Windows are commonly used in residential and commercial buildings, e.g., in storefronts and in curtain walls used on the façade of high-rise buildings. Aesthetic considerations play an important part in architectural design, including the design of window systems and curtain walls. The architecture of curtain walls for residential and commercial buildings typically include a plurality of vertical structural elements secured to a plurality of horizontal structural elements, and the interconnected vertical and horizontal structural elements are adapted to frame and hold glazing panels, such as panes of window glass, polycarbonates, or other clear, translucent, tinted, or opaque panels.
Glazing panels are conventionally secured to the interconnected vertical and horizontal structural elements using an assembly of gaskets, silicone adhesives, sealants, and/or structural tapes that seal the joints in the framing system against water and air infiltration. Currently, the installer must cut gaskets to length on site and install the individual gaskets in channels defined in the vertical and horizontal structural elements. Liquid sealant must then be applied at the corners of the vertical and horizontal structural elements and joint plug areas and allowed to cure to complete a full gasket seal around individual frames on the interior of the curtain wall.
Properly sealing a glazing panel within a curtain wall frame can be a time consuming process that requires skilled labor. Moreover, this installation process requires the use of substantial amount of liquid sealant and is prone to user error if not carefully undertaken.
Embodiments disclosed herein include a curtain wall system that includes a vertical member, a horizontal member coupled to the vertical member at a joint, and a vertical bridge gasket coupled to the vertical member. The vertical bridge gasket includes a vertically-extending interior gasket, a vertically-extending thermal break gasket, and a vertical bridge member extending between the vertically-extending interior and thermal break gaskets. The curtain wall system further includes a horizontal bridge gasket coupled to the horizontal member and joined to the vertical bridge gasket at a corner joint, the horizontal bridge gasket including a horizontally-extending interior gasket, a horizontally-extending thermal break gasket, and a horizontal bridge member extending between the horizontally-extending interior and thermal break gaskets, wherein the vertical and horizontal bridge gaskets cover the joint between the vertical and horizontal members. In a further embodiment of the curtain wall system, the vertical member defines a first vertical channel and a second vertical channel, and the horizontal member defines a first horizontal channel and a second horizontal channel, and wherein the vertically-extending interior gasket is coupled to the first vertical channel, the vertically-extending thermal break gasket is coupled to the second vertical channel, the horizontally-extending interior gasket is coupled to the first horizontal channel, and the horizontally-extending thermal break gasket is coupled to the second horizontal channel. In another further embodiment of any of the previous embodiments, the curtain wall system may further include a glazing panel mounted adjacent the vertical and horizontal members, wherein the vertically-extending interior gasket interposes the vertical member and the glazing panel, and the horizontally-extending interior gasket interposes the horizontal member and the glazing panel. In another further embodiment of any of the previous embodiments, wherein the vertical member provides a vertical tongue that defines the second vertical channel, and the horizontal member provides a horizontal tongue that defines the second horizontal channel. In another further embodiment of any of the previous embodiments, the curtain wall system may further include a first pressure plate secured to the vertical tongue with a first fastener, wherein the vertically-extending thermal break gasket interposes the first pressure plate and the vertical tongue, and a second pressure plate secured to the horizontal tongue with a second fastener, wherein the horizontally-extending thermal break gasket interposes the second pressure plate and the horizontal tongue. In another further embodiment of any of the previous embodiments, the curtain wall system may further include a vertical tongue extending from the vertical member, a first thermal tongue extension interposing the vertically-extending thermal break gasket and the vertical tongue, wherein the second vertical channel is defined in the first thermal tongue extension, a horizontal tongue extending from the vertical member, and a second thermal tongue extension interposing the horizontally-extending thermal break gasket and the horizontal tongue, wherein the second vertical channel is defined in the