Windows must be sealed from the elements in order to protect both the integrity of the window and the finished interior of a building. Traditionally, liquid sealants are used, such a silicone, as the means for managing air and water within the window system. Often silicone is applied in a thin strip, or applied with skips in the bead creating pin sized holes allowing water to penetrate to the interior of the building. Cured liquid sealants can shear or separate during product handling and are not visible, creating the opportunity for water to enter the building.
Additionally, in nearly all the current window glazing systems, at the corner joints, a bead of liquid sealant is placed along the profiled edge of the corner. This sealant bead is then compressed between the two frame members. The sealant is compressed to such a thin amount that if the window is handled poorly during transportation or installation, the sealant can shear or separate from itself. This will allow water to enter the frame and eventually enter the building.
A window system that is superiorly effective at sealing out the elements is desirable.
The following presents a simplified summary of the invention in order to provide a basic understanding of some aspects of the invention. This summary is not an extensive overview of the invention. It is not intended to identify critical elements of the invention or to delineate the scope of the invention. Its sole purpose is to present some concepts of the invention in a simplified form as a prelude to the more detailed description that is presented elsewhere herein.
In one embodiment, a window system includes a window frame surrounding a window unit. The window frame includes a glazing leg and a glazing bead separated by a thermal break. The glazing leg is disposed on a first side of the window unit and the glazing bead is disposed on a second opposing side of the window unit. The glazing leg includes a J-shaped stem forming a J-channel configured to direct liquid away from the window unit.
In another embodiment, a window system includes an insulated glass unit having a first side and a second side; and a window frame surrounding the insulated glass unit. The window frame has a glazing leg with an outer wall and a J-shaped inner wall. The outer wall forms a first opening for receiving a first gasket, and the inner wall forming a second opening for receiving a second gasket. The first gasket is disposed between the glazing leg and the first side of the insulated glass unit and the second gasket is disposed inboard of the first gasket between the glazing leg and the first side of the insulated glass unit. A glazing bead disposed on an opposite side of the insulated glass unit from the glazing leg, and is separated from the glazing leg via a thermal spacer. The glazing bead forms a third opening for receiving a third gasket. The insulated glass unit is maintained in position between the first, second, and third gaskets, each respective gasket being compressed between the respective glazing leg or glazing bead and the insulated glass unit.
In still another embodiment, a window system has a window frame that surrounds a window unit. The window frame has a glazing leg with an outer wall and an inner wall. The inner wall forms a J-shaped stem, which forms a J-shaped channel between the inner wall and the outer wall. A first gasket engages with the outer wall, and is maintained in compression between the outer wall and the window unit. Likewise, a second gasket engages with the inner wall, and is maintained in compression between the inner wall and the window unit.
In a further embodiment, a window system includes a window frame spatially separated from a subframe. The subframe has a receptor leg spatially separated from a wedge bead by a thermal break. The receptor leg includes a channel for directing liquid away from the subframe; a first gasket disposed between the receptor leg and the window frame at a first location; and a second gasket disposed between the receptor leg and the window frame at a second location. Liquid passing between the first gasket and the window frame is directed into the channel via the second gasket.
In still yet another embodiment, a framing system includes a frame unit spatially separated from a subframe. The subframe has a receptor leg which is spatially separated from a wedge bead by a thermal break. The receptor leg has a channel for directing liquid away from the subframe. The channel has an outer wall and an inner wall. A first gasket is disposed between the outer wall and the frame unit, and a second gasket is disposed between the inner wall and the frame unit below the first gasket. A wedge gasket is disposed between the wedge bead and the frame unit. Liquid passing between the first gasket and the frame unit is directed into the channel via the second gasket.
In still another embodiment, a window system has a window frame surrounding a window unit and a subframe. The window frame includes a glazing leg, a glazing bead separated from the glazing leg by a thermal break, and an outer gasket disposed between the glazing leg and the window unit. The subframe includes a receptor leg spatially separated from a wedge bead by a thermal break. The receptor leg has a channel for directing liquid away from the subframe, a first gasket disposed between the receptor leg and the window frame, and a second gasket disposed between the receptor leg and the window frame inboard of the first gasket. Liquid passing between the first gasket and the window frame is directed into the channel via the second gasket.
The window system described herein is constructed without the use of traditional liquid sealants. In the place of traditional liquid sealants, gaskets may be disposed around the edge of the window using a compression technique to create air and water barriers or channels within the window system. Utilizing gaskets as taught herein may improve the reliability of the window system by eliminating the requirement that the manufacturer must properly apply a bead of silicone with adequate thickness across large expanses and intricate profiles in order to seal the window from the elements. A further benefit of using gaskets as described herein is the ability for a user to conduct a quick and accurate visual inspection of the window system for quality and completeness.
