This invention relates to the fabrication of insulating glass structures on a sash frame having integral spacing and mounting components, and more particularly to the direct mounting of glazing panes to, e.g., a window or door frame using vacuum and/or a roll press to affix the glazing panes to a respective adhesive sealant or the like.
When a window, glazed door, skylight or the like is manufactured, a glazing pane assembly is typically mounted to a sash frame using an adhesive sealant in a process known as backbedding. A more recent technology, disclosed, for example, in commonly assigned U.S. Pat. No. 6,286,288 and 6,536,182, provides an integrated sash in which glazing panes are mounted directly to the sash via sealant. In the process of placing a glazing pane (e.g., glass) onto or into the sealant along the sash glazing surface, the glazing pane may be inadvertently pressed beyond the sealant's recommended sealant thickness/height dimension. A recommended sealant thickness may be required to provide an appropriate amount of such sealant to ensure a sealed airspace that will perform to the “life expectancy” of the sash. Sealant viscosity may vary, and therefore the sealant thickness dimension will vary according to the sealant type applied.
It would be advantageous to provide methods for pressing (or pulling) one or more glazing panes against an adhesive sealant bead (or similar material) on an integrated sash structure without producing excessive spreading (also referred to as excessive “whet-out”) of the material. It would be further advantageous to provide structure in the integrated sash to control, maintain, and/or direct a consistent and appropriate seal thickness between a glazing pane and a structural mounting surface on the sash. It would be still further advantageous to provide structures and fabrication methods for assuring a suitable bond line between the glazing pane and a glazing surface of a window sash. The present invention provides structures and methods having the aforementioned and other advantages.
In accordance with one aspect of the invention, a method is provided for fabricating an integrated sash insulating glass unit. A sash frame is provided having a first mounting surface for a first glazing pane and a second mounting surface for mounting a second glazing pane substantially parallel to the first glazing pane. The first and second mounting surfaces are spaced apart to provide an insulating space between the glazing panes. An evacuation opening (e.g., a hole and/or a breather tube) is provided in communication with the insulating space. The first glazing pane is adhesively mounted to the first mounting surface and the second glazing pane is adhesively mounted to the second mounting surface. Air is allowed to exhaust through the evacuation opening as the insulating space is formed between the glazing panes. A vacuum is drawn from the evacuation opening to draw the first and second glazing panes closer together after the panes have been mounted on their respective mounting surfaces.
In one disclosed embodiment, the glazing panes are mounted to their respective mounting surfaces using an adhesive sealant. The vacuum is drawn until edges of the glazing panes are at least partially embedded into the sealant. The evacuation opening is plugged after the vacuum has been drawn.
The insulating space may be filled with an insulating gas via said evacuation opening, after said vacuum has been drawn. The evacuation opening is then plugged after said gas filling step.
Stops (“sealant directors”) can be provided on the mounting surfaces to limit whet-out of the sealant. In such an embodiment, the vacuum may be drawn until the glazing panes contact the stops. The evacuation opening is then plugged after said vacuum has been drawn. As described above, the insulating space can be filled with an insulating gas via the evacuation opening, after said vacuum has been drawn. In this case, the evacuation opening is plugged after the gas filling step.
The glazing panes can, for example, be applied to their respective mounting surfaces using at least one roller. In one embodiment, multiple rollers are provided on a roll press. The roller(s) or roll press can also be used to attach a glazing bead for at least one of the glazing panes. In an illustrated embodiment, the glazing bead is attached simultaneously with the mounting of the respective glazing pane to its respective mounting surface. Pressure from the roller(s) can be applied to the at least one glazing pane via the respective glazing bead.
In accordance with another aspect of the invention, a method is provided for fabricating an integrated sash insulating glass unit where the use of a vacuum, as described above, is optional. A sash frame is provided which has a first mounting surface for a first glazing pane and a second mounting surface for mounting a second glazing pane substantially parallel to said first glazing pane. The first and second mounting surfaces are spaced apart to provide an insulating space between the first and second glazing panes. The first glazing pane is mounted to the first mounting surface via an adhesive sealant. The second glazing pane is mounted to the second mounting surface via an adhesive sealant. Surfaces of the first and second glazing panes adjacent to their respective mounting surfaces are pressed into the respective adhesive sealant using at least one roller (e.g., a single roller or a roll press with multiple rollers).
Stops may be provided on the mounting surfaces to limit whet-out of the sealant. Surfaces of the glazing panes can be pressed using the roller(s) to a point at which the glazing panes contact the stops. It is possible for the roller(s) to be used to attach a glazing bead for at least one of the glazing panes. The glazing bead can be attached simultaneously with the mounting of the respective glazing pane to its respective mounting surface. Pressure from the roller(s) may be applied to the glazing panes via the respective glazing bead.
