The present invention relates to hysteretic damping for structures used in sloped roof constructions, and in particular to a lateral bracing system constructed to provide a high degree of energy dissipation through hysteretic damping along with high initial stiffness so that energy is dissipated at low displacement thresholds within a sloped roof construction.
Shear stresses due to natural phenomena such as seismic activity and high winds can have devastating effects on the structural integrity of sloped roof constructions. Lateral forces generated during such natural phenomena may cause the top portion of a wall to move laterally with respect to the bottom portion of the wall, which movement can result in damage or structural failure of the wall and, in some instances, collapse of the building.
In constructions such as residences, warehouses and small buildings, lateral bracing systems were developed to counteract the potentially devastating effects of shear stress on the structural integrity of light-framed constructions. Although various designs are known, one type of lateral bracing system includes vertical studs spaced from each other and beams affixed to and extending between the studs. In constructions including sloped roofs, the beams may extend at an obtuse or acute angle from the vertical columns.
Many conventional lateral bracing systems perform well initially under lateral loads, but yield and fail upon the repetitive lateral loads which often occur during significant seismic activity and high winds. Upon appreciable yield or failure of the lateral bracing system, the entire system must be replaced.
The present technology relates to a lateral bracing system of a moment frame for use in a slope roof construction. The moment frame comprises a pair of spaced apart vertical columns, and a pair of beams extending from the columns at the angle of the roof and connected to each other at an apex of the roof. Each column may include a top portion with a connecting face perpendicular to an axial length of the beam when assembled.
The moment frame may further include a pair of lateral bracing systems used to attach the beams to the columns. Each lateral bracing system may further include a pair of buckling-restrained braced devices, affixed to the top and bottom flanges of the beam. Each buckling-restrained braced device comprises a yield link affixed between the beam and column, and a buckling restraint plate covering a portion of the yield link. In one embodiment, the yield link may affix to the end face of the column with a right-angle plate (perpendicular to a major plane of the yield link). In a second embodiment, the yield link may affix to a top edge of the column with a flat plate (parallel to a plane of the yield link). By providing the connecting face of the column perpendicular to an axial length of the beam, the tensile and compressive forces exerted on the yield link by the beam and column are constrained to the plane of the yield link.
In one example, the present technology relates to a sloped roof construction, comprising: a beam having a major axis at a non-horizontal angle following a slope of the roof; a column comprising a connecting face configured to be oriented at an angle perpendicular to the major axis of the beam; a shear tab affixed between the column and beam, between a top and bottom flange of the beam; and a lateral bracing system affixed between the column and beam, including: first and second buckling-restrained braced devices, one each on the top and bottom flange of the beam, each buckling-restrained braced device comprising: a yield link comprising a first end connected to the column and a second end connected to the beam, the yield link comprising a section of narrowed width defining first and second notches on opposite sides of the yield link, the yield link configured to yield in tension and compression at the narrowed width section to dissipate stress within the construction upon a lateral load applied to the beam and/or column; first and second spacers fitting within the first and second notches, respectively; a buckling restraint plate configured to mount over the yield link and spacers to sandwich the yield link and spacers between the buckling restraint plate and the face of one of the top and bottom flanges of the beam.
In a further example, the present technology relates to a sloped roof construction, comprising: a column comprising: a top edge at a non-horizontal angle following a slope of the roof, and a connecting face adjacent the top edge; a beam having a major axis at the non-horizontal angle following the slope of the roof; a shear tab affixed between the column and beam, between a top and bottom flange of the beam; and a lateral bracing system affixed between the column and beam, including: first and second buckling-restrained braced devices, one each on the top and bottom flange of the beam, the first buckling-restrained braced device comprising: a first yield link comprising: a first end comprising a first planar section with a first surface configured to mount parallel to and against the top edge of the column, a second end comprising a second planar section with a second surface configured to mount parallel to and against the first flange of the beam, and a section of narrowed width between the first and second ends, the narrowed width section defining first and second notches on opposite sides of the first yield link, the first yield link configured to yield in tension and compression at the narrowed width section to dissipate stress within the construction upon a lateral load applied to the beam and/or column; first and second spacers fitting within the first and second notches, respectively; and a buckling restraint plate configured to mount over the first yield link and spacers to sandwich the first yield link and spacers between the buckling restraint plate and the first flange of the beam.
