The present disclosure relates to building elements suitable for use in construction. In particular the disclosure relates to cladding elements suitable for use in a building envelope.
The embodiments have been developed primarily for use as cladding elements and will be described hereinafter with reference to this application. However, it will be appreciated that the embodiments are not limited to this particular field of use and that the embodiments can be used in any suitable field of use known to the person skilled in the art.
Any discussion of the prior art throughout the specification should in no way be considered as an admission that such prior art is widely known or forms part of the common general knowledge in the field.
Wood cladding elements are sometimes used to protect and/or improve the aesthetic qualities of walls and other structures. However, wood can be difficult and expensive to install and can have limited durability.
It is an object of the present disclosure to overcome or ameliorate at least one of the disadvantages of the prior art, or to provide a useful alternative.
In some embodiments, a cladding element comprises a front face; a rear face opposite the front face; a first mating end; a second mating end opposite the first mating end; a first joint end; and a second joint end opposite the first joint end. In some embodiments, the cladding element includes a first mating feature on the first mating end. The first mating feature can comprise a recessed portion having a front recessed face. In some embodiments, the first mating features comprises a transition portion between the front recessed face and the front face. The first mating feature can include a first angled portion extending from the rear face. In some embodiments, the cladding element includes a second mating feature on the second mating end. The second mating feature can include a sloped portion extending from the front face toward the rear face and away from the first mating end. In some cases, the second mating feature includes a recess having a rear recessed face and a second sloped portion extending away from the first mating end and toward the rear face. In some embodiments, the sloped portion of the second mating feature and a transition portion of a first mating feature of a second cladding element form a groove when the cladding element is mated with a second cladding element.
In some embodiments, the groove has a V shape. In some cases, the sloped portion has a concave shape. In some embodiments, the groove has a cove shiplap shape. The cladding element can include a surface groove on the front face of the cladding element, the surface groove extending parallel to the first mating end. In some cases, the surface groove has substantially the same shape as the groove formed by the sloped portion of the second mating feature and the transition portion of the first mating feature of the second cladding element. In some embodiments, a gap is formed between the front recessed face of the first mating feature of the cladding element and a rear recessed face of a second mating feature of a second cladding element when the first mating feature of the cladding element is mated with the second mating feature of the second cladding element. In some cases, the gap is 0.06 inches.
According to some variants, a cladding element has a front face; a rear face opposite the front face; a first mating end; a second mating end opposite the first mating end; a first joint end; and a second joint end opposite the first joint end. The cladding element can include a first joint feature on the first joint end comprising a first joint face having a first sealing channel. In some embodiments, the cladding element includes a second joint feature on the second joint end comprising a second joint face having a second sealing channel. The cladding element can include a sealing element disposed within at least one of the first and second sealing channels.
In some embodiments, the sealing element is an elastomeric rod. In some cases, the first sealing channel extends along an entire length of the first joint end. In some embodiments, the first joint face is positioned at an offset angle from the rear face of the cladding element. In some cases, the offset angle is between 35 degrees and 55 degrees. In some embodiments, the first sealing channel extends through a first mating feature on the first mating end of the cladding element and through a second mating feature on the second mating end of the cladding element. In some cases, the first joint face extends over at least a portion of thickness of the cladding element between the front face and the rear face.
According to some variants, a cladding element includes a front face; a rear face opposite the front face; a first mating end; a second mating end opposite the first mating end; a first joint end; and a second joint end opposite the first joint end. In some embodiments, the cladding element includes a joint protrusion on and extending from the first joint end away from the second joint end. The cladding element can include a joint recess on the second joint end and configured to receive a joint protrusion on the first joint end of an adjacent cladding element.
In some embodiments, the joint protrusion includes a sealing channel in a surface of the joint protrusion. In some cases, the joint recess includes a sealing channel in a surface of the joint recess. In some embodiments, the cladding element includes a sealing element positioned in the sealing channel. In some cases, the sealing element is an elastomeric rod. In some embodiments, one of the rear face and the front face of the cladding element forms a surface of the joint protrusion. In some cases, the joint protrusion is positioned between and spaced from the front face and the rear face of the cladding element as measured perpendicular to the front face of the cladding element. In some embodiments, the joint protrusion extends in a direction parallel to the front face of the cladding element. In some cases, the joint protrusion extends through a first mating feature on the first mating end and through a second mating features on the second mating end of the cladding element.
