The present invention relates to a beam for use in a frame for building structures such as walls, floors, roofs, etc., the beam having a pair of spaced apart chords joined by clips. In its various aspects, the invention concerns: the clips which join the chords; the assembled beam; the frame including such beams; and methods for assembling the beam and frame.
There are a variety of approaches currently taken to the construction of frames for building structures such as walls, floors, ceilings, trusses, etc. One example, a wood beam used as a stud or a joist, is still in common use. Wood is becoming increasingly expensive and should be treated to prevent rot and possible insect infestation. Wood may also warp and may be of inconsistent quality. A general characteristic of a wood beam is that a beam of given dimensions has particular load bearing characteristics, and increasing the load bearing characteristics of a frame constructed of wood beams generally requires using a greater number of beams or beams of increased cross-dimension. Wood, being a solid material, also requires holes to be drilled for the passage of concealed wires, etc., through the beams of a floor, or wall. Wood beams nevertheless have an advantage of being easily cut to fit a particular application, although a certain amount of pre-fabrication of wooden building frames has become common.
When designing a building structure, an architect or designer determines the load which the structure is required to bear. Load bearing beams are selected from those which are available. Consideration is given to material characteristics, such as weight, cost, beam spacing and dimension required to bear the required load. An architect is limited by these considerations. For example, an architect may prefer to use 6″ deep wood joists in a floor, but finds that to meet the determined load requirement, the joists must be spaced no more than 14″ apart. Standard sub-flooring materials require joists spaced at 48″ intervals. A common solution to this problem would be simply over-build the floor by using the 6″ deep wooden joists spaced 12″ apart. This would result in the use of more material and labor necessary than to simply meet the determined load bearing capacity. An alternative solution might be to use 8″ deep wooden joists spaced 16″ apart, but this changes the depth, i.e. thickness, of the floor which may be undesirable or even not possible within the constraints of a particular situation. In any event, it might still lead to an over-built floor. It would thus be advantageous to have a beam for use in a building structure which beam permits the load bearing capacity of the structure to be conveniently tailored to a particular situation without necessarily requiring alteration of the beam dimension or spacing. Such a beam would provide a structure having material and labor costs more commensurate with the load bearing requirements of the structure.
One example of providing for a beam for use in a building structure which permits the load bearing capacity to be tailored to a particular situation without requiring alteration of the beam dimension or spacing is found in U.S. Pat. No. 5,761,873 to Slater. The invention disclosed in Slater provides for beams made from metal webs attached to the outside of metal chords, which beams can be used to form building structures, such as walls and floors. While the Slater invention works well in many situations, it would be advantageous to have an improved building system to provide for greater strength with less components and less weight, in an easier and more cost effective composition, while still providing a beam for use in a building structure that permits the load bearing capacity of the structure to be conveniently tailored to a particular situation without necessarily requiring alteration of the beam dimension or spacing.
The approach of the present invention is to provide load bearing members of a building structure, such as beams for wall studs, floor joists and roof trusses, which are tailored such that the load requirements of a particular building structure are met. Each beam is assembled to include a pair of component chords and at least one clip, which are selected from a set of chords and clips according to a recipe. Given the load bearing requirements of a structure, the recipe indicates beam spacing within the frame, the type of chord, the type of clips and the number and position of clips to be included in each beam.
The present invention thus provides, in one aspect, a beam kit of parts. The kit includes standard chords and clips. These are assembled into beams according to a recipe and included in the frame of a structure having a required load-bearing capacity according to predetermined criteria. The recipe for beam assembly indicates which type of chords to include in each beam, and the number and type of clips to be included. The predetermined criteria indicate the spacing of beams necessary for the required load bearing capacity of the structure.
According to a preferred embodiment, the set of chords include generally “T” shaped chords formed from a flat length of metal, being steel, aluminum or other such composite material, by a rolled-form process, or other similar shaping process, leaving an opening at the end of the elongate vertical portion of the “T” shaped chord. Two chords are connected together by clips formed from metal, being steel, aluminum or other such composite material, by a rolled-form process, or other similar shaping process. A clip may be a plate clip, a tubular clip or other clip, depending on the strength requirements of the desired beam. The clips have tag portions which fit inside the opening at the ends of the elongate portion of the “T” shaped chords, at which points the clips may be fastened to the chords by fastening means, such as clinching, screwing or bolting. Clips are preferably dimensioned such that an assembled beam is of a depth which may be used with conventional building materials.
The present invention also includes methods for assembling beams and constructing frames, walls, floors, ceilings, trusses and other building forms from such beams.