In another example, the present technology relates to a sloped roof construction, comprising: a vertical column comprising: a top edge at a non-horizontal angle following a slope of the roof, and a connecting face adjacent the top edge, the connecting face provided at a non-vertical angle perpendicular to the slope of the roof; a beam having a major axis at the non-horizontal angle following the slope of the roof; and a lateral bracing system affixed between the column and beam, including: first and second buckling-restrained braced devices, one each on a top flange and a bottom flange of the beam. The first buckling-restrained braced device comprises: a first yield link comprising: a first end comprising a first planar section with a first surface configured to mount parallel to and against the top edge of the column, a second end comprising a second planar section with a second surface configured to mount parallel to and against the first flange of the beam, and a first section of narrowed width between the first and second ends, the first narrowed width section defining first and second notches on opposite sides of the first yield link, the first yield link configured to yield in tension and compression at the first narrowed width section to dissipate stress within the construction upon a lateral load applied to the beam and/or column; and a first buckling restraint plate configured to mount over the first yield link to sandwich the first yield link between the buckling restraint plate and the first flange of the beam. The second buckling-restrained braced device comprises: a second yield link comprising: a first end comprising a perpendicular plate configured to mount parallel to and against the connecting face of the column, a second end comprising a planar section with a surface configured to mount parallel to and against the second flange of the beam, and a second section of narrowed width between the first and second ends, the narrowed width section defining first and second notches on opposite sides of the yield link, the yield link configured to yield in tension and compression at the second narrowed width section to dissipate stress within the construction upon a lateral load applied to the beam and/or column; and a second buckling restraint plate configured to mount over the second yield link to sandwich the second yield link between the buckling restraint plate and the second flange of the beam.
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 as an aid in determining the scope of the claimed subject matter. The claimed subject matter is not limited to implementations that solve any or all disadvantages noted in the Background.
The present invention will now be described with reference to
Referring now to
The moment frame 108 may further include a pair of lateral bracing systems 120 coupling the columns 110 and beams 112 to each other on each side of the construction 100. Each lateral bracing system 120 on opposed sides of a moment frame 108 may be the mirror image of the other, though they need not be in further embodiments. As such, one lateral bracing system 120 is described below, with the understanding that the other lateral bracing system in a given moment frame 108 includes the identical components in mirror image.
Each column 110 may be formed of primary portion 110a, extending most of the length of column 110, and a top portion 110b formed at a top of column 110. The primary and top portions may be formed integrally with each other, and may for example include a stiffener flange 121 at a boundary between the primary and top portions. In further embodiments, the primary and top portions may be welded, bolted or otherwise affixed to each other after they are formed. The primary portion 110a may comprise a first flange (affixed to wall 102) extending vertically, and a second flange which is angled relative to vertical so that the web of the primary portion 110a tapers along its length to be wider at the top of the primary portion 110a than at a base of the primary portion 110a. In one example, the top of the primary portion 110a may have a width of 24″ to 60″, and it may taper to a bottom having a width of 8″ to 12″. These dimensions are by way of example only, and the top and/or bottom dimensions may vary in further embodiments. Both flanges of the primary portion 110a may be vertical and parallel to each other in further embodiments. The beams, while shown as constant depth, might also taper in depth along their length.
The top portion 110b may comprise a first flange (affixed to wall 102) extending vertically from the first flange of the primary portion 110a. The top portion 110b may have a second, non-vertical flange. In embodiments the second flange tapers inward from bottom to top, so that the web of the top portion 110b is wider at its base than at its top. The second flange of the top portion 110b of column 110 forms a connecting face to which the beam 112 is affixed via a lateral bracing system.
In embodiments, the second flange of the top portion 110b is provided at an angle that is perpendicular to a major axis of the beam 112 (i.e., along the beam axial length) and a slope of the roof 104 when assembled. As explained below, this configuration ensures that the forces exerted on a yield link of the lateral bracing system between the beam and column remain in the major plane of the yield link.
