1. Field of the Invention
The present invention relates to precast composite floor systems.
2. Related Technology
Precast concrete construction is often used for commercial and industrial buildings, as well as some larger residential buildings such as apartment complexes. Precast construction has several advantages, such as more rapid erection of a building, good quality control, and allowing a majority of the building structural members to be precast. Conventional precast structures, however, suffer from several disadvantages, such as being heavy and requiring complex connections between precast members and to the rest of the building structure.
Currently, precast single tee and double tee panels are used for constructing floors. The precast single and double tees are typically eight feet wide and often between 25 and 40 feet long or longer. The single tee sections typically have a deck surface about 1.5 to 2 inches thick and a beam portion extending down from the deck surface along the longitudinal center of the deck. The beam is usually about 8 inches thick and about 24 inches tall.
Double tee panels usually have a deck surface which is about 2 inches thick and have two beams extending down from the deck. The beams are placed about four feet apart running down the length of the panel, and are about 6 inches thick and 24 inches tall. Often, after the single and double tee panels are installed, about 2 or 3 inches of concrete is placed on top of the panels.
Single and double tee panels can be heavy. Heavy floor panels can require heavier columns and beams (i.e., columns and beams with increased strength and structural integral) to support the floor panels and so on, increasing the weight of nearly every structural part of the building structure. Heavier structural elements often use more materials and are thus more expensive, require increased lateral and vertical support, and may limit the height of the building for a particular soil load bearing capacity.
A composite floor panel includes a concrete floor deck having a side portion and an edge member secured to the side portion. The edge member is configured to be positioned in proximity to an adjacent edge member. The adjacent edge member is coupled to an adjacent concrete floor deck. The edge member is further configured to have a junction formed between the edge member and the adjacent edge member to define a channel. The edge member is further configured to have a binder material placed in the channel to form a joint between the concrete floor deck and the adjacent concrete floor deck.
A method of forming a precast structural floor system may include precasting a first composite floor panel having a floor deck, precasting a second composite floor panel, securing a second edge angle of the first composite floor panel to a first edge angle of the second composite floor panel to define a channel therebetween, and placing a binder material in the channel.
This Summary is provided to introduce a selection of concepts in a simplified form that are further described below in the Detailed Description. This Summary is not intended to identify key features or essential characteristics of the claimed subject matter, nor is it intended to be used as an aid in determining the scope of the claimed subject matter.
Various embodiments of the present invention are shown and described in reference to the numbered drawings wherein:
It will be appreciated that the drawings are illustrative and not limiting of the scope of the invention which is defined by the appended claims. The embodiments shown accomplish various aspects and objects of the invention. It is appreciated that it is not possible to clearly show each element and aspect of the invention in a single figure, and as such, multiple figures are presented to separately illustrate the various details of the invention in greater clarity. Similarly, not every embodiment need accomplish all advantages of the present invention.
Exemplary precast structural flooring systems, composite flooring panels, composite girders, joints and methods for forming each will now be discussed in reference to the numerals provided therein so as to enable one skilled in the art to practice the present invention. The drawings and descriptions are exemplary of various aspects of the examples disclosed and are not intended to narrow the scope of the appended claims.
The examples disclosed below may reduce the weight of a flooring system compared to a conventional system. For example, a conventional concrete double tee system with similar spans and loading conditions would weigh approximately 100% more per square foot than examples disclosed herein. Other structural members such as concrete girders and concrete columns that are used with double tee systems are also much heavier than columns used with the present invention. Increased weight of the double tee floor system necessitates larger footings and foundation walls. This is restrictive for taller structures and for construction in areas with poor soil bearing capacity.
The vertical legs or walls of a double tee floor panel are solid and will not allow for passage of mechanical, plumbing or electrical through the tee, thereby increasing the floor to floor dimension because all of the utilities need to be run below the floor structure. Openings in the stem wall of the present system allow the mechanical, electrical and plumbing to pass through the structure, thereby eliminating the need to run these elements below the floor structure.
