This relates to building materials, and particularly to building claddings or curtain walls, and more particular to modular or unitized cladding systems.
Modem building facades may be formed of building cladding that is not load bearing. Such cladding is often referred to as a curtain wall. Curtain walls may be mounted to the main building structure through connections at floors or columns of the building.
Curtain wall systems are typically designed with aluminium or steel framing members. The aluminium frame is typically in-filled with glass, which provides an architecturally pleasing appearance to the building exterior. Other common infills include stone veneer, metal panels, louvres, and operable windows or vents.
Such curtain walls may be formed by attaching a sub-frame to a building or structure and attaching the curtain wall framework elements thereto. In-fills are then installed in the framework. This approach is often referred to as the “stick” approach. Alternatively, the curtain wall may be pre-assembled in modules or units, which are applied to a building. Such curtain wall system are referred to as “unitized” or “modular”. An overview of curtain wall systems, is for example provided in Glass and Metal Curtain Walls (Best practice guide, building technology)—Public Works and Government Services Canada, ISBN 0-660-19394-9, the contents of which are hereby incorporated by reference.
To the extent that buildings clad by curtain walls must meet certain thermal requirements, additional insulation is typically formed interior to the curtain walls. The curtain walls themselves provide limited insulation. Curtain wall sub-frames often detracts from any insulation properties of the curtain wall as it is typically exposed.
Accordingly, there is a need for improved curtain wall/cladding systems.
Accordingly, a cladding system includes modular cladding panels, each including a composite layer mounted onto metal or alloy sub-frames. The cladding panels may be pre-manufactured to the dimensions of a specific building, and mounted on the exterior of the building. Cladding panels may be mounted vertically and horizontally adjacent to each other. The composite layer provides an outer insulation to the system, and a generally flat outer surface to which a veneer may be mounted. The composite layer further acts as an air and vapour barrier for the building envelope. The sub-frames may connect to one another by a tongue and groove interconnect to form a complete building envelope.
In an aspect, there is provided a modular cladding system for mounting to the exterior of a building, comprising: a plurality of cladding panels pre-manufactured for mounting the exterior of the building, each cladding panel comprising a frame, comprising vertical top and bottom transoms; and a plurality of mullions extending therebetween; a cladding layer formed of opposed metal layers and an insulating core to which the opposed metal layers are adhered. The cladding layer is formed in front of the frame and thermally insulates the frame, once installed to the exterior of the building.
In another aspect, there is provided a building envelope, comprising a modular cladding system mounted to the exterior of the building, the building envelope comprising: a plurality of pre-manufactured cladding panels, mounted adjacent to each other on the exterior of the building, each cladding panel comprising a frame, comprising vertical top and bottom transoms; and a plurality of mullions extending therebetween; a cladding layer formed of opposed metal layers and an insulating core to which the opposed metal layers are adhered; insulates the frame, once installed to the exterior of the building; and a plurality of weather strips formed between the cladding layer of adjacent cladding panels to seal the building envelope.
Other features will become apparent from the drawings in conjunction with the following description.
In the figures which illustrate example embodiments,
Cladding system 10 may be used to clad the entirety of a structure, by pre-measuring the structure, and determining the size and mounting location of suitably sized panels 12. Cladding panels 12 may be mounted vertically and horizontally adjacent to each other, as describe below. Cladding system 10 when so installed may form a building envelope. Cladding system 10 may be used to clad newly erected structures, or to re-clad existing structures
Cladding system 10, when attached to a structure is not load bearing. Instead, it is attached externally to load bearing elements of the structure. For example, each cladding panel 12 may be attached to floors and pillars of the structure, as further described below. As will be explained, each cladding panel 12 may be mounted to the structure using suitable anchors, similar to those used to mount conventional curtain walls to the exterior of similar structures.
Each cladding panel 12 includes a frame 14, on which a composite layer 16 is mounted. Optionally, an exterior veneer layer 18 is mounted on composite layer 16.
Optionally, as well, openings, such as a window, door or louvered openings may be formed within a panel 12. A window 50 in a corresponding opening in panel 12 is depicted in
Frame 14 is made of a metal or alloy, and includes several vertical mullions 30a, 30b, 30c and 30d (individually and collectively mullion(s) 30) extending between horizontally extending top and bottom transoms 32a, 32b (individually and collectively mullion(s) 32). Mullions 30 and transoms 32 may for example be formed of steel, aluminium or other suitable materials known to those of ordinary skill. Mullions 30 and transoms 32 may be extruded, or formed otherwise; they may also be hollow, as for example illustrated in cross-section in
Cross-sectional views near the top and bottom of window 50 are depicted in
Depending on the width of panel 12, the number of interior mullions 30 on a frame 14 may vary. The number of mullions 30 may be chosen to provide a relatively uniform spacing between vertically extending mullions 30 of about 0.75-3 meters. In an embodiment, the distance between mullions 30 is nominally about 1.5 m center to center. Of course, this distance could be greater or less, depending on spans, wind loads, and the weight or type of veneer 18. Panels 12, further, typically have a height corresponding to the distance between floor and ceiling of a typical building. In this way a single row of panels 12 may span a floor of a structure/building.
