The present disclosure relates generally to concrete wall panel construction, and more particularly to an anchor or bracket device for connecting a concrete wall to a floor or footing.
Precast concrete wall panel construction or tilt-up construction is a common construction method used to construct buildings, such as commercial buildings (e.g., office buildings, warehouses, factories, and the like). In general, concrete forms are constructed in several sizes and shapes (most commonly various shaped panels and columns) dictated by the specifications of what will become the finished structure. The forms are filled with liquid concrete which is then allowed to cure. The cured concrete structures are then erected and secured at a foundation to form the skeleton of a structure.
Often, the concrete structures are secured at the foundation via respective components of the structure and foundation that must be aligned or fitted together when the structure is erected, such as base plates at the bottom surface of the structure and embedded anchors at the upper surface of the foundation. However, such embedded two-piece securing means must be precisely located during formation of the structures and foundation to ensure proper alignment and the bolts and base plates can easily be damaged during construction. Thus, such embedded two-piece securing means can be unreliable during the construction process. A misaligned or damaged securing element can cause delays and increase construction costs.
It is generally known to use a component that is pre-placed in only the precast concrete structure and therefore does not need to be aligned with a matching component in the foundation. However, such known components typically require drilling into the foundation below the concrete structure via a passageway of the pre-placed component and then inserting a metal rod, such as rebar, into the drilled hole. The hole and passageway are then filled with wet concrete that must cure for the rod to secure the structure to the foundation, which at times can be undesirable.
Securing the concrete panels to the foundation is critical to provide resistance to lateral or uplift forces on the erected structures relative to the foundation caused, for example, by strong winds, earthquakes, or other forces. Therefore, a need exists for connection means to secure precast concrete structures to a foundation in a manner that advances the art.
The present disclosure provides a foundation connection device or a slant anchor and method for use of such device in the forming, placing, and securing of a concrete structure at a foundation, such as a floor or footing.
According to one aspect of the present disclosure, a foundation connection device is configured to be embedded within a concrete structure at a bottom surface of the concrete structure for securing the concrete structure to a foundation when a bolt engages the foundation connection device and is driven into the foundation. The foundation connection device includes a base plate that has an upper surface, a lower surface opposite the upper surface, and an aperture through the upper and lower surfaces. The lower surface is configured to substantially align with the bottom surface of the concrete structure. A tubular post includes a lower end that is connected to the base plate and defines an opening at the lower end that surrounds the aperture of the base plate. A central axis of the tubular post is oriented at a non-right angle relative to the base plate. An anchoring member includes a lower portion that is coupled to at least one of the base plate and the tubular post. An upper portion of the anchor member has engagement features that are configured to form an embedded connection in the concrete structure. A stop member is fixed within an interior the tubular post and includes a through-hole and a peripheral upper surface surrounding the through-hole. When the bolt engages the foundation connection device and is driven into the foundation, a shaft of the bolt extends through the through-hole of the stop member and the aperture of the base plate into the foundation and a head of the bolt engages the peripheral upper surface of the stop member.
Implementations of the disclosure may include one or more of the following optional features. In some implementations, the second end of the tubular post has a flange surface planar to the second opening and the flanged opening may lie on a plane perpendicular to the base plate. In some implementations the body of the tubular post is a cylindrical pipe and in those implementations, the second end of the tubular post defines an oval shape.
In some examples, the bolt may include of the tubular post has a flange surface planar to the second opening and the flanged opening may lie on a plane perpendicular to the base plate. In some implementations the body of the tubular post is a cylindrical pipe and in those implementations, the second end of the tubular post defines an oval shape.
In some implementations the anchor member includes an anchor rod that is attached at an exterior surface of the tubular post. In those implementations, the anchor rod has a lower length tangential and attached to the exterior surface of the tubular post and an upper length extending away from the tubular post and angled relative to the lower length so as to be perpendicular to the base plate.
According to another aspect of the present disclosure, a method is provided for securing a concrete structure to a foundation with a foundation connection device within the concrete structure. The method includes the step of providing a foundation connection device having a base plate with an aperture through the base plate and a tubular post defining a cavity. The tubular post is disposed at an upper surface of the base plate surrounding the aperture at a first end and extends at a non-right angle relative to the base plate. The method further includes the step of positioning and retaining a lower surface of the base plate of the foundation connection device at an interior wall of a concrete form so that the lower surface of the base plate will be aligned with a lower surface of the concrete structure made using the concrete form. The next step is pouring liquid concrete into the concrete form such that a second end of the tubular post is exposed at an exterior surface of the poured liquid concrete. The method also includes curing the liquid concrete to form the concrete structure and removing the concrete form from the formed concrete structure. The method further includes the step of erecting the formed concrete structure at the foundation such that the lower surface of the base plate and the lower surface of the concrete structure engage an upper surface of the foundation. Next, drilling along a central axis of the tubular post into the upper surface of the foundation to form a hole in the foundation. The method includes driving a bolt through a stop plate within the cavity of the tubular post and into the hole in the foundation until a bolt head of the bolt engages a surface of the stop plate so that the bolt engages the foundation. The method includes covering an exposed flanged opening at the second end of the tubular post with patching grout to provide a smooth outer surface of the concrete structure.
