One or more embodiments of the present disclosure relate generally to architectural covering and more particularly, for example, to systems and methods for an insulated architectural covering.
Insulated architectural coverings, such as garage doors, retractable storefronts, and the like, typically have a metal framework filled with foam insulation to reduce heat loss through the frame. Foam insulated architectural coverings are often heavy and require heavy springs and other hardware to install and move the covering. Current techniques can also limit when the frame can be finished in the production process, often requiring the frame members to be foam insulated and assembled post-finishing, resulting in scratches, dents, and scuffs to the finishing and the finished product. In addition, current production techniques are often difficult to automate. For example, foam insulated doors typically include a bolted frame design, requiring expensive and time-consuming assembly.
Therefore, there is a need in the art for systems and methods for an insulated architectural covering that addresses the deficiencies noted above, other deficiencies known in the industry, or at least offers an alternative to current techniques.
Techniques are disclosed for systems and methods associated with an insulated architectural covering. In accordance with one or more embodiments, an apparatus for an architectural opening includes a plurality of panels pivotably connected together. At least one of the plurality of panels includes a frame including a plurality of first frame members connected to a plurality of second frame members at respective interfaces to define at least one opening. Each frame member may include an internal cavity filled with a gas having a thermal conductivity less than atmospheric air. An inset panel may be secured within the at least one opening.
In accordance with one or more embodiments, a panel configured to at least partially cover an architectural opening includes a frame including at least one opening defined by a plurality of first frame members connected to a plurality of second frame members at respective interfaces. Each frame member may include an internal cavity filled with a gas having a thermal conductivity less than atmospheric air. An inset panel may be secured within the at least one opening.
In accordance with one or more embodiments, a method may include connecting a plurality of first frame members to a plurality of second frame members at respective interfaces to define at least one opening of a panel frame. Each frame member may include an internal cavity. The method may include filling the internal cavities of each frame member with a gas having a thermal conductivity less than atmospheric air. The method may include inserting in inset panel within the at least one opening.
The scope of the invention is defined by the claims, which are incorporated into this section by reference. A more complete understanding of embodiments of the invention will be afforded to those skilled in the art, as well as a realization of additional advantages thereof, by a consideration of the following detailed description of one or more embodiments. Reference will be made to the appended sheets of drawings that will first be described briefly.
Embodiments of the invention and their advantages are best understood by referring to the detailed description that follows. It should be appreciated that like reference numerals are used to identify like elements illustrated in one or more of the figures.
In accordance with various embodiments of the present disclosure, multi-panel architectural coverings, such as garage doors, retractable storefronts, windows, entry doors, or the like, benefit from a vacuum insulated frame design. The frame may define at least one opening within which a transparent or translucent window or other inset panel is secured. Each opening may be defined by a pair of rails secured to a pair of stiles at respective interfaces. The interfaces may be sealed in a manner allowing a vacuum to be created inside at least a portion of the frame. The architectural covering may include a plurality of panels, each panel including the frame design described herein. The multiple panels of the architectural covering may be secured together via one or more hinges to allow articulation of the covering as the covering is moved between positions, such as to enable movement of the covering along a track between a vertical (closed) position and a horizontal (open or overhead) position.
Depending on the application, the covering 100 may be a sectional or multi-panel door. For instance, the covering 100 may include a plurality of panels 102 that together at least partially enclose an opening 104 in a building or other structure 106. In the embodiments illustrated in
With continued reference to
In some embodiments, the frame 120 may define an insulation characteristic of the covering 100. For instance, the frame 120 may be sealed to allow for a vacuum to be created inside the frame 120, as described in more detail below. In other embodiments, the frame 120 may be filled with a low conductivity gas (e.g., argon or similar gas) to provide an insulation characteristic, as described below. In some embodiments, the frame 120 may be formed from materials with low thermal conductivity, such as stainless steel, aluminum, or other material, to decrease the thermal conductivity of the frame 120 itself. The low thermal conductivity of the frame 120 may also limit or prevent condensation formation on the frame 120, which may be beneficial in cold weather applications.
Each opening 122 of the frame 120 may be defined by a plurality of first frame members (e.g., a pair of rails 130) secured to a plurality of second frame members (e.g., a pair of stiles 132) at respective interfaces 134. The interfaces 134 may seal the rails 130 to the stiles 132 to allow for a vacuum to be created inside at least a portion of the frame 120. For example, the rails 130 may be welded to the stiles 132 to create an airtight interface between the rails 130 and stiles 132. Welding the stiles 132 to the rails 130 may provide a more ridged frame that will leak less air than a conventional bolted design. However, although welding is mentioned specifically, other suitable connection methods are contemplated that create an airtight interface and allow for a vacuum to be created inside at least a portion of the frame 120. For example, soldering, brazing, friction welding, laser welding, press-fitting, or using malleable or compressible materials are contemplated in addition to traditional and non-traditional welding methods that may or may not include welding filler materials to seal the joint. Depending on the application, the rails 130 and/or stiles 132 of one opening 122 may also define the rails 130 and/or stiles 132 of an adjacent opening 122. For instance, a single stile may define portions of horizontally adjacent openings 122 and/or vertically adjacent openings 122 of the frame 120. Similarly, a single rail may define portions of horizontally adjacent openings 122 and/or vertically adjacent openings 122 of the frame 120. In this manner, a single stile may run a vertical length of the frame 120 and/or a single rail may run a horizontal width of the frame 120 to define two or more adjacent openings 122.
