SUPPORTING SYSTEM WITH BRIDGING MEMBERS
A supporting system for use between two opposing supports comprised of at least two joists and at least one bridging member. The joists span between the opposing supports and are adjacent to each other. The joists each include bridging holes. The bridging members are between the adjacent joists and the bridging members are adapted to engage the bridging holes in the joists.
Latest BEST JOIST INC. Patents:
This patent application relates to U.S. Provisional Patent Application No. 60/514,622 filed on Oct. 28, 2003 entitled SINGLE WEB COLD FORMED JOIST, U.S. patent application Ser. No. 10/721,610 filed on Nov. 25, 2003 entitled SEGMENTED COLD FORMED JOIST, U.S. patent application Ser. No. 10/974,964 filed on Oct. 28, 2004 entitled COLD-FORMED STEEL JOISTS, and U.S. patent application Ser. No. 12/461,367 filed on Aug. 10, 2009 entitled LOWER CHORD COLD-FORMED STEEL JOISTS and incorporates by reference subject matter of these applications in its entirety herewith.
FIELD OF INVENTIONThis invention relates to cold-formed steel joists and to assemblies of such joists to provide structural support for floors and roofs in the building construction industry, such as support including fire rated steel-concrete composite structures. Both top chord and bottom chord supported joists are included as aspects of the said invention.
BACKGROUND OF INVENTIONJoists are commonly used in the construction industry to span a distance between opposing walls and provide a structural support for a floor, roof or the like. Joists can be comprised of a variety of materials including softwood, wood based laminates, and metal, particularly steel.
Steel joists can be constructed in an open web configuration, which generally consists of spaced apart upper and lower chord members which extend longitudinally thereof and are fastened together by a zig-zag web. Such open web joists are typically manufactured from hot-rolled steel structural members namely the upper and lower chords and the webs. The webs typically can be comprised of hot-rolled steel rods, which are formed into a zig-zagged pattern and welded to the upper and lower chords. Integral parts of the web are the end angled supports that connect the ends of the lower chord to the upper chord to counter load stresses at the ends of the joist. Open web joists are normally top chord bearing meaning that they are supported by the underside of the top chord, so that the top chord extends longitudinally beyond the bottom chord and the end angle supports to provide bearing interface with the opposing walls.
Open web joists are by their nature highly customizable in terms of their load bearing capabilities. Both chords and the zig-zag web can be made from different thickness of steel, and the members constituting the zig-zag web can vary in thickness along the length of the joist. The webs are open in the sense that there is a space between the rods longitudinally along the central web section that can receive utilities such as wires, pipe work, air ducts or the like. Open web joists can be concentric, meaning that the load being supported exerts forces that substantially pass through the centres of gravity of the joists. If the joists are loaded otherwise, they are termed eccentric.
The joist industry has introduced various types of composite steel-concrete non-combustible floor and roof systems for the construction industry, in which the top chords are embedded into a concrete slab, such a slab having both load bearing and fire resistant properties. Examples of composite joists can be found in U.S. Pat. Nos. 5,941,035, 4,741,138, 4,454,695 and U.S. Publication No. 2002/0069606 A1. A composite joist design permits the top chord member of a joist to be designed with less steel in comparison with non-composite systems since the concrete slab when properly bonded to the upper steel joist provides additional load support for the floor or roof system.
Generally speaking, for a structural joist member to be composite it must have means to mechanically interlock with the concrete to provide sheer bonding. It is generally difficult and costly to design steel and concrete composite floors using steel joists. Simply affixing vertical studs to the top chord is forbidden by safety regulations in many jurisdictions which state that structural members cannot have objects extending above a structural floor member that will encumber the walking path of a worker.
The methods for providing sheer bonding between the joist and the concrete in a composite joist are generally expensive to produce in the prior art.
Furthermore, camber (defined as a slight arch added to the joist) has been introduced into the open web joist technology to offset the deflection associated with dead loads such that only the live load deflection of the joist needs to be accounted for in designs of the joist. However large machines or jigs are needed to impart the camber to the chords of the joist where typically the web resists the cambering process.
Moreover, hot-rolled open web joists are typically coated or finished with a coloured primer. Steel joists manufacturers typically use large tanks of paint into which completed welded joist assemblies are dipped to receive a coating of primer paint. However, the process has become more expensive due to environmental considerations when using dipped tanks containing volatile solvents.
Furthermore construction with open web joists is dependent on skilled labour which in many instances sets the critical path schedule on many construction projects during busy construction season periods when skilled labour is in highest demand. Because both the manufacture and usage in construction are labour intensive, open web steel joists are costly, so that their use is viable only in larger commercial and industrial structures requiring spans near 40 feet and above.