A method for assembling a beam for use as part of a frame of a building structure having a required load bearing capacity includes selecting a combination of chords and clips according to a recipe; positioning a first clip and chord in a predetermined position; fastening the clip and chord according to a recipe; positioning a second chord in a position parallel to the first chord and for fastening to the clip and fastening the second chord and clip together according to a recipe.
A method for constructing a frame for a load-bearing building structure includes determining the load required to be borne by the structure; determining beam spacing and beam dimensions required for the frame to bear the load according to predetermined criteria; assembling beams by fastening together standard chords and clips according to a recipe indicating the number of clips and the types of clips and chords to be included in each beam and incorporating so assembled beams as part of the frame to have the determined spacing.
a is a cross-sectional view of a standard chord.
b is a cross-sectional view of an expanded chord;
a is a perspective view of a plate clip;
b is a cross-sectional view of a plate clip;
a is a side perspective view of a tubular clip;
b is a front perspective view of a tubular clip;
a is an isometric view of a joist end connection connecting the end of a joist to a top track and a beam;
b is a cross-sectional view of a joist end connection;
a is a perspective view of a beam with a brick connector;
b is a cross-sectional view of a beam with a brick connector;
Referring to the drawings,
a shows the cross-section of a standard chord 22. The standard chord 22 has a cross-section that is generally “T” shaped which can be formed from a flat length of metal, being steel, aluminum or other such composite material, by a rolled-form process, or other similar shaping process. This forms a standard chord 22 with a top portion 21, opposing side wall portions 25 of length y, two connecting portions 27 and an elongate portion 29 of length x. An opening 26 is formed at the distal end of the elongate portion 29 of standard chord 22 between two substantially parallel members 23 of the elongate portion 29. A depression 28 is formed in the top portion of standard chord 22.
b shows the cross-section of an expanded chord 32. The expanded chord 32 has a cross-section that is generally “T” shaped which can be formed from a flat length of metal, being steel, aluminum or other such composite material, by a rolled-form process, or other similar shaping process. This forms an expanded chord 32 with a top portion 31, opposing expanded side wall portions 35 of length y′, two connecting portions 37 and an elongate portion 39 of length x′. An opening 36 is formed at the distal end of the elongate portion 39 of standard chord 32 between two substantially parallel members 33 of the elongate portion 39. A depression 38 is formed in the top portion of expanded chord 32.
The length x and x′ of the chords 22 and 32 as shown in
As seen in
a and 4b illustrate tubular clips 100 which are formed from a tubular length of metal or other composite which is flattened at each end to form tag portions 104 at opposing ends of a central portion 102. As illustrated in
An example of a corner arrangement for wall frame members is shown in
A joist end connection is shown in
A portion of a building frame, having studs and joist made from beams assembled from the present invention is shown in
Sheathing such as drywall, stucco, sheet metal, rigid foam insulation, etc. may be secured to beams in a conventional manner. Drywall screws may be fastened directly into the chords of the preferred embodiment.
a and 15b show a brick connector 150 for beam 20 installed included as a stud as part of a wall frame. Brick connector 150 includes sheet metal trough with walls 152, 154 and base 156 secured to beam 20 by fastening means, such as screws. Lateral extension 158 having aperture 160 for receipt of tie wire 162 provides for connection of a brick veneer wall to the beam in a manner familiar to those skilled in the art, and illustrated further below.
Beam 20 installed as part of an outer wall is illustrated in
Beam 20 may be installed as part of an outer wall as illustrated in
Beam 20 may be installed as part of an outer wall as illustrated in
Exemplary building components including beams of the present invention are shown in
The strength of a beam may be tailored to suit a particular framing application by the use of chords of a particular strength and by the use of clips having a particular size and shape and by the use of particular configurations for fastening the clips and chords together. Examples of the manner in which a beam of the preferred embodiment is tailored for particular applications are given below.
Chords and clips of the illustrated embodiment may be made from galvanized steel, ASTM A513-35Y. The gauge of steel depends upon the strength requirements of the application for which the beam is to be used, and is generally in the range between 22 GA and 14 GA. The chords and clips may also be manufactured from aluminum or other composite materials.
The preferred embodiment beam is shown in use as part of frames for various building structures. It will be appreciated that in certain contexts the beam is used in place of a conventional stud, joist, etc. but that the beam has additional uses as well.
It will further be appreciated that beam 20 may be supplied as a “kit of parts” including unassembled chords and clips. The beam may thus be shipped and stored compactly and assembled at a building construction site or possibly by a manufacturer prior to shipment.
The following examples are provided for purposes of illustrating various aspects of the preferred embodiment of the present invention. It will be appreciated by a person skilled in the art that other and additional configurations can be made by varying the parameters without venturing beyond the scope of the present invention.
