The present invention relates to the construction of buildings in a modular fashion from constituent parts.
International patent publication number WO 2005/124049 describes a building system including walls constructed from overlying corrugated panels. Each panel is formed from two L-shaped corrugated sheets, which are arranged to form a U-shaped panel having a base including an overlap region between the corrugated sheets and single thickness side walls. The side walls are held in relative position by bracing members.
Testing of the building system of WO 2005/124049 has confirmed a high degree of strength and stability, particularly compared to the relatively low weight of structures thus assembled. The building system requires a degree of expertise to assemble, in particular with the correct installation of bracing members within panels. In addition, the stacking of the L-shaped corrugated sheets for transport can be cumbersome.
The present invention seeks to provide a system for the construction of buildings in a modular fashion which achieves some of the advantages of the system of WO 2005/124049 and avoids some the identified disadvantages.
According to one aspect of the present invention there is provided a panel for use in a modular building, the panel including a first side wall, a second side wall, and a base portion; the panel being movable between a first position and a second position; whereby when the panel is in the first position the first side wall and the second side wall are angled with respect to each other, and when the panel is in the second position the first side wall is generally parallel to and opposed to the second side wall. It will be appreciated that the first position represents a position in which a plurality of panels can be readily stacked for transport; and the second position represents an assembled position in which the panels can be used to form a wall of a building.
The panel may be a wall panel, a floor panel, a roof panel or other desired building panel.
In the first position the first side wall and the second side wall will be relatively disposed at an angle less than 180°. This could be an angle of zero degrees, where the first side wall, the base portion, and the second side wall are generally in the same plane, through to an angle of 90° and even higher.
Put in other terms, it will be understood that the panel may be flat or nearly flat when in its first position.
It is preferred that at least one of the first side wall and the second side wall are joined to the base portion along a longitudinally extending bend, whereby movement of the panel between its first and second positions is achieved by rotation of at least one of the first and second side walls relative to the base portion about the respective longitudinally extending bend.
The bend(s) may be formed by a thinning of material in a longitudinal direction. Alternatively, the bend(s) may be formed by perforations within the body of the panel.
In another embodiment, at least one of the first side wall and the second side wall may be joined to the base portion at a hinge, such that movement of the panel between its first and its second positions can be achieved by rotation of at least one of the first and second side walls relative to the base portion about the respective hinge.
In an alternative embodiment the base portion includes a first base portion joined to a second base portion along a longitudinally extending bend, whereby movement of the panel between its first and second positions is achieved by movement of the first base portion relative to the second base portion about the longitudinally extending bend.
In this embodiment the first base portion may be connected to the first side wall at a bend of about 90°, and the second base portion is connected to the second side wall at a bend of about 90°. In this embodiment the first position of the panel may be represented by the first base portion being bent relative to the second base portion at an angle between about 60° and about 150°; and the second position of the panel represented by the first base portion being parallel to the second base portion.
It is preferred that the base portion locates internally of the side walls when in its first position.
The panel is preferably constructed from a corrugated material, having ridges and grooves extending in the longitudinal direction. In one embodiment, the corrugations may be angular, using straight sections. Alternatively, the corrugations may be curvilinear. It will be understood that where the panel is described as ‘flat’ in its first position, this does not exclude the panel being formed from corrugated material: it is a reference to the state of the first and second bends.
The panel may include further longitudinally extending bends located on the first side wall and/or the second side wall. Movement of side wall portions about a further longitudinally extending bend preferably permits movement of the panel into a third position in which the panel is closed at an outer end remote from the base portion, or into a fourth position in which an outer portion of a side wall extends away from the panel in a direction parallel to the base portion.
It will be appreciated that in the third position the panel becomes effectively a single box beam.
In accordance with a second aspect of the present invention there is provided a method of forming a portion of a building element, the method including the steps of:
providing a first panel and a second panel, each panel having a first side wall and a second side wall, the side walls being constructed from a corrugated material;
moving the panels into an assembled position whereby the first side wall of each panel is parallel to the corresponding second side wall; and
locating the second panel at least partially within the first panel, such that a portion of the first side wall of the second panel overlaps a portion of the first side wall of the first panel, the overlapping portions being complementary in shape.
The building element is preferably a building wall. Alternatively, it may be a floor, ceiling, roof or other constituent element.
The overlapping portion may represent a single corrugation wave form. Alternatively, the overlapping portion may represent two or more corrugation wave forms.
The panels may be associated with a plurality of coupling members. In a preferred embodiment, each coupling member has a first face shaped to complement an internal portion of the first side wall; a second face shaped to complement a corresponding internal portion of the second side wall; and an outer face shaped to complement an abutting panel.