In some embodiments, the plurality of panels 102 may be movably connected to move between positions, such as between a closed position and an open position, between a closed position and an overhead position, or otherwise between a first position and a second position. As shown in
Referring to
As shown in
Depending on the application, the panel 300 may include one or more openings defined by the frame members 304. For example, the first rail 310, second rail 312, first stile 320, and second stile 322 may define a first opening 330 of the panel 300. Similarly, the first rail 310, second rail 312, second stile 322, and third stile 324 may define a second opening 332 of the panel 300, and the first rail 310, second rail 312, third stile 324, and fourth stile 326 may define a third opening 334 of the panel 300. In such embodiments, the panel 300 may include a first inset panel 340 secured within the first opening 330 of the frame 302, a second inset panel 342 secured within the second opening 332 of the frame 302, and a third inset panel 344 secured within the third opening 334 of the frame 302. The first inset panel 340, second inset panel 342, and third inset panel 344 may be similar or may be configured differently. Each of the first inset panel 340, second inset panel 342, and the third inset panel 344 may be similar to the inset panel 124 of
The first rail 310, second rail 312, and stiles 314 may include many configurations. For example, the first rail 310, the second rail 312, and each of the first, second, third, and fourth stiles 320, 322, 324, 326 may be hollow members, such as boxed frame members, hollow extrusions, or the like. In such embodiments, each of the first rail 310, the second rail 312, the first stile 320, the second stile 322, the third stile 324, and the fourth stile 326 may include an internal cavity, which may run the length of the respective frame members 304. In some embodiments, the frame members 304 may be secured together such that the respective internal cavities of the frame members 304 are in communication with one another. For example, the first, second, third, and fourth stiles 320, 322, 324, 326 may be secured to the first rail 310 and the second rail 312 such that the entirety of the frame 302 is hollow, though other configurations are contemplated, such as the frame 302 being at least partially hollow (e.g., greater than 25% hollow, greater than 50% hollow, greater than 75% hollow, greater than 90% hollow, or the like). In this manner, one cavity may be created within the frame 302 once the frame members 304 are secured together. In some embodiments, multiple cavities may be created within the frame 302 once the frame members 304 are secured together.
The frame members 304 may be secured together in many configurations. For instance, the first stile 320 may include opposing first and second ends 360, 362, the second stile 322 may include opposing third and fourth ends 366, the third stile 324 may include opposing fifth and sixth ends 368, 370, and the fourth stile 326 may include opposing seventh and eighth ends 372, 374. In such embodiments, the first end 360 of the first stile 320, the third end 364 of the second stile 322, the fifth end 368 of the third stile 324, and the seventh end 372 of the fourth stile 326 may be secured to the first rail 310, such as via welding or other fastening methods. Similarly, the second end 362 of the first stile 320, the fourth end 366 of the second stile 322, the sixth end 370 of the third stile 324, and the eighth end 374 of the fourth stile 326 may be secured to the second rail 312, such as via welding or other fastening methods, which may be the same or different than the connections to the first rail 310. The attachment of the first end 360, the third end 364, the fifth end 368, and the seventh end 372 to the first rail 310 and the attachment of the second end 362, the fourth end 366, the sixth end 370, and the eighth end 374 to the second rail 312 may be airtight. In this manner, the respective interfaces between the first rail 310 and each of the first stile 320, second stile 322, third stile 324, and fourth stile 326 may seal the first rail 310 to the first stile 320, second stile 322, third stile 324, and fourth stile 326 to allow for a vacuum to be created inside at least the first rail 310, the first stile 320, the second stile 322, the third stile 324, and the fourth stile 326, or any combination thereof. Similarly, the respective interfaces between the second rail 312 and each of the first stile 320, second stile 322, third stile 324, and fourth stile 326 may seal the second rail 312 to the first stile 320, second stile 322, third stile 324, and fourth stile 326 to allow for a vacuum to be created inside at least the second rail 312, the first stile 320, the second stile 322, the third stile 324, and the fourth stile 326, or any combination thereof.
In some embodiments, the first rail 310 and the second rail 312 may be configured to accommodate the stiles 314 and/or facilitate the connection between the stiles 314 and the respective rail. For instance, as shown in
In some embodiments, the ends of the stiles 314 may be sized and/or shaped to facilitate attachment of the stiles 314 to the rails 310, 312. For instance, as shown in
As shown, a vacuum 502 may be connected to the panel 300, such as at a vacuum connection 504 defined in the first rail 310 adjacent to the fourth stile 326, although other configurations are contemplated, including multiple vacuum connections 504, a connection at another portion of the panel 300, or enclosing part or all of the panel 300 inside a vacuum chamber. Once the vacuum 502 is connected to the panel 300, the internal cavitiy(ies) of the frame 302 are evacuated of air, after which the vacuum connection(s) 504 is/are sealed to create a vacuum insulated panel.