The present system also allows for greater flexibility in locating slab penetrations (openings through the floor slab) because the beams are spaced farther apart, typically 8 feet on center versus 4 or 5 feet for the legs of a double tee system.
Double tee systems are assembled by weld plates embedded in each component and must bear on concrete or masonry structures. The current system is bolted into a lighter steel structure which makes it possible to use in mid to high-rise construction.
Conventional steel and concrete composite construction also has several problems which are alleviated by the present invention. Conventional composite floor framing is very labor intensive on site. After installation of the columns for a conventionally framed floor, the rest of the materials for the conventional system are installed individually, and include the girders, joists, metal deck, nelson studs, reinforcing, edge enclosures, and poured concrete. This assembly takes much longer than the present invention due to the precast nature of the present system. With the present invention, tradesmen are able to occupy the floor to complete construction in a much shorter time frame which means shortened overall construction time.
Because of the way the calculations are performed for a conventional composite floor, the concrete that is below the top of the flute in the decking is not used in the composite section, but still contributes to the weight of the concrete in the building and the cost for that material. By precasting the floor panels, the present system has eliminated the need for the metal deck. This eliminates the material and the labor required to weld the steel deck in place.
In normal steel construction, the controlling factor over the size of the steel members is the necessity of the steel framing members to carry the full weight of the wet concrete without any of the concrete strength. In the present invention, the steel beams will be completely shored by the forms while the concrete is wet. This by itself reduces the size of the steel beam and eliminates the need for precambering the beam since the beams aren't required to support the weight of the wet concrete.
Additionally, in normal steel construction the beams are aligned so that the tops of the girders and joists are flush. This is done because the metal deck is placed on the joists and girders and the deck is used as a form for the concrete slab. When calculating the section properties for this system, the distance from the top of the steel beam to the middle of the concrete is one of the biggest factors. The present invention places a concrete stem wall between the steel beam and the concrete slab and removes the steel deck, thereby increasing the distance from the top of the steel beam to the centerline of the concrete slab and creating a composite section. As such, the load-bearing strength and span capabilities of the precast panel system are greatly increased. The present floor system eliminates a significant amount of steel and concrete material as compared to a conventional poured-in-place system.
In describing the precast structural floor system of the present invention, multiple views of the floor panel and girder are shown, including views of the parts thereof and cross-sectional views showing the internal construction thereof. Not every structure of the panel or girder is labeled or discussed with respect to every figure for clarity, but are understood to be part of the panel or girder.
As illustrated in
As illustrated in
As illustrated in
In the illustrated example, the concrete slab 210 may be supported by, connected to, and/or integrally formed with the concrete stem wall 230. In particular, the stem wall 230 may extend downwardly and away from the lower surface 212B of the concrete slab 210. The stem wall 230 may include a plurality of stem supports 232 with openings 234 (also referred to as blockouts) defined in the concrete stem wall 230 between the stem supports 232. The openings 234 may reduce the amount of concrete utilized in the stem wall 230 relative to a continuous support, which in turn may reduce the dead load of the composite floor panel 200. In such a configuration, the stem supports 232 provide the structure to transfer shear loads between the concrete slab 210 and the steel panel beam 240. Further, the openings 234 may provide a convenient space to run HVAC ducts, piping and electrical conduit.
In at least one example, the concrete stem wall 230 also includes a plurality of ridges 236 that span the openings 234 between the stem supports 232. The ridges 236 may be in contact with and/or integrally formed with the lower surface 212B of the concrete slab 210 as desired. In at least one example, the ridges 236 may have a thickness that is approximately 50 percent of the thickness of the concrete slab 210. Accordingly, the concrete stem wall 230 may vary in thickness along the interface between the stem wall 230 and the concrete slab 210.
The concrete stem wall 230 is also connected to the steel panel beam 240. The concrete stem wall 230 may be connected to the steel panel beam 240 in any suitable manner, such as by welded studs and/or rebar. In the illustrated example, the steel panel beam 240 includes an I-Beam configuration. Accordingly, the steel panel beam 240 may include an upper flange 242, a lower flange 244, and a web 246 between the upper flange 242 and the lower flange 244. In the illustrated example, the upper flange 242 supports the stem supports 232.
