The present application relates to the general art of structural, bridge and geotechnical engineering, and to the particular field of foundations for culverts, buried bridges other structures.
Buried bridge structures are frequently formed of precast or cast-in-place reinforced concrete and are used in the case of bridges to support a first pathway over a second pathway, which can be a waterway, a traffic route, or in the case of other structures, a storage space or the like. The term “buried bridge” will be understood from the teaching of the present disclosure, and in general as used herein, a buried bridge is a bridge formed of a bridge element or elements that rest on a foundation and has soil or the like resting thereon and thereabout to support and stabilize the structure and in the case of a bridge provide the surface of the first pathway.
In the past the bridge elements of overfilled bridge structures have been constructed to rest on prepared foundations at the bottom of both sides of the structure. Fill material, at the sides of the arch (backfill material) serves to diminish the outward displacements of the structure when the structure is loaded from above. The foundations previously used have typically been cast-in-place, requiring significant on-site preparation and manufacturing time and labor, and potential inconsistencies in quality control, making foundation preparation a very weather effected step of the construction process.
The foundation system of U.S. Pat. No. 8,789,337 solves many of the problems with such prior foundation systems by utilizing foundation structures that are formed by a combination of precast concrete and cast-in-place concrete. However, the precast concrete foundation units of such patent are heavy and can create labor-intensive manufacturing and shipping difficulties.
It would be desirable to improve upon the combination foundations described in U.S. Pat. No. 8,789,337 by providing a more readily transportable foundation unit.
As used herein the term “cast-in-place” or “cast-in-place concrete” as used in reference to a structure or portion of a structure means that the concrete of the structure or portion of the structure was poured and cured at the installation/use location of the structure or portion of the structure.
As used herein the term “concrete” means traditional concrete as well as variations such as concrete formulas with plastics/polymers or resins incorporated therein or with fibers or other materials incorporated therein.
As used herein the terminology “bridge element” or “bridge structure” is intended to encompass structures that have spaced apart bottom sides or walls and one or more raised wall or walls spanning therebetween, it being understood that the geometry could vary (e.g., entirely curved, or some linear sections and some curved section or all linear sections) and the material could vary (e.g., metal, concrete etc.), which encompasses structures commonly referred to as either culverts and bridges in the art.
In a first aspect, a metal foundation unit for use in constructing a combination metal and cast-in-place concrete foundation structure is provided. The metal foundation unit includes a first elongated upright metal wall member and a second elongated upright metal wall member spaced apart from the first elongated upright wall member to define a channel therebetween, and multiple upright metal supports located within the channel. Each of the multiple upright metal supports extends laterally between the first elongated upright metal wall member and the second elongated upright metal wall member to (i) define multiple spaced apart cells along a length of the channel and (ii) rigidly connect the first elongated upright metal wall member to the second elongated upright metal wall member. Each of the multiple cells is open at the topA receiving slot (e.g., a keyway) is located atop each of the multiple upright metal supports. At least some of the multiple upright metal supports include at least one flow opening extending from cell to cell for permitting cast-in-place concrete to flow from one cell through the upright metal support to another cell during concrete pouring and multiple reinforcement openings through which elongated reinforcement can be passed from cell to cell prior to concrete pouring.
In another aspect, a bridge system includes first and second combination metal-frame and cast-in-place concrete foundation structures. The first combination metal-frame and cast-in-place concrete foundation structure includes: a first metal-frame foundation unit having an inner elongated upright metal plate wall and an outer elongated upright metal plate wall spaced apart from the inner elongated upright metal plate wall to define a channel therebetween, and multiple upright metal plate supports located within the channel and extending between and connecting the inner and outer elongated upright metal plate walls; and cast-in-place concrete within the channel of the first metal-frame foundation unit and tied to each of the inner and outer elongated upright metal plate walls at least by surface contact therewith and by substantial embedment of each of the upright metal plate supports. The second combination metal-frame and cast-in-place concrete foundation structure is spaced apart from the first combination metal-frame and cast-in-place concrete foundation structure and extends substantially parallel thereto. The second combination metal-frame and cast-in-place concrete foundation structure includes: a second metal-frame foundation unit having an inner elongated upright metal plate wall and an outer elongated upright metal plate wall spaced apart from the inner elongated upright metal plate wall to define a channel therebetween, and multiple upright metal plate supports located within the channel and extending between and connecting the inner and outer elongated upright metal plate walls; and cast-in-place concrete within the channel of the second metal-frame foundation unit and tied to each of the inner and outer elongated upright metal plate walls at least by surface contact therewith and by substantial embedment of each of the upright metal plate supports. A metal span bridge structure has spaced apart first and second sidewalls and an interconnecting top wall. A bottom portion of the first sidewall is supported by the first combination metal-frame and cast-in-place concrete foundation structure and at least partly embedded in the cast-in-place concrete of the first combination metal-frame and cast-in-place concrete foundation structure, and a bottom portion of the second sidewall supported by the second combination metal-frame and cast-in-place concrete foundation structure and at least partly embedded in the cast-in-place concrete of the second combination metal-frame and cast-in-place concrete foundation structure.
In a further aspect, a method of constructing a combination metal-frame and cast-in-place concrete foundation structure involves: receiving at a construction site a first metal-frame foundation unit having a first elongated upright wall member and a second elongated upright wall member spaced apart from the first elongated upright wall member to define a channel therebetween, and multiple upright supports located within the channel; placing the first metal-frame foundation unit at a desired use location of the construction site; delivering concrete into the channel of the first metal-frame foundation unit while the first metal-frame foundation unit remains at the desired use location; and allowing the concrete to cure-in-place such that each of the first and second elongated upright wall members are connected to the cured-in-place concrete by surface contact with the concrete and by substantial embedment of the upright supports in the concrete.