As seen for example in
Yield link 126 may further include bolt holes 136 in planar section 132, at a second end of the yield link 126 opposite plate 128. Bolt holes 136 are provided to bolt holes 130, and are provided to allow bolting of the second end of the yield links to the top and bottom flanges of beam 112.
A shear tab 140 may further be affixed between the connecting face 122 and the web of beam 112. The shear tab 140 may include a flange 142 parallel to connecting face 122 and configured to be bolted or welded to connecting face 122. Shear tab 140 further include plate 144 parallel to the web of beam 112, and configured to be bolted to the web of beam 112. In particular, plate 144 includes a central circular hole 146 for bolting plate 144 to the web of beam 112. Plate 144 further includes oblong holes 148 for bolting plate 144 to the web of beam 112, while allowing rotation of the beam relative to the column. As explained below, upon lateral loads above a predefined threshold, the beam will rotate relative to the column. The lateral bracing system is configured to allow such rotation, which will take place about an axis through central bolt hole 146. The oblong holes 148 have slots oriented tangential to radii from central bolt hole 146, and will allow such rotation without damage to the shear tab or beam web. At the same time, the holes 146 and 148 support the beam 112 against gravity on column 110. The number, position and size of the oblong holes 148 is shown by way of example, and the number, position and/or size may vary in further embodiments.
As seen in
Referring to
The spacers 152 may be the same thickness as the yield link 126, and may take up most or substantially all of the empty space defined by notches 135, for example between 60% to 99%, or for example 80% to 90% of the area of the notches 135. In this way, the spacers 152 ensure uniform load distribution of the BRPs 150 on the yield links 126 when the BRPs 150 are bolted over the yield links 126.
The lateral bracing systems 120 in a moment frame 108 have the advantage that they may be easily assembled on-site. In one example, the yield link 126 and shear tab 140 may be assembled onto the column 110 before arrival at the job site, or before column 110 is erected. Thereafter, once the column 110 and beam 112 are positioned, the opposite ends of the yield link and shear tab may be affixed to the beam. These connections may for example be made by bolting and no on-site welding is required.
In operation, the pair of buckling-restrained braced devices 124 operate in tandem to oppose rotation of the beam 112 relative to the column 110 (i.e., rotation about the shear tab 140) under a lateral load. Attempted rotation in a first direction will place the first of the devices 124 in tension and the second of the devices in compression. Attempted rotation in the opposite direction will place the first of the devices in compression and the second in tension.
The yield link 126 of the respective devices 124 provides high initial stiffness and tensile and compression resistance to relative movement between the column 110 and the beam 112 under lateral loads, but provides stable yielding and hysteretic energy dissipation under lateral loads above a predictable and controlled level. In particular, the bending strength of the column and beam may be designed to exceed the moment capacity of the yield links 126, and in particular, the reduced diameter section 134 of yield links 126. Thus, the yield links 126 yield under lateral loads before yielding or failure of the column or beam, and any damage is limited to the yield links which may be easily removed and replaced.
The BRPs 150 prevent buckling of the yield links under a compressive load. The shear tab 140 is provided to oppose beam end shear (i.e., beam shear orthogonal to the major axis of beam 112) under vertical and lateral frame loads.
Upon lateral loads, the perpendicular plates 128 of the yield links 126 exert forces on the connecting face 122 of the column 110 to which the yield links are attached. Accordingly, stiffening plates 156 may optionally be affixed to a side of the connecting face 122 opposite that receiving the yield links to oppose the forces exerted by the yield links. A stiffening plate 156 may be mounted perpendicularly to the web of top column portion 110b, on one or both sides of the web, to oppose the forces on the portion 110b from the bottom yield link 126. The length of the stiffening plate 156 may be aligned with the major plane of the yield link (perpendicular to the connecting face 122).