second thermal tongue extension. In another further embodiment of any of the previous embodiments, the curtain wall system may further include a first vertical dart extending along at least a portion of the length of the vertically-extending interior gasket and received within the first vertical channel, a second vertical dart extending along at least a portion of the length of the vertically-extending thermal break gasket and received within the second vertical channel, a first horizontal dart extending along at least a portion of the length of the horizontally-extending interior gasket and received within the first horizontal channel, and a second horizontal dart extending along at least a portion of the length of the horizontally-extending thermal break gasket and received within the second horizontal channel. In another further embodiment of any of the previous embodiments, the vertical bridge member is angled by about 90° to extend to each of the vertically-extending thermal break and interior gaskets, and the horizontal bridge member is angled by about 90° to extend to each of the horizontally-extending thermal break and interior gaskets. In another further embodiment of any of the previous embodiments, the vertical bridge gasket is a first vertical bridge gasket, and the horizontal bridge gasket is first horizontal bridge gasket, the curtain wall system further including a second vertical bridge gasket laterally offset from the first vertical bridge gasket and including a vertically-extending interior gasket, a vertically-extending thermal break gasket, and a vertical bridge member extending between the vertically-extending interior and thermal break gaskets of the second vertical bridge gasket, and a horizontal bridge gasket vertically-offset from the first horizontal bridge gasket and including a horizontally-extending interior gasket, a horizontally-extending thermal break gasket, and a horizontal bridge member extending between the horizontally-extending interior and thermal break gaskets of the second horizontal bridge gasket, wherein the first and second horizontal bridge gaskets extend between the first and second vertical bridge gaskets, and wherein each end of the first and second horizontal bridge gaskets is joined to a corresponding end of the first and second vertical bridge gaskets at corresponding corner joints to form a four-sided frame.
Embodiments disclosed herein may further include a curtain wall frame gasket that may include first and second vertical bridge gaskets laterally-offset from each other, each vertical bridge gasket including a vertically-extending thermal break gasket, a vertically-extending interior gasket, and a vertical bridge member extending between the vertically-extending thermal break and interior gaskets, and first and second horizontal bridge gaskets vertically-offset from each other, each horizontal bridge gasket including a horizontally-extending thermal break gasket, a horizontally-extending interior gasket, and a horizontal bridge member extending between the horizontally-extending thermal break and interior gaskets, wherein the first and second horizontal bridge gaskets extend between the first and second vertical bridge gaskets, and wherein each end of the first and second horizontal bridge gaskets is joined to a corresponding end of the first and second vertical bridge gaskets at corresponding corner joints to form a four-sided frame. In a further embodiment, the curtain wall frame gasket may include a first relief defined in the first horizontal bridge gasket, and a second relief defined in the second horizontal bridge gasket and vertically-aligned with the first relief. In a further embodiment, each corner joint of the corresponding corner joints forms a 90° angle between each end of the first and second horizontal bridge gaskets and the corresponding end of the first and second vertical bridge gaskets. In a further embodiment, the curtain wall frame gasket may include a first vertical dart extending along at least a portion of the length of the vertically-extending thermal break gasket, a second vertical dart extending along at least a portion of the length of the vertically-extending interior gasket, a first horizontal dart extending along at least a portion of the length of the horizontally-extending thermal break gasket, and a second horizontal dart extending along at least a portion of the length of the horizontal-extending interior gasket. In a further embodiment, the curtain wall frame gasket further includes one or more barbs defined on one or both of the first vertical dart and the first horizontal dart. In a further embodiment, the vertical bridge member is angled by about 90° to extend to each of the vertically-extending thermal break and interior gaskets, and the horizontal bridge member is angled by about 90° to extend to each of the horizontally-extending thermal break and interior gaskets.