The steel panel beam 240 may also serve as a base for the braces 250 to provide additional support for the I-Beam and reduce vibration in the concrete slab. In the illustrated example, the braces 250 may include a lower end 252 secured to the web 246 and/or the lower flange 244. An upper end 254 of the braces 250 may be secured to the weld plates 219 embedded in the concrete slab 210. Such a configuration can allow the steel panel beam 240 to support the concrete slab 210 by way of the concrete stem wall 230 as well as the braces 250. The concrete slab 210, the concrete stem wall 230, the openings 234, and the steel panel beam 240 can have any desired dimensions.
In at least one example, the concrete slab 210 is about eight feet wide, between about five and 40 feet long, and about three inches thick. The concrete stem wall 230 may be between, but not limited to, 12 and 36 inches in height. The openings 234 in the concrete stem wall 230 may be located adjacent the concrete stem wall 230, and may occupy the entire height of the concrete stem wall 230 as desired. Further, in at least one example, a 24 inch concrete stem wall 230 can be provided in which the openings 234 may be about 24 inches wide and 24 inches tall while the stem supports 232 may be approximately twelve inches wide and be placed between the openings. In at least one example, the steel panel beam 240 may be about twelve inches high overall. Further, the upper flange 242 and/or the lower flange 244 may be between about four and eight inches wide.
In general, when a beam supported at both ends is loaded the top half of the beam is under compression while the bottom half of the beam is under tension. Concrete has relatively high compressive strength but relatively low tensile strength, while steel has high tensile and compressive strength. Steel beams, however, may be expensive relative to concrete. In the example composite floor panel 200, the relative position of the concrete slab 210 causes the concrete slab 210 to be under compression while the relative position of the steel panel beam 240 may cause the steel panel beam 240 to be under tension. As a result, the configuration of materials of the composite floor panel 200 may utilize the best structural properties of concrete while optimizing the use of relatively expensive structural steel components.
Further, the configuration of the composite floor panel 200 allows them to be quickly installed at a building site. As will be discussed in more detail below, the composite floor panels 200 can be precast at a separate location as desired, brought to the building site, and lowered into place through the use of a crane. Once in place, the joint 220 may be formed between composite floor panels 200, 200′ using binder materials, such as grout, reinforcing materials; such as welded wire mesh, anchors, shear studs and/or other reinforcing materials and fastening procedures such as welding or bolting.
As shown in
With continuing reference to
The concrete stem wall 330 can be coupled to or supported by the flange beam 340 in any desired manner. In the illustrated example, the flange beam 340 may include an upper flange 342, a lower flange 344, and a web 346 that extends between the upper flange 342 and the lower flange 344. The upper flange 342 may be configured to support the concrete stem wall 330.
A saddle 360 may be fastened to the flange beam 340 to provide support for the steel panel beam 240. Accordingly, the composite girder 300 is configured to provide support for the composite floor panels 200, 200′. The configuration and interaction of the saddle 360 will be described in more detail below in connection with the description of the joint 320 formed between the composite girder 300 and the composite floor panel 200 after a discussion of the joint 220 between adjacent composite floor panels 200, 200′.
The configuration of the example joint 220 will now be discussed in more detail.
When a junction, such as a weld 290, is formed that connects the edge members 218A, 218B, and the transverse portions 215A, 215B in particular, a channel is formed between the edge members 218A, 218B. In the illustrated example, anchors 221 may be secured to the edge members 218A, 218B. The anchors 221 may also be embedded within the concrete slab 210. In at least one example, the anchors 221 are shear studs or other similar types of anchors. In the illustrated example, the edge members 218A, 218B are generally L-shaped to thereby define a generally vertical portion and a generally horizontal portion. It will be appreciated that other configurations are possible, including an inverted T-configuration or any other configuration desired.