According to some variants, a cladding system can include a plurality of cladding elements. The system can include first and second cladding elements constructed from fibre cement. Each of the first and second cladding elements can have a front face and a rear face opposite the front face. The elements can include a first mating edge between the front face and the rear face. In some embodiments, the elements include a second mating edge between the front face and the rear face, opposite the first mating edge. The elements can include a first mating structure on the first mating edge. The first mating structure can include a recessed portion having a front-facing surface set rearward from the front surface of the cladding element. The first mating structure can include a first angled portion extending rearward from the front face of the front surface of the cladding element and away from the second mating edge. In some embodiments, the first mating structure includes an offset portion extending between the first angled portion and the front-facing surface of the recessed portion. The first mating structure can include a second angled portion extending from the rear face of the cladding element toward the front face of the cladding element and away from the second mating edge. The elements can include a second mating structure on the second mating edge. The second mating structure can include a first angled portion extending from the front face of the cladding element toward the rear face of the cladding element and away from the first mating edge of the cladding element. In some embodiments, the second mating structure includes a recessed portion having a rear-facing surface set forward from the rear face of the cladding element. The second mating structure can include a second angled portion extending in a direction from the rear face of the cladding element toward the front face of the cladding element and toward the first mating edge of the cladding element. In some embodiments, the second mating structure includes an abutment face connecting the rear-facing surface of the recessed portion with the second angled portion. In some embodiments, the elements include a first joint end between the front face and the rear face. The elements can include a second joint end between the front face and the rear face, opposite the first joint end. In some embodiments, the first mating structure of the first cladding element is mated with the second mating structure of the second cladding element. In some embodiments, at least a portion of the second angled portion of the first mating structure of the first cladding element contacts at least a portion of the second angled portion of the second mating structure of the second cladding element. In some embodiments, the offset portion of the first mating structure of the first cladding element contacts at least a portion of the second mating structure of the second cladding element. In some embodiments, the front-facing surface of the recessed portion of the first mating structure of the first cladding element is spaced from the rear-facing surface of the recessed portion of the second mating structure of the second cladding element in a direction non-parallel to a plane of the front surface of the second cladding element.
In some configurations, the first angled portion of the first mating structure of the first cladding element and the first angled portion of the second mating feature of the second cladding element form a V-shaped groove.
In some configurations, the abutment face of the second cladding element is spaced from the first mating edge of the first cladding element.
In some embodiments, the system includes a third cladding element. The third cladding element can have a front face, a rear face opposite the front face, a first mating edge between the front face and the rear face, a second mating edge between the front face and the rear face, opposite the first mating edge, a first mating structure on the first mating edge, a second mating structure on the second mating edge, a first joint end between the front face and the rear face, and/or a second joint end between the front face and the rear face, opposite the first joint end. In some configurations, the first joint end of the first cladding element is mated with the second joint end of the third cladding element.
In some configurations, the first joint end of the first cladding element includes a joint recess and the second joint end of the third cladding element includes a joint protrusion. In some configurations, at least a portion of the joint protrusion of the third cladding element is received in the joint recess of the first cladding element.
The embodiments will now be described more particularly with reference to the accompanying drawings, which show by way of example only cladding elements of the disclosure.
Although making and using various embodiments are discussed in detail below, it should be appreciated that the embodiments described provide inventive concepts that may be embodied in a variety of contexts. The embodiments discussed herein are merely illustrative of ways to make and use the disclosed devices, systems and methods and do not limit the scope of the disclosure.
In the description which follows like parts may be marked throughout the specification and drawing with the same reference numerals, respectively. The drawing figures are not necessarily to scale and certain features may be shown exaggerated in scale or in somewhat generalized or schematic form in the interest of clarity and conciseness.
