The present invention relates to metal connectors and more particularly to a connector for connecting a metal building stud to an underlying or overlying support structure.
In recent years, cold-formed steel framing for both residential and commercial applications has grown at a tremendous rate. Today, engineers, architects and contractors appreciate that light steel framing is a better value than more traditional materials such as masonry or wood.
Light steel framing is ideal for floors, roofs, support structures for finishes, non-load bearing walls, and even load-bearing walls up to approximately nine stories. With wall systems, whether they are load-bearing or non load-bearing, it is customary to use connectors or clips to secure individual metal studs to overlying and/or underlying support structures. Various connector or clip designs are known. For example, it is known to use simple L-shaped connector designs to interconnect metal studs with an underlying or overlying floor structure, for example. However, typical L-shaped connectors may not necessarily handle the variety of loads and forces that are sometimes experienced where studs are joined or secured to a floor or other support structure. More particularly, conventional connector designs may not always efficiently and effectively resist uplift, horizontal and rotational loads that are experienced about connecting points between such studs and an adjacent support structure.
Therefore, there has been and continues to be a need for a more heavy duty and durable connector for connecting metal studs to floors and other adjacent support structures that will effectively resist uplift, horizontal and rotational loads.
The present invention relates to a connector for use in a wall structure. In one mode, the connector is designed to be anchored or secured to an underlying support structure and to a stud that forms a part of the wall structure. In another mode, the connector itself can function as a stud in a wall structure.
The connector, in the present invention, includes a web and a pair of flanges. Formed about the lower end of the connector is a plurality of tabs that includes one or more openings that permit one or more fasteners to be extended therethrough for anchoring the connector to an underlying support structure. In use, a series of fasteners is extended through the web of the connector for connecting to the web of an adjacent stud.
Furthermore, the connector of the present invention can be utilized as a stud itself. This mode of use is particularly appropriate when the wall structure is a partial or half-wall.
In one exemplary embodiment, the connector is provided with a reinforcing member such as a plate or a reinforcing channel that is disposed over the one or more tabs formed in a bottom portion of the connector. In either case, one or more fasteners extends through the reinforcing member and on through one or more underlying tabs to where the one or more fasteners are anchored into the underlying support structure. This securely anchors the connector to the underlying support structure.
Other objects and advantages of the present invention will become apparent and obvious from a study of the following description and the accompanying drawings which are merely illustrative of such invention.
With further reference to the drawings, the connector of the present invention is shown therein and indicated generally by the numeral 10. As will be appreciated from subsequent portions of the disclosure, connector 10 is adapted to be used in a building construction assembly and while the connector 10 may be utilized in different ways, in one exemplary embodiment the connector 10 is utilized to fasten or connect metal building studs to an underlying or overlying support structure.
Turning to a description of the connector 10, as seen in
Extending from the connecting plate 10 is a base plate 16. Base plate 16 includes a series of reinforcing ribs 18. The reinforcing ribs 18 extend generally perpendicular to a juncture or fold line indicated by the numeral 24. Further, base plate 16 includes one or more openings that enable fasteners to be extended downwardly through the base plate 16 so as to secure the entire connector 10 to an underlying structure such as a concrete floor, for example. In the case of the embodiments illustrated in
Also comprising a part of connector 10 is an upturned flange 26. Note that upturned flange 26 extends from the base plate 16 opposite the juncture 24. The upturned flange can be formed by bending an edge portion of the base plate 16 upwardly. Alternatively, the upturned flange 26 can be a separate element or component and can be secured to the base plate 16 by weldment or suitable means.
Turning to
Formed centrally within the reinforcing member 26 is a central opening 28a that would align with the central opening 20 formed in the base plate 16. In addition, if additional fasteners are needed to secure the connector 10 to an underlying support structure, the reinforcing member 28 can be provided with additional openings that would align with other openings, such as openings 22, formed in the base plate 16.
About the underside of the reinforcing member 28, there may be provided a series of grooves or notches that are referred to as recesses 30. These recesses 30 are designed to receive and mate with the ribs 18 shown in
The reinforcing member of block 28 may in some embodiments be secured to the underlying base plate 16. For example, as indicated in
In use, the connector 10 of the present invention may be used in various ways in building construction to secure one component to another component. In the way of an example, the connector 10 can be utilized to connect a stud, indicated generally by the numeral 50 in
Turning briefly to
The connector 10 of the present invention has numerous advantages. It is designed for strength and rigidity. In particular, it is designed to form a firm and rigid heavy duty connection between the opposed end portions of the studs 50 and any adjacent connected supporting structure.