Embodiments of layered dual gasket window systems are described herein. The window system may utilize a primary and secondary gasket compressed against the glass to improve reliability of the window system. As will be further described below, the system works by using the primary gasket to reduce the amount of adverse environmental elements (e.g., moisture, light, etc.) that come in contact with the secondary gasket. Thus, the primary gasket is intended to eliminate water and any ultraviolet light exposure to the secondary gasket. The secondary gasket, in turn, provides reassurance against water penetration and creates an air tight seal meeting strict AAMA (American Architectural Manufacturers Association) requirements.
The secondary gasket is presented to the glass via a unique “J” shaped stem. The gap between the two gaskets provides an alley allowing any water that should penetrate the primary gasket to shed off the secondary gasket and fall harmlessly into the channel created by the “J” shaped stem. This channel funnels water to the exterior of the building through weeps located in the sill of the window. A corner profile gasket designed to encompass the corner profiles of the frame ensures an even and complete seal across the entire joint. The corner profile gaskets described herein are simple to apply and are extremely reliable.
The dual gaskets may be disposed at the glazing leg. More particularly, the glass to window frame seal may include two perimeter gaskets installed on the glazing leg of the window frame, including one primary, exterior gasket and one secondary, internal gasket, which may each be compressed to the glass.
Attention is now directed to the figures, which illustrate an embodiment of a window system 100.
When the pane 106 is placed into position with the frame 104, the primary gasket 108 is compressed between the frame 104 and the pane 106, effectively sealing off the inside of the frame 104. To further prevent entry of elements into the frame 104, the gasket 108 may include an angled upper edge 108a. The angle may be configured so that it is positioned away from the pane 6 so that water (or other liquid) may be directed away from the pane 106 and towards the outer edge of the frame 1. In embodiments, the angle may be between 0 and 90 degrees, and preferably between 30 and 60 degrees.
While the primary gasket 108 may prevent a large degree of unwanted element penetration, it may still be possible for water, UV-light, etc. to enter into the frame 104. Disposed inboard of the primary gasket 108, the secondary gasket 110 acts as a continuous seal to prevent any water from entering through the window 102, and may further reduce air infiltration such that the window may meet the strictest AAMA standards. Thus, the secondary gasket 110 is a second means to prevent entry of the elements into the window 102 and ultimately the structure in which the window system 100 is installed. As noted above, as a result of the placement of the primary gasket 108 outboard of the secondary gasket 110, the secondary gasket 110 is not exposed to any elements which could cause it to degrade. Thus, the dual gasket system may give the window system 100 superior durability compared other window, and particularly, glazing systems.
The secondary gasket 110 may be configured to engage with the panes 106 via a unique “J” shaped stem 112 formed in the exterior die/glazing leg 120 of the frame 104. A tongue 111 on the secondary gasket 110 may engage with an opening 113 formed in the “J” shaped stem 112. A top edge 114 of the stem 112 abuts the secondary gasket 110 to provide an additional seal around the frame 104.
The secondary gasket 110 may be a continuous seal installed in one length after the frame 104 is constructed. The secondary gasket 110 may be cut so as to meet beginning and end points at the head (A) of the window frame 104. When compressed, these two ends form a tight seal around the window pane 106. Compression of the panes 106 is achieved by means of an interior compression gasket 130 positioned at a glazing bead 135 of the frame 104. Upon installation, the glazing bead 135, along with the interior compression gasket 130, pushes the panes 106 against the primary 108 and secondary 110 gaskets at the glazing leg 120 of the window frame 104.
Moving on, with reference to
The J-shaped stem 112 (and corresponding channel 115) allows water W to exit from within the frame 104 by directing the water away from the panes 106. Additionally, the unique J-shaped channel 115 prevents water from pooling inside the frame 104, which may then eventually leak into the interior of the window 102 or may cause corrosion of the window frame 104 materials. Those of skill in the art shall understand that while reference is made to water entering into the frame 104, other fluids or solutions may additionally, or alternately, penetrate the primary gasket 108. Such solutions may be harmful to the frame 104 materials, causing corrosion or other unwanted or undesirable reactions.
The window glazing system 100 may further include corner profile gaskets 160 to provide water proofing capabilities to the corners of the window 102, illustrated in
When the two corners 155a and 155b are brought together, the corner gasket(s) 160 is compressed therebetween. The gasket allows the window system 100 to be handled, and for thermal flexing of the joint, without shearing or breaking the seal. The corner gasket 160 may further allow the window corner to flex during transportation and installation and subsequently conform back to match the mitered profile to maintain a water tight seal.
A thermal break 150 extends between the interior die 145 and the glazing leg 120. The thermal break 150 may provide additional stability to the frame 140, and may further prevent heat transfer across the frame 140.
