The specification relates to a locating pin assembly, a hoistable pin assembly using the locating pin assembly, a method for coupling modular frame units having the locating pin assembly, a method of assembling a modular unit having the locating pin assembly and a building having the locating pin assembly.
Modular buildings and modular homes are sectional prefabricated buildings, or houses, that consist of multiple sections called modules. “Modular” is a method of construction differing from other methods of building. The module sections are constructed at an off site (sometimes, remote) facility, then delivered to the intended site of use. Complete construction of the prefabricated sections are completed on site. The prefabricated sections are sometimes lifted and placed on basement walls using a crane, the module prefabricated sections are set onto the building's foundation and joined together to make a single building. The modules can be placed side-by-side, end-to-end, or stacked, allowing a wide variety of configurations and styles in the building layout.
Such prefabricating modular building units constructed from standardized components in a controlled factory setting can be desirable due to the lowered costs and the increased quality which is obtainable in comparison to performing similar work on an outdoor construction job site. Thus prefabricated modular building units having a floor, walls and an overhead structure, and which contain all the systems and furnishings pre-installed within them can be preferred and known in the art. Building assembly systems composed of the means and methods to join two or more modular building units together to form a larger structure are also known in the art.
Devices which engage a specially prepared aperture on the upper or side surface of the structural frame so as to provide a releasable connection for the purpose of lifting, moving and connection of the modular building units are known in the art. For instance, PCT publication numbers WO 2014/127472, WO 2015/164975, WO 2016/165022 and WO 2017/027965, and PCT application number PCT/CA2018/050065 (all incorporated herein by reference and the reader is directed to the relevant sections for further consideration) disclose various connectors for coupling and forming modular building structures.
Although the connectors referred to above can help address a number of issues, in particular, for forming tall, multi-story and slender buildings, there is still a need in the art for connectors for forming short and few-story buildings that can help to reduce the overall cost and increase efficiency in the construction of such buildings.
In one aspect, the specification relates to a locating pin assembly for coupling a first modular frame to a second modular frame, the first modular frame having a first-modular-frame-first-hollow-tubular-member and a first-modular-frame-first-beam coupled at a first end of the first-modular-frame-first-hollow-tubular-member, and the second modular frame having a second-modular-frame-first-hollow-tubular-member and a second-modular-frame-first-beam coupled at a first end of the second-modular-frame-first-hollow-tubular-member, the locating pin assembly having:
In another aspect, the specification relates to a modular frame assembly having:
a first modular frame coupled to a second modular frame with a locating pin assembly sandwiched between the first modular frame and the second modular frame, the first modular frame having a first-modular-frame-first-hollow-tubular-member and a first-modular-frame-first-beam coupled at a first end of the first-modular-frame-first-hollow-tubular-member, and the second modular frame having a second-modular-frame-first-hollow-tubular-member and a second-modular-frame-first-beam coupled at a first end of the second-modular-frame-first-hollow-tubular-member, wherein the locating pin assembly having:
In another further aspect, the specification relates to a system of modular frame units for forming a modular building, having a first modular frame coupled to a second modular frame with a locating pin assembly sandwiched between the first modular frame and the second modular frame, wherein the locating pin assembly is as described herein.
In still another aspect, the specification relates to a method of coupling modular frame units for forming a modular building, having coupling a first modular frame to a second modular frame with a locating pin assembly sandwiched between the first modular frame and the second modular frame, wherein the locating pin assembly is as described herein.
In still another further aspect, the specification relates to a hoistable modular frame unit, comprising a locating pin assembly coupled to a first modular frame, wherein the locating pin assembly is as described herein.
Reference will now be made, by way of example, to the accompanying drawings which show example embodiments of the present application, and in which:
Similar reference numerals may have been used in different figures to denote similar components.
Related aspects of applications of the locating pin assembly and the modular units are described in PCT publication numbers WO 2014/127472, WO 2015/164975, WO 2016/165022 and WO 2017/027965, and PCT application number PCT/CA2018/050065 (all incorporated herein by reference) and the reader is directed to the relevant sections for further consideration.
The locating pin assembly, a hoistable pin assembly using the locating pin assembly, a method for coupling modular frame units having the locating pin assembly, a method of assembling a modular unit having the locating pin assembly and a building having the locating pin assembly will be described with reference to the Figures.