Embodiments disclosed herein may further include a method of sealing an interior of a curtain wall system including a vertical member and a horizontal member coupled to the vertical member at a joint, the method including coupling a vertical bridge gasket to the vertical member, the vertical bridge gasket including a vertically-extending interior gasket, a vertically-extending thermal break gasket, and a vertical bridge member extending between the vertically-extending interior and thermal break gaskets. The method may further include coupling a horizontal bridge gasket to the horizontal member, the bridge gasket being joined to the vertical bridge gasket at a corner joint and including a horizontally-extending interior gasket, a horizontally-extending thermal break gasket, and a horizontal bridge member extending between the horizontally-extending interior and thermal break gaskets. The method may further include covering the joint between thermal break the vertical and horizontal members with the vertical and horizontal bridge gaskets. In a further embodiment, the vertical member defines first and second vertical channels, and the horizontal member defines a first and second horizontal channels, the method may further include coupling the vertically-extending interior gasket to the first vertical channel, coupling the vertically-extending thermal break gasket to the second vertical channel, coupling the horizontally-extending interior gasket to the first horizontal channel, and coupling the horizontally-extending thermal break gasket to the second horizontal channel. In a further embodiment, the method may include mounting a glazing panel adjacent the vertical and horizontal members, arranging the vertically-extending interior gasket between the vertical member and the glazing panel, and arranging the horizontally-extending interior gasket between the horizontal member and the glazing panel. In a further embodiment, the vertical member provides a vertical tongue that defines the second vertical channel, and the horizontal member provides a horizontal tongue that defines the second horizontal channel, the method may further include securing a first pressure plate to the vertical tongue with a first fastener, wherein the vertically-extending thermal break gasket interposes the first pressure plate and the vertical tongue, and securing a second pressure plate to the horizontal tongue with a second fastener, wherein the horizontally-extending thermal break gasket interposes the second pressure plate and the horizontal tongue. In a further embodiment, the vertical member provides a vertical tongue and the horizontal member provides a horizontal tongue, the method may further include arranging a first thermal tongue extension between the vertically-extending thermal break gasket and the vertical tongue, wherein the second vertical channel is defined in the first thermal tongue extension, and arranging a second thermal tongue extension between the horizontally-extending thermal break gasket and the horizontal tongue, wherein the second vertical channel is defined in the second thermal tongue extension.
The following figures are included to illustrate certain aspects of the present disclosure, and should not be viewed as exclusive embodiments. The subject matter disclosed is capable of considerable modifications, alterations, combinations, and equivalents in form and function, without departing from the scope of this disclosure.
The present disclosure is related to building products and, more particularly, to window structures, window frames, curtain walls, and curtain wall assemblies with improved seals.
The chassis subassembly 100 may be designed for installation in a large commercial building, such as a low- to mid-rise building, but the principles of the present disclosure could be equally applicable to skyscrapers. In such embodiments, the vertical and horizontal members 102a,b and 104a-c will typically be extruded from an aluminum alloy, which is a strong, lightweight and corrosion-resistant material, but the vertical and horizontal members 102a,b and 104a-c could alternatively by formed of other materials, such as other metals or metal alloys. As will be appreciated, the technology of this disclosure may also be applicable to smaller commercial or residential buildings.
The chassis subassemblies 100 include and otherwise frame a plurality of glazing panels 208a-208j (e.g., glass), alternately referred to as “glazing units,” installed therein between the vertical and horizontal members (102b and 104a shown). In modern construction, the glazing panels 208a-j are typically double or triple glazed with air, an inert gas, and/or a coating(s) between adjacent panels to control transmission of thermal energy by radiation and convection between the interior of the building and the exterior environment.
The glazing panels 208a-j are conventionally secured to the corresponding chassis subassemblies 100 using gaskets, silicone adhesives, sealants, and/or structural tapes. Embodiments described herein, however, discuss improved gaskets and gasket assemblies that eliminate the need to apply silicone adhesives or sealants at gasket joints and the joints between the vertical and horizontal members, around joint plugs, and over the screw heads that secure the vertical and horizontal members together.
In some installations, one or more cover elements or “covers” 210 may be used. The covers 210 provide an architectural finishing detail between adjacent glazing panels 208a-j and simultaneously provide a mechanism for supporting the glazing panels 208a-j in place on the curtain wall system 202, e.g., as a back-up or supplemental support for a glazing unit, which is adhered to the chassis subassembly 100. The covers 210 may also help insulate and occlude gaps 212 between adjacent glazing panels 208a-j and thereby help prevent the influx of foreign matter, such as dirt, leaves, debris, insects, birds, etc. into the gaps 212. The covers 210 can also help reduce wind noise generated by air flowing through or proximate the gaps 212.
