The present invention relates to a self-sealing window with a flexible gasket that extends around the entire perimeter of closure assemblies and a method of installing such closure assemblies in a rough opening.
One of the more time consuming jobs in the construction and restoration fields is the setting (i.e. installing, leveling, and plumbing) of closures assemblies such as doors, windows, side lights, transoms, gable air vents, portals, skylights, etc., in rough structural openings. The rough opening is typically slightly larger than the closure assembly to facilitate installation.
Installers typically use wooden shims placed and sometime driven in the gap between the closure frame or jamb and the wall studs that form the rough opening. A level is used during this process to confirm the positioning of the jamb in the opening and re-adjustment of the shims is made as necessary to complete the installing, leveling and plumbing process. Levels are used on closures that have a flat vertical or horizontal side or sides. A plumb line is used on closures where a level is ineffective, such as a circular or oval closure.
Although the wooden shim is still the dominant means today for installing closures, it does have some limitations including: (1) the method of installing with wood shims is very time consuming; (2) wood shims are difficult to use on rounded surfaces (i.e. circular, oval-portals, stained glass ovals, etc.); (3) wood shims often interfere with complete sealing of the window to the rough opening; and (4) wood shims can slip out of place during installation of the closure assembly.
A gap is typically maintained between the closure assembly and the rough opening to accommodate expansion and contraction of building materials throughout temperature changes, as well as overall shifting and settling of the structure. Water, such as airborne moisture and liquid water in the form of rainwater, ice, snow can penetrate into the building wall interior from in and around building closure assemblies.
Attempts have been made to prevent entry of water into the building wall interior by sealing or caulking entry points in and around closure assemblies as the primary defense against water intrusion, or by installing flashing around the closure assemblies to divert the water. These attempts have not been completely successful. Sealants are not only difficult and costly to property install, but tend to separate from the closure assembly or wall due to climatic conditions, building movement, the surface type, or chemical reactions. Flashing is also difficult to install and may tend to hold the water against the closure assembly, accelerating the decay.
The efficiency of such weatherproofing relies largely on the careful installation of both the closure assembly and the weatherproofing materials. However, no matter how carefully installed, moisture may enter into gaps between the closure assembly and the rough opening. Moisture penetration may be due to shifting or expansion/contraction of materials post-installation.
Such moisture typically collects below the closure assembly, where it can cause rot and other undesirable damage to both the closure assembly and the structure below the closure assembly. In some situations attempts to prevent water penetration around closure assemblies may actually trap the water within the structure, exacerbating the problem.
Various drain holes systems for closure assemblies have been used to divert water from the structure, such as disclosed in U.S. Pat. Nos. 3,851,420 (Tibbetts); 4,691,487 (Kessler); and 5,890,331 (Hope).
Specialized flashing structures have been developed for installation in the gap between the rough opening and the closure assembly. Examples of such specialized flashing structures are shown in U.S. Pat. Nos. 4,555,882 (Moffitt et al.); 5,542,217 (Larivee); and 6,098,343 (Brown et al.). U.S. Pat. Nos. 5,822,933 (Burroughs et al.) and 5,921,038 (Burroughs et al.) disclose a water drainage system with an angled pan and a plurality of ribs that is located underneath a closure assembly.
These specialized flashing structures, however, do not effectively remove water from the interior of the structure. Additionally, the installation of moisture guards often requires changes in the way the closure assembly is installed into the rough opening and how the closure assembly is finished on the room side so as to accommodate the vertical height of the angled pan. Furthermore, the gap between the closure assembly and the rough opening must be sufficient to accommodate the raised end of the angled pan.
The Installation Instructions for New Construction Vinyl Window with Integral Nailing Fin published by Jeld-Wen, Inc. discloses installing a 6″ tall section of screen to the exterior of the structure below the closure assembly. The screen extends about the width of the closure assembly and is located on top of flashing tape and building wrap. Another layer of flashing tape is applied to the top of the screen. The screen, however, forms one contiguous channel that is too large to permit effective drainage of water.
Various embodiments of the present invention relate to a self-sealing window with a flexible sealing member that extends around the entire perimeter of closure assemblies and a method of installing such closure assemblies in a rough opening. The installation methods reduce the time and cost of installing closure assemblies, while increasing the performance of the closure assembly.
