including levelling connection assemblies and the grout splicing method.
Also, U.S. Pat. No. 6,668,507 to Blanchet discloses a precast composite building system that combines the use of precast wall and floor panels and steel beams (primarily S-shaped), with welded joints between panels. This system does not have the benefits of the present invention such as the improved method of splicing adjacent floor panels, improved leveling connections, and it lacks the diaphragm chord reinforcement feature.
Thus, there is a need in the industry for a precast modular structural building system that addresses the limitations of the prior art. There is a further need in the industry to provide a modular building system with enhanced connection strength and levelling between composite raised floor panels. The present invention is designed to address these needs.
The present invention addresses the problems described above with an entirely new structural system consisting of prefabricated, precast, composite concrete floor and steel beam panels with adjustable levelling connection assemblies between panels, optimally supported by steel columns, although other supports, such as wide flange steel girders, can be accommodated. The structural system also has the ability to accommodate the use of the floor by construction personnel during the on-site assembly process. The perimeter of the raised floor slab can be provided with hollow ducts for a field installed conventional reinforcement means to create a continuous structural diaphragm for the floor panel.
The composite beam system (beam connected to concrete during pre-casting process) of the present invention combines two industries, concrete and steel, that do not currently work together to address the multitude of problems in the current environment. The method of this invention, where these raised floors are installed at the building site, allows the trades to work on the raised floor immediately, leading to substantial time and money savings as well as fewer safety incidents.
As described above, cast-in-place and precast concrete raised floor systems can have camber, deflection, levelness, and flatness issues. The unique adjustable levelling connection assembly in this invention provides the capability to use torque to draw two adjacent floor panels level with each other.
Additionally, precast slabs are not cast with ducts, channels, conduits, or voids for future placement of perimeter reinforcement, such as rebar or chord steel, radiant floor heating, Wi-Fi wiring, fires suppression systems, or other MEP systems. This invention provides this capability. Further, the raised floor panels of the present invention can be provided with insulation to meet the project's thermal and sound attenuation needs and with clips, tracks or light gauge framing for the construction of mechanical chases or architectural soffits under the floor.
A topping slab is often required in precast raised floor systems for structural support and earthquake resistance. The floors and roof of a building are generally designed to act as diaphragms, which refer to horizontal or sloped systems that act to transmit lateral forces to lateral load-resisting elements. The panel system of the present invention can vary in thickness to address required diaphragm capacity, without requiring a topping slab.
Further, the perimeter of the raised floor slab can be provided with ducts or channels for a field installed conventional reinforcement means. In one embodiment, a fully developed overlapping welded wire fabric connection can be created across all joints along with continuous reinforcing in the perimeter concrete slabs creating a continuous diaphragm for the floor panel. A continuous cable can be field placed through an embedded metal duct located at the perimeter of the diaphragm to resist the tension chord forces. This cable can be prestressed strand that is post-tensioning or un-tensioned. Conventional reinforcement, such as rebar, can also be utilized.
The method of the present invention uses the modular structural building system described herein to install raised floors comprising the steps of precasting a plurality of raised floor panels, transporting the precast raised floor panels to the building site, attaching each precast raised floor panel to at least one beam such that the precast raised floor panels are suspended and stable enough for construction personnel to walk on the precast raised floor panels, connecting adjacent angled edges of the precast raised floor panels to each other, installing within the receptacle created by connecting adjacent angled edges to each other at least one adjustable levelling connection assembly, said assembly being capable of using torque to draw two adjacent raised floor panels level, applying torque to the adjustable levelling connection assembly until the adjacent precast raised floor panels are level; and filling the receptacle with grout.
As used herein, certain terms have the following definitions:
“Angle” can be any shape that, when connected to the adjacent “angled” edge of another panel, a receptacle is created that can receive grout including, but not limited to V-shaped, U-shaped, or rounded or squared or any combination of the above.
“Beam” includes a beam with an “I” shaped cross-section (I-beam), a wide flange beam, preferably hot rolled, a steel beam, a channel (C and MC) steel beam, a light gauge steel section, a light gauge metal joist, a timber beam, or any long, sturdy piece that can span a part of a building and support a raised floor. Beams could be either composite or non-composite members.
“Cementitious” means having the properties of cement.
“Column” is defined as a piece that provides vertical support and can be made of any material suitable for the size and purpose of a building, such as iron or steel column, a horizontal wide flange girder, iron or steel beam, or any compound structure.