The intersections of the vertical and horizontal members of the chassis subassembly 100 require proper seals and sealing techniques to prevent the influx of fluids (e.g., water and air) into the interior of each curtain wall system 202 and 302. Currently, gaskets must be cut on-site by installers and installed as cut lengths into gasket channels defined in the vertical and horizontal members. A liquid sealant (e.g., silicone, rubber bonding cement, etc.) is then applied by the installer at the intersection of the vertical and horizontal members, the exposed ends of the gaskets, and the joint plug areas (e.g., areas designed to allow weeping and horizontal mullion continuity). The curing of sealant will result in a full gasket seal provided around individual frames on the interior side of the curtain wall.
According to embodiments of the present disclosure, a new gasket sealing system is disclosed that eliminates the need to cut the gaskets to length and apply liquid sealant at various locations on the interior side of the curtain wall to properly seal the glazing panel. The frame gaskets described herein can be easily installed as a continuous frame into the frame opening prior to installing the glazing panels. The frame gaskets can be pre-formed by a supplier into a four-sided frame that will act as a water/air barrier that eliminates the need to wet seal the vertical-to-horizontal intersections and joint plug areas with liquid sealant. The frame gaskets, however, can be pre-formed to have more than four sides or any other number of sides, such as an octagonal gasket, without departing from the scope of the disclosure. Moreover, those skilled in the art will readily appreciate that the principles of the present disclosure can be incorporated into all pressure plate curtain wall systems.
The vertical member assembly 502 may be configured to help laterally support and/or secure one or more glazing panels, shown in
As illustrated each glazing panel 504a,b includes a first or “exterior” glass panel 506a and a second or “interior” glass panel 506b with a spacer 508 positioned therebetween. The space between the first and second glass panels 506a,b may be filled with air or an inert gas to help control transmission of thermal energy by radiation and convection between the interior of the building and the exterior environment. Alternatively, one or more plastic films or low-e coatings may be positioned within the space to help control transmission of thermal energy. Accordingly, the glazing panels 504a,b may each comprise a conventional “double-glazed” frame arrangement. It will be appreciated, however, that the principles of the present disclosure may be equally applicable to other glazing panel designs and configurations, without departing from the scope of the disclosure.
As illustrated, the vertical member assembly 502 includes a vertical member 510, alternately referred to as a “mullion.” The vertical member 510 may also be referred to as a “transverse” member since it does not necessarily have to be perfectly vertical or otherwise orthogonal from a horizontal plane. The vertical member 510 may comprise a rigid extrusion made of aluminum, an aluminum alloy, or other metals and metal alloys. The vertical member 510 may be coupled to the building structure, such as a beam (e.g., the beams 204 of
The vertical member assembly 502 further includes a pressure plate 512 and a cover 514 removably coupled to the pressure plate 512. The cover 514 may be similar to the covers 210, 306 of
The pressure plate 512 may be operatively coupled to the vertical member 510 with a fastener 520, which may be a mechanical fastener, that extends through a glazing pocket 522 defined laterally between the vertical member 510 and the pressure plate 512. The glazing pocket 522 may also be defined horizontally between the first and second glazing panels 504a,b. In the illustrated embodiment, the fastener 520 comprises a screw that may be received within or otherwise threaded into a vertical tongue 524 extending from and forming part of the vertical member 510.
In the illustrated application, a thermal tongue extension 526 is positioned within the glazing pocket 522 and interposes and otherwise extends between the pressure plate 512 and the vertical tongue 524. The thermal tongue extension 526 may form part of the vertical tongue 524 or otherwise extend therefrom, and the fastener 520 may be configured to penetrate the thermal tongue extension 526 to reach the vertical tongue 524. The thermal tongue extension 526 is made of material having low thermal conductivity (e.g., rubber, an elastomer, a low conductance polymer, etc.), thus helping to reduce the conductive pathway for thermal energy between the exterior environment of a building and the climate controlled interior of the building.