Unless the context clearly requires otherwise, throughout the description and the claims, the words “inclined surface”, “angle of inclination”, and the like are to be construed as referring to inclination with respect to the plane that extends perpendicularly from the first face. In the instance where the cladding element is installed in a vertical arrangement, the horizontal plane is the plane that extends perpendicularly from the first face. Accordingly in the following description the terms horizontal plane and the plane that extends perpendicularly from the first face are sometimes used interchangeably.
Cladding elements can be assembled to produce cladding systems (e.g., wall portions). These cladding systems can be installed on an exterior or interior surface of a wall to provide aesthetic improvement, improved weather resistance, improved thermal efficiency, improved structural stability, and/or many other improvements to an existing wall. For example, the cladding systems disclosed herein can be installed on a wooden frame or other internal wall structure.
The cladding element 1000 includes a first profiled edge 1004 extending between the front and rear faces 1001, 1002. The cladding element 1000 can include a second profiled edge 1005 extending between the front and rear faces 1001, 1002 on a side of the element 1000 opposite the first profiled edge 1004. The first profiled edge 1004 of a first element 1000A (
The first profiled edge (e.g., mating edge) 1004 of the cladding element 1000 can include a recessed portion 1007. The recessed portion 1007 can include a front face 1019 substantially parallel to and positioned rearward of the front face 1001 of the cladding element 1000. The first profiled edge 1004 can include a first angled portion 1008 extending from the front face 1001 of the cladding element 1000 toward the rear face 1002 of the element 1000 away from the second profiled edge 1005 of the element 1000. The first profiled edge 1004 can include a second angled portion 1012 extending from the rear face 1002 of the element 1000 toward the front face 1001 of the element 1000 and away from the second profiled edge 1005 of the element 1000.
The second profiled edge 1005 of the cladding element 1000 can include a first angled portion 1018 extending away from the front face 1001 of the element 1000 toward the rear face 1002 and away from the first profiled edge 1004 of the cladding element 1000. The second profiled edge 1005 of the cladding element 1000 can include a recessed portion 1010. The recessed portion 1010 can include a rear face 1023 substantially parallel to and positioned forward of the rear face 1002 of the cladding element 1000. The portion of the second profiled edge 1005 between the recess 1010 and the front surface 1001 of the cladding element 1000 can include an overlap portion 1009. The second profiled edge 1005 can include second angled portion 1003 having a sloped surface 1011 extending in a direction from the rear surface 1002 toward the front face 1001 and toward the first profiled edge 1004 of the cladding element 1000.
In some embodiments, the recessed portion 1007 of the includes an offset portion 1017 between the angled portion 1008 and the front face 1019 of the recessed portion 1007, as measured substantially perpendicular to the first face 1001 of the cladding element 1000. The overlap portion 1009 can include an abutment face 1021 between the angled portion 1018 and a rear face 1023 of the overlap portion 1009 as measured substantially perpendicular to the second face 1002 (e.g., the rear face) of the cladding element 1000.
As illustrated in the cladding system of
The overall shape of the groove 1020 can be altered through adjustment of certain parameters. For example, the angles β1, β2 of the angled portions 1008, 1018 as measured from the first surface 1001 (e.g. the front face) can be varied. In some instances, the angle β1 of angled portion 1008 is the same as the angle β2 of angled portion 1018. In some cases, the angle β1 of angled portion 1008 is greater than or less than the angle β2 of angled portion 1018. Increasing the value of one or more of the angles β1, β2 while maintaining the depth D of the groove 1020 can decrease the width W of the groove 1020. Many variations are possible.
As illustrated in
In some cases, a gap G can remain between the rear face 1023 of the overlap portion 1009 of a first cladding element 1000a and the front face 1019 of the recessed portion 1007 of a second cladding element 1000b when the first and second cladding elements 1000a, 1000b are connected to each other. The gap G can be between 0.01 inches and 0.1 inches when measured perpendicular to the first face 1001 of first cladding element 1000a. In some embodiments, the gap G is approximately 0.06 inches measured substantially perpendicular to the first face 1001 of the first cladding element 1000a. Many variations are possible. A second gap G2 in the cladding system can be formed between the abutment face 1021 of the second cladding element 1000b and the tip of the first profiled edge 1004 of the first cladding element 1000a. The second gap G2 can be connected to and/or continuous with the gap G.