The design of the connector including the ribs 18, the upturned flange 26 and the reinforcing member 28, enables the connector 10 to resist uplifting, horizontal and rotational loads that might be applied directly to or transferred to the connecting points where the studs 50 connect to the underlying or overlying channels and to the adjacent supporting structure.
Connector 10 may be constructed of various materials but it is contemplated that in one embodiment the connector would be constructed of metal. The embodiment illustrated herein is formed from a single metal piece by an appropriate stamping operation. Other fabrication methods could be used. The thickness or gauge of the material utilized for the connector can vary to suit various types of applications.
With reference to
First, with respect to
Viewing the connector 200 shown in
Disposed at the lower or bottom end portion of the connector 200 is a series of tabs, tabs 210, 212 and 220. Tab 210 is referred to as a first tab, tab 212 is referred to as a second tab, and tab 220 is referred to as a third tab. In the embodiment illustrated herein, the first tab 210 is an extension of first flange 204. That is, tab 210 is bent and extended from the first flange 204. The second tab 212 is an extension of the second flange 206. Again, the second tab 212 is bent about the lower end of the flange 206 and directed inwardly therefrom. The third tab on the other hand is an extension of the web 202. The third tab 220 is bent at an angle and extended underneath the first and second tabs 210 and 212. As seen in
Tabs 210, 212 and 220 include openings 230 for permitting fasteners to be extended through the same. As seen in
As will be appreciated from subsequent portions of the disclosure, the lower end of the connector 200 is seated in a track, the lower track referred to by the numeral 64, as shown in
In at least one embodiment, the lower structure of the connector 200 is reinforced by a reinforcing member such as plate 240. The reinforcing plate 240 includes a pair of openings 242. Reinforcing plate 240 is seated over the tabs 210 and 212 such that the openings 242 therein align with the openings 230 in tabs 210 and 212 as well as openings in the third tab 220. Fasteners are then extended through the reinforcing plate 240, the tabs 210 and 212, and the underlying third tab 220.
A slightly altered design for the connector 200 is shown in
A third connector design is shown in
While the angles can vary, the first and second flanges 404 and 406 extend at an angle of approximately 90 degrees with respect to the web 402. Third and fourth flanges 408 and 410 extend at an angle of approximately 90 degrees with respect to the first and second flanges 404 and 406.
The connector 200 shown in
The tabs 412, 414, 416 and 418 include openings 420 for permitting a fastener to pass through the same. In addition, the flanges 408 and 410 include a series of spaced apart openings 422 for permitting a fastener to pass through these openings. As will be discussed later, the flanges 408 and 410 are designed to butt against the web of a stud such that the connector 200 can be secured to the web of the stove by extending fasteners through the openings 422 and through the web of the stud.
As discussed above, all of the connector designs discussed herein are designed such that the connector can be secured to a stud and function to reinforce the stud especially in the area where the stud connects to an underlying structure. In
Turning to
The wall structure 80 shown in
The length of the connectors shown in
In the embodiment illustrated in
As stated before, the connectors 200 may actually serve as studs. This is illustrated in
It is contemplated that the reinforcing channel 500 could be easily fabricated or constructed of ⅜ths inch steel. The dimension of such a reinforcing channel 500 could vary. In one embodiment it is contemplated that the reinforcing channel 500 would be approximately one inch high, approximately two inches deep, and have a width that permits the reinforcing channel to fit between the flanges 204 and 206 of the connectors shown in
The present invention may, of course, be carried out in other specific ways than those herein set forth without departing from the scope and the essential characteristics of the invention. The present embodiments are therefore to be construed in all aspects as illustrative and not restrictive and all changes coming within the meaning and equivalency range of the appended claims are intended to be embraced therein.
This is a continuation-in-part of U.S. patent application Ser. No. 10/095,411 filed on Mar. 12, 2002 entitled “Connector for Connecting Building Components”. The disclosure of this application is expressly incorporated herein in its entirety and referred to herein as the “incorporated application”.
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Number | Date | Country | |
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Parent | 10095411 | Mar 2002 | US |
Child | 12468499 | US |