The method of installing a closure assembly in a rough opening of a structure includes the step of attaching a sealing member continuously around an entire perimeter of the closure assembly to form a water impermeable seal between the sealing member and the closure assembly. The closure assembly is accurately positioned in the rough opening and secured in place. The sealing member is engaged with an exterior surface of the structure proximate the rough opening. A foam material is delivered into at least a portion of a space between perimeter edge surfaces of the closure assembly and inner surfaces of the rough opening.
The present application is also directed to a closure assembly for installation in a rough opening of a structure. The closure assembly includes a window frame and at least one glazing panel located within the window frame. At least one sealing member is attached to, and extends continuously around, a perimeter of the window frame. The sealing member comprises a water impermeable seal around the entire perimeter of the closure assembly.
While multiple embodiments are disclosed, still other embodiments of the present invention will become apparent to those skilled in the art from the following detailed description, which shows and describes illustrative embodiments of the invention. Accordingly, the drawings and detailed description are to be regarded as illustrative in nature and not restrictive.
While the invention is amenable to various modifications and alternative forms, specific embodiments have been shown by way of example in the drawings and are described in detail below. The intention, however, is not to limit the invention to the particular embodiments described. On the contrary, the invention is intended to cover all modifications, equivalents, and alternatives falling within the scope of the invention as defined by the appended claims.
The present invention is directed to a self-sealing, closure assembly and system for installing a closure assembly in a rough opening. As used herein, “closure” and “closure assembly” refer to double-hung, casement, awning and fixed windows, skylights, sliding and hinged doors, and the like. As used herein, “rough opening” refers to an opening in a wall or structure that has a perimeter sized and shaped to receive a closure assembly, and a plurality of inner surfaces. As used herein, “inner surfaces” refers to the sill, header and jamb surfaces forming the rough opening in the wall or structure. The rough opening extends from an interior side of the structure to an exterior side. The exterior side of the structure is typically exposed to rain, wind, snow, ice and the like, while the interior side is typically protected from the elements.
In one embodiment, sealing members 300a-300d are attached substantially around a perimeter of closure assembly 52 at a remote location. As used herein, “remote location” refers a location remote from the rough opening 20, such as a manufacturing facility, warehouse, or construction materials preparation site. The sealing members 300a-300d is preferably factory installed prior to the closure assembly 52 being shipped to the installation site.
In one embodiment, distal edges 301a-301d of the sealing members 300a-300d are positioned toward an exterior side of the closure assembly 52 (corresponding to the exterior side 65 of the structure) for installation. In the illustrated embodiment, the sealing members 300a-d are butyl flashing tape. In an alternate embodiment, the flashing tape includes a foil backing. However, the sealing members 300a-300d may have other configurations as are known in the art, some of which are discussed in further detail later on. In addition, sealing members 300a-300d may be replaced with a single continuous sealing member.
The sealing member 802 can be constructed as a continuous segment or ring, preferably with a generally planar structure. In embodiments where the sealing member 802 is a continuous segment, seam 812 where the ends of the segment meet preferably overlap and are sealed with an adhesive, thermal or solvent welding, or a variety of other water impermeable sealing methods. In one embodiment of
The sealing member 802 provides a continuous seal around the corners 806, where leakage often occurs. Any seam in the sealing member 802 is preferably formed at a location other than the corners 806. As used herein, “continuous corner seal” refers to a sealing member that extends uninterrupted around, and is continuously attached to, a corner of a closure assembly. In the preferred embodiment, the sealing member comprises continuous corner seals with all corners of the closure assembly.
The sealing member 802 is flexible and preferably can be stretched at the corners 806 to create a seal completely around the perimeter 804. The sealing member 802 is preferably elastically or plastically deformable, without compromising the water impermeability. The sealing member 802 can be a single layer or multi-layer structure, with or without an adhesive layer.
The sealing member 802 may experience bulging or deformation at the corners 806. In some embodiments, relief cuts are made in the sealing member 802 to relieve stress at the corners 806. The relief cuts can be surface cuts or partial severing of the sealing member 802 at the distal edges near the corners 806. The relief cuts preferably do not sever or cut completely through the sealing member 802. In an alternate embodiment, the sealing member 802 is heated to relieve stress at the corners 806. Pressure can optionally be applied to the corners 806, either alone or in combination with heat. Plastic deformation of the sealing member 802 at the corners 806 preferably does not compromise water impermeability.