“Conventional Reinforcement Means” includes welded wire fabric, reinforcing mesh, steel, splice, concrete reinforcing bars (rebar), prestressed concrete strand (PC strand), post-tensioned strand, or any material that adds tensile strength to the concrete slab.
A “duct” is a channel or tube used for conveying something. In concrete, it is usually a void that may be created using a light gauge hollow tube cast into the concrete. This void is typically grouted at a later date once conventional reinforcement means are installed in the duct.
The term “diaphragm” is used here in the structural engineering sense and is defined as a structural element that transmits lateral loads to the lateral load resisting elements of a structure.
“Grout” is a filling, which when poured into a receptacle will fill in the receptacle and consolidate the adjacent edges into a solid mass, such as cementitious mortar or other cement-based materials, bentonite, bentonite/sand mixtures, graphite-based materials, carbon nanotubes and nanofibers, or a similar material.
“Raised floor” refers to any floor in a building that is suspended and supported. It does not include a typical ground floor that is slab-on-grade.
“Reinforced Concrete Slab” is a concrete slab that is reinforced with Conventional Reinforcement Means.
“Torque” is defined as a twisting force that tends to cause rotation.
In an alternative embodiment, the means 19 of coupling the beam 18 to the bottom 16 of the reinforced concrete slab 14 is a plurality of light gauge composite clips that attach to the top of the beam 18 and extend into the concrete slab 14 so that composite action is formed between the beam 18 and concrete slab 14.
A structural footer and ground floor concrete slab are shown in
For example,
Whereas the figures and description have illustrated and described the concept and preferred embodiment of the present invention, it should be apparent to those skilled in the art that various changes may be made in the form of the invention without affecting the scope thereof. The detailed description above is not intended in any way to limit the broad features or principles of the invention, or the scope of patent monopoly to be granted.
This application is a divisional of U.S. Pat. No. 10,550,565 entitled “Precast Modular Structural Building System and Method,” which claimed the benefit of the filing of Provisional Application No. 62/462,759, filed on Feb. 23, 2017, entitled “Precast Modular Structural Building System.” The specification and claims of both prior-filed applications are incorporated here by reference.
Number | Name | Date | Kind |
---|---|---|---|
973165 | Cahill | Oct 1910 | A |
1564264 | Murray | Dec 1925 | A |
1660370 | Billner | Feb 1928 | A |
2047109 | Nagel | Jul 1936 | A |
2215975 | Rackle | Sep 1940 | A |
2306320 | Rapp | Dec 1942 | A |
2466106 | Hoge | Apr 1949 | A |
3368016 | Birguer | Feb 1968 | A |
3434263 | Wald | Mar 1969 | A |
3478481 | Schuppisser | Nov 1969 | A |
3491499 | Dyer | Jan 1970 | A |
3555753 | Magadini | Jan 1971 | A |
3596423 | Jacobus | Aug 1971 | A |
3645056 | Gerola | Feb 1972 | A |
3762115 | McCaul, III | Oct 1973 | A |
3775928 | Dawson | Dec 1973 | A |
4006570 | Stolz | Feb 1977 | A |
4398378 | Heitzman | Aug 1983 | A |
5311629 | Smith | May 1994 | A |
5761862 | Hendershot | Jun 1998 | A |
6668412 | Tadros | Dec 2003 | B1 |
6668507 | Blanchet | Dec 2003 | B2 |
8011147 | Hanlan | Sep 2011 | B2 |
8468766 | Keenan | Jun 2013 | B1 |
8499511 | Platt | Aug 2013 | B2 |
20010008319 | Kistner | Jul 2001 | A1 |
20020069602 | Blanchet | Jun 2002 | A1 |
20020083991 | Sorkin | Jul 2002 | A1 |
20030061672 | Eustace | Apr 2003 | A1 |
20040107660 | Moreau | Jun 2004 | A1 |
20060075707 | Cretti | Apr 2006 | A1 |
20080016805 | Walter | Jan 2008 | A1 |
20080092466 | Zirbel | Apr 2008 | A1 |
20080134598 | Rizzuto | Jun 2008 | A1 |
20090188194 | Williams | Jul 2009 | A1 |
20110113714 | Hsu | May 2011 | A1 |
20150275499 | Lubberts | Oct 2015 | A1 |
Number | Date | Country | |
---|---|---|---|
20200131754 A1 | Apr 2020 | US |
Number | Date | Country | |
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Parent | 15901042 | Feb 2018 | US |
Child | 16683495 | US |