The present invention relates to concrete dowel devices suitable for road construction and, more particularly, to a field-assembly dowel basket assembled from standardized components on an as-needed, where-needed basis.
Concrete dowels are embedded into joints between adjacent slabs of concrete to prevent vertical displacement between the slabs to maintain a smooth pavement surface and increase the strength of the concrete in the region of the joint. While the dowels are provided to prevent excessive vertical displacement between the slabs, they may be designed to allow a small amount of horizontal separation and lateral displacement between the slabs to relieve internal stress to accommodate drying shrinkage and thermal expansion and contraction of the slabs. This permits a normal amount of slab movement to prevent excessive cracking while still maintaining a smooth top surface of the pavement. In road construction, a series of dowels is typically installed at each expansion joint between adjacent sections or slabs of pavement.
In concrete road construction, a long structure known as a dowel basket is often used to hold a line of dowels in place at the edge of a section of pavement before the slab is poured. The basket positions each dowel so that half of the dowels will be embedded in the concrete slab to be poured, with the other half to be embedded in the adjacent slab to be poured next. An expansion joint is typically formed into the joint or cut into the dried concrete above the dowel basket at each expansion joint. The road is thus constructed section after section, and mile after mile, with a line of dowels held in place by a dowel basket embedded into the concrete at each expansion joint.
Constructing a road in this manner requires the dowel baskets to be continually constructed and made available at the construction site as section after section, and mile after mile, of road is poured. In conventional road construction, the dowel baskets are welded together at a welding shop and then transported, typically by truck, to the construction site. For a long road construction project, a series of welding jobbers may be contracted along the route as the road is constructed. Dowel basket fabrication can be a significant logistical challenge and a major cost factor in road construction. At times, dowel basket fabrication may become the critical path item, causing the construction crew to sit idle waiting on dowel basket delivery before road construction project can continue. As a result, there is a persistent need for cost effective solution to dowel basket manufacturing to facilitate concrete road construction.
The present invention meets the needs described above in a field-assembly dowel basket for concrete construction configured for in-the-field assembly from standardized components. This allows a number of standard components, including clips, connectors and wire frame components, to be conveniently transported and stored on construction sites to facilitate on-site assembly of dowel baskets on an as-needed, where-needed basis. Since the dowel basket components are much smaller than assembled baskets, they can be shipped and stored much more cost effectively. Standardization of components allows mass production, consolidates inventory management, and avoids the need for ad hoc fabrication for each construction site. On-site fabrication largely eliminates welding from the dowel basket fabrication process (wire frame clips may involve welding), avoids shipping of fabricated dowel baskets, and allows assembly of dowel basket by construction workers as opposed to highly skilled welding shops.
In view of the foregoing, it will be appreciated that field-assembly concrete dowel baskets represent a significant improvement in concrete construction and, more particularly, in concrete road construction. The foregoing relates only to the exemplary embodiments of the present invention, and that numerous changes may be made therein without departing from the spirit and scope of the invention as defined by the following claims.
Embodiments of the invention may be realized in a field-assembly dowel basket, components for a field-assembly dowel basket, a method for constructing a concrete road or other structure using field-assembly dowel baskets, and a road or other structure constructed with field-assembly dowel baskets. Rather than the conventional approach of fabricating dowel baskets at welding shops and transporting the fabricated dowel baskets to the construction site, embodiments of the present invention provide field-assembly dowel baskets assembled at the construction site from a small number of standard components.
The field-assembly dowel basket uses clips to removably hold the dowels in place within a basket frame constructed from the clips, wire segments and connectors. The dowels, clips, wire segments and connectors can therefore be transported to the construction unassembled, where they are stored in bulk and assembled in the field on an as-needed, where needed basis. Once assembled, the dowel basket is positioned at the edge of a first concrete slab prior to pouring the slab. The dowel basket holds the dowels in place about midway up the thickness of the slab. A concrete form is positioned around the dowels near the centerline of the dowel basket. The first slab is poured so that about half of the dowels extend into the slab and half extend beyond the slab. After the first slap sets, the form is removed and a second slab is poured over the portions of the dowels that extending beyond the first slab. An expansion joint is formed or cut over the dowel basket at the intersection of the two slabs.
