This disclosure relates to seal assemblies and in particular a seal assembly for use with light weight exterior wall panels systems that include panel joint seals.
There are two commonly used light weight exterior wall panel systems used in the construction industry today, namely aluminum framed curtain walls and exterior insulated finish system (EIFS).
Aluminum framed curtain wall panels are the most common method for providing exterior walls on multi-story buildings, they have extruded dry-seal systems incorporated that protect the building against air and water infiltration and provide superior longevity. A dry seal system can be designed to incorporate the Rain Screen Principle, so the joint can be pressure equalized to help keep moisture away from the seals. The panels can incorporate windows, stone finish or a metal finish. The downside of aluminum framed curtain wall panels is that they perform quite poorly regarding thermal protection of the building.
Exterior insulated panels (sometimes referred to as E.I.F.S.) are becoming more commonly used today for multi-story curtain wall construction. When these panels are properly designed and installed, they will provide optimum thermal protection for a building. Unfortunately, this type of construction typically requires the joints between the panels to be caulked after the panels are erected. Caulking is what is known as a wet-seal system, they are subject to human error and inclement weather. Caulked joints do not provide the same level of quality and endurance as dry-seal systems and incorporating the Rain Screen Principle is difficult to do with caulked joints. Unfortunately caulking the joints needs to be done using scaffolding or swing stages located on the outside of the building, this can be costly and makes the work more dangerous to do. The latter is expensive and adds time required to complete the installation. Caulking is also problematic when the proximity of the adjacent building is too close to the new wall to allow access.
Both of these commonly used systems have disadvantages. In regard to the aluminum framed curtain wall panels it would be advantageous to provide a wall system that has better thermal characteristics. In regard to Exterior Insulated panels (EIFS) it would be advantageous to provide a wall system that incorporates dry seals and reduces onsite work thus reducing the labor costs and inherently increasing the quality of the wall system. It would be further advantageous to provide pressure equalized seal system that also provides a means for moisture to drain from within the seal system.
The present disclosure relates to a seal assembly for use with exterior insulated wall panels. The seal assembly has a top and a bottom. The seal assembly includes a first connector, a second connector and a vertical seal. The first connector is attached to one of a first and a second exterior insulated panel. The second connector is attached to the other of the first and second exterior panel. The vertical seal is attached to one of the first and second connector. The first and second connectors are configured to be connected together such that the first and second exterior insulated panels are horizontally adjacent so as to connect and seal horizontally adjacent exterior insulated panels.
The vertical seal may include a vertical seal base and at least a first projection and a second projection extending outwardly therefrom wherein the first projection and second projection are resiliently deformable.
The first connector may have a pair of ends and the second connector may have a pair of ends wherein the first connector has a hook on either end thereof adapted to engage a channel on either end of the second connector. The exterior insulated panel of the first and second exterior insulated panels to which the first connector is attached may be pivoted relative to the other of the first and second exterior insulated panels such that the hooks of the first connector engage the channels of the second connector to provide a seal between the first and second exterior insulated panels.
The seal assembly may include a first thermal separator between the first connector and the exterior insulated panel to which it is attached and a second thermal separator between the second connector and exterior insulated panel to which it is attached.
The first connector may include a first portion and a second portion connected with a connector thermal separator. The second connector may include a first portion and a second portion connected with a connector thermal separator.
The seal assembly may include a top chamber plate positioned at the top of the seal assembly and a bottom chamber plate positioned at the bottom of the seal assembly.
The vertical seal may include two pairs of opposed sides wherein one pair of opposed sides each have a bend therein such that the bend is resilient facilitate the other pair of opposed sides to be pushed closer together under pressure. The seal assembly may include a plurality of feet extending outwardly from one pair of opposed sides such that the feet engage the first and second connectors.
The second connector may include a leg extension portion extending outwardly from the channel.
The seal assembly may include a pair of plugs positioned at the top and the bottom of the seal assembly. Each plug may have a body portion and a sloped portion and the sloped portion is positioned for drainage and air circulation. The seal assembly may include a bottom seal boot inside the bottom of the seal assembly and a top seal boot inside the top of the seal assembly.
An exterior wall system includes a plurality of exterior insulated wall panels, a plurality of seal assemblies and a plurality of horizontal seals. The seal assemblies are connected between horizontally adjacent exterior insulated wall panels. The plurality of horizontal seals are between vertically adjacent panels.