A roll press can be designed to simultaneously press the surfaces of the first and second glazing panes toward their respective mounting surfaces. For example, it is possible for the roll press to comprise successive roller sets that are spaced progressively closer together as said sash frame and glazing panes are transported therebetween.
An evacuation opening, such as a hole or a breather tube, can be provided in communication with the insulating space to allow the escape of air as the glazing panes are mounted to their respective mounting surfaces and pressed by the roller(s). After the glazing panes have been mounted and pressed, the evacuation opening may be plugged. The insulating space can be filled with an insulating gas via the evacuation opening, after the glazing panes have been mounted and pressed. Where gas filling is provided via the evacuation opening, the evacuation opening is plugged after the gas filling step.
For a further understanding of the present invention, reference will be made to the following detailed description of the invention which is to be read in association with the accompanying drawings, wherein:
a illustrates the use of a first example breather tube coupled to the airspace between the glazing panes; and
b illustrates the use of a second example breather tube coupled to the airspace between the glazing panes
Turning now to the drawings,
“Sealant Directors” or “Whet-out and Compression Limiters” 10 are illustrated in the context of providing a superior seal line and an improved process for establishing appropriate “whet-out” of sealant affixed to the glazing surfaces of the integrated sash. In fabricating windows, doors, skylights and other glazed products using an integrated sash (i.e., where the sash frame has a glazing pane spacing and mounting structure integral therewith), it is desirable to control, maintain and/or direct a consistent and appropriate seal thickness between the glazing pane and the structural mounting surface on the sash. Such control would include the ability to restrict the area to which a sealant/adhesive can propagate as the glazing panes are mounted.
In the process of placing a glazing pane of glass, plastic or other material onto or into the sealant along the sash glazing surface, the glazing panel may inadvertently be pressed beyond the sealant's recommended sealant thickness/height dimension. A recommended sealant thickness may be required to provide an appropriate amount of such sealant to ensure a sealed airspace that will perform to the “life expectancy” of the sash. Sealant viscosities vary, and therefore the sealant thickness dimension will vary according to the sealant type applied. By providing one or more sealant directors, the oozing of sealant beyond a desired area be limited. In addition, the flattening out of the sealant can be limited by using the sealant director as a stop to limit the travel of the glazing pane toward the integral spacing and mounting structure.
Sealant may be applied in a number of ways. It may be applied in a “strip” or “bead” or any other shape that allows for efficient flow from a sealant dispensing unit. The sealant strip or bead may be of any shape such as triangular, oval, round, square, rectangular, or any combination of these or other shapes. While the glazing pane may be manually pressed against the sealant until a final dimension is reached, such an approach is imprecise and relies on the skill of a window assembler.
In one embodiment, the present disclosure contemplates the use of a vacuum to “pull” or “draw” the glazing panels toward, into, or against the sealant bead/strip in a manner that properly adheres the glazing pane to the glazing surface of the sash frame via the sealant. Such an embodiment is illustrated in
As can be seen from
In order to fabricate an insulating glass window, door or the like, sealant 20 is applied, preferably in the form of beads or strips, to respective glazing surfaces of the spacing and mounting structure 16. In the embodiment illustrated in
As the glazing panes 14 are placed against the sealant 20, air can exhaust from the insulating space between the panes via the evacuation opening 18, in the direction indicated by arrow 22. After the air has been naturally exhausted in this manner, and both glazing panes are in contact with their respective sealant beads or strips, a vacuum can be drawn from the evacuation opening 18. The vacuum would be drawn in the direction indicated by arrow 22, using a suitable probe or nozzle that communicates via opening 18 with the insulating space 30 between the glazing panes. The probe or nozzle (not shown) will seal around or within the opening 18 so that a suitable vacuum can be achieved.
When the vacuum is drawn, the glazing panes will be drawn together in such that the sealant 20 compresses to a desired extent. This can be seen by comparing the bottom two illustrations in
At the completion of the vacuum drawing stage, the insulating space 30 between the glazing panes can be permanently sealed by inserting a plug 24 into the evacuation opening 18, in the direction of arrow 26. The plug can comprise, for example, rubber, silicone, or any other resilient material that will plug the opening. Alternatively, a screw, bolt or other hardware component, or a dab of adhesive, putty, sealant, molten plastic, etc. could be used as a plug. The intent of plugging the opening is to provide an hermetic seal for the insulating space 30.
Prior to plugging the opening 18, the opening can be used to fill the insulating space with a gas such as Argon, Krypton, or other element or combination thereof that may be used for insulating purposes. Such gasses are commonly used to increase the insulating value of the window or door, etc.