In one embodiment, the sealing member 802 is captured between the frame 766 and the metal cladding 764 around the entire perimeter 804 of the closure assembly 800. (See e.g.,
The position of the securing members 605 on the closure assembly 800 are preferably located to control the depth of penetration of the closure assembly 800 in the rough opening 20. For example, the depth of penetration needs to take into consideration the thickness of wall board and the shape of finish trim. In one embodiment, the location of the securing members 605 is determined at a remote location, such as the factory. In another embodiment, the installer can adjust the location of the securing members 605 at the installation site. In the illustrated embodiment, the securing members 605 include holes 607 sized and positioned to receive fasteners adapted to engage with the rough opening 20.
Located generally between the exterior sealing plane 334 and the interior sealing plane 336 of the closure assembly 330 is a perimeter edge surface 338. The perimeter edge surface 338 includes one or more surfaces on the perimeter of the closure assembly 330 that extend between the exterior and interior sealing planes 334, 336. As used herein, “perimeter edge surface” refers to one or more external surfaces located between interior and exterior sealing planes of a closure assembly.
In one embodiment, the perimeter edge surface 338 includes one or more longitudinal recesses 340. In one embodiment, one or more shims 350 are releasably attached or coupled to the longitudinal recess 340, preferably along each side of the closure assembly 330. The shims 350 may be attached to the closure assembly 330 at a remote location or at the installation site.
In one embodiment, the sealing member 762 is positioned against the frame 766 during shipping. Prior to installation, a distal edge of the sealing member 762 is positioned towards the exterior side 65 of the closure assembly 760. In the illustrated embodiment, the sealing member 762 is folded forward along arc 768 until it is adjacent to the aluminum cladding 764. Once the closure assembly 760 is positioned in the rough opening 20, the sealing member 762 is folded along arc 770 and attached to the structure 22 adjacent the rough opening 20. Positioning the sealing member 762 in the position 768 is particularly useful for installing the closure assembly 760 from the interior.
In the embodiment illustrated in
In the illustrated embodiment, portion 814 of the sealing member 802 is captured between the cladding 764 and the frame 766 around the entire perimeter of the closure assembly 800, including at the corners (see
The rigid portion 814 facilitates handling of the sealing member 802 during assembly of the closure assembly 800. The rigidity of the portion 814 supports the flexible portion 816 and retains the sealing member 802 on the frame 766 while the cladding 764 is attached. In one embodiment, an adhesive or fastener is used to attach the portion 814 to the frame 766 before the cladding 764 is attached.
The sealing member 802 can be constructed from a variety of flexible materials, such a for example rubber, polymeric materials, metal foil, and composites thereof. In the illustrated embodiment, the sealing member 802 includes an adhesive layer 808 covered by a release liner 810 (see also
The inner portion 822 is preferably formed with a contour that corresponds to the shape of the wood frame at the location of attachment. The corners 826 can be precisely formed, without the deformation that occurs when bending a linear section around a corner. This embodiment of the sealing member 820 can also be manufactured in high volumes at low cost. The difficulty is that closure assemblies are manufactured in a large number of sizes and shapes, requiring considerable inventory of the sealing member 820.
The closure assembly 840 is preferably formed to the shape and size of the closure assembly in a separate processing step, such as for example using heat and pressure to thermally deform the corners. Adhesive layer 846 and release liner 848 can optionally be added to the outer portion 844 either before or after the processing step.
The closure assembly 330 is preferably packaged and shipped with the adjustable shims 350 pre-attached. Alternatively, some or all of the adjustable shims 350 can be snap-fit into the longitudinal recess 340 at the installation site. The adjustable shims 350 can preferably be attached and detached from the recess 340 without the use of tools. In one embodiment, the adjustable shims 350 are adapted to form a snap-fit relationship with the longitudinal recess 340. In another embodiment, one or more fixed or block shims 351 may be used in combination with the adjustable shim 350 to form a more complex shim arrangement. The block shims 351 establish a minimum gap between the closure assembly 330 and the sill of the rough opening. The adjustable shim 350 permits the closure assembly 330 to be leveled relative to the block shim 351.
The constant pressure shim 702 includes spring portion 706 that applies force 708 against an interior surface 710 of the frame member 24 defining the rough opening 20. Portions 716, 724 apply forces 719, 720 against the closure assembly 52. In the illustrated embodiment, portion 716 is attached to the closure assembly 52. Force 708 and the forces 719, 720 generated by the spring portion 706 are balanced to maintain a gap 724 between the closure assembly 52 and the interior surface 710. When multiple constant pressure shims 702 are positioned around the perimeter of the closure assembly 52, the forces 708, 719, 720 may be used to accurately position the closure assembly 52 in the rough opening 20.