A composite layer 16 is formed from one or more composite panel segments 34a, 34b, 34c (individually and collectively panel segment 34).
Composite layer 16 is attached to the outer face of frame 14, proud of frame 14. Composite panel segments 34a, 34b interlock to each other. Likewise panel segment 34b and 34c to form layer 16 that is co-extensive with frame 16. In this way, the front face of layer 16 is generally flat, allowing panel 12 to be generally flat. Moreover, composite layer effectively covers and insulates frame 14.
Each composite panel segment 34 may be formed as an insulated metal panel. To that end, each composite panel segment 34 includes opposed, relatively thin (e.g. 0.4-2 mm (and typically between 0.4 and 0.8 mm))) metal layers 40a, 40b, on either side of an insulation layer 42. Insulation layer 42 may, for example, be between 50 and 300 mm. Suitable insulating materials include polyurethane (e.g. spray foam polyurethane); Styrofoam; fiberglass; or other suitable insulation material. Insulation layer 42 may be adhered to the metal outer layers 40a, 40b, for example by way of an adhesive, or by injecting a foam layer between metal outer layers 40a, 40b. Metal outer layers 40a, 40b, may, for example, be bent or extruded to form a cavity therebetween. An insulating material in the form of foam, or liquid may be injected into the cavity to form insulation layer 42. Alternatively, metal outer layers may be adhered to a preformed insulation—in the form of foam, bat, or the like. Insulating material may have suitable fire-ratings so that panel 12 is sufficiently fire retardant to be used as an exterior cladding in accordance with applicable building codes. Foam insulation will typically have a density of 32 kg/m3 or greater. Batt insulation will typically have a density of 120 kg/m3 or greater.
As will be appreciated, each composite panel segment 34 has a pre-defined thermal R value, and rigidity. Rigidity will depend on the thickness and type of metal and insulation used. The rigidity of composite panel segment 34 and its fastening to frame 14 effectively allows the composite panel segment to act as diaphragm on frame 14 of each composite panel 12. The in-plane stiffness of the diaphragm transmits the weight of the panel to the end mullions 32a and 32b of frame 14 where it is transferred to the building structure by fixed connection brackets (e.g. bracket 150 in
Insulated metal panel may, for example, be an insulated metal panel of the type readily manufactured by Kingspan Group, or MetlSpan, and generally available.
Composite panel segments 34 may be formed with predefined dimensions. Conventional metal segments 34, are for example, available in widths of less than 120 cm. Optionally, panel segments 34 may include joints—such as tongue and groove joint 90, formed of as shown in
Composite layer 16 may be attached to the exterior facing side of frame 14 by suitable fasteners 98—such as bolts, screws of the like, as illustrated in cross-section in
Optionally, a veneer 18 may be affixed to the exterior of composite layer 16. In the depicted embodiment, veneer 18 may be formed as additional metal panels 66 fabricated from tension-leveled, architectural grade aluminum plates, with optional stiffening ribs (if required). Panel corners may be press formed panels to provide a seamless finish and post painted. Panel corners may be mitred to provide a return edge. Veneer 18 may alternatively be formed of roll formed metal cladding, preformed metal cladding, terracotta tiles or panels, cement panels, high-pressure laminate panels, porcelain tile, brick veneer, or other typical building veneers, known to those of ordinary skill.