An alternative approach to the open web steel joist is the cold-formed steel joist. Cold-formed steel structural designs have been used in floor and roof joists in the building construction trade for some time. However prior art cold-formed steel joists have found limited application due to the high costs of construction assembly, and are not cost effective for span lengths much above 24 feet usage is restricted to single and multi-family housing, and to commercial low rise structures.
Provided that light gauge steel is used, cost effective mass manufacture of cold-formed steel joists is practical because highly automated cold forming operations such as roll-forming are commercially available. Joists in the prior art are produced by cold-forming a single piece of sheet metal into a joist comprising a top chord, a web and a bottom chord forming a continuous single structure, and are predominately used in bottom chord bearing conditions. These joists are generally eccentric in that the load forces do not pass through the centre of gravity of the joist. The most common example from prior art is the C-shaped joist which has a cross sectional profile like the letter C. Other examples of cold rolled constructions are shown in U.S. Patent Publication Nos. 2002/0020138 A1 and 2003/0084637 A1.
Composite fire rated floor structures constructed using cold-formed joists are commercially available. Examples are Hambro D510 and Speed Floor both of which have end attachments that are welded, bolted or screwed onto a single strip cold-formed section to provide a top chord bearing joist. However these provide only limited load capacity due to the nature of the localized connection of the end attachments to the cold-formed joist member. Further, they are costly to produce. Cold-formed joist manufacturers provide holes longitudinally along the central web section that are sized to receive utilities for follow-up trades. Since cold-formed joist material can be pre-finished (i.e. the coils of steel can be galvanized or painted) the manufacturing process is less harmful to the worker and environment than the open web coating process described above.
Although cold-formed joists possess superior surface finishes, and can be mass manufactured in a cost-effective manner because there is very little dependency on manpower involved relative to the open web joist technology, current state of the art cold-formed joist technology does not fully exploit the inherent strength to mass ratio of steel, nor does it optimize material usage throughout the length of the joist. The same thickness of steel is used in both of the chords and the web, this thickness being constant along the length of the joist. Eccentric designs have a tendency to be unstable under load due to a mechanical moment about the longitudinal axis. Consequently substantial bracing is required between joists to counteract this effect.
These properties compare unfavourably with the open web steel joist where the chords and the web may be of different thickness and the web member thickness may be varied over the span length in response to loading requirements.
Accordingly, a joist and method of producing said joist that can utilize the beneficial attributes while avoiding the drawbacks from each of the open web joist technology and cold-formed joist technology is desirable. Further, it is desirable to manufacture the joist using automated cold-forming methods as opposed to the labour intensive welding and handling methods employed in open web steel joist construction. It is also desirable to have cost effective fire rated composite floors and roofs based on cold-formed steel joists integrally attached to a concrete slab.
Also both open web and cold-formed steel joist floor and roof structures normally require bridging systems, comprising steel members spanning the gap between joists in a floor or roof assembly, to stabilize the assembly from any lateral movement or rotational movement about the longitudinal direction in response to applied loading. It is common practice to weld bridging in place between open web joists, while cold-formed joist systems have bridging structures that commonly use screws or welding for fastening. Consequently a cost effective means to provide bridging between joists is highly desirable.
SUMMARY OF THE INVENTIONA supporting system for use between two opposing supports comprised of at least two joists and at least one bridging member. The joists span between the opposing supports and are adjacent to each other. The joists each include bridging holes. The bridging member are between the adjacent joists and the bridging members are adapted to engage the bridging holes in the joists.
The joists may include an upper chord, a web and a lower chord. The bridging holes may be formed in the web. The bridging holes may be formed in at least one of the upper chord and lower chord.
The bridging members may include generally horizontal bridging members. The bridging members may further include criss-crossed bridging member attached to the generally horizontal bridging members.
The bridging member may be a diaphragm assembly. The diaphragm assembly may include a steel plate.
The bridging member may further include horizontal bridging members and the steel plate may be attached to the horizontal bridging members. The steel plate may have a hole formed therein.
Each bridging may be adapted to be snapped in place.
The bridging holes are a plurality of spaced apart bridging holes.
The upper chord and lower chord may each include at least one inner flange and the bridging holes may be formed in the inner flanges.
The supporting system may include a plurality of joists and a plurality of bridging members.
The bridging members include an upper bridging member and a lower bridging member.
The bridging members may be generally L-shaped.
These and other objects and features of the invention shall now be described in relation to the following drawings:
In the description that follows, like parts are marked throughout the specification and the drawings with the same respective reference numbers. The drawings are not necessarily to scale and in some instances proportions may have been exaggerated in order to more clearly depict certain features of the invention.