In the illustrated embodiment, the sealing member 704 includes an adhesive layer 726 covered by a release liner 728. During installation of the closure assembly 52, the release liner 728 is removed and the sealing member 704 is folded as shown by arrow 731 so that the adhesive layer 726 bonds to a surface 730 on the exterior side 65 of the structure.
The alternate shim system 700 optionally includes a stop 732 that limits how far the closure assembly 52 is inserted in the rough opening 20. The stop 732 is preferably integrally formed from the same material as the constant pressure shim 702 and the sealing member 704. In the illustrated embodiment, the stop 732 is located near the interior side 64 of the closure 52. Consequently, the closure assembly 52 is preferably inserted from the interior side 64 of the rough opening 20. In one embodiment, the stop 732 is used to secure the closure assembly 52 in the rough opening 20, such as by securing the constant pressure shim 702 to the frame member 24 with fastener 736.
The closure assembly 52 optionally includes a groove 750 having a surface 752 that engages with a distal end 754 of the spring portion 744. Once engaged, the distal end 754 prevents the closure assembly 52 from being displaced in direction 756. The spring portion 744 also serves to position the closure assembly 52 in the rough opening 20. In one embodiment, the constant pressure shim 740 is used only to position and secure the closure assembly 52 in the rough opening 20.
For interior installation applications, the embodiment of
A closure assembly, such as for example the closure assembly 330, optionally includes one or more securing members 602, shown in
Securing members 602 are employed to provide convenient securing of the closure assembly 330 within the rough opening 20 during installation. The securing members 602 are preferably attached to the closure assembly 330 at location remote from the rough opening 20 prior to installation of the closure assembly 330, such as a manufacturing factory. This embodiment permits the securing members 602 to be factory installed prior to the closure assembly 330 being shipped to the installation site. In other embodiments, however, the securing member(s) 602 are attached to the closure assembly 330 at the installation site.
The securing members 602 are preferably mounted proximate an interior portion of the closure assembly 330. In the embodiment of
In other embodiments, the securing member 602 does not change position. In one embodiment, in the insertion position, the securing member 602 extends from the perimeter of the closure assembly 330 in the interior plane of the closure assembly 330. In this position, the securing member 602 may function as a stop, preventing over insertion of the closure assembly 330 from the interior side 64 of the structure 22. In other embodiments, a separate accessory carried on the closure assembly 330 may function as a stop for installation from either the exterior side 65 or the interior side 64 of the structure 22.
Any of the closure assembly described herein may be installed in the rough opening 20 as shown in
A flashing member 608 is preferably applied over the jamb surface 30d. The flashing member 608 may be a foil backed flashing tape. Preferably, the flashing member 608 is longer than the length of the sill surface 30d so that the ends of the flashing member 608 extend up the jambs surfaces 30b and 30c (30c not visible) as well. The flashing member 608 is positioned partially forward of the plane of the rough opening 20 so that a portion of the flashing member 608 is located on the sill surface 30d and a portion of the flashing member 608 extends to the exterior side 65 of the structure 22.
The exterior portion of the flashing member 608 is folded down and away from the rough opening 20 over the water resistant barrier 28. As shown in
The preceding steps prepare the rough opening 20 to receive a closure assembly. Any of the closure assembly discussed above may be combined with other features disclosed herein, including for example the adjustable shims, securing members, sealing members, and the like. The closure assembly can be installed from either the exterior or interior.
In one embodiment of the present invention, as shown in
In one embodiment, the closure assembly is installed into the rough opening 20 from the interior side 64 of the structure 22. Where the securing member 602 are pre-installed on the closure assembly 52, the securing members 602 are folded from the shipping position to the installation position as illustrated in
The position of the securing member 602 in the installation position may be chosen such that the interior plane of the closure assembly 616 is flush or at a pre-selected position relative to the interior plane of the structure 22. In this manner, over insertion of the closure assembly may be reduced. This may also function as a safety feature, aiding in preventing the closure assembly from falling through the rough opening 20. Furthermore, the stop may provide a quick and easy method of aligning the interior plane of the closure assembly 616 with the interior plane of the structure 22.