The embodiment of the first modular frame 4 shown in
A pair of beams 10 (noted herein as a first-modular-frame-first-beam) are coupled to the first-modular-frame-first-hollow-tubular-member 8 at the first end 12 of the first-modular-frame-first-hollow-tubular-member 8. The pair of beams 10 (first-modular-frame-first-beam) extending perpendicularly to the first-modular-frame-first-hollow-tubular-member 8 and to each other. In other words, if the first-modular-frame-first-hollow-tubular-member 8 lies in the Z-axis, one of the first-modular-frame-first-beam 10 extends in the X-axis and the other first-modular-frame-first-beam extends in the Y-axis. The method of coupling the first-modular-frame-first-beams 10 to the first-modular-frame-first-hollow-tubular-member 8 is not particularly limited, and should be known to a person of skill in the art. In one embodiment, for example and without limitation, the first-modular-frame-first-beam 10 is welded to the first-modular-frame-first-hollow-tubular-member 8.
Each first-modular-frame-first-beam 10 has an opening 54 (noted herein as a first-modular-frame-first-beam-first-aperture) for receiving fastening means 26 to fasten the first modular frame 4 to the gusset plate 20, as is described herein.
The second modular frame 6 is similar to the first modular frame 4 in structure, but relates to the top end of a lower modular frame, and is provided with features (as described herein) to assist with coupling of the first modular frame 4 to the second modular frame 6, with the gusset plate 20 sandwiched in between the first modular frame 4 and the second modular frame 6.
Like the first modular frame 4, the second modular frame 6 shown in
A pair of beams 16 (noted herein as a second-modular-frame-first-beam) are coupled to the second-modular-frame-first-hollow-tubular-member 14 at the first end 18 of the second-modular-frame-first-hollow-tubular-member 14. The pair of beams 16 (second-modular-frame-first-beams) extending perpendicularly to the second-modular-frame-first-hollow-tubular-member 14 and to each other. In other words, if the second-modular-frame-first-hollow-tubular-member 14 lies in the Z-axis, one of the second-modular-frame-first-beam 16 extends in the X-axis and the other second-modular-frame-first-beam 16 extends in the Y-axis. The method of coupling the second-modular-frame-first-beams 16 to the second-modular-frame-first-hollow-tubular-member 14 is not particularly limited, and should be known to a person of skill in the art. In one embodiment, for example and without limitation, the second-modular-frame-first-beam 16 is welded to the second-modular-frame-first-hollow-tubular-member 14.
Each second-modular-frame-first-beam 16 has a pair of openings. The first opening 56 (noted herein as a second-modular-frame-first-beam-first-aperture) for receiving second fastening means 28 to fasten the gusset plate 20 to the second modular frame 6. While the second opening 66 (noted herein as a second-modular-frame-first-beam-second-aperture) for receiving the fastening means 26 that couples the first modular frame 4 to the gusset plate 20 and the second modular frame 6. Hence, the second-modular-frame-first-beam-second-aperture 66 aligns with the first-modular-frame-first-beam-first-aperture 54, and is also sized to receive the fastening means 26 for coupling the first modular frame 4 to the second modular frame 6. In one embodiment, as disclosed in the figures, the first opening 56 formed on the second-modular-frame-first-beam 16 is distal from the second-modular-frame-first-hollow-tubular-member 14, while the second opening 66 being more proximate to the second-modular-frame-first-hollow-tubular-member 14.
To couple the first modular frame 4 to the second modular frame 6, a locating pin assembly 2 is used. The locating pin assembly 2 has a gusset plate 20 (also noted herein as the first gusset plate) and a pin 30.
The gusset plate 20 disclosed herein is a flat plate positioned between the first modular frame 4 and the second modular frame 6, and is provided with features to accommodate the pin 30 and help with coupling of the first modular frame 4 to the second modular frame 6.
In the embodiment shown in
The gusset plate 20 is provided with a first gusset plate aperture 22 and a second gusset plate aperture 24. The first gusset plate aperture 22 and second gusset plate aperture 24 are formed in the gusset plate 20 so that they align with the second-modular-frame-first-beam-second-aperture 66 and the second-modular-frame-first-beam-first-aperture 56, respectively. In other words, the first gusset plate aperture 22 aligns with the second-modular-frame-first-beam-second-aperture 66, and the second gusset plate aperture 24 aligns with the second-modular-frame-first-beam-first-aperture 56.
In addition, the first gusset plate aperture 22 is formed to also align with the first-modular-frame-first-beam-first-aperture 54. Hence, when fastening means 26 is used for coupling the first modular frame 4 to the second modular frame 6, the fastening means 26 engages the first-modular-frame-first-beam-first-aperture 54, the first gusset plate aperture 22 and the second-modular-frame-first-beam-second-aperture 66 to affix and couple the first modular frame 4 to the second modular frame 6.