The outer face of each coupling member preferably has a raised surface and a lowered surface, the raised surface and the lowered surface each being perpendicular to the first and second faces.
Alternatively, the outer face of the coupling member may include a portion which is angled at an obtuse angle relative to at least one of the first and second faces. In a preferred embodiment, the obtuse angle is about 72°. In use, this allows for attachment of a roof panel to the outer face, the roof panel having an 18° pitch.
The building wall may include at least one channel member arranged to engage with the panels. In a preferred embodiment, the channel member has side walls arranged to locate internally of the panel side walls. The channel member may have locating slots within which base portions of the panels may locate.
The method may include the further step of pinning the panel side walls to the channel member side walls. This may be done through use of a deformable fastener.
In accordance with a third aspect of the present invention there is provided a connecting member for engaging with a building panel, the building panel having side walls formed of a corrugated material;
the connecting member having an outer face including a raised planar surface, a lowered planar surface, and a sloped planar surface connecting the raised planar surface and the lowered planar surface, the sloped planar surface being generally rectangular; the raised planar surface being parallel to the lowered planar surface, a join between the sloped planar surface and the raised planar surface defining an orientation direction of the connecting member;
the connecting member having four side walls, each shaped to engage with the corrugated material;
the connecting member having a first orientation wherein the orientation direction of the connecting member is parallel to the side walls of the building panel and a second orientation wherein the orientation direction of the connecting member is perpendicular to the side walls of the building panel.
It will be convenient to further describe the invention with reference to preferred embodiments of the present invention. Other embodiments are possible, and consequently the particularity of the following discussion is not to be understood as superseding the generality of the preceding description of the invention. In the drawings:
Referring to the Figures,
In the embodiment of
The panel 10 is oriented such that the corrugations extend in the longitudinal direction. In the embodiment shown each side wall 12 represents about 3.5 corrugation wavelengths, with the base 16 representing nearly 1 corrugation wavelengths.
The arrangement is such that the first side wall 12 is connected to the base 16 along a first bend 22, the first bend 22 extending longitudinally along the panel 10. Similarly, the second side wall 14 is connected to the base 16 along a second bend 24, the second bend 24 extending longitudinally along the panel 10.
In the embodiment shown in
The bends 22, 24 are constructed so as to form a natural flexing point for the panel 10. This may be done by a thinning of material along the bend 22, 24, or by the provision of perforations, or other means. The arrangement is such that a small degree of pressure applied to the side walls 12, 14 will cause the panel 10 to move from the second position shown in
The first position shown in
A second panel 10b is introduced into the open space 28a of the first panel 10a. The second panel 10b faces in the same direction as the first panel 10a, with its open space 28b facing towards the outer end of the wall portion 50.
The second panel 10b is located about 0.75 corrugated wave length within the first panel 10a. In other words, the corrugated wave immediately next to the open space 28a of the first panel 10a locates outside of, and contiguous with, the corrugated wave immediately next to the base 16b of the second panel 10b, through to about 0.75 wavelengths. It will be appreciated that these waves are complementary in shape.
It can be seen that the wall portion 50 has side walls 52, 54 which are each the thickness of one side wall 12, 14 through their first three corrugations from the inner end, then the thickness of two side walls 12, 14 through a further 0.75 wavelengths. As successive panels 10 are added, it will be understood that the thickness of side walls 52, 54 alternates between one and two thicknesses.
It will be appreciated that an outer end of the wall 50 may be formed by incorporating a final panel 10 in the third position of
Alternatively, an outer end of the wall 50 may be formed by incorporating a final panel 10 in the fourth position of
In the arrangement of
The panel 10 is preferably used in conjunction with a connecting member or connecting block 60 as shown in
The connecting block 60 has an outer face 62 bordered by four side edges: a first side edge 64, a second side edge 66, a third side edge 68 and a fourth side edge 70.
The outer face 62 has a substantially planar raised surface 72 extending from the first side edge 64 towards the third side edge 68, and a substantially planar lowered surface 74 extending from the third side edge 68 towards the first side edge 64. The raised surface 72 and the lowered surface 74 are parallel to each other, and each extend about 45% of the way across the outer face 62.
A substantially planar sloped surface 76 connects the raised surface 72 and the lowered surface 74. The sloped surface 76 is generally rectangular, and extends from the second side edge 66 to the fourth side edge 70. The sloped surface 76 connects to the raised surface 72 along a first connection line 78 which is generally parallel to the first and third edges 64, 68. The sloped surface 76 connects to the lowered surface 74 along a second connection line 80 which is parallel to the first connection line 78. The sloped surface is angled at about 65° with respect to each of the raised surface 72 and lowered surface 74.