At least four wall exterior insulated panels are arranged to form a 4-way joint and wherein plates are buttered with silicone and installed to the top and bottom of the seal assembly to span horizontally across the 4-way joint above and below the horizontal seal, thereby providing a continuous sealing surface for the horizontal seals to bear against.
The plates may be installed to span horizontally across the top and bottom of the seal assembly and the plates are buttered with silicone and attached to the top and bottom of the seal assembly.
The vertical seal chamber may have holes along a vertical exterior face, thereby providing a means for inducing pressure equalization in the vertical seal chamber when air pressure differences experienced by the vertical seal.
The horizontal seals may be buttered onto a top of the exterior insulated panels.
The exterior wall system may include at least one positioning pin between vertically adjacent wall exterior insulated panels.
A horizontal seal for use with horizontally adjacent exterior insulated wall panels includes a base, a top, an exterior wall and an interior wall. The base has at least a pair of spaced apart base feet extending downwardly therefrom. The top is spaced apart from the base and has at least a pair of spaced apart top feet extending upwardly therefrom. The exterior wall extends between the base and the top and the exterior wall has a bend therein. The interior wall extends between the base and the top and the interior wall has a bend therein. The base, the top, the exterior wall and the interior wall define a tubular member and the bend in the exterior wall and the bend in the interior wall facilitates movement of the base relative to the top.
The base feet may be aligned with exterior wall and the interior wall. The top feet may be aligned with the exterior wall and the interior wall.
The horizontal seal may include a chamber wall positioned between the exterior wall and the interior wall and extending between the base and the top, thereby forming two chambers.
The horizontal seal may include a plurality of chamber walls positioned between the exterior wall and the interior wall and extending between the base and the top, thereby forming a plurality of chambers.
Further features will be described or will become apparent in the course of the following detailed description.
The embodiments will now be described by way of example only, with reference to the accompanying drawings, in which:
Referring to
Referring to
The vertical seal assembly 20 includes a pair of connectors namely a first connector 26 and a second connector 28 and a vertical seal 30. The first 26 and second 28 connectors engage each other. The vertical seal 30 includes a vertical seal base 32 and at least a first projection 34 and a second projection 36. The first projection 34 and second projection 36 are spaced apart. The vertical seal 30 is made of a resilient deformable material such that the vertical seal 30 has a memory of the shape of the first projection 34 and the second projection 36. The first 34 and second 36 projection extend outwardly from the vertical seal base 32. The first 34 and second 36 projections are dimensioned so that when the first 26 and second 28 connectors are connected the first 34 and second 36 projections are pressed between the connectors 26 and 28 and deformed slightly to ensure a good seal.
The first 26 and second 28 connectors are made from cold rolled steel. The first connector 26 has hooks 38 projecting inwardly from each end thereof. The second connector 28 has a pair of channels 40 formed therein and projecting inwardly from each end thereof. A guide 42 extends inwardly from each channel 40. When the first 26 and second 28 connectors are connected, the hooks 38 engage the channels 40 and the guides 42 help them to be guided into place. A seal channel 44 is formed on either side of the second connector 28. The vertical seal 30 is positioned in the seal channels 44. The engagement between the hook 38 and the channel 40 accommodates a small amount of movement due to fabrication tolerance and thermal expansion/contraction. By way of example only, in a typical wall system the assembly and fabrication tolerances are +/− 1/16 inch and the thermal expansion is +/−⅛ inch.
The first connector 26 is attached to one exterior insulated panel 10 and the second connector 28 is attached to another exterior insulated panel 10. The hooks 38 on the first connector 26 and the channels 40 on the second connector 28 are configured such that a snap in place connection may be achieved. The connectors are designed such that a hook 38 on one side of the first connector 26 engages a channel 40 on one side of the second connector 28. One panel 10 is then pivoted around the engaged hook 38 and channel 40 until the other hook and channel 40 are snapped in place and the horizontally adjacent panels 10 are connected.
A pair of thermal separators 46 are positioned between the first 26 and second 28 connectors and the exterior insulated panels 10.