This aspect may include one or more of the following optional features. Before pouring liquid concrete into the concrete form, a foam plug may be positioned at the second end of the tubular post to prevent liquid concrete from entering the flanged opening. The foundation connection device may further have an anchor rod extending from an exterior surface of the tubular post.
Therefore, a slant anchor and method for use according to the present disclosure provides an improved securing means for a concrete structure to a foundation where a hole is drilled through the slant anchor into the foundation and a bolt is driven into the drilled hole to engage a stop plate of the slant anchor and engage the foundation beneath the slant anchor. A slant anchor with a bolt connection provides reliability as the receiving hole for the bolt is drilled into the foundation after the concrete structure is erected. Consistency is achieved in the depth and angle of the bolt driven into the concrete due to the stop plate within the post and the bolt engaging the stop plate and engaging the foundation ensures a durable connection between the bolt and foundation. The flanged surface providing a receiving surface for patching grout also ensures that after the bolt is driven into the foundation through the slant anchor, the slant anchor may be sealed into the concrete structure, hidden from sight with limited mess at the outer surface of the structure.
The details of one or more implementations of the disclosure are set forth in the accompanying drawings and the description below. Other aspects, advantages, purposes, and features will be apparent upon review of the following specification in conjunction with the drawings.
Like reference symbols in the various drawings indicate like elements.
Referring now to the drawings and the illustrative examples depicted therein, a foundation connection device (referred to herein as a “slant anchor”) is embedded in a precast concrete structure (such as a tilt-up or precast wall panel or column) at the base of such structure for securing the precast concrete structure to a foundation and for providing rigid support to the structure's connection at the foundation. As shown in
As will become clear through the disclosure below, use of a slant anchor to secure a concrete structure to a foundation provides increased reliability, durability, and consistency over methods known in the art. Drilling a hole into the foundation guided by the angle of the tubular post and stop plate disposed within the post ensures a consistent engagement angle among multiple structures erected and secured via a bolt engaging a slant anchor. The bolt engaging the stop plate and engaging the foundation ensures a consistent engagement depth. The flanged opening of the tubular post provides a receiving surface for patching grout to seal the slant anchor into the wall, hidden from sight. Overall, a method of securing a concrete structure to a foundation via a bolt engaging the foundation and the slant anchor provides a more reliable, durable, consistent, and discrete connection.
To dispose the slant anchor 10 in a cured concrete structure, a concrete form is first built. The slant anchor 10 is positioned at an interior surface of the form so that the bottom surface 12b of the base plate 12 will align with the bottom surface 30b of a cured concrete structure 30 (such as seen in
In reference to
A cylindrical or tubular post 18 is welded to or integrally formed with a top surface 12a of the base plate 12 and extends at a non-right angle from the base plate, with an interior surface of the tubular post 18 defining a cavity therethrough. Extending the length of the tubular post 18, the cavity (and therefore bottom opening 22 of the tubular post) aligns with the opening 14 through the base plate. The opening 14 through the base plate 12 may have a smaller diameter than the cylindrical cavity of the tubular post 18. This helps to improve the accuracy or matching of the angle of the hole 36 drilled into the foundation 32 through the base plate (and therefore the angle of the bolt 38 driven into the drilled hole 36) to the angle of the tubular post 18.
At the end of the tubular post 18 distal the end integrally formed with the base plate is a flanged opening 20 with a flange surface 26 surrounding the opening of the tubular post 18. The tubular post is angled relative to the base plate such that the opening 20 and flange surface 26 are exposed at a vertical surface 30a of the wall panel 30 perpendicular to the bottom surface 30b at which the base plate 12 is exposed. The flange surface 26 is parallel to the vertical surface 30a of the wall and, like the bottom surface of the base plate, is exposed at the surface of the wall panel following the curing process. However, and as discussed above, the flange surface 26 may be present within a recess 30c of the wall panel 30 due to the placement of the foam plug at the flange surface during the forming process of the wall panel. The flanged opening 20 of the tubular post 18 lies on a plane perpendicular to the base plate 12. Due to the angle and cylindrical form of the tubular post 18 and the vertical nature of the flanged opening 20, the flanged opening has an elongated oval shape. As will become clear, this elongated oval shape provides the advantage of a wide opening to the cavity of the tubular post and therefore increased visibility and access for tools and the bolt that will be disposed in the tubular post when the wall panel is erected at the foundation. The opening through the flange matches the elongated oval shape of the tubular post.