The gaps G and/or G2 can be sized and/or shaped to accommodate adhesives, sealants, insulators, and/or other materials. For example, an adhesive material can be applied to the front face 1019 of the recessed portion of the first cladding element 1000B and/or to the rear face 1023 of the overlap portion 1009 of the second cladding element 1000A before the first and second cladding elements 1000A, 1000B are mated together. Positioning materials in the gap G between the front face 1019 of the recessed portion of the first cladding element 1000B and the rear face 1023 of the overlap portion 1009 of the second cladding element 1000A can increase the weather resistance of the assembled cladding elements 1000A, 1000B by reducing the likelihood that moisture (e.g., rain, condensation, etc.) will pass between the groove 1020 and the second surfaces 1002 of the cladding elements 1000A, 1000B. In some cases, sealant or other materials can be inserted into the second gap G2 without insertion of sealant into the other gap G.
In some embodiments, the interface between the first profiled side edge 1004 of the first cladding element 1000A and the second profiled side edge 1005 of the second cladding element 1000B can provide a tortuous (e.g., tedious, serpentine, labyrinthine) path through which moisture would be required to travel to reach the second surface 1002 of the cladding elements 1000A, 1000B from the groove 1020. For example, the interface can include a plurality of turns (e.g., 3 turns, 4 turns, 5 turns, etc.) through which the moisture would be required to pass. In some cases, the tortuous interface between the two cladding elements 1000A, 1000B would force the moisture to switch direction one or more time (e.g., vertically and/or laterally) when traveling from the groove 1020 to the second surfaces 1002.
In some embodiments, the interface between the first profiled side edge 1004 of the first cladding element 1000a constructed from fibre cement and the second profiled side edge 1005 of the second cladding element 1000b constructed from fibre cement can have significantly reduced water leakage (e.g., water through a thickness of the assembled elements 1000a, 1000b) as compared to two cladding elements constructed from wood. Such water-resisting characteristics are immediately apparent when conducting an ASTM E 331 test. The ASTM E 331 test comprises constructing a cladding element system (e.g., a cladding element wall) comprised of multiple mated cladding elements. In the present case, a 4′ by 8′ cladding system control specimen consisting of V-Groove wood elements was constructed, as was a 4′ by 8′ cladding system test specimen consisting of V-Groove fibre cement elements (e.g., elements 1000, described above). The respective walls were subject to incrementally-increased water pressure until leakage was detected on a back side of the wall. Water was applied for 5 minutes at each pressure increment. When water was detected on the back side of the wall, the pressure was maintained for 5 minutes and the leaked water was collected for measurement. When subject to the ASTM E 331 test, the fibre cement elements resisted water penetration for water pressures up to at least 225 psi, whereas wood elements having substantially the same geometric shapes as the elements 1000a, 1000b, permitted water penetration at 0 psi. In some cases, the water penetration through the fibre cement elements was less at 325 psi than the water penetration through the wood elements at 150 psi. Results of the test are reflected in
As illustrated in
In some embodiments, the use of cladding elements 1000 to cover a wall (e.g., to assembly a cladding system) can reduce the overall installation time of the cladding elements 1000 (e.g., as compared to the time required to install traditional wood cladding elements). For example, an installer may use a level or other tool to confirm the alignment of the first-installed cladding element 1000 (e.g., the bottom cladding element) when installing the cladding elements 1000. Subsequent cladding elements 1000 can be installed without the use of an alignment tool, as the mating of profiled edges 1004, 1005 of adjacent cladding elements align the subsequent cladding elements 1000 with the first-installed cladding element 1000. The self-alignment of the subsequent cladding elements 1000 can reduce the overall installation time of the cladding elements 1000 by 10-20%. In some cases, the self-alignment of the cladding elements 1000 can increase installation efficiency by over 25%. For example, on average, the self-alignment of the cladding elements 1000 can reduce the installation time to under two minutes. In some cases, the average installation time per cladding element can be approximately 100 seconds.