The joint 220 also includes binder material 222, such as high strength and/or non-shrink grout. In the illustrated example, various reinforcements are embedded in the binder material 222. These reinforcements may include welded wire mesh 224 and/or reinforcements 226A, 226B.
In at least one example, the reinforcement 226A is embedded in the side 214A of the concrete slab 210 and extends through the edge member 218A into the binder material 222. Similarly, the reinforcement 226B may be anchored in the side 214B of the concrete slab 210 and extend through the edge member 218B into the binder material 222.
In the illustrated example, the second portions 228A, 228B are generally oriented parallel to the edge members 218B, 218A respectively. Further, the second portions 228A, 228B may be oriented to face each other. In addition, the first portions 227A, 227B may extend sufficiently into the binder material 222 to result in overlap of the first portions 227A, 227B within the binder material 222. The configuration of the reinforcements 226A, 226B can allow for rapid formation of the joint 220 as the composite floor panels 200, 200′ (
As illustrated in
As particularly shown in
Another aspect of the joint 320 is also shown in
Reinforcements 382 may also be embedded within the concrete stem wall 330. The reinforcements 382 may extend into the recess 352. As a result, when the binder material 380 is placed in the recess 352, the anchors 283 as well as the reinforcements 382 may be embedded within the binder material 380. Further, additional reinforcements, such as welded wire mesh 384, may also be embedded within the binder material 380.
In at least one example, the binder material 380 may include a grout material, such as a non-shrink grout material. Accordingly, the joint 320 may be formed with several aspects that secure the composite floor panel 200 to the composite girder 300. The joint 320 between the composite floor panel 200 and the composite girder 300 as well as the joint 220 (
The steel panel beam 240 may then be placed upright so as to rest on the lower flange 244. Nelson studs 400 or similar connectors are then welded to the top side of the upper flange 242. Spacing of the Nelson studs 400 is per approved shop drawings at intervals less than or equal to the maximum spacing allowed by prevailing building codes. Vertical L-shaped reinforcing bars 410 may then be welded into place adjacent to the Nelson studs 400 which were previously welded to the upper flange 242 of the beam. The vertical reinforcing bars 410 may project upward from the upper flange 242 and then turn 90 degrees to thereby define short legs 412 and long legs 414. In such a configuration, the short legs 412 of the L-shaped reinforcing bars 410 run horizontally and perpendicular to a longitudinal axis 248 of the steel panel beam 240. The vertical reinforcing bars 410 are spaced according to the shop drawings approved by the engineer of record, typically with one vertical reinforcing bar 410 per every Nelson stud 400.
Lifting loops 420 made from reinforcing bar or other similar steel bar which have been bent into u-shapes may also be secured to the upper flange 242 of the steel panel beam 240 between the vertical reinforcing bars 410 where concrete will be poured to surround the lifting loops 420 and vertical reinforcing bars 410, leaving the tops of the lifting loops uncovered by concrete for lifting with a crane. The length of the lifting loops 420 may be approximately 0.25″ less than the distance from the top side of the upper flange 242 to the top surface of the finished concrete slab 210 (
The assembled steel panel beam 240, with the vertical L-shaped reinforcing bar 410 and the lifting loops 420 secured thereto, is then moved to a floor-mounted jig (not shown) to hold the components steady while horizontal slab reinforcements 430, 440 are secured in place. In particular, the reinforcing bars 430 may be oriented parallel to the longitudinal axis 248 of the steel panel beam 240. The reinforcing bars 430 may be tied into place using standard tie wire to the horizontal legs 412 of the L-shaped reinforcing bars 410 or in any other suitable manner.
Reinforcing bars 440, which may be oriented perpendicular to the longitudinal axis 248 of the steel panel beam 240, may then be tied to the previously installed reinforcing bars 430. In at least one example, the reinforcing bars 430, 440 may be cut to a length about two inches shorter than the overall length or width of final concrete slab 210 (
Blockout forms 450 may be secured to the upper flange 242 at any desired point during the formation process. In at least one example, the blockout forms 450 may be formed of metallic material secured to the steel panel beam 240. In particular, the blockout forms 450 may be formed of steel plates that are bent to a desired shape. The blockout forms 450 may be secured to the steel panel beam 240 in any desired manner, such as by welding, magnets, fasteners such as bolt, and/or clips.