Furthermore, when second fastening means 28 are used to couple the gusset plate 20 with the second modular frame 6, the second fastening means 28 engages the second gusset plate aperture 24 and the second-modular-frame-first-beam-first-aperture 56 for coupling the gusset plate 20 with the second modular frame 6. By providing the gusset plate 20 with the second gusset plate aperture 24, the gusset plate 20 can be aligned, positioned and coupled to the second modular frame 6 prior to coupling of the first modular frame 4 to the second modular frame 6, and assist in manufacturing a modular structure.
The thickness of the gusset plate 20 is not particularly limited and can be varied depending upon design and application requirements. In a particular embodiment, the gusset plate 20 has a thickness equal to the thickness of a stop 38 (as described herein) provided on the pin 30, so that the gusset plate 20 and the stop 38 provide a surface of uniform surface between the first modular frame 4 and the second modular frame 6.
The gusset plate 20 is also provided with a cutout 42 for receiving and positioning of the pin 30 in the second-modular-frame-first-hollow-tubular-member 14. In the embodiment shown in
The pin 30 in the pin assembly 2 engages the first gusset plate 20, the first modular frame 4 and the second modular frame 6. In the embodiment disclosed herein, the pin 30 is generally flat and elongated, and has a flat quadrilateral-type plate like section 32 and a flat inverted conically shaped section 34. In other words, the flat conically shaped section is analogous to an inverted V-shaped flat section, with the apex of the V-shaped section being distal from the flat quadrilateral-shaped plate like section 32. The flat inverted conically shaped (or V-shaped) section 34 is coupled to the flat quadrilateral-type plate like section 32 at a first end 58 of the flat quadrilateral-type plate like section 32, with the apex 72 of the flat inverted conically shaped section 34 positioned away from the first end 58 of the flat quadrilateral-type plate like section 32. The apex 72 of the flat inverted conically shaped (or flat inverted V-shaped) section 34 is not particularly limited in shape, and in one embodiment, is formed by tapering of the lateral edges to an apex, which can be rounded.
The shape and size of the flat quadrilateral-type plate like section 32 is not particularly limited, and can be varied, depending upon design and application requirements. In one embodiment, for example and without limitation, the flat quadrilateral-type plate like section 32 is generally shaped as a rectangular cube, with the flat inverted conically shaped (or V-shaped) section 34 extending from the first end 58 of the flat quadrilateral-type plate like section 32. When coupling the pin 30 with the second-modular-frame-first-hollow-tubular-member 14, the flat quadrilateral-type plate like section 32 contacts only one inner face of the second-modular-frame-first-hollow-tubular-member 14 (as shown in the figures), while being spaced from an opposing inner face of the second-modular-frame-first-hollow-tubular-member 14, where the quadrilateral-type plate like section 32 is inserted. In a further embodiment, as shown in
In one embodiment, as disclosed herein, to couple and affix the pin 30 to the second-modular-frame-first-hollow-tubular-member 14, the flat quadrilateral-type plate like section 32 of the pin 30 is provided with a first orifice 48 and a second orifice 50, adapted and sized to receive third fastening means 74 and fourth fastening means 76, respectively, to couple the pin 30 to the second-modular-frame-first-hollow-tubular-member 14. To achieve the coupling, the second-modular-frame-first-hollow-tubular-member 14 is provided with a first opening 78 (noted herein as a second-modular-frame-first-hollow-tubular-member-first-opening) and a second opening 80 (noted herein as a second-modular-frame-first-hollow-tubular-member-second-opening). In a particular embodiment, for example and without limitation, as shown in
When the flat quadrilateral-type plate like section 32 of the pin 30 is inserted into the opening 64 at the first end 18 of the second-modular-frame-first-hollow-tubular-member 14, the stop 38 helps position the flat quadrilateral-type plate like section 32 such that the first orifice 48 aligns with the second-modular-frame-first-hollow-tubular-member-first-opening 78 and the second orifice 50 aligns with second-modular-frame-first-hollow-tubular-member-second-opening 80. Third fastening means 74 can then be inserted into the second-modular-frame-first-hollow-tubular-member-first-opening 78, and the fourth fastening means 76 can be inserted into the second-modular-frame-first-hollow-tubular-member-second-opening 80 to couple and affix the pin 30 in place in the second-modular-frame-first-hollow-tubular-member 14.
As noted above, the pin 30 is provided with a stop 38 on the flat quadrilateral-type plate like section 32 of the pin 30, with the stop 38 being positioned close to the first end 58 of the flat quadrilateral-type plate like section 32. The shape and size of the stop 38 is not particularly limited and can be varied depending upon design and application requirements, so long as the stop can help with positioning of the pin 30 in the second-modular-frame-first-hollow-tubular-member 14 or with alignment of the orifices (48, 50) with the first and second apertures (78, 80) in the second-modular-frame-first-hollow-tubular-member 14.