The closure assembly 52 is then accurately positioned within the rough opening 20. This step may entail making adjustments to the position of the closure assembly, as shown in
In other embodiments, shims are inserted between closure frame and either or both of the sill surface 30D or jamb surface 30B, 30C (not shown). A combination of adjustable shims, block or wedge shims, or constant pressure shims may be used to accurately position the closure assembly within the rough opening. This step may further include adjusting the position of a shim relative to the closure assembly, for example, by sliding the shim along the frame to a selected location for engaging the structure 22.
The closure assembly is then secured in the rough opening 20 by engaging the securing member 602 with an interior surface of the rough opening 20. The securing member 602 may be deployed or opened from the insertion position to the attachment position for engaging the interior portion of the rough opening 20. The securing members 602 are attached to the structure 22 to hold the closure assembly 52 in place, as shown in
As illustrated in
Referring now to
In one embodiment, the upper portion 802A of the sealing member 802 is adhered to the sheathing 26 at the top of the rough opening 20, the header flap 606A having been previously folded away from the rough opening 20. The header flap 606A is then folded down to overlap the header sealing member 300a. This configuration provides a watershed arrangement whereby moisture is diverted to the exterior side of the closure assembly. The side portions and lower portion of the sealing member 802 are preferably attached to the water resistant barrier 28.
As shown in
In the embodiment illustrated in
As used herein, “primary structural attachment” refers to a mechanism that provides at least 50% of an attachment force that resists separation of the closure assembly 616 from the framing members 24 or composite panel along a direction generally perpendicular to a major surface of the structure 22. That is, the shear characteristics of the foam material 620 are substantially greater than the anticipated force F. In the preferred embodiment, the cured foam material 620 preferably provides about 70%, and more preferably about 80%, and most preferably about 95%, of the attachment force.
In another embodiment, the substantially cured foam material 620 provides the sole structural attachment between the closure assembly 52 and the framing members 24 or composite panel. As used herein, “sole structural attachment” refers to a mechanism that provides 100% of an attachment force that resists separation of a closure assembly 616 from the structure 22 along a direction generally perpendicular to a major surface of the structure 22, excluding any attachment force provided by the securing members 602, fins (not shown) or the sealing arrangement.
In another embodiment, nails, screws or bolts are driven through a portion of the closure assembly 616 into the structure 22. When the closure assembly 52 is secured to the structure 22, a different method of preparing the rough opening 20 to receive the closure assembly 52 may be employed. Rather than cutting the water resistant barrier 28 to correspond to the rough opening 20, the flaps 606A-D of water resistant barrier 28 are formed at the header, sill and jamb members 30A-D. The sill and jamb flaps 606B-D are folded toward the inside of the rough opening 20 so that they cover the sill and jamb surfaces 30B-30D of the rough opening 20. The sill and jamb flaps 606B-D are affixed to the structure 22, for example by stapling or adhering. In one embodiment, the ends of the flaps 606A-D are cut at approximately a 45° angle.
This configuration permits the flaps 606A-D to be folded inwardly without wrinkling the material of the moisture barrier 28. Flashing members 608 may be applied to the sill surface 30D over the sill flap 606D as previously described, and the watershed arrangement with the header flap 606A may be formed as previously described. The closure assembly 52 is then inserted into the rough opening 20 as previously described. This method is preferably employed when the closure assembly 616 is secured to the rough opening 20 by conventional means, for example, by nailing or bolting the closure assembly 52 to frame members 24 surrounding the rough opening 20, rather than with the curable foam 620.
As best illustrated in
Referring generally to FIGS. 1 and 22-23, in one embodiment, the drainage system 32 includes a channel assembly 46 and a moisture barrier 38 positioned on the sill plate 24A. The channel assembly 46 is located on the generally vertical surface 44 of the moisture barrier 38 generally in front of the sill plate 24A.
As will be discussed in detail below, the channel assembly 46 includes one or more channels 48A-48E (referred to collectively as “48”) that are configured to siphon water on the collection surface 42 from the channel entrance 45 in direction 50 and out a discharge opening 47 to a drainage area 40A. The channel assembly 46 is alternately a material that transports water from the collection surface 42 to the discharge opening 47, such as for example the polymeric foam and scrim sheathing disclosed in U.S. Pat. Nos. 6,536,176 (Nordgren et al.) and 7,100,337 (Nordgren et al.), which are hereby incorporated by reference. As used herein, “siphon” refers to conduit that uses the weight of a liquid to pull the liquid from the higher level to a lower level.