The following examples are provided based on the International Building Code—2006, North American Specification—2001 and ASTM quality standards. It will be appreciated by a person skilled in the art that varying the standards will require other and additional configurations, which can be obtained without venturing beyond the scope of the present invention.
Example 1 illustrates the fabrication of a wall stud 8 feet in length. The Depth refers to the outside dimension. The Chord Type refers to the nature of the cross-section profile of the chord, where 1 refers to the standard chord with measurement “y” approximately equal to ¼″ and where 2, 3 and 4 refer to the expanded side wall chord with measurement “y1” approximately equal to ½″, 1½″ and 2½″, respectively. The Gauge refers to the thickness of the steel, where 20, 18 and 16 refer to thicknesses of 0.032″, 0.044″ and 0.06″, respectively. The Clip Type refers to the kind of clip to be used, where 1 refers to a tubular clip 1″ in diameter and 2 refers to a plate clip. The clips used in any given wall stud are all of the same dimension from tag portion to tag portion. The number of clips refers to the quantity of clips to be used, where there is always one clip approximately 2″ from each end of the beam and the remaining clips are distributed such that the center points of all clips are equally spaced from one another. Where more than one number is indicated for the number of clips and gauges, the first number of clips is matched with the first gauge number and each subsequent number of clips is matched with each subsequent gauge number. In the event that clips of different gauges are to be used in the same beam, the thicker clip(s) is/are to be affixed in the positions lowest to the bottom of the beam.
Referring to Table 1 for the fabrication of wall stud of 8 feet in length and 6 inches in depth, the desired wind load is chosen from the table, indicating the appropriate row of information. The type and gauge of chord is referenced in the corresponding column in that row. The number and type and gauge of clips is also referenced from the corresponding column in that row. The wall stud is then fabricated by inserting the clips within the chords in the positions indicated by the above noted recipe and fastening the clips to the chords.
Example 2 illustrates the fabrication of a floor joist 10 feet in length. The Depth refers to the outside dimension. The Chord Type refers to the nature of the cross-section profile of the chord, where 1 refers to the standard chord with measurement “y” approximately equal to ¼″ and where 2, 3 and 4 refer to the expanded side wall chord with measurement “y1” approximately equal to ½″, 1½″ and 2½″, respectively. The Gauge refers to the thickness of the steel, where 20, 18 and 16 refer to thicknesses of 0.032″, 0.044″ and 0.06″, respectively. The Clip Type refers to the kind of clip to be used, where 1 refers to a tubular clip 1″ in diameter and 2 refers to a plate clip. The number of clips refers to the number of sets of two clips to be used, where a set of clips comprises two tubular clips attached to the bottom chord at approximately the same location at an angle to each other that is approximately 90 degrees. The clips used in any given joist are all of the same length. The clip sets are positioned with the outer upper connection of a clip set approximately 2″ from each end of the top chord. The remaining clip sets are spaced such that the center of the bottom connection points are equidistant from each other.
Referring to Table 2 for the fabrication of a floor joist of 10 feet in length and 8 inches in depth, the desired factored load is chosen from the table, indicating the appropriate row of information. The type and gauge of top chord and bottom chord is referenced in the corresponding column in that row. The number of clip sets and gauge of clip is also referenced from the corresponding column in that row. The floor joist is then fabricated by inserting the clips within the chords in the positions indicated by the above noted recipe and fastening the clips to the chords.
Example 3 illustrates the fabrication of a truss 30 feet in span. The Height refers to the distance between the bottom chord of the truss and the peak of the truss. The Chord Type refers to the nature of the cross-section profile of the chord, where 1 refers to the standard chord with measurement “y” approximately equal to ¼″ and where 2, 3 and 4 refer to the expanded side wall chord with measurement “y1” approximately equal to ½″, 1½″ and 2½″, respectively. The Gauge refers to the thickness of the steel, where 20, 18 and 16 refer to thicknesses of 0.032″, 0.044″ and 0.06″, respectively. The Clip Type refers to the kind of clip to be used, where 1 refers to a tubular clip 1″ in diameter and 2 refers to a plate clip. The Quantity refers to the number of clips used in the truss. The clips used in any given truss are not all of the same length. The truss clips are positioned according to the configuration chosen from those which are commonly known in the art, depending on the span, pitch and loads required.
Reference is made to
Referring to Table 3 for the fabrication of a truss of 30 feet in span and 5′6″ inches in height, the desired loads are chosen from the table, indicating the appropriate row of information. The type and gauge of top chords and bottom chord is referenced in the corresponding column in that row. The number of clips and gauge of clip is also referenced from the corresponding column in that row. The truss is then fabricated by inserting the clips within the chords in the positions indicated by the above noted recipe and fastening the clips to the chords.