Referring to
As best seen with reference to
Each of the multiple cells 26 is open at both the top and the bottom, and a receiving slot 28 is located atop each of the multiple upright metal plate supports 24. The upright metal plate supports 24 include at least one flow opening 30 extending from cell to cell for permitting cast-in-place concrete to flow from one cell through the upright metal support to another cell during concrete pouring and multiple reinforcement openings 32 through which elongated reinforcement can be passed from cell to cell prior to concrete pouring, as will be described in further detail below.
Generally, the upright metal supports 24 may be connected to the upright walls 20 in any suitable manner (e.g., welding, rivets, nuts and bolts etc.) that provides sufficient rigidity and strength to the metal-frame foundation unit. In the illustrated embodiment, each upright metal support 24 has ends fixed (e.g., by welding) to respective brackets 34 mounted (e.g., welded) at the interior sides of the upright metal walls 20. Here, each bracket is an angle member with one flange 36 seated against the interior side of the wall 20 and one flange 38 seated against one side of the support 24.
In the illustrated embodiment, the receiving slots 28 are formed by a cut-out at the top of the metal plate. A lower support surface 40 of each receiving slot 28 is defined at least in part by a bracket 42 fixed (e.g., bolted or welded) to a side of the metal plate support 24. Each bracket 42 includes an upright mounting flange 44 adjacent metal plate and a support flange 46 extending laterally from the mounting flange to at least in part define the lower support surface 40.
Each of the metal plate walls 20 includes a bottom bend 50 forming a lateral ground surface seating flange 52. The seating flange 52 helps support the metal-frame foundation unit against sinking into the ground during installation. The bend 50 also provides additional overall rigidity to the overall metal-frame foundation unit structure. Here, each lateral ground surface seating flange 52 is located within the channel 22. In alternative embodiments the bends could be outward to place the seating flanges 52 exterior of the channel. In addition, the flanges could be sized larger, such as to abut or overlap and effectively close the bottom of the channel. A separate bottom panel could also be connected between the bottoms of the metal plate walls to close the bottom of the channel.
A plurality of stabilizing members 60 are located at the bottom of the metal foundation unit for inhibiting sliding movement of the metal foundation unit on a ground surface (e.g., during backfill and/or concrete pouring). Generally, the stabilizing members may take any suitable configuration, such as a stake opening in a portion of metal plate that is either internal of the channel or external of the channel and/or a downwardly projecting metal member at the bottom of the metal foundation unit and that is either internal of the channel or external of the channel. In the illustrated embodiment, the stabilizing members 60 are formed by a plurality of metal straps 62 extending laterally across the bottom of the channel 22 and below the metal plate walls 20. The straps 62 may be welded or otherwise fixed to the wall seating flanges 52. Each metal strap includes end portions 64 exterior of the channel 22 and having a respective stake opening 66 through which a stake or spike can be driven into the ground when the metal-frame foundation unit is properly positioned on-site for install.
As seen in
In some cases the foundation structure needed at a given installation site may be short enough to permit the use of a single metal-frame foundation unit at each side of the bridge installation, in which case the foundation unit will typically include closed metal plate end walls 80 at the ends of the unit to retain concrete in the channel during the on-site pour.
In other cases the foundation structure needed at a given installation site may require two of more metal-frame foundation units 16 to be connected end to end as shown in
The metal-frame foundation units are shipped to and received at a construction site. In use, a final use/installation site is prepared to receive the metal-frame foundation units by excavating to the desired elevation in a smaller area than traditional methods and preparing a level subsurface which may include additional backfill materials on which to install the units.
Once the site is prepared to receive the metal-frame foundation units 16, the units are placed to form two spaced apart foundation structures 12. Once the metal-frame foundation units 16 are set in desired positions (with or without the use of stakes or spikes 88), the reinforcement can be manually placed and/or adjusted if needed (i.e., in cases where the reinforcement was not incorporated prior to shipping to the job site) and the bridge structure 10 placed (as a single unit or by interconnecting multiple pieces) atop the metal-plate supports 24. In this regard, as shown in
While embedment of the bottom ends of the bridge structure is contemplated, in some instances the concrete may be poured in the U-shaped foundation prior to the bridge being set in place.
With respect to lengthwise reinforcement 70, support for such reinforcement within the openings 32 of the metal plate supports 24 may be provided. In this regard, reference is made to
The spacing gusset 110 includes an outer flange 120 with one face 122 that is substantially planar so as to seat flushly against one face 25 of the metal support plate 24 when the gusset is installed. A plurality of circumferentially spaced latching fingers 124 extend from the outer flange 120, and each finger includes a ramped portion 126 that leads to an outwardly facing lip 128 that faces the seating face 122 of the flange 120. The fingers are sized such that the ramped portions 126 engage the edge of the opening 32 during insertion, causing the fingers to flex slightly until the spacing gusset is fully seated in the opening and the fingers spring back out so that the lips 128 extend out beyond the opening edge and retain the spacing gusset in the opening per the depiction in
The combination metal-frame and cast-in-place concrete foundation structures described herein can be utilized to support bridge structures other than metal plate bridge structures. Moreover, other types of structures could be supported as well. On-site time and expense associated with foundation placement is reduced (e.g., the need for form placement and much of the reinforcement placement is eliminated).
It is to be clearly understood that the above description is intended by way of illustration and example only and is not intended to be taken by way of limitation, and that changes and modifications are possible. For example, the metal foundation units could also be used to establish the foundations for wingwalls of a bridge system. Accordingly, other embodiments are contemplated and modifications and changes could be made without departing from the scope of this application.
Number | Date | Country | |
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62545009 | Aug 2017 | US |