Any of the aforementioned processes or steps may be in tandem, in combination with any other, or function as separate work stations either in-line or as a fully automated process, semi-automated process, or as a manual means of fabrication. Instead of, or in addition to using a vacuum to draw the glazing panes against the sealant, a roller press (also referred to as a “roll press”) may be used to apply pressure along the entire edge perimeter of the glazing pane from one side or simultaneously on multiple (e.g., two) sides. A roller mechanism may work in tandem with the aforementioned process steps and follow along the perimeter of the glazing panel(s) so as to compress the glazing pane(s) against the seal line as the “roller” follows the perimeter of the glazing pane(s).
Examples of roll press embodiments are shown in
Such a roll press embodiment is useful to “size” the glazing panel to its “finished” condition. Examples of possible implementations include those where the “press” is formed by a series of rollers, wheels or rotating cylinders that may be tapered or otherwise designed to gradually reduce the distance between the opposing compression/pressing mechanism. This process allows for a more gradual “sizing” to occur so as to prevent an immediate pressure on the glazing structure such that the glazing pane may stress to the point of fracture, damage, or irreparable fatigue.
This roll press may be implemented in a vertical, horizontal, or a combination of vertical and horizontal orientations. The process may also be accomplished at some angle in relation to vertical and horizontal. Moreover, the process may be implemented in conjunction with or in line with other processes such as automated sealant placement, automated glazing panel placement, curing and staging areas such as UV curing stations, gas filling stations or processes, vacuum (air evacuation) stations or processes, or any other process or function that may be automated, semi-automated, or manual such that a complete or partial integrated sash is produced.
The compression process shown in
Instead of an evacuation opening as shown in
Each of the embodiments of
After assembling a window unit as described above, it may be desired to cure the seal line. Ultraviolet, microwave, ultrasonic, heat, compression, or any combination of such techniques may be used when and where required along the fabrication line, either by automated, semi-automated, or manual means.
Any or all of the aforementioned functions may be provided in a process that fabricates the finished products via one glazing pane or side per machine cycle or process cycle, or two simultaneous glazing pane applications, or any number more than one per cycle. Sealant/adhesive may also be placed on both the glazing panel perimeter surface and on the sash profile glazing surface. This may facilitate a rapid bonding process wherein similar materials “mate” upon contact, providing an improved seal line. Sealant may be placed on the glazing panel only and then placed onto or against the glazing surface of the substrate.
The sealant bead may be applied at a greater thickness/height dimension than the protruding sealant directors (compression limiters). The glazing pane(s) may be applied either “robotically”, “mechanically”, and/or “manually.” The glazing pane(s) may be pressed upon and/or into the sealant “bead” or “strip” so as to “whet-out” or compress the sealant to the same dimension (or greater) that the sealant director protrudes from the glazing wall or surface of the sash.
The sealant directors may be of any suitable dimension, width, thickness, and/or dimension or location on the glazing surface. The glazing surface may be vertical, horizontal, or a combination of vertical and horizontal surfaces. There may be one, two, or more limiters per glazing surface of the sash. The sealant directors may be of the same material as the sash, of a different co-extruded material, of an applied material or substance, or a tape, caulked bead or strip, or any material or product that will function as a “director” or “compression limiter.” The sealant directors may be of any suitable hardness, stiffness, flexibility, rigidness, or softness.
It should now be appreciated that the present invention provides methods for fabricating glazed insulating units directly on a sash frame. Integrated insulating sash units of the type described have many benefits over traditional insulating glass panels. These benefits include increased performance of the sealant/adhesive bead due to a “fixed” location on the sash frame, control of the flow and/or whet-out of the sealant, and the ability to dispense sealant in an efficient manner to reduce the quantity (and thereby, cost) of the sealant used. The disclosed methods also provide an aesthetic improvement that “contains” the seal bead/strip to a given uniform location and dimension with straight and/or uniform edge lines. This could potentially eliminate the need for conventional exterior glazing beads. Bead limiters may also provide a means of improving the bond line and/or seal line for the adhesive/sealant characteristics of the material upon the sash surface, as well as the cohesive properties of the adhesive/sealant.
While the present invention has been shown and described with reference to the preferred mode as illustrated in the drawings, it will be understood by those skilled in the art that various changes in detail may be effected therein without departing from the spirit and scope of the invention as defined by the following claims.
This application is a divisional of U.S. application Ser. No. 10/681,495, filed Oct. 7, 2003, now abandoned, which claims the benefit of commonly assigned provisional patent application No. 60/420,392 filed on Oct. 21, 2002, the entire disclosure of which is incorporated herein by reference.
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Number | Date | Country | |
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Number | Date | Country | |
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Number | Date | Country | |
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Parent | 10681495 | Oct 2003 | US |
Child | 11070954 | US |