Each of the four side edges 64, 66, 68, 70 are shaped to locate within a single waveform of the panel 10 corrugations. They each have a recessed face 82 and an outward face 84, arranged to locate against ‘convex’ and ‘concave’ parts of the panel 10 waveform. The recessed faces 82 and outward faces 84 are all perpendicular to the raised surface 72 and lowered surface 74.
The third side edge 68 has an outwardly extending extension portion 86 on its outward face 84. The extension portion 86 extends above the lowered surface 74 to an upper edge 88 having a height corresponding to that of the raised surface 72. An internal face 90 extends from the upper edge 88 to the lowered surface 74, meeting the lowered surface 74 at an angle of about 65°.
The first side edge 64 has a cut-out portion 92 on its outward face 84, complementary in shape to the extension portion 86 on the third side edge 68.
The connecting blocks 60 can be located in the panels 10 in two different configurations. In a first configuration, the connecting blocks 60 can be located in an orientation whereby the connection lines 78, 80 are perpendicular to the direction of the side walls 12, 14. This creates a stepped configuration along an upper or lower edge of the panel 10. The connecting blocks 60 are arranged to be inserted within the panel 10 such that the lowered surface 74 is level with an outer edge of the panel 10, with the raised surface 72 extending outside the edges of the panel 10. The resulting stepped configuration is complementary in shape to the side walls 12, 14 of a second panel 10, the second panel 10 being oriented at 90° first panel 10. This allows for the easy creation of 90° joins within a building, either wall-to-wall or wall-to-floor. This can be seen in
In the second configuration, the connecting blocks 60 can be located in an orientation whereby the connection lines 78, 80 are parallel to the direction of the side walls 12, 14. The raised surfaces 72 of the connecting blocks 60 align to form a continuous raised surface, with the lowered surfaces 74 forming a continuous lowered surface. The resulting configuration is complementary in shape to a longitudinal edge of a second panel 10, oriented at 90° to the first panel 10. This allows for a wall-to-floor connection where the direction of floor corrugations is the same as the direction of the wall.
The roof connector block 94 has an outer face 104 having a first portion 106 extending from the second side edge 100 towards the fourth side edge 102, and a second portion 108 extending from the fourth side edge 102 towards the second side edge 100. The first and second portions 106, 108 meet along a centre line 110. The first and second portions 106, 108 each angle up towards to the centre line 110 at an angle of about 18°. The arrangement is such that when a roof connector block 94 is inserted atop a wall panel 10 a roofing panel (not shown) can then be affixed to it, with the roof having an 18° pitch.
An alternative connecting block 120 is shown in
As with the connecting block 60, each of the four side edges 64, 66, 68, 70 of the alternative connecting block 120 are shaped to locate within a single waveform of the panel 10 corrugations, with a recessed face 82 and an outward face 84. The third side edge 68 has an outwardly extending extension portion 86 on its outward face 84.
The difference between the connecting block 60 and the alternative connecting block 120 is that the former is moulded into a desired shape, whereas the latter is formed from a single cut sheet 122 which is arranged to be folded into shape. As a consequence, the recessed faces 82 and outward faces 84 of the alternative connecting block 120 are not joined by interconnecting webs as in the connecting block 60.
Similarly, an alternative roof connector block 124 is shown in
It will be understood that a connector block can be formed similarly to the roof connector block 124, with the outer face 104 being perpendicular to the side edges 96, 98, 100, 102. Such a connector block can be used in place of the connecting blocks 60, 120 to cap a panel, such as for a wall-to-floor connection. It is also anticipated that at least one connector block may be located internally of a panel 10 to provide stiffening if required.
Panels 10 can be locked to each other and/or locked to connecting blocks 60, 120 or roof connector blocks 94, 124 by means of apertures 130 located within each recessed corrugation of the first side wall 12 and second side wall 14. In use, these apertures 130 are arranged to align with associated apertures 132 in the connecting blocks 60, 120 or associated apertures 134 in the roof connector blocks 94, 124.
The locking of panels 10 to each other or to connecting blocks 60, 120 is achieved by use of a fastener 140 as shown in
In a preferred embodiment of the invention, the apertures 130, 132, 134 may be associated with a recessed portion of the relevant body. This, it is envisaged, will assist in aligning apertures 130, 132, 134 and in easy locating of the fastener 140 within.
The panels 10 described above are envisaged being shipped either in the L-shaped second position of
It will be appreciated that while the wall portion 50 described above is straight, with a small change in the geometry of each panel 10 it is possible to form a curved wall portion 150. An exaggerated example of such a curved wall portion 150 is shown in
Another alternative wall panel 210 is shown in
In the embodiment of
The panel 210 is oriented such that the corrugations extend in the longitudinal direction. In the embodiment shown each side wall 212 represents about 4.5 corrugation wavelengths, with the base 216 representing about 2 corrugation wavelengths.