A second stiffening plate 156 may be mounted on top of the columns 110 to oppose the forces on the portion 110b from the top yield link 126. The second stiffening plate 156 may be mounted on a top edge of the top column portion 110b, in the plane of the web of top portion 110b. As seen in
Embodiments of the present technology shown in
Each column 210 may be formed of primary portion 210a, extending most of the length of column 210, and a top portion 210b formed at a top of column 210. The top portion 210b may comprise a first flange (affixed to wall 102) extending vertically from the first flange of the primary portion 210a. The top portion 210b may have a second flange extending at a non-vertical angle. In embodiments the second flange tapers inward from bottom to top, so that the web of the top portion 210b is wider at its base than at its top. The second flange of the top portion 210b of column 210 forms a connecting face 222 to which the beam 212 is affixed.
In embodiments, the connecting face of the top portion 210b is provided at an angle that is perpendicular to a major axis of the beam 212 and a slope of the roof 104 when assembled. As explained below, this configuration ensures that the forces exerted on the yield link between the beam and column remain in the plane of the yield link.
In the second embodiment, the first (bottom) buckling-restrained braced device 224a includes a yield link 226a, and the second (top) buckling-restrained braced device 224b includes a yield link 226b. The bottom yield link 226a may be identical to the bottom yield link 126 described above, including a perpendicular plate 228 forming a flange at a first end of the link that is perpendicular to a length and major plane of the yield link 226a. The perpendicular plate 228 of link 226a may include bolt holes 230, as described above with respect to
In accordance with this second embodiment, the top yield link 226b may have no perpendicular plate, but may instead be a generally flat, planar component along its entire length. As shown in edge view in
The top edge 229 is provided at a non-horizontal angle matching the major axis of the beam 212 and following a slope of the roof 104. The top edge 229 is also coplanar with the top flange of beam 212. Thus, the flat plate yield link 226b may lie flat on top of both the top flange of beam 212 and the top edge 229 of column 210, and be bolted to the top flange of beam 212 and the top edge 229 via bolt holes 236. While the top of the connecting face 122 extended above the top edge of top column portion 110b in the embodiment of
A shear tab 240 may further be affixed between the connecting face 222 and the web of beam 212. The shear tab 240 may be structurally and operationally identical to shear tab 140. The beam 212 may include notches 249 at its top and bottom flanges that are structurally and operationally identical to notches 149. Each of the two buckling-restrained braced devices 224 may further include a buckling restraint plate (BRP) 250, and spacers 252 in notches 235 of both yield links 226a, 226b. BRP 250 and spacers 252 may be structurally and operationally identical to BRP 150 and spacers 152, respectively.
In operation, the pair of buckling-restrained braced devices 224 operate in tandem to oppose rotation of the beam 212 relative to the column 210 (i.e., rotation about the shear tab 240) under a lateral load. Attempted rotation in a first direction will place the first of the devices 224 in tension and the second of the devices in compression. Attempted rotation in the opposite direction will place the first of the devices in compression and the second in tension.
The yield links 226a, 226b of the respective devices 224 both provide high initial stiffness and tensile and compression resistance to relative movement between the column 210 and the beam 212 under lateral loads, but provide stable yielding and hysteretic energy dissipation under lateral loads above a predictable and controlled level. The yield link 226a may transmit tensile and compressive loads (before yielding) to and from the column top portion 210a via the perpendicular plate 228. The yield link 226b may transmit tensile and compressive loads (before yielding) to and from the column top portion 210a via the bolts in bolt holes 236b. Stiffening plate 256 may optionally be affixed to the connecting face 222 to oppose the tensile and compressive forces exerted by the yield link 226a. Stiffening plate 256 may be structurally and operationally identical to stiffening plate 156 described above.
In the embodiments described above, the roof 104 has an apex generally midway between opposed walls 102, such that both beams 112/212 on opposed walls 102 slope upward from their connection to columns 110/210. In a further embodiment of the present technology shown in
The moment frame 308 includes a pair of lateral bracing systems 320a and 320b, one of which couples the columns 310 and beam(s) 312 to each other on each side of the construction the moment frame 308. On a first side of construction 100, the beam 312 angles upward from the column 310, following the slope of the roof 104, and lateral bracing system 320b on that first side may be identical to the lateral bracing systems 120/220 described above in coupling the first column 310 to the beam 312.