In an illustrative embodiment, each field-assembly dowel basket is formed from a number of basket web assemblies that each removably hold two dowels in place. Any number of basket web assemblies can be connected together with “T” clips to form a dowel basket of desired length, which typically extends laterally across the road under construction. Each basket web assembly includes two basket side sub-assemblies spaced apart from each other by the T″ clips and shipping wires. Each side assembly includes two clips and wire segments that removably attach to the clips. The wire segments in each side assembly include two end wires and a frame wire that connects the clips together. Each clip includes two integral sockets built into the clip. Alternatively, separate sockets may removably attach to the clips the wire segments. For example, integral sockets made from bent sheet metal can be formed into sheet metal clips, while separate plastic sockets may be utilized with wire frame clips.
Different types of clips may be provided to receive different types of dowels, such as bar dowels and plate dowels. In alternative embodiments, the clips may support the dowels from above or below. In a particular embodiment, the plate dowel may itself be a sub-assembly formed from steel slats and one or more plastic separators. This configuration provides the plate dowel with some “give” allowing the concrete slabs connected by the dowel to laterally shift slightly with respect to each other without cracking. An illustrative dowel includes two slats and a separator.
In an embodiment, the standardized components include dowels, clips with integral sockets, end wires, frame wires, and “T” connectors. As an option, separate sockets may be provided with wire frame clips or other types of clips that do not include integral sockets. The clips may be manufactured from steel, wire, plastic such as Propylene, PVC or Nylon, or any other suitable material. In a particular embodiment, the clips may be made from sheet metal, such as 24-gauge cold rolled mild or spring steel, with sockets integrally formed by bending the sheet metal to form the sockets. Wire frame clips are also suitable, which may be bent and welded in bulk. The wire segments and wire frame clips (when used) may be manufactured from the type of steel wire typically used in wire mesh for concrete reinforcement. The “T” connectors, separate sockets (when used), and dowel separators may be made from a suitable inexpensive plastic such as Propylene, PVC or Nylon.
While specific dimensions may vary as a matter of design choice, the following dimensions are typical for an illustrative embodiment. The plate dowels are typically 12 inches long, 2 to 2.5 inches wide, and ¼ to ½ inch thick. The bar plate dowels are typically 15 to 18 inches long and ⅜ to ¾ inch in diameter. The dowel-to-dowel spacing is typically 18 to 24 inches. The side-to-side spacing the basket frame is typically 12 inches. The basket frame typically supports the dowels midway in the slab to be poured (e.g., 4 inches for 8 inch thick slab) above the base where the concrete is to be poured. The clips may be ¾ to 1.5 inches wide and made from 12 to 18 gauge sheet metal, such as spring steel. The wire components may be made from ¼ to ⅜ inch diameter concrete reinforcement steel wire. The plastic components may be made from any suitable plastic, such as Polypropylene, PVC, Nylon, or many other options.
The clips of the basket frame may be configured to receive bar dowels or plate dowels, which the clips may support from above or below.
FIG.19 is a logic flow diagram 1900 for constructing a concrete road using the field-assembly dowel baskets.
Step 1906 is followed by step 1907, in which a form is positioned around the dowel basket, as illustrated by the dowel basket and form assembly 200 shown in
After the first concrete slab has set sufficiently, step 1907 is followed by step 1908, in which the form is removed and a second concrete slab is poured over the dowel stubs extending from the first slab. Step 1908 is followed by step 1909, in which an expansion joint is formed or cut into the joint between the slabs above the dowel basket.
Although the field-assembly dowel baskets have been illustrated in the context of horizontal road pavement, it will be appreciated that the dowel basket is well adapted for but not limited to the road construction application and can be used for any concrete joint of sufficient size regardless of its intended purpose or orientation. For example, the invention is equally applicable to joints in concrete sidewalks, building floors, walls, ceilings, abutments and other structures. Those skilled in the art will appreciate that the foregoing describes preferred embodiments of the invention and that many adjustments and alterations will be apparent to those skilled in the art within the spirit and scope of the invention as defined by the appended claims.
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Number | Date | Country | |
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20180195240 A1 | Jul 2018 | US |