Patent Grant
10533314
Residential and/or commercial building structures may include drywall panels for interior walls and/or ceilings. When installing the drywall, pieces of drywall may be cut to fit a particular layout of a room in the building. Cutting and finishing drywall for various room layouts may be labor intensive, which can add significant costs to building construction.
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 features of the claimed subject matter, nor is it intended to be used to limit the scope of the claimed subject matter. Other features, details, utilities, and advantages of the claimed subject matter will be apparent from the following more particular written Detailed Description of various implementations and implementations as further illustrated in the accompanying drawings and defined in the appended claims.
The present application discloses an infill wall support clip that includes a top flange, a side tab, and a side flange. The top flange is configured to anchor the infill wall support clip to a bottom track of a truss. The side tab is configured anchor the infill wall support clip to a top track of a wall panel. The side flange is between the top flange and the side tab and provides spacing for drywall to be overlaid on top of the wall panel.
The infill wall support clip described herein provides lateral bracing for partition walls in residential or commercial buildings yet allows drywall to run continuously over the top of the partition walls. This may eliminate costly cutting, taping, and finishing of drywall. It also provides a continuous fire rated assembly and transfers load from trusses to wall panels. The infill wall support clips are brackets that may be securely anchored to the tops of partition walls (e.g., wall panels) and bottoms of ceiling structures such as trusses. The infill wall support clips provide spacing between the tops of the partition walls and the ceiling structures. Drywall and resilient channels are installed in the provided spacing, and the drywall may be installed over the top of the wall panel without significant cutting and fitting. The resilient channels provide support for the drywall and sound insulation. The assembly of the infill wall support clips, drywall, resilient channels, wall panels, and ceiling/floor channels are resistant to spreading fire when compared to other assemblies.
The side tab 106 is positioned substantially perpendicular to a plane comprising the side flange 104. The side tab includes a pilot hole 118 configured to receive a fastener configured to anchor the infill wall support clip to a top track of a wall of the building structure. The fastener may be a screw, bolt, etc. It should be understood that the side tab 106 may include no pilot holes or more than 1 pilot hole.
The side flange 104 is positioned substantially perpendicular to a plane comprising the top flange 102 and substantially perpendicular to a plane comprising the side tab 106. The side flange 104 is positioned between the top flange 102 and the side tab 106 and is configured to provide spacing (e.g., a space illustrated by line 114) between a top track of a wall (not shown) of the building structure and the bottom track of a floor truss. The spacing provides an opening between the top track of the wall and the bottom track of the floor truss through which drywall (not shown) may be installed. As such, the dry wall may not have to be cut to fit between walls of a building structure. Furthermore, the side flange 104 provides support between the top track of the wall and the bottom track of the floor structure. The size of the spacing defined by the line 114 (e.g., the height of the side flange 104) may vary depending on the depending on implementations. In some example implementations, an edge 122 of the side flange 104 does not extend to a bottom edge 124 of the side tab 106. For example, the edge 122 may be positioned or extend down apportion of the side tab 106 as illustrated by lines 126.
In implementations, the dimensions of the infill wall support clip 100 does not vary with different sizes of components where the infill wall support clip 100 is attached. In some example implementation, a height of the space defined by the line 114 is about 1¼ inches, but it should be understood that other heights are contemplated. Furthermore, in some example implementations, a height 128 of the side tab 106 is about 1 inch, but other heights 128 of the side tab 106 are contemplated. Yet further, in some example implementations, a width 140 of the top flange 102 is about 1½ inches, but other widths 140 are contemplated. In some example implementations, the length 112 of the top flange 102 is about 1¾ inches, but other lengths 112 are contemplated.
The side tab 106 and the side flange 104 form an abutment notch in a space 120. The abutment notch is configured to receive a top track of a wall structure (not shown), such as a wall panel. For example, when installed on the top track, a fastener is inserted through the pilot hole 118 and into a side of the top track. Thus, the side tab 106 rests against the side of the top track. Furthermore, a bottom edge 116 of the side flange 104 rests against the top of the top track. Thus, the abutment notch rests against the top and the side of the top track of the wall panel providing support for the bottom track of the floor truss.
In the illustrated implementation, the top flange 102 is positioned parallel to a plane defined by an x axis and a y axis, the side flange 104 is positioned parallel to a plane defined by the y axis and a z axis, and the side tab 106 is positioned parallel to a plane defined by the x axis and the z axis. The plane defined by the x and y axis is substantially perpendicular to the plane defined by the y and z axis and the plane defined by x and z axis. Furthermore, the plane defined by the y and z axis is substantially perpendicular to the plane defined by the x and y axis and the plane defined by the x and z axis. Yet further still, the plane defined by the x and z axis is substantially perpendicular to the plane defined by the x and y axis and the plane defined by the y and z axis. In some example implementations, the various components of the infill wall support clip are not positioned substantially parallel to the defined planes.
In some example implementations, the infill wall support clip 100 is configured to provide sound insulation in a building structure. For example, the side flange 104 includes slots that dissipate sound vibrations traveling between structures such as the top track of the wall and the bottom track of a truss. Furthermore, the spacing provided by the side flange (e.g., the spacing illustrated by a line 114) provides sound insulation properties and allows for additional sound dissipating elements to be installed. For example, resilient channels may be installed between the drywall and the bottom track of the floor truss. The resilient channels further insulate sound vibrations between various building elements.