The upper and lower chord members 22 and 24 are produced from single sheets of steel. The joist can be formed in a concentric fashion as shown in
In these embodiments the upper chord member 22 is cold-formed to present a substantially flat upper load bearing surface 34 which is formed as shown in
The upper load bearing surface 34 and lower load bearing extensions 36 and 38 are disposed in this case symmetrically about the web 26, the direction of which defines the “Y” axis 27 as shown in
The spot clinches 32 in combination with the cold-formed chords connect the two folded portions 34 and 36 and 34 and 38 to reduce the width to thickness ratio of the section to avoid local buckling. The spot clinch 32 in combination with the cold work forming increases the yield strength of the steel part.
As shown in
The web 26 can include a plurality of utility holes 72 which provide an access for utilities such as electrical wires, air ducts or the like. The holes 72 as shown are circular although any configuration can be produced including square holes or the like. Furthermore, the holes 72 can include a cold-formed lip 74 as shown in
The web 26 may also include a plurality of stiffening means 80 to stiffen of the web member 26.
The stiffening means 80 comprises a first stiffening means 82 and a second stiffening means 84. The first stiffening means 82 generally consists of the ends of the web segment 26 being bent to form a stiffening tab 82 which is disposed at approximately a 90 degree angle from the web 26. The second stiffening means 84 may consist of a hollow embossed rib structure 86 as illustrated in
The hollow rib structure 86 can be produced by a variety of means and in one example is produced by a punch (not shown) which pushes the web material 26 to present the stiffening structure 84. The stiffening structure has two spaced side walls 88 and 90 as well as upper and lower walls 92 and 94 and stiffening front wall 96. The stiffening front wall 96 has stiffening holes 98 which are adapted to receive bridging members 170 and 171 in a manner to be more fully particularized herein.
Furthermore, the web 26 can comprise a plurality of web segments 104, 106 and 108, as shown in
The web segments can either all have the same thickness or have different selected thickness. For example the web segments can be thicker at the ends of the joist than segments in the middle of the joist since the shear stresses under load are greater at the ends than in the middle.
The joist shown in
A structural assembly comprising a plurality of joists 20 partially shown at
A plurality of bridging members 170 and 171 may be used to connect adjacent joists 20 together as shown so as to stiffen the said joist assembly. Parallel bridges 170 may be used as shown in
The bridge members such as 170 may be formed in an L-shaped cross section from sheet steel to produce a first surface 172 and a second surface 174. The second surface 174 is slotted at 176 as shown and the width W of surface 174 is less than the depth D of the hole 98 to permit the end 178 of the bridging member 170 to be inserted into the hole 98 and then rotated so as to lock the edges of the slot 176 against the reinforcement face 96 adjacent the hole 98. Criss-crossed bridging members 171 may then be added and fastened as shown in
A steel deck 198 is adapted to rest on the top surface of the horizontal upper chord extensions 190 as shown in
The shear bond between the extensions 194 and 202 and the concrete may be increased by using rivets spot clinches or the like to increase the surface area of contact between the concrete and the top chord. Despite the asymmetry provided by the horizontal engaging extension 202, this embodiment of the joist is substantially concentric since the extensions 194 and 202 are bonded to the concrete and the steel-concrete composite effectively distributes the applied load to each joist through its centre of gravity
In the following, methods to locate and affix the joist to the opposed supporting walls are described. The joist 20 can be supported along the bottom chord 24 as shown in
In particular the ends 400 of the joist are disposed within the lower stud wall 402 and upper stud wall 404 as shown. The lower stud wall 402 includes a stud wall track 406 which is generally a flat piece of sheet steel 408 bent at its ends so as to present a solid surface to the joist. The upper stud wall 404 includes a similar stud wall track 406. The stud walls 402 and 404 also includes a floor joist track 412 adjacent the end 400 of joist 20.
The view of the joist 20 seen in
In particular the joist 20 rests on a foundation 401 having a bearing support 410. The end 400 of the joist 20 includes a reinforcing flap 82, which provides support against the compressive forces arising from loads applied through the stud wall 404, and is further particularized in
Wooden or metal backing plates 412 are also utilized as shown in
Further end reinforcing members 700 may be utilized which comprises an elongated section of sheet metal having web contacting portions 702 and rigidifying portions 704 extending generally perpendicular to the web contacting portions 702. The ends of the rigidifying portions 704 are bent at 706 and 708 and adapted to contact the upper chord 22 and lower chord 24 respectively. Furthermore fastening means may be utilized to fasten the rigidifying section 700 to web 26 and upper and lower chords 22 and 24.
Moreover
The shear 125 can be used to produce the plurality of segmented webs 104, 106 and 108. Each web segment 104, 106, 108 can have the left hand and right hand stiffening flaps 82 produced by stiffening station 130 and 132. An appropriate punch 133 is used to produce the second stiffening means 84 as described above in a drawing operation. As well, punch 133 is used to produce holes 72 and area embossments 184.