In another example, the blockout forms 450 may be made using a variety of materials, including but not limited to, styrene foam, rubber, wood and steel. In the case that the blockout forms 450 are formed of styrene foam blocks, the blockout forms 450 may be secured to the steel panel beam 240 by use of an adhesive, such as tape or glue. The blockout forms 450 may also be coated in form release oil or silicone to prevent the blockout forms 450 from bonding to the concrete of the concrete stem wall 230 (
The resulting assembly may then be placed into a form 460, as illustrated in
The form 460 may be sprayed with form release oil prior to placing the components in the form 460 as desired. In at least one example, forms 460 may be formed of steel. The structure of the forms 460 can vary in length and width as well as construction so long as the inside shape of the form is the correct profile for the finished concrete portion of the composite floor panel 200 (
The edge members 218A, 218B, weld plates 219, reinforcements 227A, 227B, anchors 221, and other desired reinforcements are positioned in the form 460 and secured by tie wire or small bolts and held in position until the concrete has cured sufficiently. Though not shown, the other edge angles 280A, 280B, reinforcements 272, and anchors 282, 283 as well as the weld plate shown in
Rebar chairs (not shown) may be placed under the reinforcing bars 430, 440 to maintain a desired separation between the lower surface 212B (
Concrete (not shown) is placed in the forms in a manner to ensure that all reinforcing bars 430, 440 are sufficiently covered to thereby form the concrete slab 210 and concrete stem wall 230 (both seen in
The braces 250 shown in
The flange beam 340 may then be oriented to rest on the lower flange 344. Nelson studs 500 or similar connectors may then be secured to an upper surface of the upper flange 342. Spacing of the Nelson studs 500 is per approved shop drawings at intervals less than or equal to the maximum spacing allowed by prevailing building codes. Vertical L-shaped reinforcing bars 510 may then secured to the upper flange 342 into place. In at least one example, the L-shaped reinforcing bars 510 are positioned adjacent to Nelson studs 500 which were previously secured to the upper flange 342 of the flange beam 340.
In at least one example, the L-shaped reinforcing bar 510 projects upward from the upper flange 342 of the composite girder 300 and then turns ninety degrees to project horizontally and perpendicular to the longitudinal axis 348 of the flange beam 340. As a result, the L-shaped reinforcing bars 510 include a short leg 512 and a long leg 514. The L-shaped reinforcing bars 510 may be spaced according to the shop drawings approved by the engineer of record, typically with one L-shaped reinforcing bar 510 per every Nelson stud 500.
Lifting loops 520, such as reinforcing bar which has been bent into a u-shape, are also secured to the upper flange 342 of the flange beam 340. The length of the lifting loops 520 may be approximately 0.25″ less than the distance from an upper surface of the upper flange 342 of the beam to a top surface of the completed concrete stem wall 330 (
The flange beam 340 with the lifting loops 520 and the L-shaped reinforcing bars 510, is then moved to a floor-mounted jig (not shown) to hold it steady. Reinforcing bars 530, which may be oriented generally parallel to the longitudinal axis 348 of the flange beam 340, may be tied to the short legs 512 of the L-shaped reinforcing bars 510. Reinforcing bars 540, which may be oriented generally perpendicular to the longitudinal axis 348 of the flange beam 340, may then be positioned on the reinforcing bars 530 and tied into place. In at least one example, the reinforcing bars 530 may be tied in place using 16 gauge tie wire.
Blockout forms 550 may be secured to the upper flange 342 at any desired point during the formation process. In at least one example, the blockout forms 550 may be formed of metallic material secured to the flange beam 340. In particular, the blockout forms 550 may be formed of steel plates that are bent to a desired shape. The blockout forms 550 may be secured to the flange beam 340 in any desired manner, such as by welding, magnets, fasteners such as bolts, and/or clips.