The shiplap-type labyrinthine connection between the first and second profiled edges 1004, 1005 of the cladding elements 1000 can facilitate either vertical installation (e.g., the length of each cladding element 1000 extends vertically) or horizontal installation (e.g., the length of each cladding element 1000 extends horizontally) of the cladding elements 1000 onto the wall of a structure. For example, as explained above, the labyrinthine connection between the first and second profiled edges 1004, 1005 can reduce the likelihood that moisture would pass from the grooves 1020 to the rear faces 1002 of the cladding elements 1000.
In some embodiments, the shiplap-type labyrinthine connection between the first and second profiled edges 1004, 1005 of the cladding elements 1000 in a cladding system can increase the overall wind resistance of the installed cladding elements. For example, the labyrinthine engagement between the cladding elements 1000 can reduce the amount of wind access between the cladding elements 1000 and the wall or other structure onto which the cladding elements 1000 are installed. In some cases, the labyrinthine engagement between the cladding elements 1000 can increase the wind resistance of the installed cladding elements by over 100% as compared to the wind resistance of plank cladding elements. In some cases, the cladding elements 1000 can withstand wind-induced loads of over 85 pounds per square foot. Reduction of wind access to a rear side of the cladding elements 1000 can reduce pressure build up between the cladding elements 1000 in a cladding system and the wall onto which they are installed.
Use of cladding elements 1000 can have a significant impact on the durability of a wall (e.g., cladding system). Such impact has been proven via testing of impact resistance on a test cladding system specimen 6′ by 8′ wall comprising fibre cement cladding elements 1000. The control cladding system specimen for the test was a 6′ by 8′ wall of fibre cement planks. Both the test specimen and the control specimen were subject to impacts of incrementally-increasing energy. The test results indicate that walls (e.g., cladding systems) constructed from cladding elements 1000 having the shiplap-type labyrinthine connections can realize an increased impact resistance of over 20% as compared to plank walls. In some cases, the cladding elements 1000 are capable of withstanding over 130 Joules of energy before cracking, as compared to 97 Joules for a plank wall. In some embodiments, the cladding elements 1000 are capable of withstanding over 160 Joules of energy before splitting, as compared to 130 Joules for a plank wall. In some cases, the shiplap-type labyrinthine connection of the cladding elements 1000 (e.g., the overlap realized in the labyrinthine connections) can facilitate energy distribution among adjacent cladding elements in a more efficient manner than is the case with plank walls. The use of joints to connect adjacent cladding elements, as described below, can further increase energy distribution and/or impact resistance of the cladding elements. Results of the testing are shown in
In some embodiments, a cladding element 1070 can include one or more channel features 1081 in the first surface 1071 of the cladding element 1070. The channel features 1081 can have the same shape (e.g., V groove, cove, wide cove, square channel, etc.) as the shapes of the grooves formed between mated cladding elements.
Cladding elements may be installed in cladding systems in conjunction with flashing strips, caulk, and/or other weatherproofing materials to reduce moisture transfer to the structure on which the cladding elements are installed. In some cases, it may be advantageous to provide weatherproofing structure on the cladding elements themselves to reduce or eliminate the need for additional weatherproofing materials and/or waterproofing installation steps. For example, the cladding elements may include one or more joint features configured to facilitate drainage of moisture from the assembled/installed cladding elements away from the structure on which the cladding elements are installed. The joint features can be configured to facilitate moisture drainage from the cladding elements as the cladding elements shrink and/or expand after installation (e.g., due to temperature change, evaporation, chemical processes, etc.). In some embodiments, the joint features create a tortuous and/or labyrinthine passage between a front side of the cladding elements and a back side of the elements, thereby reducing the amount of moisture passage between the front side of the cladding elements and the back side of the cladding elements when the cladding elements are installed on a wall or other structure. In some cases, cladding elements which include joint features are capable of being installed both vertically (e.g., having joint features on top and bottom sides of the cladding elements) and horizontally (e.g., having joint features on lateral sides of the cladding elements), depending on the application. Examples of such joint features are described below.