The sheet steel at stations 112, 118 and 122 can be galvanized or painted as desired prior to the forming process. Furthermore the roll forming machine 116 may include punches to punch the appropriate holes 52 in the upper and lower chord members 22 and 24 so as to accommodate the appropriate fastening means 28.
Alternatively the roll forming machine 116 can include apparatus to spot clinch 32 the members together.
Accordingly the joist fabricated herein can be coated with a variety of paint colours which are painted prior to fabrication so as to produce a variety of joists having different colours and avoiding the dip painting characteristic of open web joist construction. The invention as described herein presents a number of advantages over the prior art. For example, many open web steel joists in the prior art include a cambering of the upper and lower chords 4 and 6 so as to present a slight arch to increase load bearing capabilities of the joist. Such prior art cambering techniques required working against the web during the cambering process. Applicant's invention on the other hand presents an advantage since the upper and lower chord members 22 and 24 can be cambered individually and separately from the web 26. Once the upper and lower chord members 22 and 24 are cambered they can be attached to the web 26 as described since the depth of the said camber is adequately contained within the web receiving tabs 46, 48 of the upper chord and 64, 66 of the lower chord as depicted in
Alternate versions of the invention are shown in
As shown in
Perspectives of bottom and top chord bearing composite joist versions of this embodiment are shown in
An alternate embodiment is shown in
A structural assembly comprising a plurality of joists 20 partially shown at
A further aspect of this invention is illustrated in
The snap-in bridging illustrated in
The support structures described in this invention can be utilized either as floor joists or roof joists for single family residential, multi-family residential, commercial or industrial building construction. Further it will be appreciated by those skilled in the art that the system described herein may be used as a stay in place forming system. Analysis and testing of said structures demonstrate that the prior art is advanced in several regards including:
-
- more economical bottom chord bearing cold-formed steel joists with spans up to 40 feet
- more economical top chord bearing joists capable of mass manufacture and customization
- more effective and economical composite floor and roof structures.
Although the joist embodiments as well as the manufacturing operations and use in construction have been specifically described in relation to the drawings, it should be understood that variations in these embodiments could be achieved by a person skilled in the art without departing from the spirit of the invention as claimed herein.
As used herein, the terms “comprises” and “comprising” are to be construed as being inclusive and opened rather than exclusive. Specifically, when used in this specification including the claims, the terms “comprises” and “comprising” and variations thereof mean that the specified features, steps or components are included. The terms are not to be interpreted to exclude the presence of other features, steps or components.
It will be appreciated that the above description related to the invention by way of example only. Many variations on the invention will be obvious to those skilled in the art and such obvious variations are within the scope of the invention as described herein whether or not expressly described.
Claims
1. A supporting system for use between two opposing supports comprising:
- at least two joists spanning between the opposing supports and adjacent to each other wherein the joists each include bridging holes; and
- at least one bridging member between the adjacent joists wherein the bridging members are adapted to engage the bridging holes in the joists.
2. The supporting system of claim 1 wherein the joists include a upper chord, a web and a lower chord.
3. The supporting system of claim 2 wherein the bridging holes are formed in the web.
4. The supporting system of claim 2 wherein the bridging holes are formed in at least one of the upper chord and lower chord.
5. The supporting system of claim 2 wherein the bridging members include generally horizontal bridging members.
6. The supporting system of claim 5 wherein the bridging members further include criss-crossed bridging member attached to the generally horizontal bridging members.
7. The supporting system of claim 2 wherein the bridging member is a diaphragm assembly.
8. The supporting system of claim 7 wherein the diaphragm assembly includes a steel plate.
9. The supporting system of claim 8 wherein bridging member further includes horizontal bridging members and the steel plate is attached to the horizontal bridging members.
10. The supporting system of claim 9 wherein the steel plate has a hole formed therein.
11. The supporting system of claim 10 wherein each bridging is adapted to be snapped in place.
12. The supporting system of claim 1 wherein the bridging holes are a plurality of spaced apart bridging holes.
13. The supporting system of claim 3 wherein the bridging holes are a plurality of spaced apart bridging holes.
14. The supporting system of claim 2 wherein the upper chord and lower chord each include at least one inner flange and the bridging holes are formed in the inner flanges.
15. The supporting system of claim 14 wherein the bridging holes are a plurality of spaced apart bridging holes.
16. The supporting system of claim 1 wherein the supporting system includes a plurality of joists and a plurality of bridging members.
17. The supporting system of claim 1 wherein the bridging members include an upper bridging member and a lower bridging member.
18. The supporting system of claim 17 wherein the bridging members are generally L-shaped.
Type: Application
Filed: Feb 1, 2011
Publication Date: May 26, 2011
Applicant: BEST JOIST INC. (Richmond Hill)
Inventors: Michael Richard STRICKLAND (Richmond Hill), Lei XU (Waterloo)
Application Number: 13/019,205
International Classification: E04C 3/08 (20060101);