A vertically-extending thermal break gasket 528 interposes the pressure plate 512 and the thermal tongue extension 526. The thermal break gasket 528 may be made of rubber or an elastomer to facilitate a sealed interface against the inner wall (surface) of the pressure plate 512. The thermal break gasket 528 may also operate as a thermal barrier between the pressure plate 512 and the thermal tongue extension 526, thus further reducing the conductive pathway for thermal energy between the exterior and the interior.
As illustrated, the thermal break gasket 528 defines or otherwise provides a dart 530 sized to be received within a vertical channel 532 defined in the thermal tongue extension 526. It should be noted, however, that the thermal tongue extension 526 is not required in all embodiments. Instead, the thermal tongue extension 526 may be omitted and the vertical tongue 524 may alternatively extend toward the pressure plate 512. In such embodiments, the thermal break gasket 528 would interpose the pressure plate 512 and the vertical tongue 524, and the vertical channel 532 would be defined in the vertical tongue 524 to receive the dart 530.
The assembly 502 further includes a first vertically-extending exterior gasket 534a and a second vertically-extending exterior gasket 534b that interpose the first and second glazing panels 504a,b, respectively, and the pressure plate 512. Similar to the thermal break gasket 528, the exterior gaskets 534a,b may be made of rubber or an elastomer to provide a substantially sealed interface between the glazing panels 504a,b and the pressure plate 512 on the exterior of the building, thus helping to prevent the migration of fluids (e.g., water, air, etc.) into the glazing pocket 522 and potentially past the waterline.
The assembly 502 also includes a first vertically-extending interior gasket 536a and a second vertically-extending interior gasket 536b, alternately referred to as “glazing gaskets,” that interpose the first and second glazing panels 504a,b, respectively, and the vertical member 510. Similar to the thermal break gasket 528, the interior gaskets 536a,b may also be made of rubber or an elastomer to provide a substantially sealed interface between the glazing panels 504a,b and the vertical member 510 on the interior of a building, thus helping to prevent the migration of fluids (e.g., water, air, etc.) into the glazing pocket 522 from the interior, and further preventing the migration of these fluids into the building. As illustrated, each interior gasket 536a,b defines or otherwise provides a dart 538 sized to be received within a corresponding vertical channel 540 defined in the vertical member 510.
In the prior art vertical member assembly 502 of
As can be appreciated, this process of cutting and installing the individual lengths of the thermal break and interior gaskets 528, 536a,b, and subsequently applying liquid sealant at appropriate locations on the interior frame is time consuming, requires skilled labor, and is prone to labor error. As described herein, a frame gasket and/or gasket assembly is disclosed and described that eliminates the need to cut gaskets to length, seal the joint between the vertical and horizontal curtain wall members, or seal the ends of the gaskets and joint plug areas.
Similar to the vertical member assembly 502 of
Unlike the vertical member assembly 502 of
The vertical bridge gaskets 604 may be entirely or partially made of rubber or an elastomer and thereby capable of providing sealed interfaces between the pressure plate 512 and the thermal tongue extension 526, and between the vertical member 510 and the glazing panels 504a,b. In at least one embodiment, the vertical bridge gaskets 604 may be made of extruded ethylene propylene diene monomer (EPDM), a typical material for architectural gaskets with good thermal and hardness properties.
The vertically-extending thermal break gasket 606 is similar in some respects to the thermal break gasket 528 of
The vertically-extending interior gasket 608 is similar in some respects to the interior gaskets 536a,b of
The vertical bridge member 610 extends between and effectively joins the thermal break gasket 606 and the interior gasket 608 to form a monolithic component part. The vertical bridge member 610 may comprise a generally thin section of material angled at about 90° to extend to each of the thermal break gasket 606 and the interior gasket 608. In other designs or applications, however, the vertical bridge member 610 may be angled at other angles to extend to the thermal break and interior gaskets 606, 608. The thin material provides flexibility to the vertical bridge gasket 604, which may prove advantageous in helping proper installation and location of the thermal break and interior gaskets 606, 608 in the corresponding vertical channels 532, 540.