In one embodiment, for example and without limitation, as shown in
In a particular embodiment, the stop 38 has a thickness that equals the thickness of the gusset plate 20, such that when pin 30 and the gusset plate 20 are placed in position on the second modular frame 6, the gusset plate 20 and the stop 38 lie in a single plane. This can help with proper alignment of modular frames (4, 6) and to help avoid tilting of the modular assembly.
As noted above, the pin 30 is also provided with a flat inverted conically shaped section 34 which is inserted into an opening 62 at the first end 12 of the first-modular-frame-first-hollow-tubular-member 8. Although it is not absolutely necessary to provide tapered section that extends beyond the first end 58 of the flat quadrilateral-type plate like section 32 and gets inserted into the opening 62 at the first end 12 of the first-modular-frame-first-hollow-tubular-member 8, tapering of the section to form the flat inverted conically shaped section 34 can help with ease in alignment, insertion and coupling of the first modular frame 4 to the second modular frame 6.
In one embodiment, as disclosed herein, the flat inverted conically shaped section 34 is provided with a hoisting aperture 36. The hoisting aperture 36 being formed proximate to the apex 72 of the flat inverted conically shaped section 34. When the pin 30 is coupled to the second modular frame 6, the hoisting aperture 36 on the flat inverted conically shaped section 34 of the pin 30 can be used for hoisting the second modular frame 6 and positioning it at the appropriate site of construction of the modular assembly before the first modular frame 4 is positioned on the second modular frame 6.
In addition to the above, although not shown, the hoisting aperture 36 can be used to affix the flat inverted conically shaped section 34 of the pin 30 to the first-modular-frame-first-hollow-tubular-member 8, by forming an aperture near the first end 12 of the first-modular-frame-first-hollow-tubular-member 8 that aligns with the hoisting aperture 36 once the flat inverted conically shaped section 34 of the pin 30 is inserted into the opening 62 at the first end 12 of the first-modular-frame-first-hollow-tubular-member 8.
The fastening means (26, 28, 74, 76) used to couple and fasten the different parts of the locating pin assembly 2 and modular frames (4, 6) together are not particularly limited and can be varied depending upon design and application requirements. In one embodiment, for example and without limitation, the second, third and fourth fastening means are flat head screws. In another embodiment, for example and without limitation, the first fastening means are formed using a threaded bolt 84 and a compression sleeve 86. Use of a compression sleeve 86 in the first-modular-frame-first-beam 10 can help avoid compression of first-modular-frame-first-beam 10 and assist with proper coupling of the first modular frame 4 to the second modular frame 6.
In one embodiment, as shown herein, the columns (8, 14) and beams (10, 16) in the modular frames (4, 6) are made of hollow structural sections (HSS). The weld blocks 88 disclosed herein can help to provide structural support to the HSS and/or can help to avoid compression of the second-modular-frame-first-beam 16 when coupling the first modular frame 4 to the second modular frame 6. In an alternative embodiment, non-HSS structures can be used; however, such structural members may not be preferred due to cost considerations.
The gusset plate 20 disclosed in the embodiment of
The gusset plate 20 is also provided with a plurality of first and second gusset plate apertures (22, 24) that function analogous to the first and second gusset plate apertures (22, 24) shown in
Further, the gusset plate 20 is also provided with a cutout 42 sized to receive the pair of pins 30 for coupling the first modular frame 4 to the second modular frame 6. In addition, the cutout 42 is sized such that the edge 68 of the cutout 42 aligns with edges 70 of the second-modular-frame-first-beam 16, to accommodate positioning of the pins 30 in the second-modular-frame-first-hollow-tubular-member 14.
The embodiment shown in
The gusset plate 20 disclosed in
The embodiment shown in
The gusset plate 20 shown in
In the embodiments shown in
The planar stop plate 40 shown in the embodiments of
The gusset plate 20 used in the embodiment disclosed in
Certain adaptations and modifications of the described embodiments can be made. Therefore, the above discussed embodiments are considered to be illustrative and not restrictive.
This application is a U.S. national phase application filed under 35 U.S.C. § 371 of International Application No. PCT/CA2019/050960, filed 12 Jul. 2019, designating the United States, which claims priority from U.S. Provisional Application No. 62/697,088, filed 12 Jul. 2018, which are hereby incorporated herein by reference in their entirety for all purposes.
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Number | Date | Country | |
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20210277649 A1 | Sep 2021 | US |
Number | Date | Country | |
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62697088 | Jul 2018 | US |