The flange surface 26 is recessed from the vertical surface 30a of the wall 30 so that the slant anchor 10 may more easily be grouted in to the wall 30 (patched over with patching grout 42 following the final step of securing the wall panel 30 to the foundation 32) to seal the cavity of the tubular post 18 and hide the slant anchor 10 from view after the wall 30 is secured. Thus, during the curing process of the concrete, a foam plug 28 is placed at the flange surface 26 to prevent liquid concrete from entering the tubular post 18 through the flanged opening 20. The flange surface provides a flat surface for the foam plug 28 to be placed, adhered, or otherwise disposed over the opening 20 and also provides a surface to which the patching grout 42 may be placed once the wall panel is secured at the foundation.
The foam plug 28, which is preferably made of STYROFOAM™ material but may comprise any suitable material, has substantially the same dimensions as the flange surface 26 and a thickness suitable to prevent liquid concrete from covering the flange surface 26 or entering the flanged opening 20 and therefore cover the flange or fill the tubular post during the curing process. The foam plug 28 may be adhered to the flange surface 26 such as via an adhesive backing to prevent movement of the plug from during the pouring and curing process. When the curing process is complete and the wall panel 30 is formed, the foam plug 28 is removed from the flange surface (before or after the wall panel is erected and positioned at the foundation) to provide access to the cavity of the tubular post through the flanged opening 20.
In reference to
As shown in
Furthermore, because the stop plate 40 is positioned perpendicular to the walls of the tubular post 18, passage of the bolt 38 through the stop plate as it is driven into the foundation 32 beneath the wall panel 30 helps to ensure that the angle of the bolt is substantially similar to the angle of the tubular post. Therefore a more consistent and safe connection between the wall panel 30 and the foundation 32 may be established. Because the bolt 38 is responsible for transferring lateral forces experienced at the connection between the wall panel and the foundation upwards through the slant anchor 10 and (as will be discussed in further detail below) one or more anchor rods 24 or plates of the slant anchor to the concrete wall, consistent placement of bolts at a desired angle across multiple panels is critical in being able to calculate the structural limits of a given structure and ensure structural integrity. Optionally, the bolt 38 may threadably engage the stop plate so as to provide a more snug connection between the bolt and the stop plate or the bolt may simply pass through an unthreaded opening in the stop plate to engage the foundation beneath the wall panel. A threaded connection between the bolt and stop plate may also align the angle of the bolt to the tubular post as the bolt is driven into the foundation.
Use of a bolt in retaining the slant anchor to the foundation is critical to securing the wall panel at the foundation. The bolt 38 engages the foundation 32 (and optionally threadably engages the stop plate or hole in the base plate of the slant anchor) to retain the bolt. The entire length 38b of the bolt 38 may be threaded for threadably engaging the foundation or, such as in the case of a self-tapping concrete bolt, the length 38b of the bolt may have both a threaded portion threadably engaging the foundation and an unthreaded portion engaging the foundation. Therefore, when forces act upon the bolt 38 as a retaining element of the slant anchor 10 (such as vibrations during construction, epoxy or concrete poured into the cavity of the tubular post, or environmental conditions acting on the wall panel), the bolt 38 will remain in position within the foundation 32. In other words, the bolt is less likely to shift or pull out of the foundation than a non-threaded retaining element and therefore improves the structural integrity of a wall panel with a slant anchor according to the present disclosure.
After the bolt 38 is driven through the foundation 32 beneath the bottom surface 30b of the wall panel 30 and bottom surface 12b of the base plate 12 to secure the slant anchor 10 and wall 30 at the foundation 32, patching grout 42 may be placed at the flange surface 26 to cover the flanged opening 20 and therefore seal the opening and visibly hide the slant anchor 10 from view within the wall panel. Material, such as concrete or epoxy, may also be poured into the cavity of the tubular post 18 after driving the bolt into the foundation and before applying the patching grout if desired. Thus, the slant anchor and bolt becomes completely covered and is fully inside the wall with no exposed portion at or beyond the outer surfaces of the wall panel.