In embodiments, the frame 104 is made from traditional materials, such as aluminum and is configured to receive the gaskets 108 and 110 as described herein. In other embodiments, alternative materials may be utilized, including but not limited to polyvinyl chloride, fiberglass, wood, etc. Preferably, the material is inherently able to resist the harmful effects of ultraviolet light, or is coated with a material that keeps the UV light from breaking down the material.
The gaskets 108 and 110 may be manufactured from a plastic, polymer, or any other type of appropriate material. Those of skill in the art shall recognize that it is preferable that the material for the gaskets 108 and 110 (and gasket 130) be configured to resist the harmful effects of UV light and corrosive substances.
Another embodiment of a window system 200 is illustrated in
Here, the frame 204 includes a glazing bead 235 that is specifically configured to provide additional strength to the system 200. Teeth 231 formed as part of the glazing bead 235 interact with respective teeth 246 of the interior die 245. The teeth 231 are identical, and hook into contact with the teeth 246 of the interior die 245 from the same direction. This is in contrast to the glazing bead 135, which has teeth 131 that engage with respective teeth 146 in the interior die 145 from opposite sides (
As shown in
Those of ordinary skill in the art shall recognize the many benefits presented as a result of the window glazing system described herein. For example, both gaskets 108 (and corresponding gasket 208) and 110 are easy to apply in a manufacturing setting. Further, inspections on the window are greatly simplified as the gaskets are either present or not, allowing for quick visual inspections. The gaskets additionally eliminate the need for sealant applicators to try and avoid pin sized holes in the sealant which are nearly impossible to detect and can cause a great amount of damage.
Still another embodiment of a framing system 300 is illustrated in
The subframe 365 includes a receptor leg 367 separated from a wedge bead 373 by a thermal break 375. The receptor leg 367 includes an outer wall 368 and an inner wall 369 defining a channel 370 therebetween. A first gasket 371a is disposed between the outer wall 368 and the window frame 304, and a second gasket 372a is disposed between the inner wall 369 and the window frame 304. The second gasket 372a is positioned inboard (e.g., below) the first gasket 371a. While the gaskets 371a are designed to prevent liquid from entering the subframe 365, any liquid that passes between the first gasket 371a and the window frame 304 is directed into the channel 370 via the second gasket 372a. A weep 366 may be formed into the outer wall 368. The weep 366 allows the liquid to pass from the channel 370 to the outside of the subframe 365. Further, a wedge gasket 374a may be disposed between the wedge bead 373 and the window frame 304.
As shown in
A portion of the window frame 304a rests atop the platform 382. In use, the window frame 304 is placed atop the sub sill such that the portion of the window frame 304a presses down on the platform 382. The force from the window frame 304 captured by the platform 382, causes the first gasket 371a and the second gasket 372a to seal against the window frame 304.
As shown in
The horizontal member 388 has a first end 388a and a second hooked end 388b. The first send 388a may have a cavity formed therein for receiving the fastener 389. Optionally, the cavity may be threaded. The hooked end 388b is configured to engage with a respective catch 390 in the subhead 385. The fastener 389 is inserted through the hole in the vertical member 387 and into the cavity in the first end 388a of the horizontal member 388 to form the retaining clip 386. In use, the vertical member 387 abuts a portion 304b of the window frame 304, while the hooked end 388b engages with the respective catch 390 in the subhead 385. When the fastener 390 is tightened in the cavity of the horizontal member 388, the window frame 304 is biased toward the subhead 384, which seals the respective gaskets 371b, 372b, and 374b against the window frame 304.
Many different arrangements of the described invention are possible without departing from the spirit and scope of the present invention. Embodiments of the present invention are described herein with the intent to be illustrative rather than restrictive. Alternative embodiments will become apparent to those skilled in the art that do not depart from its scope. A skilled artisan may develop alternative means of implementing the disclosed improvements without departing from the scope of the present invention.
Further, it will be understood that certain features and subcombinations are of utility and may be employed without reference to other features and subcombinations and are contemplated within the scope of the claims. Not all steps listed in the various figures and description need to be carried out in the specific order described. The description should not be restricted to the specific described embodiments.
This application is a continuation-in-part of U.S. patent application Ser. No. 15/726,319, which is pending and was filed on Oct. 5, 2017, and which claims priority to U.S. Provisional Patent Application No. 62/405,076, filed Oct. 6, 2016, the entireties of which are incorporated by reference herein.
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Number | Date | Country | |
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20200199932 A1 | Jun 2020 | US |
Number | Date | Country | |
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62405076 | Oct 2016 | US |
Number | Date | Country | |
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Parent | 15726319 | Oct 2017 | US |
Child | 16357432 | US |