On the second side of the construction 100, the beam 312 angles downward from the column 310 at the lateral bracing system 320b.
The lateral bracing system 320 in
Referring now to
The lateral bracing system 320 in
It is a feature of the above-described embodiments that the connecting face 122/222 of the column is perpendicular to a major axis of the beam 112 and a slope of the roof 104 when assembled. Thus, the angle of the connecting face 122/222 will vary depending on the slope of the roof and beams. Having the connecting face 122/222 perpendicular to an axial length of the beam ensures that the loads on the yield link 126/226a/226b will be tensile and compressive loads in the plane of the yield link.
Similarly, for the embodiment including flat plate yield link 226b, the top edge 229 of the column is also provided at an angle that matches a slope of the beam 212 and roof 104, and the top edge 229 is coplanar with a top surface of the top flange of the beam 212. Having the top edge 229 coplanar with the top flange of the beam ensures that the loads on the flat plate yield link 226b will be tensile and compressive loads in the plane of the yield link.
As used herein, a connection may be a direct connection or an indirect connection (e.g., via one or more other parts). In some cases, when an element is referred to as being affixed, connected or mounted to another element, the element may be directly connected to the other element or indirectly connected to the other element via intervening elements. When a first element is referred to as being directly affixed, directly connected or directly mounted to a second element, then there are no intervening elements between the first and second elements.
Although the invention has been described in detail herein, it should be understood that the invention is not limited to the embodiments herein disclosed. Various changes, substitutions and modifications may be made thereto by those skilled in the art without departing from the spirit or scope of the invention as described and defined by the appended claims.
This application claims priority to U.S. Provisional Patent Application No. 63/150,460, entitled “MOMENT FRAME FOR A SLOPED ROOF CONSTRUCTION”, filed Feb. 17, 2021, which application is incorporated herein by reference in its entirety.
Number | Name | Date | Kind |
---|---|---|---|
4074947 | Matake | Feb 1978 | A |
4696137 | Schleich | Sep 1987 | A |
6474902 | Beauvoir | Nov 2002 | B1 |
6739099 | Takeuchi | May 2004 | B2 |
7497054 | Takeuchi | Mar 2009 | B2 |
8074359 | Bong | Dec 2011 | B2 |
10550572 | Webb | Feb 2020 | B2 |
10669718 | Pryor | Jun 2020 | B2 |
11162260 | Pryor | Nov 2021 | B2 |
20020184836 | Takeuchi | Dec 2002 | A1 |
20040187430 | Takeuchi | Sep 2004 | A1 |
20040244330 | Takeuchi | Dec 2004 | A1 |
20050257451 | Pryor | Nov 2005 | A1 |
20060144006 | Suzuki | Jul 2006 | A1 |
20100205891 | Bong | Aug 2010 | A1 |
20130001383 | Jay | Jan 2013 | A1 |
20130200227 | Jay | Aug 2013 | A9 |
20190010700 | Webb | Jan 2019 | A1 |
20190292783 | Pryor | Sep 2019 | A1 |
20190330873 | Richard | Oct 2019 | A1 |
20200109556 | Pryor | Apr 2020 | A1 |
20200291653 | Pryor | Sep 2020 | A1 |
20200354947 | Richard | Nov 2020 | A1 |
20230117355 | Robinson | Apr 2023 | A1 |
Number | Date | Country |
---|---|---|
202008012407 | Mar 2009 | DE |
2228920 | Dec 1974 | FR |
Entry |
---|
International Search Report and Written Opinion dated May 31, 2022 in International Patent Application No. PCT/US2022/016826. |
English language Abstract for FR2228920 published Dec. 6, 1974. |
English language machine translation for DE202008012407 published Mar. 26, 2009. |
Number | Date | Country | |
---|---|---|---|
20220259844 A1 | Aug 2022 | US |
Number | Date | Country | |
---|---|---|---|
63150460 | Feb 2021 | US |