Similar to the vacuum-insulated panel 300 of
As shown, the frame members 304 and/or frame 302 may be filled with low conductivity gas using an air purging system 552. Air purging system 552 may include a gas source 560 (e.g., an argon gas source, a low conductivity gas source, etc.) providing a low conductivity gas to fill panel 300 or frame members 304, either collectively or individually. For example, low conductivity gas may be provided by gas source 560 at a fill connection 562. In embodiments, panel 300 or frame members 304 may be purged of atmospheric air. For example, atmospheric air may be first removed from panel 300/frame members 304 and replaced with low conductivity gas. In some embodiments, panel 300/frame members 304 may include a release valve 564 allowing air to be released from panel 300/frame members 304 as low conductivity gas is filling panel 300/frame members 304. Depending on the application, the air released from panel 300/frame members 304 (e.g., via release valve 564) may be vented to atmosphere or collected by an air collection system 570.
In block 602, process 600 may include manufacturing a plurality of rails and a plurality of stiles for a panel frame. The rails may be similar to the first rail 310 and second rail 312 of
In block 604, process 600 includes assembling the plurality of rails to the plurality of stiles to define at least one opening of the panel frame. For instance, the first rail 310 and second rail 312 may be secured to the first stile 320, second stile 322, third stile 324, and fourth stile 326 of
In block 606, process 600 includes sealing the interfaces between the plurality of rails and the plurality of stiles. In some embodiments, the interfaces may be sealed via the assembly process itself. For instance, sealing the interfaces may including welding the plurality of rails to the plurality of stiles. Depending on the application, the interfaces may be welded by hand or via an automated assembly (e.g., robotic welding). In some embodiments, the interfaces may be sealed using one or more additional components between the rails and stiles. For instance, a sealing element (e.g., O-ring, elastomeric material, etc.) may be placed between the rails and stiles to seal the interfaces and allow the panel frame to be vacuum sealed.
In block 608, process 600 includes evacuating air from an interior space of the panel frame. For instance, once the interfaces between the plurality of rails and the plurality of stiles are sealed, the panel frame may be connected to a vacuum or placed in a vacuum chamber and at least a portion of the panel frame may be vacuum insulated. For example, one or more internal cavities of the panel frame may be evacuated of air by vacuum. Once the internal cavity(ies) of the panel frame are evacuated of air, the vacuum connections may be sealed.
In block 610, process 600 may include finishing the panel frame after the panel frame is vacuum insulated. For instance, the panel frame may be powder coated or anodized, although other finishing options are contemplated, including painting, clear coated, or the like. Finishing the panel frame after the panel frame is assembled and vacuum insulated reduces the likelihood of the finish being damaged during assembly. This reduces scrap and rework costs and improves customer satisfaction with the panel frame.
In block 612, process 600 includes inserting a panel member within each opening of the panel frame. The panel member may be similar to the member of
In block 614, process 600 may include assembling a plurality of panel frames together to define a multi-panel covering. For instance, a plurality of panel frames may be hingedly connected to define a retractable multi-panel garage door, storefront, or the like. In such embodiments, the multiple panel frames may be secured together via one or more hinges. The hinges may be similar to the hinges 140 of
In block 704, process 700 includes connecting first frame members (e.g., rails) to second frame members (e.g., stiles) to define at least one opening of a panel frame. For instance, the first rail 310 and second rail 312 may be secured to the first stile 320, second stile 322, third stile 324, and fourth stile 326 of
In block 706, process 700 includes sealing the interfaces between the first frame members and the second frame members. In embodiments, the interfaces may be sealed via the assembly process itself. For instance, sealing the interfaces may including welding the first frame members (e.g., rails) to the second frame members (e.g., stiles). In embodiments, the interfaces may be sealed using one or more additional components between the frame members, such as a sealing element (e.g., O-ring, elastomeric material, etc.) placed between the frame members to seal the interfaces.
In block 708, process 700 includes filling the internal cavities of each frame member with a gas having a thermal conductivity less than atmospheric air. In embodiments, block 708 may include purging atmospheric air from the internal cavity of each frame member, and sealing the internal cavity of each frame member independently. In embodiments, block 708 may include filling the panel frame with low conductivity gas once assembled.
In block 712, process 700 includes inserting an inset panel within the at least one opening of the panel frame. The inset panel may be similar to the member of
Embodiments described above illustrate but do not limit the invention. It should also be understood that numerous modifications and variations are possible in accordance with the principles of the invention. Accordingly, the scope of the invention is defined only by the following claims.
The present application is a continuation-in-part of U.S. application Ser. No. 16/786,766, filed Feb. 10, 2020, entitled “VACUUM INSULATED ARCHITECTURAL COVERING SYSTEMS AND METHODS,” the disclosure of which is hereby incorporated by reference for all purposes.
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Number | Date | Country | |
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20220195787 A1 | Jun 2022 | US |
Number | Date | Country | |
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Parent | 16786766 | Feb 2020 | US |
Child | 17654307 | US |