In another example, the blockout forms 550 may be formed of a foam material that are secured to the upper flange 342 of the flange beam 340, such as by adhesives such as glue and/or tape. The flange beam 340 with the reinforcements described above are then placed into a form 560 as shown in
Concrete is placed in the form 560 in a manner to ensure that all the reinforcing bars 510, 530, 540 are sufficiently covered, typically leaving the tops of the lifting loops 520 not covered in concrete. One or more of the surfaces may then be finished to industry standards for concrete floors. The resulting girder may be cured by industry accepted methods. Once the concrete has cured sufficiently the composite girder 300 is lifted out of the form 560 by the lifting loops 520.
The forms 560 may have any configuration. In at least one example, the form 560 are formed from a metallic material, such as steel. Further, the structure of the form 560 can have any inside shape to provide a desired profile for the finished composite girder 300. The forms may also be of sufficient strength to allow for numerous repetitive uses while maintaining the correct shape and configuration.
The saddles 360 described above (
Once the composite girders 300 and the composite floor panels are completed, the precast structural floor system 100 as shown in
Once the composite girders 300 are in place, the composite floor panels 200, 200′, 200″ may be installed. In at least one example, the composite floor panel 200 may be positioned by a crane via a cable secured to the lifting loops 420 (
As illustrated in
Similarly, the joint 320 between the composite floor panel 200 and the composite girder 300 may also be formed rapidly. In particular, once the composite floor panel 200 is positioned relative to the composite girder 300 as described above and as shown in
While example joints 220 between composite floor panels 200 and between composite floor panels 200 and composite girder 300 have been described, it will be appreciated that other configurations are possible. For example,
For example, in
In addition, a joint 710 may be between the composite floor panel 200, the composite girder 300, and an opposing composite floor panel 200″ in addition to between a composite floor panel 200 and the composite girder 300 as previously described, as shown in
Further,
As illustrated in
In at least one example, the supports 830A-830H are oriented such that the supports 830A-830H are positioned in a common plane as shown more clearly in
As also shown in
The supports 835A-835H can be secured to the base plate 825 in any suitable manner at any number of desired locations. In at least one example, the supports 835A-835H are secured to the base plate 825 in such a manner that connections of the supports 835A-835H and the base plate 825 lie in a line on the base plate 825. In at least one example, the connections between the base plate 825 and the supports 835A-835H and the connections between the base plate 825 and the supports 830A-830H all lie in a common plane on the base plate 825. It will be appreciated that other configurations are also possible.
In addition, one or more of the supports 830A-830H of the first set of lateral support members 815 can be joined at substantially the same location on the base plate 825 as one or more of the supports 835A-835H of the second set of lateral support members 820. In particular, as shown in
As shown in
According to one embodiment of the invention, the first and second sets of lateral support members 815, 820 can be secured to the concrete portion 810 so as to have substantially similar distances between first ends of adjacent supports. For example, in one embodiment, the distance between the first end of support 830A and the first end of support 835A is substantially equal to the distance between the first end of support 830A and the first end of support 830B, which can be substantially equal to the distance between the first end of support 835A and the first end of support 835B, which can be substantially the same distance between the first end of support 830B and the first end of support 830C, and so forth. In another embodiment, the distance between the first end of support 830B and the first end of support 830C is substantially equal to the distance between the first end of support 835B and the first end of support 835C.
As also shown in
In at least one example, the supports 830A-830H, 835A-835H, can be formed of a high-strength material, such as steel. For example, the supports 830A-830H, 835A-835H, can be formed from rolled steel angle members and/or heavy gauge bent shapes. The girder connection plates 846-849 can also be formed of a high-strength material, such as steel, including rolled steel angle members and/or heavy gauge bent shapes.