As illustrated in
The cladding element 2000 can include a first mating edge 2006. As illustrated, the cladding element 2000 can include a second mating edge 2008 distanced from and/or positioned opposite the first mating edge 2006. The first and second mating edges 2006, 2008 can be sized and/or shaped to couple with the first or second mating edges of an adjacent cladding element. In some embodiments, the cladding element 2000 is generally planar and has a generally rectangular shape bound on two opposite sides by the first and second joint edges 2002, 2004 and on the other opposite sides by the first and second mating edges 2006, 2008. As illustrated in
As illustrated in
In some embodiments, as illustrated in
As illustrated in
The use of joint edges (e.g., non-flat and perpendicular edges) to mate the ends of the cladding elements in a cladding system can increase the cladding system's resistance to moisture passage through the assembled cladding elements. For example, the joint edges 2043, 2045 of the cladding elements 2040 of
In some embodiments, cladding elements are advantageously arranged in a cladding system wherein a plurality of elements (e.g., any of the elements described above) are arranged such that the profiled edges of two elements are mated with each other. Additional elements can be arranged in connection with the two elements such that the joint edges of the adjacent elements in the cladding system are mated to each other. The cladding elements can be arranged in a number of different patterns, including, but not limited to, patterns in which the mating interfaces between the joint edges of pairs of elements align with each other in a direction parallel to the joint edges. In some cases, mating interfaces between joint edges of cladding elements in a respective row are offset in a direction perpendicular to the mating interfaces between the joint edges of cladding elements in adjacent rows (e.g., or columns in scenarios where the cladding elements are arranged vertically). For example, the cladding elements in a cladding system can be arranged in a stretcher bond pattern. Overlap between the respective mating interfaces (e.g., joint mating interfaces and profiled edge mating interfaces) of the adjacent cladding elements in the cladding systems can improve the overall characteristics of the system. These improved characteristics include, but are not limited to, wind resistance, water resistance, debris resistance, and/or impact resistance. For example, the interfaces between the profiled edges and the joint ends of the respective cladding elements can facilitate improved performance of the cladding system in both the vertical and horizontal directions (e.g., load and impact energy transfer between elements in both directions). Further, as discussed above, the mating interfaces between the cladding elements can increase the efficiency of constructing the cladding systems, as the interfaces can provide confirmation of alignment between the adjacent cladding elements.
Although the embodiments has been described with reference to specific examples, it will be appreciated by those skilled in the art that the disclosure may be embodied in many other forms.
It is also contemplated that various combinations or sub-combinations of the specific features and aspects of the embodiments may be made and still fall within the scope of the disclosure. Accordingly, it should be understood that various features and aspects of the disclosed embodiments can be combined with or substituted for one another in order to form varying modes of the disclosed embodiment. Thus, it is intended that the scope of the present disclosure herein disclosed should not be limited by the particular disclosed embodiments described above, but should be determined only by a fair reading of the claims that follow.
Similarly, this method of disclosure, is not to be interpreted as reflecting an intention that any claim require more features than are expressly recited in that claim. Rather, as the following claims reflect, inventive aspects lie in a combination of fewer than all features of any single foregoing disclosed embodiment. Thus, the claims following the Detailed Description are hereby expressly incorporated into this Detailed Description, with each claim standing on its own as a separate embodiment.
This application is a continuation of U.S. patent application Ser. No. 15/686,037, filed Aug. 24, 2017 and entitled CLADDING ELEMENT which claims the benefit of U.S. patent application Ser. No. 14/838,217, filed Aug. 27, 2015 and entitled CLADDING ELEMENT, which claims the benefit of U.S. Provisional Patent Application No. 62/042,758, filed Aug. 27, 2014 and entitled CLADDING ELEMENT, all of which are hereby incorporated by reference in their entirety and for all purposes.
Number | Date | Country | |
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62042758 | Aug 2014 | US |
Number | Date | Country | |
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Parent | 15686037 | Aug 2017 | US |
Child | 16931278 | US | |
Parent | 14838217 | Aug 2015 | US |
Child | 15686037 | US |