An anchoring member or anchor rod 24 extends from the tubular post vertically into the height of the wall panel 30 and is aligned with the bolt 38 driven into the foundation so that lateral or upward forces experienced by the slant anchor, such as due to strong winds or earthquakes, are transferred to the concrete wall. The anchor rod also provides increased attachment surface area between the slant anchor 10 and the concrete structure. The anchor rod 24 has a lower portion 24b and an upper portion 24a. The lower portion 24b is welded to or integrally formed with an outer surface of the tubular post 18. The lower portion 24b of the anchor rod is angled relative to the base plate 12 at the same angle as the tubular post 18 and is positioned at an upward-facing surface of the tubular post 18 so that the upper portion 24a (angled relative to the lower portion so as to be perpendicular to the base plate) extends vertically from the tubular post 18 into the height of a concrete structure at which a slant anchor is disposed with the base plate at a bottom surface of the structure. For example and as seen in
In additional implementations, the slant anchor may have more than one anchoring member, such as anchor rods or anchor plates, at the sides or rear of the tubular post 18 and/or base plate 12 to provide further support and further dissipate any load felt by the slant anchor within the concrete wall. For example, and as shown in
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Thus the present disclosure provides a foundation connection device or a slant anchor and method for use of such device in the forming, placement, and securing of a concrete structure at a foundation. The slant anchor provides a base plate with a bottom surface flush with the bottom surface of a cured concrete structure and with a post extending from a top surface of the base plate. The post extends from the top surface of the base plate at a non-right angle relative to the base plate and defines a cavity extending the length of the post. The cavity of the post aligns with a hole through the thickness of the base plate. The end of the post opposite the end integrally formed with the base plate defines a flanged opening. When the cured concrete structure is erected at a foundation, the flanged opening is exposed at a vertical surface of the concrete structure, the bottom surface of the base plate aligned with the bottom surface of the concrete structure is resting on an upper surface of the foundation with the hole of the base plate exposed to the foundation, and the post provides a cavity between the flanged opening and the hole in the base plate. A stop plate with a through-hole aligned with the central axis of the post is disposed within the cavity of the post. A hole is drilled into the foundation through the slant anchor so that the axis of the hole aligns with the central axis of the post. A bolt is then drilled into the foundation so that a head of the bolt engages the stop plate as a threaded portion of the bolt extends through the through-hole of the stop plate, within the cavity of the post, through the hole in the base plate, and threadably engages the foundation beneath the concrete structure. Therefore, a slant anchor and method for use according to the present disclosure provides an improved securing means for a concrete structure to a foundation where a hole is drilled through the slant anchor into the foundation and a bolt is driven into the drilled hole to engage a stop plate of the slant anchor and threadably engage the foundation beneath the slant anchor.
For purposes of this disclosure, the term “coupled” (in all of its forms, couple, coupling, coupled, etc.) generally means the joining of two components (electrical or mechanical) directly or indirectly to one another. Such joining may be stationary in nature or movable in nature; may be achieved with the two components (electrical or mechanical) and any additional intermediate members being integrally formed as a single unitary body with one another or with the two components; and may be permanent in nature or may be removable or releasable in nature, unless otherwise stated.
The terms “comprising,” “including,” and “having” are intended to be inclusive and mean that there may be additional elements other than the listed elements. Additionally, it should be understood that references to “one embodiment” or “an embodiment” of the present disclosure are not intended to be interpreted as excluding the existence of additional implementations that also incorporate the recited features. Numbers, percentages, ratios, or other values stated herein are intended to include that value, and also other values that are “about” or “approximately” the stated value, as would be appreciated by one of ordinary skill in the art encompassed by implementations of the present disclosure. A stated value should therefore be interpreted broadly enough to encompass values that are at least close enough to the stated value to perform a desired function or achieve a desired result. The stated values include at least the variation to be expected in a suitable manufacturing or production process, and may include values that are within 5%, within 1%, within 0.1%, or within 0.01% of a stated value.
Also for purposes of this disclosure, the terms “upper,” “lower,” “right,” “left,” “rear,” “front,” “vertical,” “horizontal,” and derivatives thereof shall relate to the orientation shown in
Changes and modifications in the specifically described embodiments may be carried out without departing from the principles of the present invention, which is intended to be limited only by the scope of the appended claims as interpreted according to the principles of patent law. The disclosure has been described in an illustrative manner, and it is to be understood that the terminology which has been used is intended to be in the nature of words of description rather than of limitation. Many modifications and variations of the present disclosure are possible in light of the above teachings, and the disclosure may be practiced otherwise than as specifically described.
The present application claims the filing benefit of U.S. Provisional Application, Ser. No. 63/154,842, filed Mar. 1, 2021, which is hereby incorporated herein by reference in its entirety.
Number | Date | Country | |
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63154842 | Mar 2021 | US |