In some embodiments, the vertical bridge gaskets 604 may be used independently of other gaskets. In such embodiments, the vertical bridge gasket 604 may be cut to length by an installer (worker) and the vertical darts 612, 616 of the vertically-extending thermal break and interior gaskets 606, 608, respectively, may be aligned with and inserted into the vertical channels 532, 540 defined in the thermal tongue extension 526 (or alternatively the vertical tongue 524) and the vertical member 510, respectively. The vertical bridge member 610 extends across joints between the vertical member 510 and any adjoining horizontal member, thus eliminating the need for the installer to apply liquid sealant at the joints or any plug areas.
In other embodiments, and as briefly mentioned above, the vertical bridge gaskets 604 may each form part of a corresponding curtain wall frame gasket. Each frame gasket will include two laterally-offset vertical bridge gaskets 604, and two vertically-offset horizontal bridge gaskets (described below with reference to
The horizontal member assembly 702 may be configured to help support and/or secure one or more glazing panels, shown in
The horizontal member assembly 702 further includes a horizontal member 710 (alternately referred to as a “transom”), which may comprise a rigid extrusion made of aluminum or an aluminum alloy. The horizontal member assembly 702 further includes a pressure plate 712 and a cover 714 removably coupled to the pressure plate 712. Aside from being horizontally oriented, the pressure plate 712 and the cover 714 may be similar to the pressure plate 512 and the cover 514 of
The pressure plate 712 may be operatively coupled to the horizontal member 710 with a fastener 716, which may be a mechanical fastener, that extends through a glazing pocket 718 defined vertically between the horizontal member 710 and the pressure plate 712. The glazing pocket 718 may also be defined vertically between the first and second glazing panels 704a,b. In the illustrated embodiment, the fastener 716 comprises a screw that may be received within or otherwise threaded into a horizontal tongue 720 extending from or forming part of the horizontal member 710. In the illustrated embodiment, the horizontal tongue 720 extends almost to the pressure plate 712 within the glazing pocket 718. In other embodiments, however, a thermal tongue extension similar to the thermal tongue extension 526 of
The horizontal member assembly 702 may further include one or more setting blocks 722 at least partially positioned within the glazing pocket 718 and used to help position and support the upper glazing panel 704a under the influence of gravity. More specifically, the setting block 722 may interpose the upper glazing panel 704a and the horizontal tongue 720 (or alternatively a thermal tongue extension, if used). Accordingly, the upper glazing panel 704a may rest directly on the setting block 722. In some embodiments, the setting block 722 may be made of rubber or an elastomer, but may alternatively be made of a polymer.
A first or upper exterior gasket 724a and a second or lower exterior gasket 724b interpose the upper and lower glazing panels 704a,b, respectively, and the pressure plate 712. The exterior gaskets 724a,b may be made of rubber or an elastomer and thereby provide a substantially sealed interface between the glazing panels 704a,b and the pressure plate 712 on the exterior of the building.
The horizontal member assembly 702 further includes one or more horizontal bridge gaskets 726 (two shown on opposite sides of the horizontal tongue 720). Similar to the vertical bridge gaskets 604 of
The horizontally-extending thermal break gasket 728 provides a sealed interface against the inner wall of the pressure plate 712, and may also operate as a thermal barrier between the pressure plate 712 and the horizontal tongue 720 (or a thermal tongue extension). Moreover, the thermal break gasket 728 defines or otherwise provides a dart 734 sized to be received within a horizontal channel 736 defined in the horizontal tongue 720 (or a thermal tongue extension). The darts 734 may be designed similar to the darts 612 of
The horizontally-extending interior gasket 730 provides a substantially sealed interface between one of the glazing panels 704a,b and the horizontal member 710 on the interior of a building. Moreover, the interior gasket 730 defines or otherwise provides a dart 738 sized to be received within a corresponding horizontal channel 740 defined in the horizontal member 710.