In an alternate embodiment is shown in
Referring to
Referring to
As can be seen in a comparison between
Each vertical seal assembly 20 has a top chamber plate 76 and a bottom chamber plate 78. The top chamber plate 76 includes a plate 80, a front lip 82 and back lip 84 both extending downwardly from the plate 80. The front lip 82 has a drip edge 86 extending downwardly and outwardly from the front lip 82. The bottom chamber plate 78 has a plate 88 and a front lip 90 extending downwardly and a back lip 92 extending upwardly therefrom. The front lip 90 has a drip edge 94 extending downwardly and outwardly therefrom. As shown in
The bottom of each vertical seal assembly 20 has a drainage or weeping hole 96 at the bottom thereof as best seen in
The exterior wall system 22 provides a panel joint seal system for curtain wall panels 10 that are framed with light steel members 12 and are insulated 14 outside of the framing. The exterior wall system 22 relates to curtain wall construction, and more particularly, a curtain wall construction made up of cold-formed steel structure 12 that has an exterior insulation system incorporated 14. The exterior wall system 22 provides a dry seal system around the periphery of the exterior insulated wall panels for building construction. The seal system incorporates the rain screen principle to reduce the demand on the seals, this reduces demand on the seal system as wind pressurizes the chamber between the outer and inner seals.
The seals are silicone or rubber, extruded into a shape that allows inherent movements to take place and resist entry of moisture and air into the building. Consideration is given to ensure the seal material maintains flexibility in hot and cold weather. The joint system is thermally efficient, there is substantially little to no thermal bridging in this new joint invention.
Ideally panels 10 are erected one complete floor level at a time. The roll-formed shape of this invention facilitates the connection between two horizontally adjacent panels 10, this allows for the vertical joints of the panels to be snapped together, then lowered into place.
The vertical seal assembly 20 incorporates a means of movement between the panels vertically and horizontally to accommodate structural and thermal changes in the panel and building structures. The roll-formed shape of the connectors 26, 28 and its double vertical seal 30 allow for horizontal movements of +/−⅛″. The Seal system along the horizontal joint allows for +/−⅝″.
A vertical seal assembly 20 includes a cold formed shaped first 26 and second 28 connectors. One of the first 26 and second 28 connector incorporates a flexible double seal component 30 and rain screen protection for the seals. The formed shape also incorporates the snap together mechanism for optimization of panel erection.
At the horizontal joints between adjoining panels a four way top chamber plate 76 is buttered (
The horizontal double seal is spliced to incorporate a drainage system, this provides a rain screen. There are a variety of ways to provide a sufficient joint. A simple butter and flat material can be incorporated to splice the seals.
A splice node with a drainage-cavity can be used to splice the horizontal double seal in order to incorporate the rain screen principle for the horizontal seal system.
For some uses a particular surface treatment can be applied to the underside surface of each panel in order interact with the functionality and movements of the horizontal double seal.
An alternate exterior wall system 22 is shown in
Referring to
The vertical seal 106 is made of resilient deformable material such that the seal has a memory of the original shape. The vertical seal 106 has a pair of opposed sides 108 and 110 and a pair of opposed sides 112 and 114 extending between sides 108 and 110. Sides 106 and 108 have little feet 116 extending outwardly at each end thereof. Side 108 is longer than side 106. Opposed sides 112 and 114, each have a bend 118 therein to make it easier for the sides 106 and 108 to be pushed closer under pressure. Bend 118 is resilient to facilitate opposed sides 106 and 108 to be pushed closer under pressure. Vertical seal 106 is positioned between first vertical seal connector 102 and second vertical seal connector when they are engaged. Feet 116 extending from sides 108 and 110 engage vertical seal connectors 102 and 104. When in position typically sides 112 and 114 will be bent inwardly from their original position so that the seal is pushing outwardly to form a good seal with the vertical seal connectors 102 and 104.
In the embodiment shown in
Referring to
A pair of thermal separators 128 are positioned between the first 102 and second 104 connectors and the exterior insulated panels 10.
Referring to
An alternate horizontal seal 140 is shown in
Referring to
Referring to
Referring to
Another alternate horizontal seal 170 is shown in
Another alternate horizontal seal 180 is shown in
A sample horizontal seal 190 is shown in
As used herein, the terms, “comprises” and “comprising” are to be construed as being inclusive and open ended, and not exclusive. Specifically, when used in the specification and claims, the terms, “comprises” and “comprising” and variations thereof mean the specified features, steps or components are included. These terms are not to be interpreted to exclude the presence of other features, steps or components.
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Entry |
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International Search Report for PCT/CA2018/051118, dated Jan. 24, 2019. |
Number | Date | Country | |
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20190078323 A1 | Mar 2019 | US |
Number | Date | Country | |
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62556861 | Sep 2017 | US | |
62648754 | Mar 2018 | US |