In at least one example, the base plate 825 can be a steel plate with a thickness of between about ⅜ inch and about ⅝ inch or more. Further, as shown in
As shown in the illustrated embodiment, a girder connection plate 851 is provided which can be secured to end support 850A, and another girder connection plate 852 is provided which can be secured to a similar end support 850B positioned on the opposing end of the composite floor panel 800. In the illustrated example, the girder connection plate 851 is positioned beneath the end edge 840 of the concrete portion while girder connection 852 is positioned beneath the opposing end edge 845 of the concrete portion 810. Such configuration can allow the girder connection plates 851, 852 to thereby support opposing ends of the concrete portion 810. Referring again briefly to
Support members 815 can be positioned in a corresponding manner with the position of support members 820, such that adjacent supports can share a common plane. For example,
As shown in
Referring again to
As shown particularly in
In at least one example, the foam insulation form 895 can have a shape that is the negative or inverse of the concrete portion 810, including any desired part of the concrete slab 860 and/or the first and second beam portions 865A, 865B. Such a configuration can also provide a layer of floor insulation for both sound and temperature. Further, the foam insulation form 895 can also be used to house and otherwise preinstall a radiant floor heating and cooling system as desired. The foam insulation form 895 can be provided separately or can be used during the formation of the concrete slab 860 and the first and second beam portions 865A, 865B. One exemplary method of forming the composite floor panel 800 will now be discussed in more detail. Though various steps will be described in an exemplary order, it will be appreciated that the steps described below can be performed in a different order and some steps can be omitted entirely as appropriate or desired. Further, steps can be combined and/or split as desired.
Referring collectively to
After supports 815, 820 and end supports 850A, 850B are secured to base plate 825, the foam insulation form 895 is then positioned relative to the supports 830A-830H, 835A-835H, 850A, 850B. The foam insulation form 895 can be supported in any suitable manner to maintain the foam insulation form 895 at a desired position and orientation relative to the base plate 825 and the supports 830A-830H, 835A-835H, 850A-850B.
Though not shown, reinforcements such as nelson studs, reinforcing rebar, shear studs, and any other reinforcement and/or intermediate supports can be positioned as desired relative to the foam insulation form 895. The reinforcements and/or intermediate members can be secured to each other and maintained in their position relative to the foam insulation form 895 in any manner desired, including through the use of wire, rebar chairs, and/or any other components as desired. In at least one example, lifting loops can also be provided as desired. Such reinforcements can also be used to tie the first ends of supports 815, 820, 850A, 850B together or to simply position the first ends of supports 815, 820, 850A, 850B in appropriate positions with respect to each other.
In one embodiment, securing the first ends of the supports 815, 820, 850A, 850B to the concrete portion 810 can include forming a beam around at least a portion of the first end of a support. In an alternative embodiment, securing the first end of a support to the concrete portion can include securing at least a portion of the first end of the support to a reinforcement member, such as rebar or a metal plate or some other type of fixture designed to be enclosed within the beam. In this manner, the support is coupled or otherwise connected to the beam and ultimately to the concrete portion.
Thereafter, the first and second beam portions 865A, 865B and at least a portion of the concrete slab 860 can be formed by pouring concrete into the foam insulation form 895. Thereafter, the concrete can be cured and the composite floor panel 800 can be ready for assembly with other composite floor panels 200 to form a precast structural floor system 900 (
Accordingly, as shown in
In particular, the edge angles 880A, 880B may be secured together in any suitable manner, including those described above. Binder material 890 may then be introduced between the edge angles 880A, 880B to form a joint 892. Further, though not illustrated in
Accordingly, the composite floor panel 800′ can be similar to the composite floor panel 800 described above except that an arch 1000 is formed in the concrete slab 860′ between first and second beam portions 865A′, 865B′. Such a configuration can provide a smooth transition between the first and second beam portions 865A′, 865B′, which can reduce stress risers within the concrete slab 860′ by reducing sharp corners.
The present invention may be embodied in other specific forms without departing from its spirit or essential characteristics. The described embodiments are to be considered in all respects only as illustrative and not restrictive. The scope of the invention is, therefore, indicated by the appended claims rather than by the foregoing description. All changes which come within the meaning and range of equivalency of the claims are to be embraced within their scope.
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