The horizontal bridge member 732 extends between and effectively joins the thermal break gasket 728 and the interior gasket 730 to form a monolithic component part. The horizontal bridge member 732 may comprise a generally thin section of material angled at about 90° to extend to each of the thermal break gasket 728 and the interior gasket 730. In other designs or applications, however, the horizontal bridge member 732 may be angled at other angles to extend to the thermal break and interior gaskets 728, 730. The thin material is thin enough to allow room for the setting block 722 and provides flexibility to the horizontal bridge gasket 726, which may prove advantageous in helping proper installation and location of the thermal break and interior gaskets 728, 730 in the corresponding horizontal channels 736, 740.
Similar to the vertical bridge gaskets 604 of
In some embodiments, the frame gasket 800 may be fabricated by a manufacturer and sent to jobsites as a monolithic, four-sided frame. Consequently, an installer need not cut gasket lengths to size on site. The frame gasket 800 may be fabricated by the manufacturer in several standard sizes used to secure and seal glazing panels (e.g., glazing panels 504a,b, 704a,b of
To fabricate the frame gasket 800, the vertical and horizontal bridge gaskets 604, 726 are first manufactured using, for example known extrusion or molding techniques. In at least one application, the vertical and horizontal bridge gaskets 604, 726 may be molded using a rubber vulcanization process. Pairs of vertical and horizontal bridge gaskets 604, 726 are then cut to length corresponding to a particular glazing panel size, and the exposed ends of the cut vertical and horizontal bridge gaskets 604, 726 are subsequently joined together to form the four-sided frame gasket 800. In some embodiments, the ends of the vertical and horizontal bridge gasket 604, 726 pieces may be joined by injecting rubber into the corners to complete the molded corners. The formed frame gasket 800 may then be shipped to a job site ready for install.
In some embodiments, one or more reliefs 802 may be molded into or otherwise defined by the horizontal bridge gaskets 726. More particularly, the reliefs 802 may be formed into the horizontally-extending thermal break gasket sections 728, and each relief 802 may be vertically-aligned with another relief 802 defined in a vertically opposite horizontally-extending thermal break gasket 728. In some applications, the vertically-aligned reliefs 802 may be configured to accommodate vertical structural members that will be installed after a glazing panel and pressure plate are installed in conjunction with the frame gasket 800. In other applications, the vertically-aligned reliefs 802 may be configured to accommodate the vertically extending exterior gaskets 534a, 534b, 724a and 724b that run through in the vertical extending pressure plate 512, 712. The reliefs 802 eliminate the need for an installer to create (cut) notches to accommodate such vertical structural members (or the vertically extending exterior gaskets 534a, 534b, 724a, 724b and allow the corners of the vertical structural members to fit flush against adjacent metal parts.
As illustrated, the curtain wall system 1002 includes the vertical member 510 and the horizontal member 710 that meet at a joint 1004. To install the first frame gasket 800a, the installer (worker) aligns the vertical darts 612, 616 of the vertically-extending thermal break and interior gaskets 606, 608, respectively, with the vertical channels 532, 540 defined in the vertical tongue 524 (or alternatively a thermal tongue extension) and the vertical member 510, respectively, and inserts the vertical darts 612, 616 into the corresponding vertical channels 532, 540. Similarly, and simultaneously, the installer aligns the horizontal darts 734, 738 of the horizontally-extending thermal break and interior gaskets 728, 730, respectively, with the horizontal channels 736, 740 defined in the horizontal tongue 720 (or alternatively a thermal tongue extension) and the horizontal member 710, respectively, and inserts the horizontal darts 734, 738 into the horizontal channels 736, 740.
The second frame gasket 800b can be installed in a similar manner by aligning and inserting the vertical darts 612, 616 into the vertical channels 532, 540, and aligning and inserting the horizontal darts 734, 738 into the horizontal channels 736, 740. As illustrated, the reliefs 802 are vertically aligned when the first and second frame gaskets 800a,b are each installed.