The channels 48 can be located anywhere along the width of the rough opening 20. Most water penetration, however, occurs between a closure assembly 52 and the vertical inner surfaces 30B, 30C of the rough opening 20. Water tends to concentrate on the collection surface 42 near the bottom corners 34, 36 of the rough opening 20. As used herein, the term “bottom corner” also refers to the intersection of a sill plate and a mullion separating adjacent closure assemblies, or the intersection of a sill plate and two vertical surfaces of adjacent closure assemblies. In the preferred embodiment, the channels 48 are concentrated near the bottom corners 34, 36. In one embodiment the channels 48A, 48B, 48C, 48D and 48E are located within a distance S from the bottom corners 34, 36. The distance S is preferably less than 4 inches, and more preferably less than 2 inches, and most preferably less than 1 inch.
Interior seal 62 is optionally located near an interior side 64 of the sill plate 24A to prevent water that collects in the gap 60 from migrating toward the interior 64 of the structure 22. In embodiments where the collection surface 42 is generally horizontal, the interior seal 62 is preferably included. Because the gap 60 is open to an exterior side 65 of the closure assembly 52 at least where any leaks are occurring, and likely through the channels 48 as well, the air pressure within the gap 60 will tend to be the same as the air pressure at the exterior side 65 of the closure assembly 52. The seal 62 isolates the gap 60 from air pressure on the interior side 64. This feature helps to ensure that the air pressure within the gap 60 is never lower than the air pressure on the exterior side 65, which could cause moisture to flow up the channels 48A-48E and into the gap 60.
The drainage system 32 removes moisture from the gap 60 in the following manner. As moisture teaks into the rough opening 20 from any location around the closure assembly 52, the moisture flows downwardly into the gap 60 under the force of gravity and collects on the collection surface 42. The collection surface 42 is water impermeable, so the sill plate 24A is protected from water damage.
Eventually, due to random accumulation and flow of moisture across the collection surface 42, or because the collection surface 42 is completely covered, moisture accumulates over the channel entrances 45. Surface tension in the water molecules will Coca time prevent the moisture from flowing down the channels 48A-48E. However, as moisture continues to accumulate, the weight of the water causes the water immediately adjacent the channel entrances 45 to flow down the channels 48 and out the discharge openings 47 into the drainage area 40A.
As water flows down the channels 48, a vacuum is created above the draining water, which draws more water down from the channel entrances 45, and so on. The negative or vacuum pressure of the descending water is strong enough to cause water on the collection surface 42 to be pulled towards the channel entrances 45. In this manner, moisture collecting on the collection surface 42 is removed to the drainage area 40A.
Because the channels 48 generate sufficient vacuum pressure to pull moisture from across the collection surface 42 towards the channel entrance 45, it is unnecessary for the collection surface 42 to be tilted or angled toward the channel assembly 46. Thus, a drainage system 32 in accordance with embodiments of the present invention does not require substantial modifications to the closure assembly 52 installation procedures, nor to the closure assembly 52 or rough opening 20, as previously described.
Various modifications and additions can be made to the exemplary embodiments discussed without departing from the scope of the present invention. For example, white the embodiments described above refer to particular features, the scope of this invention also includes embodiments having different combinations of features and embodiments that do not include all of the described features. Accordingly, the scope of the present invention is intended to embrace all such alternatives, modifications, and variations as fall within the scope of the claims, together with all equivalents thereof.
The present application is a continuation of U.S. patent application Ser. No. 12/014,531 entitled SELF SEALING WINDOW AND INSTALLATION METHOD, filed Jan. 15, 2008, which is a continuation-in-part of U.S. patent application Ser. No. 11/427,636 entitled WINDOW INSTALLATION METHOD, filed Jun. 29, 2006, now issued U.S. Pat. No. 7,669,382, and also claims the benefit of U.S. Provisional Application Ser. No. 60/975,450 entitled SELF-SEALING WINDOW AND INSTALLATION METHOD, filed on Sep. 26, 2007, all of which are hereby incorporated by reference in their entireties for all purposes.
Number | Date | Country | |
---|---|---|---|
60975450 | Sep 2007 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 12014531 | Jan 2008 | US |
Child | 13191197 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 11427636 | Jun 2006 | US |
Child | 12014531 | US |