Veneer 18 may be mounted to the exterior of composite layer 16, using laterally extending rails 60, on which veneer 18 may be hung or suspended. Suitable hangers 62 may be used to hang panels 66 on rails 60, as for example illustrated in
Frame 14 may further include complementary tongue and groove, extending from vertical mullions 30a/30b, and/or horizontal transoms 32a or 32b, forming tongue and groove assembly 120 to allow frame 14 of adjacent cladding panels 12 to be interconnected on the exterior of building/structure. Tongue/groove assembly 120 formed on two cladding panel 12-1 and 12-2, is illustrated in cross-section in
However such rails also typically extend from transoms 32a and 32b to interconnect vertically and horizontally adjacent panels 12. As illustrated in
Optionally a further weather strip 140, formed of rubber, plastic, or the like may extend from, and parallel to the lengthwise extent of one of connection strips 130, 132. As illustrated, a hook shaped extrusion 142 extends parallel to connection strips 132/134, and carries weather strip 142. Once connection strips 130/132 are interconnected, weather strip 140 sits in the seam between composite layer 16 of adjacent panels (e.g. panels 12-1, 12-2 of
Vertically adjacent panels 12 may be installed at a distance, equal to approximately the thickness of strip 140. Layers 16 of adjacent cladding panels 12 may thus be separated by a relatively narrow seam, providing a continuous planar surface on the exterior of the building. Strip 140 may for example have dimensions of about 10-15 mm×25-35 mm. Strip 140 may be compressed between layers 16 of adjacent cladding panels 12 to provide insulated seems having a thickness of less than 10 mm (e.g. 8 mm). The planar surface may thus allow for a relatively continuous veneer—like example veneer 18.
Strip 140 may fill horizontal seems, further making the building envelope formed by system 10 continuous. As well, as strip 140 are also located proud of transoms 32 (and mullions 30), they further insulate these from the environment.
A similar arrangement for vertically extending rails, extending from vertical mullions 30a/30b of adjacent panels is depicted in
As noted, panels 12 typically have a height (i.e. between transoms 32a and 32b) equal to the distance between floor and ceiling of a typical building. In this way, transoms 32a and 32b may be affixed to the subfloors of a building. Conveniently, the exterior mullions 32a, 32b may be affixed to structural pillars of the building. In this way, wind loads are absorbed by the subfloors of the building, while the weight of panels 12 are supported by through the vertical mullions 32a, 32b. Of note, the bottom most panel 12 on the exterior of a structure may be mounted directly to the foundation slab, base or curb of a structure, as for example illustrated in
As illustrated in
Additionally, as frame 14 is behind composite layer 16, frame 14 is thermally insulated from exterior temperatures, allowing the entire building envelope formed by cladding system 10 to act as an insulation layer and air and vapour barrier to a structure on which system 10 is mounted.
Of course, the above described embodiments are intended to be illustrative only and in no way limiting. The described embodiments are susceptible to many modifications of form, arrangement of parts, details and order of operation. The invention is intended to encompass all such modification within its scope, as defined by the claims.
Number | Name | Date | Kind |
---|---|---|---|
4599838 | Kaminaga | Jul 1986 | A |
4903454 | Rose | Feb 1990 | A |
8191325 | Ting | Jun 2012 | B2 |
8266851 | Campbell | Sep 2012 | B2 |
8347569 | McIntyre | Jan 2013 | B1 |
8991121 | Baker | Mar 2015 | B1 |
9163399 | Kelley | Oct 2015 | B1 |
9797143 | Luk | Oct 2017 | B2 |
9988820 | Komatsu | Jun 2018 | B2 |
20030150179 | Moreno | Aug 2003 | A1 |
20070022682 | Morgenegg et al. | Feb 2007 | A1 |
20100146893 | Dickinson | Jun 2010 | A1 |
20150184684 | Lathief | Jul 2015 | A1 |
20150300017 | Carolan | Oct 2015 | A1 |
20150308125 | Helms | Oct 2015 | A1 |
20150345152 | Libreiro | Dec 2015 | A1 |
20160326749 | Johnson | Nov 2016 | A1 |
20170298634 | Marchesi | Oct 2017 | A1 |
20170298635 | Brochu | Oct 2017 | A1 |
20180209154 | Ausseur | Jul 2018 | A1 |
Number | Date | Country |
---|---|---|
2018118536 | Jun 2018 | WO |
Entry |
---|
Benchmark by Kingspan, Architectural Building Envelope Solutions, pp. 1-308, Feb. 2019. |
Rabbet Edge Panels, Mapes Architectural Panels, pp. 1-2. |
Glass and Metal Curtain Walls, Best Practice Guide Building Technology, CMHC 2004, pp. 1-257. |
BAM South, [Retrieved Apr. 3, 2019], retrieved online via URL: https://www.eews.com/projects/bam-south/. |
Performance Appraisal Certificate, Light Gauge Steel Framed Structure with Infill Concrete Panel (LGSFS-ICP) Technology, Dec. 4, 2016, 52 pages. |
BAM South in Brooklyn, New York, Prism, Jul. 18, 2018, 8 pages. |
Number | Date | Country | |
---|---|---|---|
20200378134 A1 | Dec 2020 | US |