Properly installing the first and second frame gaskets 800a,b provides monolithic water/air barriers that eliminate the need to wet seal the joint 1004 and joint plug areas with a liquid sealant. As a result, the likelihood of user error in applying liquid sealant is eliminated, which correspondingly reduces the chance of a leak developing after installation. Accordingly, the frame gaskets 800a,b can reduce installation costs by reducing the volume of liquid sealant needed for a job, and work performed by the installer is simplified as the cumbersome process of cutting gaskets into measured lineals from rolls is eliminated.
Therefore, the disclosed systems and methods are well adapted to attain the ends and advantages mentioned as well as those that are inherent therein. The particular embodiments disclosed above are illustrative only, as the teachings of the present disclosure may be modified and practiced in different but equivalent manners apparent to those skilled in the art having the benefit of the teachings herein. Furthermore, no limitations are intended to the details of construction or design herein shown, other than as described in the claims below. It is therefore evident that the particular illustrative embodiments disclosed above may be altered, combined, or modified and all such variations are considered within the scope of the present disclosure. The systems and methods illustratively disclosed herein may suitably be practiced in the absence of any element that is not specifically disclosed herein and/or any optional element disclosed herein. While compositions and methods are described in terms of “comprising,” “containing,” or “including” various components or steps, the compositions and methods can also “consist essentially of” or “consist of” the various components and steps. All numbers and ranges disclosed above may vary by some amount. Whenever a numerical range with a lower limit and an upper limit is disclosed, any number and any included range falling within the range is specifically disclosed. In particular, every range of values (of the form, “from about a to about b,” or, equivalently, “from approximately a to b,” or, equivalently, “from approximately a-b”) disclosed herein is to be understood to set forth every number and range encompassed within the broader range of values. Also, the terms in the claims have their plain, ordinary meaning unless otherwise explicitly and clearly defined by the patentee. Moreover, the indefinite articles “a” or “an,” as used in the claims, are defined herein to mean one or more than one of the elements that it introduces. If there is any conflict in the usages of a word or term in this specification and one or more patent or other documents that may be incorporated herein by reference, the definitions that are consistent with this specification should be adopted.
As used herein, the phrase “at least one of” preceding a series of items, with the terms “and” or “or” to separate any of the items, modifies the list as a whole, rather than each member of the list (i.e., each item). The phrase “at least one of” allows a meaning that includes at least one of any one of the items, and/or at least one of any combination of the items, and/or at least one of each of the items. By way of example, the phrases “at least one of A, B, and C” or “at least one of A, B, or C” each refer to only A, only B, or only C; any combination of A, B, and C; and/or at least one of each of A, B, and C.
Although various example embodiments have been disclosed, a worker of ordinary skill in this art would recognize that certain modifications would come within the scope of this disclosure. For that reason, the following claims should be studied to determine the scope and content of this disclosure.
Filing Document | Filing Date | Country | Kind |
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PCT/US2020/031471 | 5/5/2020 | WO |
Publishing Document | Publishing Date | Country | Kind |
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WO2020/227290 | 11/12/2020 | WO | A |
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20230358039 | Wilson | Nov 2023 | A1 |
20230358040 | Wilson | Nov 2023 | A1 |
20230358055 | Wilson | Nov 2023 | A1 |
20230383528 | Wilson | Nov 2023 | A1 |
20230383536 | Wilson | Nov 2023 | A1 |
Number | Date | Country |
---|---|---|
108277916 | Jul 2018 | CN |
10-1763158 | Aug 2017 | KR |
2013-090415 | Jun 2013 | WO |
2020227290 | Nov 2020 | WO |
Entry |
---|
ISR-WO dated Aug. 12, 2020 for parent application PCT/US2020/031471. |
Number | Date | Country | |
---|---|---|---|
20220195727 A1 | Jun 2022 | US |
Number | Date | Country | |
---|---|---|---|
62843719 | May 2019 | US | |
62928045 | Oct 2019 | US |