In some example implementations, the infill wall support clip 100 may be constructed from a metal sheet. The sheet may be, for example, 12-18 gauge (between 0.050 to 0.11 inches) for stainless steel sheets. However, alternate thickness of the metal sheet may also be used. The metal sheet may be made of stainless steel, galvanized steel, aluminum, etc. For example, if standard steel sheet is used to make the infill wall support clip 100, the thickness of the flanges may be for example, 16-18 gauge standard steel, which equated to thickness of 0.00598 to 0.0478 inches. On the other hand, if galvanized steel sheet is used to make the infill wall support clip 100, the thickness of the flanges may be for example, 16-18 gauge galvanized steel, which equates to thickness of 0.0635 to 0.0516 inches. However, alternate thickness of the metal sheet may also be used.
Such construction may include cutting a piece from the metal sheet, punching the pilot holes for the top flange 102 and the side tab 106, and bending/roll forming the cut piece to the desired shape. The section of the cut piece that includes the side flange 104 and the side tab 106 may be cut to form the side tab 106 (e.g., cut along line 116). After the section is cut, the side tab 106 may be folded, bent, or roll formed into a position as shown in
In some example implementations, the side flange 104 is offset from an edge 216 of the top flange 202 at an angle 214. The angle may be from about 10 degrees to about 60 degrees from a plane (illustrated by lines 218) extending from the edge 216 of the top flange 202. In alternative implementations, the side flange 104 is not offset from the edge 216 of the top flange 202. In such implementations, the side flange 104 is a rectangular shaped body.
In
The infill wall support clips 302 and 304 provide lateral bracing for the partition walls but allow drywall 316 to run continuously over the top of the wall. The infill wall support clips 302 and 304 further transfer vertical loads from the bottom track 318 (e.g., truss) to the wall (e.g., the top track 312). The side flanges (e.g., a side flange 324 of the infill wall support clip 302) provide spacing between the top track 312 of the wall panel and the bottom track 318 of the floor truss wherein a piece of drywall 316 may pass through (illustrated by an arrow 322). This may eliminate costly cutting, tapping, and finishing of the dry wall. The piece of drywall 316 is supported further by resilient channel (RC) 320. Additional drywall 314 is installed on the side of the wall.
The infill wall support clips 302 and 304 further provide sound insulating features. For example, the side flange (e.g., the side flange 324) may include slots for dissipating sound vibrations between the top track 312 and the bottom track 318. Furthermore, the spacing provided by the side flanges allow for the drywall and the resilient channels, such as the resilient channel 320. The resilient channel 320 is connected to the bottom track 318 and the drywall 316 via fasteners, tape, or glue (not shown). The resilient channels further provide sound insulating features as dissipate sound vibrations traveling between the drywall 316 and the bottom track 318.
An installing operation 810 installs resilient channels between the bottom tracks of the floor/ceiling trusses and the top tracks of the wall panels. The resilient channels may be securely fastened to the bottom tracks of the floor/ceiling trusses. An installing operation 812 installs drywall pieces between the top tracks of the wall panels and the resilient channels. The drywall may be attached to and supported by the resilient channels using fasteners, glue, or tape. The resilient channels provide support and sound insulation between the drywall and the supporting structure.
An angle 918 between the top flange 902 and the side flange 904 may be around 90 degrees (e.g., the top flange 902 and the side flange 904 are substantially perpendicular). It should be understood that in some implementations, the angle 918 may be from about 60 to about 120 degrees. Similarly, an angle 920 between the side tab 906 and the side flange 904 may be around 90 degrees (e.g., the side tab 906 and the side flange 904 are substantially perpendicular). It should be understood that in some implementations, the angle 920 may be from about 60 to about 120 degrees.
In the view 916b, a notch 922 is illustrated. The notch 918 may be formed as a result of the manufacturing process of the infill wall support clip 900. In some implementations, the infill wall support clip is formed of a continuous piece of metal or steel. To form the side tab 906, the piece of metal is cut (e.g., using a saw, laser, etching device), and the side tab 906 is folded or bent into position. The notch 922 is formed by the cutting process, which removes material of the piece of metal so that the side tab 906 may be folded into position.
The above specification, examples, and data provide a complete description of the structure and use of exemplary embodiments of the invention. Since many embodiments of the invention can be made without departing from the spirit and scope of the invention, the invention resides in the claims hereinafter appended. Furthermore, structural features of the different embodiments may be combined in yet another embodiment without departing from the recited claims. Although the present invention has been described with reference to preferred embodiments, workers skilled in the art will recognize that changes may be made in form and detail without departing from the scope of the invention. The implementations described above and other implementations are within the scope of the following claims.
The present application is a continuation application of U.S. patent application Ser. No. 15/676,887 filed on Aug. 14, 2017, and titled “Infill Wall Support Clip” which is hereby incorporated by reference in its entirety. This application claims benefit of U.S. Provisional Application Ser. No. 62/374,535 entitled “Infill Wall Support Clip,” and filed on Aug. 12, 2016, which is incorporated herein by reference in its entirety.
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| Number | Date | Country | |
|---|---|---|---|
| 20190145093 A1 | May 2019 | US |
| Number | Date | Country | |
|---|---|---|---|
| 62374535 | Aug 2016 | US |
| Number | Date | Country | |
|---|---|---|---|
| Parent | 15676887 | Aug 2017 | US |
| Child | 16248515 | US |