The arrangement is such that the first side wall 212 is connected to the first base portion 218 along a first bend 222, the first bend 222 extending longitudinally along the panel 210. Similarly, the second side wall 212 is connected to the second base portion 220 along a second bend 224, the second bend 224 extending longitudinally along the panel 210. The first bend 222 and the second bend 224 are both 90° bends.
The first base portion 218 is connected to the second base portion 220 along a central bend 226. The central bend 226 is also about 90°, but on an opposite face of the panel 210 to the first and second bends 222, 224. The panel 210 thus forms a generally “W-shaped” configuration when viewed in cross section, as in
The central bend 226 is constructed so as to form a natural flexing point for the panel 210. This may be done by a thinning of material along the central bend 226, or by the provision of perforations, or other means. The arrangement is such that a small degree of pressure applied to the side walls 212, 214 will cause the panel 210 to move from the first position shown in
The first position shown in
A second panel 210b is introduced into the open space 228a of the first panel 210a. The second panel 210b faces in the same direction as the first panel 210a, with its open space 228b facing towards the outer end of the wall portion 240.
The second panel 210b is located about 1.5 corrugated wave length within the first panel 210a. In other words, the corrugated wave immediately next to the open space 228a of the first panel 210a locates outside of, and contiguous with, the corrugated wave immediately next to the base 216b of the second panel 210b, through to about 1.5 wavelengths. It will be appreciated that these waves are complementary in shape.
It can be seen that the wall portion 240 has side walls 242, 244 which are each the thickness of one side wall 212, 214 through their first three corrugations from the inner end, then the thickness of two side walls 212, 214 through a further 1.5 wavelengths. As successive panels 210 are added, it will be understood that the thickness of the side walls 242, 244 alternates between one and two thicknesses each 1.5 wavelengths.
It will be appreciated that an outer end of the wall 240 may be formed by reversing a final panel 210 such that its base 216 formes the outer end of the wall 240.
It can be seen that the wall portion 250 has side walls 252, 254 which are each the thickness of one side wall 212, 214 through their first two corrugations from the inner end, then the thickness of two side walls 212, 214 through the next 2 wavelengths, and the thickness of three side walls 212, 214 through a further half a wavelength. As successive panels 210 are added, it will be understood that the thickness of the side walls 252, 254 alternates between two thicknesses for 1.5 wavelengths and then three thicknesses for the next 0.5 wavelength.
It can be seen that the wall portion 260 has side walls 262, 264 which are each the thickness of one side wall 212, 214 through their first corrugation wavelength from the inner end, then the thickness of two side walls 212, 214 through the next wavelength, the thickness of three side walls 212, 214 through the next wavelength, the thickness of four side walls 212, 214 through the next wavelength and the thickness of five side walls 212, 214 through the final half a wavelength. As successive panels 210 are added, it will be understood that the thickness of the side walls 252, 254 alternates between four and five thicknesses each half wavelength.
It will be understood that panels 210 in the first position of
In use, wall portions 240, 250, 260 can be constrained within at least one channel member 272, as shown in
The arrangement is such that the side flanges 276 are spaced apart about the width of the base 216 of the panel 210.
Each side flange 276 has a plurality of receiving apertures 280 spaced along its length.
As shown in
It will also be appreciated that the panels 10, constructed from a more angular corrugated material than the panels 210, can be arranged in an analogous fashion to the wall panels 240, 250, 260 to create greater wall strength if required.
Modifications and variations as would be apparent to a skilled addressee are deemed to be within the scope of the present invention.
Number | Date | Country | Kind |
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2018902691 | Jul 2018 | AU | national |
2018904453 | Nov 2018 | AU | national |
Filing Document | Filing Date | Country | Kind |
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PCT/AU2019/050774 | 7/24/2019 | WO |
Publishing Document | Publishing Date | Country | Kind |
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WO2020/019027 | 1/30/2020 | WO | A |
Number | Name | Date | Kind |
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3807104 | Webster | Apr 1974 | A |
6253498 | Fanucci | Jul 2001 | B1 |
8256443 | Neal | Sep 2012 | B2 |
8695284 | Ho | Apr 2014 | B2 |
20100018130 | Lopez et al. | Jan 2010 | A1 |
20170051497 | Kolbe | Feb 2017 | A1 |
Number | Date | Country |
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WO-2005124049 | Dec 2005 | WO |
Entry |
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International Search Report from corresponding International Patent Application No. PCT/AU2019/050774, dated Oct. 29, 2019. |
Number | Date | Country | |
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20210293021 A1 | Sep 2021 | US |