This invention relates to a connector for joining structural members. The connector of the present invention has particular application as a sheet metal hanger for use in a hip roof, joining supported jack trusses to supporting girder trusses. A hip roof has sloped ends as well as sloped sides. The roof rises by inclining planes from all four sides of the building of which it is a part. The line where an adjacent sloping side and sloping end meet is generally called the “hip.” The four hips generally run from a corner of the building to the peak of the roof at a 45 degree angle. The hips are not merely lines, but are either rafters or trusses. The ends of the roof can be built up from flat-topped trusses that step down from the roof peak. Alternatively, the ends of the roof can be made from sloping jack trusses that run parallel to the roof peak and which are supported by the end wall of the building and by a girder truss. The ends of the roof can also be made with a combination of stepped-down flat-topped trusses and jack trusses, in which case the flat-topped truss closest to the end wall is the girder truss supporting the jack trusses. Generally, any truss that does not span from wall to wall is referred to as a jack truss, so the truss on the hip line could be referred to as a jack truss. However, for the sake of clarity, the truss on the hip line will be referred to as a hip truss in the present application. In addition to the jack trusses that run parallel to the roof peak and are supported by a girder truss, there generally are shorter jack trusses that are supported by the hip trusses where the hip trusses approach the corners of the roof and building.
In the particular application for joining multiple members, the framing members may be lumber or wood trusses, but in the most preferred form the framing members are hollow steel trusses. The connection is most typically made at the junction of the supporting girder truss and one hip truss framing member.
Prior art U.S. Pat. No. 5,253,465, granted to Tyrell T. Gilb teaches a sheet metal connector for making multiple truss connections. U.S. Pat. No. 4,817,359, granted to Karen Colonias also teaches a similar connection with a sheet metal hanger; however, neither of these patents teach the improved connector of the present invention.
The improved connector of the present invention provides a connector with a series of angularly-joined flanges. In the most preferred embodiments, the flanges are substantially planar. In the connection formed with the connector of the present invention, the flanges are substantially vertically oriented. The connector allows the end of a supported truss to be connected to a vertical member in the open web of a supporting truss. The formed connection is preferably at a 90 degree angle. At least some of the flanges are preferably reinforced by shallow embossments. The embossments reinforce the flanges against deformation so that they remain generally planar.
When the connector is formed from a sheet metal blank that is bent and formed into its final configuration, the embossments, along with the outlines of the flanges and fastener opening, are created while the blank is still flat, after which the flanges are bent out of the blank, creating the junctures between them.
The connector of the present invention is specifically designed to join a jack truss to a supporting girder truss that has an open web.
An advantage of the present invention is that it better joins members because it fastens to each of the supporting and supported members with fasteners that enter the members from at least two different principle angles or directions, so that the fasteners, attaching the connector to a member, are not all withdrawn in the same direction to disassemble the connection. This is especially helpful for hollow metal members.
An advantage of the present invention is that it is economically formed from a substantially rectangular blank that wastes virtually no material in the manufacturing process.
As shown in
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As is also shown in
Preferably, any reinforcing embossment 13 in the first flange 2 is elongated and oriented substantially perpendicular to the first juncture 8. The reinforcing embossments 13 in the third flange 4 are preferably elongated, oriented substantially perpendicular to the second juncture 12, and span from the first substantially planar portion 9 of the third flange 4 to the second substantially planar portion 10 of the third flange 4.
Preferably, the first flange 2, the second flange 3 and the third flange 4 each have a plurality of fastener openings 14.
The second flange 3 is preferably orthogonal to the first flange 2 and to the third flange 4, and the first flange 2 and the third flange 4 occupy substantially parallel planes. In this preferred arrangement, the second flange 3 defines a plane that divides or transects the third flange splitting it into the second substantially planar portion 10 of the third flange 4 and the first substantially planar portion 9 of the third flange 4. Thus, the second substantially planar portion 10 of the third flange 4 extends from the second juncture 12, and past the plane of division created by the second flange 3 in one direction toward the edge 18, and the first substantially planar portion 9 of the third flange 4 extends past the plane of division created by the second flange 3 in the opposite direction from the second substantially planar portion 10 of the third flange 4 towards edge 11. The first flange 2 extends from the plane of division created by the second flange 3 in the same direction as the second substantially planar portion 10 of the third flange 4.
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The supporting structural member 16 is preferably a supporting truss 16, and the supported structural member 17 is preferably a supported truss 17. Preferably, the supporting truss 16 has a top chord 19, a bottom chord 20, and at least one web member 21 extending between the top chord 19 and the bottom chord 20. The connector 1 preferably interfaces with the web member 21 of the supporting truss 16. Preferably, the supported truss 17 has a top chord 22, a bottom chord 23 and an end member 24 extending between the top chord 22 and the bottom chord 23. The connector 1 preferably interfaces with the end member 24 of the supported truss 17.
Preferably, the supporting structural member 16 and the supported structural member 17 are made primarily of metal. More preferably, the supporting structural member 16 and the supported structural member 17 are made primarily of hollow steel. In the most preferred embodiment, the connector 1 of the present invention is used to form a connection 15 between trusses of the NuconSteel NuTruss system.
The supporting structural member 16 and the supported structural member 17 are preferably fastened to the connector 1 with separate fasteners 25. Preferably, the separate fasteners 25 are screws 25. In fact, the connection 15 could be formed without separate fasteners 25, if the connector 1 were formed with integral mechanical fasteners 25, or if adhesives or welding were used to fasten the connector 1 to the structural members 17 and 16. If the connector 1 were used with wood members, the preferred fasteners 25 would be self-drilling wood screws of the kind exemplified by the Simpson Strong-Tie SDS screw. If the connector 1 is used to form a connection 15 with metal members, the preferred fastener 25 would be self-drilling metal screws, which install quickly and easily with an automatic driver, most preferably #10 self-drilling metal screws, a standard in the industry.
Preferably, the connection 15 of the present invention is formed by driving a plurality of the screws 25 through the second flange 3 into the supporting structural member 16, driving a plurality of the screws 25 through the first substantially planar portion 9 of the third flange 4 into the supporting structural member 16, driving a plurality of the screws 25 through the first flange 2 into the supported structural member 17, and driving a plurality of the screws 25 through the second substantially planar portion 10 of the third flange 4 into the supported structural member 17.
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When forming the connection 15 of the present invention with the preferred webs 27 and 28, a plurality of the screws 25 is preferably driven through the second flange 3 into the second side 26 of the web member 21. A second plurality of the screws 25 is preferably driven through the first substantially planar portion 9 of the third flange 4 into the first side 26 of the web member 21. Then, a third plurality of the screws 25 is preferably driven through the first flange 2 into the first side 29 of the end member 24, and a fourth plurality of the screws 25 is driven through the second substantially planar portion 10 of the third flange 4 into the second side 29 of the end member 24.
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Preferably, the connector 1 of the present invention is formed from a single piece of sheet metal, preferably steel. The steel preferably has a galvanized coating, preferably at least G90, which is a minimum of 0.90 ounce of zinc per square foot of surface area. Heavier galvanized coatings are also possible, including hot-dip galvanized, which is a minimum of 2.0 ounces of zinc per square foot of surface area. Heavier galvanized coating generally demand the use of hot-dip galvanized fasteners 23. The connector 5 can also be made from stainless steel, preferably type 316L, which requires the use of stainless steel fasteners 23.
Preferably, the embodiment of the connector 1 of the present invention, shown in
Preferably, the embodiment of the connector 1 of the present invention, shown in
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